Transcript for Nick Lane: Origin of Life, Evolution, Aliens, Biology, and Consciousness | Lex Fridman Podcast #318

This is a transcript of Lex Fridman Podcast #318 with Nick Lane. The timestamps in the transcript are clickable links that take you directly to that point in the main video. Please note that the transcript is human generated, and may have errors. Here are some useful links:

Table of Contents

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Introduction

Nick Lane (00:00:00) Well, the source of energy at the origin of life is the reaction between carbon dioxide and hydrogen. And amazingly, most of these reactions are exergonic, which is to say they release energy. If you have hydrogen and CO2, and you put them together in a Falcon tube and you warm it up to, say, 50 degrees centigrade, and you put in a couple of catalysts and you shake it, nothing’s going to happen. But thermodynamically that is less stable. Two gases, hydrogen and CO2, is less stable than cells. What should happen is you get cells coming out. Why doesn’t that happen is because of the kinetic barriers. That’s where you need the spark.
Lex Fridman (00:00:38) The following is a conversation with Nick Lane, a biochemist at University College London, and author of some of my favorite books on biology, science, and life ever written, including his two most recent titles, Transformer: The Deep Chemistry of Life and Death, and The Vital Question: Why Is Life the Way It Is? This is the Lex Fridman Podcast. To support it, please check out our sponsors in the description. And now, dear friends, here’s Nick Lane.

Origin of life

Lex Fridman (00:01:09) Let’s start with perhaps the most mysterious, the most interesting question that we little humans can ask of ourselves. How did life originate on earth?
Nick Lane (00:01:21) You could ask anybody working on the subject, and you’ll get a different answer from all of them. They will be pretty passionately held opinions, and they’re opinions grounded in science, but they’re still really at this point, they’re opinions. Because there’s so much stuff to know, that all we can ever do is get a small slice of it, and it’s the context which matters. So, I can give you my answer. My answer is, from a biologist’s point of view, that has been missing from the equation over decades, which is: well, what does life do on earth? Why is it this way? Why is it made of cells? Why is it made of carbon? Why is it powered by electrical charges on membranes? There’s all these interesting questions about cells, that if you then look to see: well, is there an environment on earth, on the early earth 4 billion years ago that kind of matches the requirements of cells?
(00:02:16) Well, there is one. There’s a very obvious one. It’s basically created by whenever you have a wet rocky planet, you get these hydrothermal vents, which generate hydrogen gas in bucket loads and electrical charges on kind of cell-like pores that can drive the kind of chemistry that life does. So, it seems so beautiful and so obvious, that I’ve spent the last 10 years or more trying to do experiments. It turns out to be difficult, of course. Everything’s more difficult than you ever thought it was going to be, but it looks, I would say, more true rather than less true over that ten-year period. I think I have to take a step back every now and then and think, “Hang on a minute. Where is this going?” I’m happy it’s going in a sensible direction.
(00:03:02) And I think then you have these other interesting dilemmas. I’m often accused of being too focused on life on earth, too kind of narrow-minded and inward looking, you might say. I’m talking about carbon, I’m talking about cells. And maybe you or plenty of people can say to me, “Oh, yeah, but life can be anything. I have no imagination.” And maybe they’re right, but unless we can say why life here is this way, and if those reasons are fundamental reasons or if they’re just trivial reasons, then we can’t answer that question. So, I think they’re fundamental reasons, and I think we need to worry about them.
Lex Fridman (00:03:40) Yeah, there might be some deep truth to the puzzle here on earth that will resonate with other puzzles elsewhere that will… solving this particular puzzle will give us that deeper truth. So, what do this puzzle… You said vents, hydrogen, wet. So, chemically, what is the potion here? How important is oxygen? You wrote a book about this.
Nick Lane (00:04:07) Yeah. And I actually just came straight here from a conference where I was chairing a session on whether oxygen matters or not in the history of life. Of course, it matters, but it matters most to the origin of life to be not there. As I see it, we have this… Life is made of carbon basically, primarily, organic molecules with carbon-carbon bonds. And the building block, the Lego brick that we take out of the air or take out of the oceans is carbon dioxide. And to turn carbon dioxide into organic molecules, we need to strap on hydrogen. And so we need… And this is basically what life is doing, it’s hydrogenating carbon dioxide. It’s taking the hydrogen that bubbles out of the earth in these hydrothermal vents, and it sticks it on CO2. And it’s kind of really as simple as that. And actually thermodynamically, the thing that I find most troubling is that if you do these experiments in the lab, the molecules you get are exactly the molecules that we see at the heart of biochemistry and the heart of life.
Lex Fridman (00:05:10) Is there something to be said about the earliest origins of that little potion, that chemical process? What really is the spark there?
Nick Lane (00:05:24) There isn’t a spark. There is a continuous chemical reaction. And there is kind of a spark, but it’s a continuous electrical charge, which helps drive that reaction.
Lex Fridman (00:05:37) So, literally spark.
Nick Lane (00:05:39) Well, the charge at least. But yes, a spark in that sense is… We tend to think in terms of Frankenstein. We tend to think in terms of electricity, and one moment you zap something and it comes alive. And what does that really mean? It’s come alive. And now what’s sustaining it? Well, we are sustained by oxygen, by this continuous chemical reaction. And if you put a plastic bag on your head, then you’ve got a minute or something before it’s all over.
Lex Fridman (00:06:07) So, it’s some way of being able to leverage a source of energy?
Nick Lane (00:06:11) Well, the source of energy at the origin of life is the reaction between carbon dioxide and hydrogen. And amazingly, most of these reactions are exergonic, which is to say they release energy. If you have hydrogen and CO2 and you put them together in a Falcon tube and you warm it up to say 50 degrees centigrade, and you put in a couple of catalysts and you shake it, nothing’s going to happen. But thermodynamically that is less stable, two gases, hydrogen and CO2, is less stable than cells. What should happen is you get cells coming out. So, why doesn’t that happen? It’s because of the kinetic barriers. That’s where you need the spark.
Lex Fridman (00:06:49) Is it possible that life originated multiple times on earth? The way you describe it, you make it sound so easy.
Nick Lane (00:06:57) There’s a long distance to go from those first bits of prebiotic chemistry to, say, molecular machines, like ribosomes.
Lex Fridman (00:07:05) Is that the first thing that you would say is life? If I introduce the two of you at a party, you would say that’s a living thing?
Nick Lane (00:07:15) I would say as soon as we introduce genes information into systems that are growing anyway, so I would talk about growing protocells, as soon as we introduce even random bits of information into there. I’m thinking about RNA molecules, for example. It doesn’t have to have any information in it. It can be completely random sequence, but if it’s introduced into a system which is in any case growing and doubling itself and reproducing itself, then any changes in that sequence that allow it to do so better or worse are now selected by perfectly normal natural selection.
Lex Fridman (00:07:51) But it’s a system-
Nick Lane (00:07:52) So, that’s when it becomes alive to my mind.
Lex Fridman (00:07:54) … that’s encompassed into an object, that keeps information, and evolves that information over time or changes that information over time.
Nick Lane (00:08:06) Yes, exactly.
Lex Fridman (00:08:06) In response to the enzymes.
Nick Lane (00:08:07) So, it’s always part of a cell system from the very beginning.
Lex Fridman (00:08:11) So, is your sense that it started only once because it’s difficult or is it possible it started in multiple occasions on earth?
Nick Lane (00:08:18) It’s possible it started multiple occasions. There’s two provisos to that. One of them is oxygen makes it impossible really for life to start. So, as soon as we’ve got oxygen in the atmosphere, then life isn’t going to keep starting over. So, I often get asked by people, “Why can’t we have life starting? If it’s so easy, why can’t life start in these vents now?” And the answer is, if you want hydrogen to react with CO2 and there’s oxygen there, hydrogen reacts with oxygen instead. You get an explosive reaction that way. It’s rocket fuel. So, it’s never going to happen. But for the origin of life earlier than that, all we know is that there’s a single common ancestor for all of life. There could have been multiple origins, and they all just disappeared.
(00:09:03) But there’s a very interesting deep split in life between bacteria and what are called archaea, which look just the same as bacteria. And they’re not quite as diverse, but nearly, and they are very different in their biochemistry. And so any explanation for the origin of life has to account, as well, for why they’re so different and yet so similar. And that makes me think that life probably did arise only once.
Lex Fridman (00:09:29) Can you describe the difference that’s interesting there, how they’re similar, how they’re different?
Nick Lane (00:09:34) Well, they’re different in their membranes primarily. They’re different in things like DNA replication. They use completely different enzymes, and the genes behind it for replicating DNA.
Lex Fridman (00:09:44) So, they both have membranes, both have DNA replication.
Nick Lane (00:09:48) Yes.
Lex Fridman (00:09:48) The process of that is different.
Nick Lane (00:09:51) They both have DNA. The genetic code is identical in them both. The way in which it’s transcribed into RNA, into the copy of a gene, and the way that that’s then translated into a protein, that’s all basically the same in both these groups, so they clearly share a common ancestor. It’s just that they’re different in fundamental ways as well. And if you think about, “Well, what kind of processes could drive that divergence very early on?” I can think about it in terms of membranes, in terms of the electrical charges on membranes, and it’s that makes me think that there were probably many unsuccessful attempts and only one really successful attempt.
Lex Fridman (00:10:30) Can you explain why that divergence makes you think there’s one common ancestor? Can you describe that intuition? I’m a little bit unclear about why the leap from the divergence means there’s one. Do you mean the divergence indicates that there was a big invention at that time from one source?
Nick Lane (00:10:50) Yes. As I imagine it, you have a common ancestor living in a hydrothermal vent. Let’s say there are millions of vents and millions of potential common ancestors living in all of those vents, but only one of them makes it out first. Then you could imagine that that cell is then going to take over the world and wipe out everything else. And so what you would see would be a single common ancestor for all of life, but with lots of different vent systems, all vying to create the first life forms, you might say.
Lex Fridman (00:11:25) So, this thing is a cell, a single-cell organism?
Nick Lane (00:11:28) Well, we’re always talking about populations of cells, but yes, these are single-celled organisms.
Lex Fridman (00:11:33) But the fundamental life form is a single cell. So, they’re always together, but they’re alone together. There’s a machinery in each one individual component, that if left by itself would still work, right?
Nick Lane (00:11:50) Yes, yes, yes. It’s the unit of selection is a single cell. But selection operates over generations and changes over generations in populations of cells, so it would be impossible to say that a cell is the unit of selection in the sense that unless you have a population, you can’t evolve, you can’t change.
Lex Fridman (00:12:07) Right, but there was one Chuck Norris, that’s an American reference, cell that made it out of the vents or the first one?
Nick Lane (00:12:19) So, imagine then that there’s one cell gets out and it takes over the world.
Lex Fridman (00:12:23) It gets out in the water. It’s floating around.
Nick Lane (00:12:25) Well, deep in the ocean somewhere. But actually two cells got out. And they appear to have got out from the same vent because they both share the same code and everything else. So unless all… We’ve got a million different common ancestors in all these different vents, so either they all have the same code, and two cells spontaneously emerged from different places, or two different cells, fundamentally different cells, came from the same place. So, either way, what are the constraints that say, “Not just one came out or not half a million came out, but two came out.”? That’s kind of a bit strange. So, how did they come out? Well, they come out because what you’re doing inside a vent is you’re relying on the electrical charges down there to power this reaction between hydrogen and CO2 to make yourself grow.
(00:13:17) And when you leave the vent, you’ve got to do that yourself. You’ve got to power up your own membrane. And so the question is: well, how do you power up your own membrane? And the answer is, well, you need to pump. You need to pump ions to give an electrical charge on the membrane. So, what do the pumps look like? Well, the pumps look different in these two groups. It’s as if they both emerge from a common ancestor, and as soon as you’ve got that ancestor, things move very quickly and divergently. Why does the DNA replication look different? Well, it’s joined to the membrane. The membranes are different. The DNA replication is different because it’s joined to a different kind of membrane. So, there’s interesting… This is detail you may say, but it’s also fundamental because it’s about the two big divergent groups of life on earth that seemed to have diverged really early on.
Lex Fridman (00:14:03) It all started from one organism, and then that organism just start replicating the heck out of itself with some mutation of the DNA. So, there’s a competition through the process of evolution. They’re not trying to beat each other up. They’re just trying to live life.
Nick Lane (00:14:24) They are just replicators.
Lex Fridman (00:14:25) Yeah. Well, let’s not minimize their… They’re just trying to chill. They’re trying to relax up in the… But there’s no sense of trying to survive. They’re replicating-
Nick Lane (00:14:36) There’s no sense in which they’re trying to do anything. They’re just kind of an outgrowth of the earth, you might say.
Lex Fridman (00:14:42) Of course, the aliens would describe us humans in that same way.
Nick Lane (00:14:46) They might be right.
Lex Fridman (00:14:47) It’s primitive life. It’s just ants that are hairless or mostly hairless.
Nick Lane (00:14:53) Overgrown ants.

Panspermia

Lex Fridman (00:14:54) Overgrown ants. Okay. What do you think about the idea of panspermia, the theory that life did not originate on earth and was planted here from outer space or pseudo-panspermia, which is like the basic ingredients, the magic that you mentioned was planted here from elsewhere in space?
Nick Lane (00:15:14) I don’t find them helpful. That’s not to say they’re wrong. So pseudo-transpermia, the idea that the chemicals, the amino acids, the nucleotides are being delivered from space. Well, we know that happens. It’s unequivocal. They’re delivered on meteorites, comets and so on. So, what do they do next? That’s, to me, the question. Well, what they do is they stock a soup, presumably they land in a pond or in an ocean or wherever they land. And then a best possible case scenario is you end up with a soup of nucleotides and amino acids. And then you have to say, “So now what happens?”
(00:15:46) And the answer is, “Oh, well, they have to go ‘bloop’ and become alive.” So, how did they do that? You may as well say that a miracle happened. I don’t believe in soup. I think what we have in a vent is a continuous conversion, a continuous growth, a continuous reaction, a continuous converting a flow of molecules into more of yourself, you might say, even if it’s a small bit. So, you’ve got a kind of continuous self-organization and growth from the very beginning. You never have that in a soup.
Lex Fridman (00:16:17) Isn’t the entire universe and living organisms in the universe, isn’t it just soup all the way down? Isn’t it all soup?
Nick Lane (00:16:26) No, no, soup almost by definition doesn’t have a structure.
Lex Fridman (00:16:29) But soup is a collection of ingredients that are randomly [inaudible 00:16:34].
Nick Lane (00:16:34) But they’re not random. We have chemistry going on here. We have membranes forming which are effectively oil-water interactions.
Lex Fridman (00:16:44) There’s a process going on. Okay, so it feels like there’s a direction to a… directed process.
Nick Lane (00:16:47) There are directions to processes, yeah. And if you’re starting with CO2, and you’ve got two reactive fluids being brought together and they react, what are they going to make? Well, they make carboxylic acids, which include the fatty acids that make up the cell membranes. And they form directly into bilayer membranes. They form like soap bubbles. It’s spontaneous organization caused by the nature of the molecules. And those things are capable of growing and are capable, in effect, of being selected. Even before there are genes, we have this. So, we have a lot of order, and that order is coming from thermodynamics. And the thermodynamics is always about increasing the entropy of the universe, but if you have oil and water and they’re separating, you are increasing the entropy of the universe, even though you’ve got some order, which is the soap and the water are not miscible.
(00:17:37) To come back to your first question about panspermia properly, that just pushes the question somewhere else, even if it’s true. Maybe life did start on Earth by panspermia, but so what are the principles that govern the emergence of life on any planet? It’s an assumption that life started here, and it’s an assumption that it started in a hydrothermal vent or it started in a terrestrial geothermal system. The question is: can we work out a testable sequence of events that would lead from one to the other one? And then test it, and see if there’s any truth in it or not. With panspermia, you can’t do any of that.
Lex Fridman (00:18:14) But the fundamental question of panspermia is: do we have the machine here on earth to build life?
Nick Lane (00:18:21) Not yet.
Lex Fridman (00:18:23) Is the vents enough? Is oxygen and hydrogen, and whatever the heck else we want, and some source of energy and heat, is that enough to build life?
Nick Lane (00:18:36) Yes.
Lex Fridman (00:18:37) Well, of course you would say that as a human, but there could be aliens right now chuckling at that idea. Maybe you need some special sauce, special elsewhere sauce. So, your sense is we have everything here.
Nick Lane (00:18:54) This is precisely the question. When I’m talking in schools, I like to start out with the idea of: we can make a time machine. We go back 4 billion years, and we go to these environments that people talk about. We go to a deep sea hydrothermal vent, we go to a kind of Yellowstone Park type place/environment, and we find some slime that looks like we can test it. It’s made of organic molecules. It’s got a structure which is not obviously cells, but is this a stepping stone on the way to life or not? How do we know? Unless we’ve got an intellectual framework that says, “This is a stepping stone, and that’s not a step…” We’d never know. We wouldn’t know which environment to go to, what to look for, how to say this. So, all we can ever hope for, because we’re never going to build that time machine, is to have an intellectual framework that can explain step by step, experiment by experiment, how we go from a sterile inorganic planet to living cells as we know them.
(00:19:52) And in that framework, every time you have a choice, it could be this way or it could be that way, or there’s lots of possible forks down that road, did it have to be that way? Could it have been the other way, and would that have given you life with very different properties? And so if you come up with… It’s a long hypothesis, because as I say, we’re going from really simple prebiotic chemistry all the way through to genes and molecular machines. That’s a long, long pathway. And nobody in the field would agree on the order in which these things happened, which is not a bad thing because it means that you have to go out and do some experiments and try and demonstrate that it’s possible or not possible.

What is life?

Lex Fridman (00:20:29) It’s so freaking amazing that it happened though. It feels like there’s a direction to the thing. Can you try to answer from a framework of: what is life? So, you said there’s some order and yet there’s complexity, so it’s not perfectly ordered, it’s not boring. There’s still some fun in it. And it also feels like the processes have a direction through the selection mechanism. They seem to be building something, always better, always improving. Maybe it’s-
Nick Lane (00:21:15) That’s a perception.
Lex Fridman (00:21:16) That’s our romanticization of things are always better. Things are getting better. We’d like to believe that.
Nick Lane (00:21:23) You think about the world from the point of view of bacteria, and bacteria are the first things to emerge from whatever environment they came from, and they dominated the planet very, very quickly, and they haven’t really changed. 4 billion years later they look exactly the same.
Lex Fridman (00:21:36) So, about 4 billion years ago, bacteria started to really run the show, and then nothing happened for a while?
Nick Lane (00:21:44) Nothing happened for 2 billion years. Then after 2 billion years, we see another single event, origin, if you like, of our own type of cell, the eukaryotic cells, so cells with a nucleus and lots of stuff going on inside. Another singular origin. It only happened once in the history of life on earth. Maybe it happened multiple times, and there’s no evidence everything just disappeared. But we have to at least take it seriously that there’s something that stops bacteria from becoming more complex, because they didn’t. That’s a fact, that they emerged 4 billion years ago, and something happened 2 billion years ago, but the bacteria themselves didn’t change. They remain bacterial. So, there is no necessary trajectory towards great complexity in human beings at the end of it. It’s very easy to imagine that without photosynthesis arising or without eukaryotes arising, that the planet could be full of bacteria and nothing else.
Lex Fridman (00:22:36) But we’ll get to that, because that’s a brilliant invention, and there’s a few brilliant inventions along the way. But what is life? If you were to show up on earth, but take that time machine, and you said, asking yourself the question, “Is this a stepping stone towards life?” As you step along when you see the early bacteria, how would you know it’s life? And then this is a really important question when you go to other planets and look for life: what is the framework of telling a difference between a rock and a bacteria?
Nick Lane (00:23:12) The question’s kind of both impossible to answer and trivial at the same time. And I don’t like to answer it because I don’t think there is an answer. I think we’re trying to describe-
Lex Fridman (00:23:22) Those are the most fun questions. What do you mean, there’s no answer?
Nick Lane (00:23:24) There is no answer. There’s lot… There are at least 40 or 50 different definitions of life out there, and most of them are, well-
Lex Fridman (00:23:31) Not convincing.
Nick Lane (00:23:32) … obviously bad in one way or another. I can never remember the exact words that people use, but there’s NASA working definition of life, which more or less says, “A self-sustaining system capable of evolution,” or something along those lines. And I immediately have a problem with the words self-sustaining, because it’s sustained by the environment. And I know what they’re getting at. I know what they’re trying to say, but I pick a hole in that. And there’s always wags who say, “But by that definition, a rabbit is not alive. Only a pair of rabbits would be alive because a single rabbit is incapable of copying itself.” There are all kinds of pedantic, silly, but also important objections to any hypothesis.
(00:24:19) The real question is: what is… We can argue all day, or people do argue all day about: is a virus alive or not? And it depends on the content. In fact, most biologists could not agree about that. So, then what about a jumping gene, a retro element or something like that? It’s even simpler than a virus, but it’s capable of converting its environment into a copy of itself. And that’s about as close… This is not a definition, but this is a kind of description of life, is that it’s able to parasitize the environment, and that goes for plants as well as animals and bacteria and viruses, to make a relatively exact copy of themselves, informationally exact copy of themselves.
Lex Fridman (00:25:04) By the way, it doesn’t really have to be a copy of itself, it just has to be… you have to create something that’s interesting. The way evolution is, so it is extremely powerful process of evolution, which is basically make a copy of yourself and sometimes mess up a little bit.
Nick Lane (00:25:24) Yes. Absolutely.
Lex Fridman (00:25:25) Okay. That seems to work really well. I wonder if it’s possible to-
Nick Lane (00:25:28) Mess up big time?
Lex Fridman (00:25:29) Mess up big time as a standard, as the default.
Nick Lane (00:25:32) It’s called the hopeful monster, and-
Lex Fridman (00:25:34) It doesn’t work?
Nick Lane (00:25:36) In principle, it can. Actually, it turns out, I would say that this is due a reemergence. There’s some amazing work from Michael Levin. I don’t know if you came across him, but if you haven’t interviewed him, you should interview him.
Lex Fridman (00:25:49) Yeah, in Boston. I’m talking to him in a few days.
Nick Lane (00:25:53) Oh, fantastic.
Lex Fridman (00:25:56) So I mentioned off… There’s two people that, if I may mention. Andrej Karpathy is a friend who’s really admired in the AI community, said, “You absolutely must talk to Michael and to Nick.” So, of course I’m a huge fan of yours, so I’m really fortunate that we can actually make this happen. Anyway, you were saying.
Nick Lane (00:26:16) Well, Michael Levin is doing amazing work basically about the way in which electrical fields control development. And he’s done some work with Planarian worms or flatworms, where he’ll tell you all about this, so I won’t say any more than the minimum, but basically you can cut their head off and they’ll redevelop a new head. But the head that they develop depends. If you knock out just one iron pump in a membrane, so you change the electrical circuitry just a little bit, you can come up with a completely different head. It can be a head which is similar to those that diverged 150 million years ago or it can be a head which no one’s ever seen before, a different kind of head. Now that is really, you might say, a hopeful monster.
(00:26:59) This is a kind of leap into a different direction. The only question for natural selection is: does it work? Is the change itself feasible as a single change? And the answer is yes. It’s just a small change to a single gene. And the second thing is it gives rise to a completely different morphology. Does it work? And if it works, that can easily be a shift. But for it to be a speciation, for it to continue, for it to give rise to a different morphology over time, then it has to be perpetuated. So that shift, that change in that one gene has to work well enough that it is selected and it goes on.
Lex Fridman (00:27:41) And copied enough times to where you can really test it.
Nick Lane (00:27:44) So, the likelihood it would be lost, but there’ll be some occasions where it survives. And yes, the idea that we can have sudden fairly abrupt changes in evolution, I think it’s time for rebirth.
Lex Fridman (00:27:54) What about this idea that… kind of trying to mathematize a definition of life and saying how many steps… the shortest amount of steps it takes to build the thing, almost like an engineering view of it? Do you find that at all compelling?
Nick Lane (00:28:10) I like that view, because I think that, in a sense, that’s not very far away from what a hypothesis needs to do to be a testable hypothesis for the origin of life. You need to spell out, here’s each step and here’s the experiment to do for each step. The idea that we can do it in the lab, some people say, “Oh, we’ll have created life within five years.” But ask them what they mean by life. We have a planet 4 billion years ago with these vent systems across the entire surface of the planet, and we have millions of years if we want it. I have a feeling that we’re not talking about millions of years. I have a feeling we’re talking about maybe millions of nanoseconds or picoseconds. We’re talking about chemistry, which is happening quickly.
(00:28:53) But we still need to constrain those steps, but we’ve got a planet doing similar chemistry. You asked about a trajectory. The trajectory is the planetary trajectory. The planet has properties. It’s basically… It’s got a lot of iron at the center of it, it’s got a lot of electrons at the center of it. It’s more oxidized on the outside, partly because of the sun, and partly because the heat of volcanoes puts out oxidized gases. So, the planet is a battery. It’s a giant battery. And we have a flow of electrons going from inside to outside in these hydrothermal vents, and that’s the same topology that a cell has. A cell is basically just a micro-version of the planet.
(00:29:34) And there is a trajectory in all of that, and there’s an inevitability that certain types of chemical reaction are going to be favored over others. And there’s an inevitability in what happens in water, the chemistry that happens in water. Some will be immiscible with water and will form membranes and will form insoluble structures. Water’s a… Nobody really understands water very well. And it’s another big question for experiments on the origin of life: what do you put it in? What kind of structure do we want to induce in this water? Because the last thing it’s likely to be is just kind of bulk water.
Lex Fridman (00:30:11) How fundamental is water to life, would you say?
Nick Lane (00:30:14) I would say pretty fundamental. I wouldn’t like to say it’s impossible for life to start any other way, but water is everywhere. Water’s extremely good at what it does, and carbon works in water especially well. And carbon is everywhere. So, those things together make me think probabilistically, if we found 1,000 life forms, 995 of them would be carbon-based and living in water.
Lex Fridman (00:30:42) Now the reverse question. If you found a puddle of water elsewhere and some carbon… No, just a puddle of water. Is a puddle of water a pretty good indication that life either exists here or has once existed here?
Nick Lane (00:31:00) No.
Lex Fridman (00:31:02) So, it doesn’t work the other way.
Nick Lane (00:31:05) I think you need a living planet. You need a planet which is capable of turning over its surface. It needs to be a planet with water. It needs to be capable of bringing those electrons from inside to the outside. It needs to turn over its surface. It needs to make that water work and turn it into hydrogen. So, I think you need a living planet, but once you’ve got the living planet, I think the rest of it is kind of thermodynamics all the way.
Lex Fridman (00:31:29) So, if you were to run Earth over a million times up to this point, maybe beyond, to the end, let’s run it to the end, how much variety is there? You kind of spoke to this trajectory, that the environment dictates chemically, I don’t know in which other way, spiritually, dictates the direction of this giant machine, that seems chaotic, but it does seem to have order in-
Lex Fridman (00:32:00) … seems chaotic, but it does seem to have order in the steps it’s taking. How often will bacteria emerge? How often will something like humans emerge? How much variety do you think there would be?
Nick Lane (00:32:15) I think at the level of bacteria, not much variety. I think we would get how many times you say you want to run it a million times? I would say at least a few hundred thousand will get bacteria again.
Lex Fridman (00:32:28) Oh, wow. Nice.
Nick Lane (00:32:29) Because I think there’s some level of inevitability that a wet, rocky planet will give rise through the same processes to something very… I think this is not something I would have thought a few years ago, but working with a PhD student of mine, Stuart Harrison, he’s been thinking about the genetic code and we’ve just been publishing on that. There are patterns that he has discerned in the code that if you think about them in terms of we start with CO2 and hydrogen and these are the first steps of biochemistry, you come up with a code which is very similar to the code that we see.
(00:33:03) So, it wouldn’t surprise me any longer if we found life on Mars and it had a genetic code that was not very different to the genetic code that we have here without it just being transferred across, there’s some inevitability about the whole of the beginnings of life, in my view.
Lex Fridman (00:33:18) That’s really promising because if the basic chemistry is tightly linked to the genetic code, that means we can interact with other life if it exists out there.
Nick Lane (00:33:30) Well, that’s potentially the guess, yes.
Lex Fridman (00:33:32) That’s really exciting if that’s the case. Okay. But then bacteria-
Nick Lane (00:33:36) Then we’ve got bacteria.
Lex Fridman (00:33:37) Yeah.
Nick Lane (00:33:39) How easy is photosynthesis? Much harder, I would say.

Photosynthesis

Lex Fridman (00:33:44) Let’s actually go there. Let’s go through the inventions.
Nick Lane (00:33:47) Yeah.
Lex Fridman (00:33:49) What is photosynthesis and why is it hard?
Nick Lane (00:33:52) Well, there are different forms. I mean, basically you’re taking hydrogen and you’re sticking it onto CO2 and it’s powered by the sun. The question is where are you taking the hydrogen from? And in photosynthesis that we know in plants, it’s coming from water. So you’re using the power of the sun to split water, take out the hydrogen, stick it onto CO2, and the oxygen is a waste product and you just throw it out, throw it away. So it’s the single greatest planetary pollution event in the whole history of the earth.
Lex Fridman (00:34:21) The pollutant being oxygen?
Nick Lane (00:34:22) Yes. Yeah. It also made possible animals, you can’t have large active animals without an oxygenated atmosphere, at least not in the sense that we know on earth.
Lex Fridman (00:34:33) So that’s a really big invention in the history of earth.
Nick Lane (00:34:35) Huge invention, yes. And it happened once, there’s a few things that happened once on earth and you’re always stuck with this problem once it happened, did it become so good so quickly that it precluded the same thing happening ever again? Or are there other reasons? And we really have to look at each one in turn and think, “Why did it only happen once?” In this case, it’s really difficult to split water, it requires a lot of power and that power you’re effectively separating charge across a membrane. And the way in which you do it, if it doesn’t all rush back and kind of cause an explosion right at the site requires really careful wiring.
(00:35:11) And that wiring, it can’t be easy to get it right because the plants that we see around us, they have chloroplasts. Those chloroplasts were cyanobacteria ones. Those cyanobacteria are the only group of bacteria that can do that type of photosynthesis, so there’s plenty of opportunity but-
Lex Fridman (00:35:29) There’s not many bacteria. So who invented photosynthesis?
Nick Lane (00:35:31) The cyanobacteria or their ancestors.
Lex Fridman (00:35:34) And there’s not many-
Nick Lane (00:35:36) No other bacteria can do what’s called oxygenic photosynthesis. Lots of other bacteria can split. I mean, you can take your hydrogen from somewhere else, you can take it from hydrogen sulphide bubbling out of a hydrothermal vent, grab your two hydrogens, the sulphur is the waste now.
(00:35:52) You can do it from iron, you can take electrons… So the early oceans, were probably full of iron, you can take an electron from ferrous iron, so Iron 2+ and make it Iron 3+, which now precipitates as rust, and you take a proton from the acidic early ocean, stick it there now you’ve got a hydrogen atom, stick it onto CO2, you’ve just done the trick. The trouble is you bury yourself in rusty iron and with sulphur can bury yourself in sulphur. One of the reasons oxygenic photosynthesis is so much better is that the waste product is oxygen, which just bubbles away.
Lex Fridman (00:36:26) That seems extremely unlikely and it’s extremely essential for the evolution of complex organisms because of all the oxygen.
Nick Lane (00:36:36) Yeah, and that didn’t accumulate quickly either.
Lex Fridman (00:36:39) So it’s converting, what is it? It’s converting energy from the sun and the resource of water into the resource needed for animals?
Nick Lane (00:36:50) Both resources needed for animals. We need to eat and we need to burn the food, and we’re eating plants which are getting their energy from the sun and we’re burning it with their waste product, which is the oxygen. So there’s a lot of circularity in that, but without an oxygenated planet, you couldn’t really have predation. You can have animals, but you can’t really have animals that go around and eat each other. You can’t have ecosystems as we know them.

Prokaryotic vs eukaryotic cells

Lex Fridman (00:37:19) Well, let’s actually step back. What about eukaryotic versus prokaryotic cells, prokaryotes, what are each of those and how big of an invention is that?
Nick Lane (00:37:31) I personally think that’s the single biggest invention in the whole history of life.
Lex Fridman (00:37:34) Exciting. So what are they? Can you explain?
Nick Lane (00:37:39) Yeah. So I mentioned bacteria and archaea, these are both prokaryotes. They’re basically small cells that don’t have a nucleus. If you look at them under a microscope, you don’t see much going on. If you look at them under a super resolution microscope, then they’re fantastically complex. In terms of their molecular machinery, they’re amazing. In terms of their morphological appearance under a microscope, they’re really small and really simple.
(00:38:03) The earliest life that we can physically see on the planet are stromatolites, which are made by things like cyanobacteria and they’re large superstructures, effectively biofilms plated on top of each other, and you end up with quite large structures that you can see in the fossil record. But they never came up with animals, they never came up with plants, they came up with multicellular things filamentous cyanobacteria for example, they’re just long strings of cells. But the origin of the eukaryotic cell seems to have been what’s called an endosymbiosis so one cell gets inside another cell, and I think that that transformed the energetic possibilities of life. So what we end up with is a kind of supercharged cell, which can have a much larger nucleus with many more genes all supported.
(00:38:54) You could think about it as multi-bacterial power without the overhead. So you’ve got a cell and it’s got bacteria living in it, and those bacteria are providing it with the energy currency it needs. But each bacterium has a genome of its own, which costs a fair amount of energy to express, to turn over and convert into proteins and so on. What the mitochondria did, which are these power packs in our own cells, they were bacteria once and they threw away virtually all their genes, they’ve only got a few left.
Lex Fridman (00:39:25) So mitochondria is, like you said, is the bacteria that got inside a cell and then throw away all this stuff it doesn’t need to survive inside the cell and then kept what?
Nick Lane (00:39:35) So what we end up with, so it kept always a handful of genes in our own case, 37 genes, but there’s a few protists which are single-celled things that have got as many as 70 or 80 genes so it is not always the same, but it’s always a small number. And you can think of it as a pared-down power pack where the control unit has really been kind pared down to almost nothing. So it’s putting out the same power, but the investment in the overheads is really pared down, that means that you can support a much larger nuclear genome. So we’ve gone up in the number of genes, but also the amount of power you have to convert those genes into proteins. We’ve gone up about fourfold in the number of genes, but in terms of the size of genomes and your ability to make the building blocks, make the proteins, we’ve gone up a hundred thousand fold or more, so it’s huge step change in the possibilities of evolution.
(00:40:29) And it is interesting then that the only two occasions that complex life has arisen on earth, plants and animals, fungi you could say are complex as well, but they don’t form such complex morphology as plants and animals, start with a single cell they start with an oocyte and a sperm fused together to make a zygote. So we start development with a single cell and all the cells in the organism have identical DNA, and in the brain, you switch off these genes and you switch on those genes and the liver, you switch off those and you switch on a different set. And the standard evolutionary explanation for that is that you’re restricting conflict, you don’t have a load of genetically different cells that are all fighting each other and so it works.
(00:41:14) The trouble with bacteria is they form these biofilms and they’re all genetically different, and effectively they’re incapable of that level of cooperation they would get in a fight.
Lex Fridman (00:41:26) Okay, so why is this such a difficult invention of getting this bacteria inside and becoming an engine, which the mitochondria is? Why do you assign it such great importance? Is it great importance in terms of the difficulty of how it was to achieve or great importance in terms of the impact it had on life?
Nick Lane (00:41:46) Both. It had a huge impact on life because if that had not happened, you can be certain that life on earth would be bacterial only.
Lex Fridman (00:41:56) And that took a really long time to-
Nick Lane (00:41:58) It took 2 billion years and it hasn’t happened since to the best of our knowledge, so it looks as if it’s genuinely difficult. And if you think about it then from just an informational perspective, you think bacteria, they structure their information differently. So a bacterial cell has a small genome, you might have 4,000 genes in it. But a single E. coli cell has access to about 30,000 genes, potentially. It’s got a metagenome where other E. coli out there have got different gene sets and they can switch them around between themselves. And so you can generate a huge amount of variation, and they’ve got more. An E. coli. metagenome is larger than the human genome, we own 20,000 genes or something, and they’ve had 4 billion years of evolution to work out what can I do and what can’t I do with this metagenome. And the answer is, you’re stuck, you’re still bacteria.
(00:42:54) So they have explored genetic sequence space far more thoroughly than eukaryotes ever did because they’ve had twice as long at least, and they’ve got much larger populations, and they never got around this problem. So why can’t they? It seems as if you can’t solve it with information alone. So what’s the problem? The problem is structure.
(00:43:16) If the very first cells needed an electrical charge on their membrane to grow, and in bacteria it’s the outer membrane that surrounds the cell, which is electrically charged, you try and scale that up and you’ve got a fundamental design problem, you’ve got an engineering problem, and there are examples of it. And what we see in all these cases is what’s known as extreme polyploidy, which is to say they have tens of thousands of copies of their complete genome, which is energetically hugely expensive, and you end up with a large bacteria with no further development. What you is to incorporate these electrically charged power pack units inside with their control units intact, and for them not to conflict so much with the host cell that it all goes wrong, perhaps it goes wrong more often than not, and then you change the topology of the cell.
(00:44:10) Now, you don’t necessarily have any more DNA than a giant bacterium with extreme polyploidy, but what you’ve got is an asymmetry. You now have a giant nuclear genome surrounded by lots of subsidiary energetic genomes they’re the control units that are doing all the control of energy generation.
Lex Fridman (00:44:32) Could this have been done gradually or does it have to be done, the power pack has to be all intact and ready to go and working?
Nick Lane (00:44:40) I mean, it’s a kind of step changing in the possibilities of evolution, but it doesn’t happen overnight. It’s going to still require multiple, multiple, generations. So it could take millions of years, it could take shorter time there’s another thing I would like to put the number of steps and try and work out what’s required at each step and we are trying to do that with sex, for example. You can’t have a very large genome unless you have sex at that point so what are the changes to go from bacterial recombination to eukaryotic recombination? What do you need to do? Why do we go from passing around bits of DNA as if it’s loose change to fusing cells together, lining up the chromosomes, recombining across the chromosomes, and then going through two rounds of cell division to produce your gametes? All eukaryotes do it that way.
(00:45:24) So again, why switch? What are the drivers here? So there’s a lot of time, there’s a lot of evolution, but as soon as you’ve got cells living inside another cell, what you’ve got is a new design, you’ve got new potential that you didn’t have before.
Lex Fridman (00:45:39) So the cell living inside another cell, that design allows for better storage of information, better use of energy, more delegation, like a hierarchical control of the whole thing. And then somehow that leads to ability to have multi-cell organisms?
Nick Lane (00:46:00) I’m not sure that you have hierarchical control necessarily, but you’ve got a system where you can have a much larger information storage depot in the nucleus, you can have a much larger genome. And that allows multi-cellularity, yes, because it allows you… It’s a funny thing, to have an animal where I have 70% of my genes switched on in my brain and a different 50% switched on in my liver or something, you’ve got to have all those genes in the egg cell at the very beginning, and you’ve got to have a program of development which says, “Okay, you guys switch off those genes and switch on those genes, and you guys you do that.” But all the genes are there at the beginning. That means you’ve got to have a lot of genes in one cell and you’ve got to be able to maintain them and the problem with bacteria is they don’t get close to having enough genes in one cell. So if you were to try make a multicellular organism from bacteria, you’d bring different types of bacteria together and hope they’ll cooperate and the reality is they don’t.
Lex Fridman (00:46:58) That’s really, really tough to do, combinatorially.
Nick Lane (00:47:00) We know they don’t because it doesn’t exist.
Lex Fridman (00:47:02) We have the data as far as we know. I’m sure there’s a few special ones and they die off quickly. I’d love to know some of the most fun things bacteria have done since?
Nick Lane (00:47:12) Oh, I mean, they can do some pretty funky things. This is broad brushstroke that I’m talking about, but it’s, yeah.

Sex

Lex Fridman (00:47:19) Generally speaking. So another fun invention, us humans seem to utilize it well, but you say it’s also very important early on is sex. So what is sex? Just asking for a friend. And when was it invented and how hard was it to invent, just as you were saying, and why was it invented? How hard was it? And when?
Nick Lane (00:47:45) I have a PhD student who’s been working on this-
Lex Fridman (00:47:45) On sex?
Nick Lane (00:47:47) … and we’ve just published a couple of papers. On sex, yes, yes, yes.
Lex Fridman (00:47:50) Nice. Where do you publish these? Is it biology, genetics, journals?
Nick Lane (00:47:55) This is actually PNAS, which is Proceedings of the National Academy of Sciences.
Lex Fridman (00:48:00) So like, broad, big, big picture stuff?
Nick Lane (00:48:02) Everyone’s interested in sex.
Lex Fridman (00:48:03) Yeah.
Nick Lane (00:48:04) The job of biologist is to make sex dull.
Lex Fridman (00:48:08) Yeah, that’s a beautiful way to put it. Okay, so when was it invented?
Nick Lane (00:48:13) It was invented with eukaryotes about 2 billion years ago. All eukaryotes share the same basic mechanism that you produce gametes, the gametes fuse together. So a gamete is the egg cell and the sperm, they’re not necessarily even different in size or shape. So the simplest eukaryotes produce what are called motile gametes, they’re all like sperm and they all swim around, they find each other, they fuse together, they don’t have much going on there beyond that. And then these are haploids, which is to say we all have two copies of our genome, and the gametes have only a single copy of the genome. So when they fuse together, you now become diploid again, which is to say you now have two copies of your genome, and what you do is you line them all up and then you double everything.
(00:49:01) So now we have four copies of the complete genome, and then we crisscross between all of these things. So we take a bit from here and stick it on there and a bit from here, and we stick it on here, that’s recombination. Then we go through two rounds of cell division. So we divide in half, so now the two daughter cells have two copies and we divide in half again, now we have some gametes, each of which has got a single copy of the genome. And that’s the basic ground plan for what’s called meiosis and syn-gametes, that’s basically sex.
(00:49:31) And it happens at the level of single-celled organisms and it happens pretty much the same way in plants and pretty much the same way in animals and so on. And it’s not found in any bacteria, they switch things around using the same machinery and they take up a bit of DNA from the environment. They take out this bit and stick in that bit, and it’s the same molecular machinery they’re using to do it.
Lex Fridman (00:49:50) So what about the, you said find each other this kind of imperative to find each other. What is that?
Nick Lane (00:49:58) Well, you’ve got a fuse cells together. So the bottom line on all of this is bacteria, I mean, it’s kind of simple when you’ve figured it out and figuring it out this is not me, this is my PhD student, Marco Colnaghi. And in effect, if you’re doing lateral, you’re E. coli cell, you’ve got 4,000 genes, you want to scale up to a eukaryotic size. I want to have 20,000 genes and I need to maintain my genome so it doesn’t get shot to pieces by mutations, and I’m going to do it by lateral gene transfer.
(00:50:32) So I know I’ve got a mutation in a gene, I don’t know which gene it is because I’m not sentient, but I know I can’t grow, I know all my regulation systems are saying, “Something wrong here, something wrong, pick up some DNA, pick up a bit of DNA from the environment.” If you’ve got a small genome, the chances of you picking up the right bit of DNA from the environment is much higher than if you’ve got a genome of 20,000 genes. To do that, you’ve effectively got to be picking up DNA all the time, all day long and nothing else, and you’re still going to get the wrong DNA. You’ve got to pick up large chunks, and in the end, you’ve got to line them up, you’re forced into sex, to coin a phrase.
Lex Fridman (00:51:10) So there is a kind of incentive-
Nick Lane (00:51:18) If you want to have a large genome, you’ve got to prevent it mutating to nothing and that will happen with bacteria, so there’s another reason why bacteria can’t have a large genome. But as soon as you give eukaryotic cells the power pack that allows them to increase the size of their genome, then you face the pressure that you’ve got to maintain its quality. You’ve got to stop it just mutating away.
Lex Fridman (00:51:38) What about sexual selection? So the finding like, “I don’t like this one. I don’t like this one. This one seems all right.” At which point does it become less random?
Nick Lane (00:51:52) It’s hard to know.
Lex Fridman (00:51:54) Because eukaryotes just kind of float around just kind of have… It’s kind of like Tinder these days.
Nick Lane (00:51:59) Yeah I mean, it’s their sexual section election in single-celled eukaryotes. There probably is, it’s just that I don’t know very much about it. By the time we-
Lex Fridman (00:51:59) You don’t hang out with eukaryotes?
Nick Lane (00:52:06) Well, I do all the time, but you know?
Lex Fridman (00:52:07) You can’t communicate with them, yeah.
Nick Lane (00:52:08) Yeah. Peacock or something.
Lex Fridman (00:52:11) Yes.
Nick Lane (00:52:13) The kind of standard, this is not quite what I work on, but the standard answer is that it’s female mate choice, she’s looking for good genes and if you can have a tail that’s like this and still survive, still be alive, not actually have been taken down by the nearest predator, then you must’ve got pretty good genes despite this handicap you are able to survive.
Lex Fridman (00:52:36) So those are human interpretable things like with a peacock. But I wonder, I’m sure echoes of the same thing are there with more primitive organisms, basically your PR, like how you advertise yourself that you’re worthy of? Yeah,
Nick Lane (00:52:54) Absolutely.
Lex Fridman (00:52:54) So one big advertisement is the fact that you survived it all.
Nick Lane (00:52:57) Yeah, let me give you one beautiful example of an algal bloom, and this can be a sign of bacteria, this can be in bacteria. So if suddenly you pump nitrate or phosphate or something into the ocean and everything goes green, you end up with all this algae growing there, a viral infection or something like that can kill the entire bloom overnight. And it’s not that the virus takes out everything overnight, it’s that most of the cells in that bloom kill themselves before the virus can get onto them. And it’s through a form of cell death called programmed cell death. And we do the same thing, this is how we have the gaps between our fingers and so on, it’s how we craft synapses in the brain. It is fundamental again, to multicellular life.
(00:53:47) They have the same machinery in these algal blooms. How do they know who dies? The answer is they will often put out a toxin and that toxin is a kind of challenge to you. Either you can cope with the toxin or you can’t. If you can cope with it, you form a spore and you will go on to become the next generation. You form kind of a resistant spore, you sink down a little bit, you get out of the way, you can’t be attacked by a virus if you’re a spore or at least not so easily. Whereas if you can’t deal with that toxin, you pull the plug and you trigger your death apparatus and you kill yourself.
Lex Fridman (00:54:27) It’s truly life and death selection.
Nick Lane (00:54:29) Yeah, so it’s a challenge, and this is a bit like sexual selection. They’re all pretty much genetically identical, but they’ve had different life histories. So have you had a tough day? Did you happen to get infected by this virus? Or did you run out of iron? Or did you get a bit too much sun? Whatever it may be. If this extra stress of the toxin just pushes you over the edge, then you have this binary choice, either you’re the next generation or you kill yourself now using this same machinery.

DNA

Lex Fridman (00:54:57) It’s also actually exactly the way I approach dating, but that’s probably why I am single. Okay. What about, if we can step back, DNA just mechanism of storing information, RNA, DNA, how big of an invention was that? That seems to be fundamental to something deep within what life is, is the ability, as you said, to kind of store and propagate information. But then you also kind of inferred that with you and your students’ work, that there’s a deep connection between the chemistry and the ability to have this kind of genetic information. So how big of an invention is it to have a nice representation, a nice hard drive for info to pass on?
Nick Lane (00:55:46) Huge, I suspect. I mean, but when I was talking about the code, you see the code in RNA as well, and RNA almost certainly came first. And there’s been an idea going back decades called the RNA world because RNA in theory can copy itself and can catalyze reactions. So it kind of cuts out this chicken and egg loop.
Lex Fridman (00:56:07) The DNA, it’s possible is not that special?
Nick Lane (00:56:09) So RNA is the thing that does the work really, and the code lies in RNA. The code lies in the interactions between RNA and amino acids and it still is there today in the ribosome, for example, which is just kind of a giant ribozyme, which is to say it’s an enzyme that’s made of RNA.
(00:56:28) So getting to RNA, I suspect is probably not that hard. But getting from RNA, there’s multiple different types of RNA now, how do you distinguish? This is something we’re actively thinking about, how do you distinguish between a random population of RNA? Some of them go on to become messenger RNA, this is the transcript of the code of the gene that you want to make. Some of them become transfer RNA, which is kind of the unit that holds the amino acid that’s going to be polymerized. Some of them become ribosomal RNA, which is the machine, which is joining them all up together.
(00:57:07) How do they discriminate themselves? There’s some kind of phase transition going on there, I don’t know, it’s a difficult question and we’re now in the region of biology where information is coming in. But the thing about RNA is very, very good at what it does but the largest genomes supported by RNA are RNA viruses like HIV, for example. They’re pretty small. And so there’s a limit to how complex life could be unless you come up with DNA, which chemically is a really small change but how easy it is to make that change? I don’t really know. As soon as you’ve got DNA, then you’ve got an amazingly stable molecule for information storage, and you can do absolutely anything. But how likely that transition from RNA to DNA was? I don’t know either.
Lex Fridman (00:57:54) How much possibility is there for variety in ways to store information? It seems to be very, there’s specific characteristics about the programming language of DNA.
Nick Lane (00:58:06) Yeah, there’s a lot of work going on on what’s called the Xeno DNA or RNA. Can we replace the bases themselves, the letters if you like, in RNA or DNA? Can we replace the backbone? Can we replace, for example, phosphate with arsenate? Can we replace the sugar ribose or deoxyribose with a different sugar? And the answer is yes, you can within limits there’s not an infinite space there. Arsenate doesn’t really work if the bonds are not as strong as phosphate, it’s probably quite hard to replace phosphate. It’s possible to do it.
(00:58:43) The question to me is, why is it this way? Is it because there was some form of selection that this is better than the other forms and there were lots of competing forms of information storage early on, and this one was the one that worked out? Or was it kind of channeled that way, that these are the molecules that you’re dealing with and they work? And I’m increasingly thinking it’s that way that we’re channeled towards ribose phosphate and the bases that are used, but there are 200 different letters kicking around out there that could have been used.
Lex Fridman (00:59:17) It’s such an interesting question. If you look at, in the programming world in computer science, there’s a programming language called JavaScript, which was written super quickly, it’s a giant mess, but it took over the world.
Nick Lane (00:59:30) Sounds very biological.
Lex Fridman (00:59:31) It was kind of a running joke that surely this can’t be… This is a terrible programming language, it’s a giant mess. It’s full of bugs, it’s so easy to write really crappy code but it took over all of front end development in the web browser. If you have any kind of dynamic interactive website, it’s usually running JavaScript and it’s now taking over much of the backend, which is the serious heavy duty computational stuff. And it’s become super fast with the different compilation engines that are running it, so it really took over the world. It’s very possible that this initially crappy derided language actually takes everything over.
(01:00:14) And then the question is, did human civilization always strive towards JavaScript or was JavaScript just the first programming language that ran on the browser and still sticky? The first is the sticky one, and so it wins over anything else because it was first. And I don’t think that’s answerable, right? But it’s good to ask that. I suppose in the lab you can’t run it with programming languages, but in biology you can probably do some kind of small scale evolutionary test to try to infer which is which?
Nick Lane (01:00:54) Yeah, I mean, in a way, we’ve got the hardware and the software here, and the hardware is maybe the DNA and the RNA itself, and then the software perhaps is more about the code. Did the code have to be this way? Could it have been a different way? And people talk about the optimization of the code, and there’s some suggestion for that. I think it’s weak, actually. But you could imagine you can come out with a million different codes and this would be one of the best ones.
Lex Fridman (01:01:22) Well, we don’t know this. We don’t know this.
Nick Lane (01:01:25) People have tried to model it based on the effect that mutations would have. So no, you’re right, we don’t know because that’s a single assumption that a mutation is what’s being selected on there and there’s other possibilities too.
Lex Fridman (01:01:39) I mean, there does seem to be a resilience and a redundancy to the whole thing.
Nick Lane (01:01:43) Yep.
Lex Fridman (01:01:43) It’s hard to mess up in the way you mess it up often is likely to produce interesting results.
Nick Lane (01:01:52) Are you talking about JavaScript or the genetic code now?
Lex Fridman (01:01:54) Both.
Nick Lane (01:01:55) Yeah? Well, I mean, it’s almost, biology is underpinned by this kind of mess as well. And you look at the human genome and it is full of stuff that is really either broken or dysfunctional or was a virus once or whatever it may be, and somehow it works and maybe we need a lot of this mess. We know that some functional genes are taken from this mess.

Violence

Lex Fridman (01:02:15) So what about, you mentioned predatory behavior.
Nick Lane (01:02:19) Yeah.
Lex Fridman (01:02:20) We talked about sex. What about violence? Predator and prey dynamics? When was that invented? And poetic and biological ways of putting it, how do you describe predator prey relationship? Is it a beautiful dance or is it a violent atrocity?
Nick Lane (01:02:43) Well, I guess it’s both, isn’t it? I mean, when does it start? It starts in bacteria, you see these amazing predators Bdellovibrio is one that Lynn Margulis used to talk about a lot. It’s got a kind of a drill piece that drills through the wall and the membrane of the bacterium, and then it effectively eats the bacterium from just inside the periplasmic space and makes copies of itself that way, so that’s straight predation. There are predators among bacteria.
Lex Fridman (01:03:08) So predation in that, sorry to interrupt, means you murder somebody and use their body as a resource in some way?
Nick Lane (01:03:17) Yeah.
Lex Fridman (01:03:18) But it’s not parasitic in that you need them to be still alive?
Nick Lane (01:03:23) No, no. I mean, predation is you kill them really.
Lex Fridman (01:03:26) Murder.
Nick Lane (01:03:27) Parasitis, you kind of live on them.
Lex Fridman (01:03:30) Okay. But it seems the predator is the really popular tool?
Nick Lane (01:03:35) So what we see, if we go back 560, 570 million years before the Cambrian Explosion, there is what’s known as the Ediacaran Fauna, or sometimes they call Vendobionts, which is a lovely name and it’s not obvious that they’re animals at all. They’re stalked things, they often have fronds that look a lot like leaves with kind of fractual branching patterns on them and-
Nick Lane (01:04:00) … branching patterns on them. And the thing is they’re found, sometimes, geologists can figure out the environment that they were in and say, “This is more than 200 meters deep because there’s no sign of any waves. There’s no storm damage down here,” this kind of thing. They were more than 200 meters deep, so they’re definitely not photosynthetic. These are animals, and they’re filter feeders. We know sponges and corals and things are filter-feeding animals; they’re stuck to the spot. And little bits of carbon that come their way, they filter it out, and that’s what they’re eating. So no predation involved in this, beyond stuff just dies anyway, and it feels like a very gentle, rather beautiful, rather limited world, you might say. There’s not a lot going on there.
(01:04:49) And something changes. Oxygen definitely changes during this period. Other things may have changed as well. But the next thing you really see in the fossil record is the Cambrian explosion. And what do we see there? We’re now seeing animals that we would recognize, they’ve got eyes, they’ve got claws, they’ve got shells. They’re plainly killing things or running away and hiding. So we’ve gone from a rather gentle, but limited world, to a rather vicious, unpleasant world that we recognize, which leads to kind of arms races, evolutionary arms races, which again is something that when we think about a nuclear arms race, we think, “Jesus, we don’t want to go there. It’s not done anybody any good.” In some ways, maybe it does do good. I don’t want to make an argument for nuclear arms, but predation as a mechanism forces organisms to adapt, to change, to be better, to escape, or to kill. If you need to eat, then you’ve got to eat. A cheetah is not going to run at that speed unless it has to because the zebra is capable of escaping. So it leads to much greater feats of evolution would ever have been possible without it, and in the end, to a much more beautiful world. So it’s not all bad, by any means.
(01:06:17) But the thing is, you can’t have this if you don’t have an oxygenated planet because it’s all, in the end, it’s about how much energy can you extract from the food you eat? And if you don’t have an oxygenated planet, you can get about 10% out, not much more than that. And if you’ve got an oxygenated planet, you can get about 40% out. And that means you can have, instead of having one or two trophic levels, you can have five or six trophic levels, and that means things can eat things that eat other things and so on, and you’ve gone to a level of ecological complexity, which is completely impossible in the absence of oxygen.
Lex Fridman (01:06:51) This reminds me of the Hunter S. Thompson quote that, “For every moment of triumph, for every instance of beauty, many souls must be trampled.” The history of life on Earth unfortunately is that of violence, just the trillions and trillions of multi-cell organisms that were murdered in the struggle for survival.
Nick Lane (01:07:17) It’s a sorry statement, but yes, it’s basically true.
Lex Fridman (01:07:20) And that somehow is a catalyst from an evolutionary perspective for creativity, for creating more and more complex organisms that are better and better at surviving-
Nick Lane (01:07:30) Survival of the fittest, if you just go back to that old phrase, means death of the weakest. Now, what’s fit? What’s weak? These are terms that don’t have much intrinsic meaning, but the thing is, evolution only happens because of death.
Lex Fridman (01:07:45) One way to die is that the constraints, the scarcity of the resources in the environment, but that seems to be not nearly as good of a mechanism for death than other creatures roaming about in the environment. When I say environment, I mean the static environment, but then there’s the dynamic environment of bigger things trying to eat you and use you for your energy.
Nick Lane (01:08:10) It forces you to come up with a solution to your specific problem that is inventive and is new and hasn’t been done before. So it forces literally change, literally evolution on populations. They have to become different.
Lex Fridman (01:08:27) And it’s interesting that humans have channeled that into more… I guess what humans are doing is they’re inventing more productive and safe ways of doing that. This whole idea of morality and all those kinds of things, I think they ultimately lead to competition versus violence. Because I think violence can have a cold, brutal, inefficient aspect to it, but if you channel that into more controlled competition in the space of ideas, in the space of approaches to life, maybe you can be even more productive than evolution is. Because evolution is very wasteful. The amount of murder required to really test the good idea, genetically speaking, is just a lot. Many, many, many generations.
Nick Lane (01:09:21) Morally, we cannot base society on the way that evolution works.
Lex Fridman (01:09:26) But that’s an invention, right, to morality?
Nick Lane (01:09:27) But actually, in some respects, we do, which is to say, “This is how science works. We have competing hypotheses that have to get better, otherwise they die.” It’s the way that society works. In Ancient Greece, we had Athens and Sparta and city states, and then we had the Renaissance and nation states, and universities compete with each other tremendous amount, companies competing with each other all the time. It drives innovation. And if we want to do it without all the death that we see in nature, then we have to have some kind of societal-level control that says, “Well, there’s some limits, guys, and these are what the limits are going to be,” and society as a whole has to say, “Right, we want to limit the amount of death here, so you can’t do this and you can’t do that.” Who makes up these rules, and how do we know? It’s a tough thing, but it’s basically trying to find a moral basis for avoiding the death of evolution and natural selection and keeping the innovation and the richness of it.
Lex Fridman (01:10:27) I forgot who said it, but that murder is illegal… Probably Kurt Vonnegut. Murder is illegal except when it’s done to the sound of trumpets and at a large scale. So we still have wars, but we are struggling with this idea that murder is a bad thing. It’s so interesting how we’re channeling the best of the evolutionary imperative and trying to get rid of the stuff that’s not productive, trying to almost accelerate evolution. The same kind of thing that makes evolution creative, we’re trying to use that.
Nick Lane (01:11:07) I think we naturally do it. I don’t think we can help ourselves to it.
Lex Fridman (01:11:11) It’s so hard to know.
Nick Lane (01:11:12) Capitalism as a form is basically about competition and differential rewards. But society, and we have a, I keep using this word, moral obligation, but we cannot operate as a society if we go that way. It’s interesting that we’ve had problems achieving balance. For example, in the financial crash in 2009, do you let banks go to the wall or not, this kind of question. In evolution, certainly, you let them go to the wall. And in that sense, you don’t need the regulation because they just die. Whereas if we as a society think about what’s required for society as a whole, then you don’t necessarily let them go to the wall, in which case you then have to impose some kind of regulation that the bankers themselves will, in an evolutionary manner, exploit.
Lex Fridman (01:12:08) Yeah, we’ve been struggling with this kind of idea of capitalism, the cold brutality of capitalism that seems to create so much beautiful things in this world, and then the ideals of communism that seem to create so much brutal destruction in history. We struggle with ideas of, “Well, maybe we didn’t do it right. How can we do things better,” and then the ideas are the things we’re playing with, as opposed to people. If a PhD student has a bad idea, we don’t shoot the PhD student. We just criticize their idea and hope they improve.
Nick Lane (01:12:42) You have a very humane [inaudible 01:12:43].

Human evolution

Lex Fridman (01:12:44) Yeah. Yeah. I don’t know how you guys do it. The way I run things, it’s always life and death. Okay. So it is interesting about humans that there is an inner sense of morality, which begs the question of, how did homo sapiens evolve? If we think about the early invention of sex and early invention of predation, what was the thing invented to make humans? What would you say?
Nick Lane (01:13:17) I suppose a couple of things I’d say. Number one is you don’t have to wind the clock back very far, five, six million years or so, and let it run forwards again, and the chances of humans as we know them is not necessarily that high. Imagine as an alien, you find planet Earth, and it’s got everything apart from humans on it. It’s an amazing, wonderful, marvelous planet, but nothing that we would recognize as extremely intelligent life, space-faring civilization. So when we think about aliens, we’re kind of after something like ourselves or after a space-faring civilization. We’re not after zebras and giraffes and lions and things, amazing though they are. But the additional kind of evolutionary steps to go from large, complex mammals, monkeys, let’s say, to humans doesn’t strike me as that long a distance. It’s all about the brain. And where’s the brain and morality coming from? It seems to me to be all about groups, human groups and interactions between groups.
Lex Fridman (01:14:22) The collective intelligence of it.
Nick Lane (01:14:24) Yes.
Lex Fridman (01:14:24) Yeah.
Nick Lane (01:14:25) The interactions, really. And there’s a guy at UCL called Mark Thomas, who’s done a lot of really beautiful work, I think, on this kind of question. I talk to him every now and then, so my views are influenced by him. But a lot seems to depend on population density. The more interactions you have going on between different groups, the more transfer of information, if you like, between groups, of people moving from one group to another group, almost like lateral gene transfer in bacteria. The more expertise you’re able to develop and maintain, the more culturally complex your society can become. And groups that have become detached, like on Easter Island, for example, very often degenerate in terms of the complexity of their civilization.
Lex Fridman (01:15:13) Is that true for complex organisms in general, population density-
Nick Lane (01:15:19) Really matters.
Lex Fridman (01:15:19) … is often productive?
Nick Lane (01:15:19) Really matters. But in human terms, I don’t know what the actual factors were that were driving a large brain, but you can talk about fire, you can talk about tool use, you can talk about language, and none of them seem to correlate especially well with the actual known trajectory of human evolution in terms of cave art and these kind of things. That seems to work much better just with population density in number of interactions between different groups, all of which is really about human interactions, human-human interactions, and the complexity of those.
Lex Fridman (01:15:58) But population density is the thing that increases the number of interactions, but then there must have been inventions forced by that number of interactions that actually led to humans. So Richard Wrangham talks about that it’s basically the beta males had to beat up the alpha male, so that’s what collaboration looks like is when you’re living together, they don’t like, our early ancestors, don’t like the dictatorial aspect of a single individual at the top of a tribe, so they learn to collaborate how to basically create a democracy of sorts, a democracy that prevents, minimizes, or lessens the amount of violence, which essentially gives strength to the tribe and make the war between tribes versus the dictator [inaudible 01:16:55]-
Nick Lane (01:16:55) I think one of the most wonderful things about humans is we’re all of those things. We are deeply social as a species, and we’re also deeply selfish. And it seems to me the conflict between capitalism and communism is really just two aspects of human nature, both of which are-
Lex Fridman (01:17:11) We’ve got both.
Nick Lane (01:17:11) We have both. And we have a constant kind of vying between the two sides. We really do care about other people, beyond our families, beyond our immediate people. We care about society and the society that we live in. And you could say that’s a drawing towards socialism or communism. On the other side, we really do care about ourselves. We really do care about our families, about working for something that we gain from, and that’s the capitalist side of it. They’re both really deeply ingrained in human nature.
(01:17:38) In terms of violence and interactions between groups, yes, all this dynamic of if you’re interacting between groups, you can be certain that they’re going to be burning each other and all kinds of physical, violent interactions as well, which will drive the kind of cleverness of, how do you resist this? Let’s build a tower. What are we going to do to prevent being overrun by those marauding gangs from over there? And you look outside humans, and you look at chimps and bonobos and so on, and they’re very, very different structures to society. Chimps tend to have an aggressive alpha male-type structure, and bonobos, there’s basically a female society, where the males are predominantly excluded and only brought in at the behest of the female. We have a lot in common with both of those groups.
Lex Fridman (01:18:29) And there’s, again, tension there. Probably chimps, more violence, the bonobos, probably more sex. That’s another tension. How serious do we want to be? How much fun we want to be?

Neanderthals

(01:18:44) Asking for a friend again, what do you think happened to Neanderthals? What did we cheeky humans do to the Neanderthals, homo sapiens? Do you think we murdered them? How do we murder them? How do we out-compete them, or do we out-mate them?
Nick Lane (01:19:01) I don’t know. I think there’s unequivocal evidence that we mated with them.
Lex Fridman (01:19:06) Yeah. We always try to mate with everything.
Nick Lane (01:19:07) Yes, pretty much. There’s some interesting… The first sequences that came along were in mitochondrial DNA, and that was back to about 2002 or thereabouts. And what was found was that Neanderthal mitochondrial DNA was very different to human mitochondrial DNA-
Lex Fridman (01:19:23) Oh, that’s so interesting.
Nick Lane (01:19:24) And you could do a clock on it, and it said the divergent state was about 600,000 years ago or something like that, so not so long ago. And then the first full genomes were sequenced maybe 10 years after that, and they showed plenty of signs of mating between. So the mitochondrial DNA effectively says no mating, and the nuclear genes say, yeah, lots of mating, but we don’t know-
Lex Fridman (01:19:48) How is that possible? Sorry, can you explain the difference between mitochondrial DNA-
Nick Lane (01:19:51) Sorry, yes.
Lex Fridman (01:19:53) … and nucleus?
Nick Lane (01:19:53) I’ve talked before about the mitochondria, which are the power packs in cells. These are the pared-down control units is their DNA. It’s passed on by the mother only. And in the egg cell, we might have half a million copies of mitochondrial DNA. There’s only 37 genes left. And it’s basically the control unit of energy production. That’s what it’s doing.
Lex Fridman (01:20:18) It’s a basic, old-school machine that does energy production.
Nick Lane (01:20:21) It’s got genes that were considered to be effectively trivial because they did a very narrowly defined job, but they’re not trivial in the sense that that narrowly defined job is about everything that is being alive. So they’re much easier to sequence. You’ve got many more copies of these things, and you can sequence them very quickly.
(01:20:42) But the problem is, because they go down only the maternal line, from mother to daughter, your mitochondrial DNA and mine, it’s going nowhere. It doesn’t matter. Any kids we have, they get their mother’s mitochondrial DNA, except in very, very rare and strange circumstances. So it tells a different story, and it’s not a story which is easy to reconcile always. And what it seems to suggest, to my mind at least, is that there was one-way traffic of genes probably going from humans into Neanderthals rather than the other way around.
(01:21:18) Why did the Neanderthals disappear? I don’t know. I suspect they were probably less violent, less clever, less populous, less willing to fight. I don’t know. I think we probably drove them to extinction at the margins of Europe.
Lex Fridman (01:21:37) And it’s interesting how much, if we ran Earth over and over again, how many of these branches of intelligent beings that have figured out how to leverage collective intelligence, which ones of them emerge, which ones of them succeed? Is it the more violent ones? Is it the more isolated one? What dynamics result to more productivity? And I suppose we’ll never know. The more complex the organism, the harder it is to run the experiment in the lab.
Nick Lane (01:22:10) Yes. And in some respects, maybe it’s best if we don’t know.

Sensory inputs

Lex Fridman (01:22:15) Yeah. The truth might be very painful. What about, if we actually step back, a couple of interesting things that we humans do? One is object manipulation and movement, and of course, movement was something that was done… That was another big invention, being able to move around the environment. And the other one is this sensory mechanism, how we sense the environment. One of the coolest high-definition ones is vision. How big are those inventions in the history of life on Earth?
Nick Lane (01:22:50) Vision, movement, again, extremely important going back to the origin of animals, the Cambrian explosion, where suddenly you’re seeing eyes in the fossil record. And it’s not necessarily… Again, lots of people historically have said, “What use is half an eye,” and you can go in a series of steps from a light-sensitive spot on a flat piece of tissue to an eyeball with a lens and so on if you assume no more than… I don’t remember. This was a specific model that I have in mind, but it was 1% change or half a percent change for each generation how long would it take to evolve an eye as we know it, and the answer is half a million years. It doesn’t have to take long. That’s not how evolution works. That’s not an answer to the question. It just shows you can reconstruct the steps and you can work out roughly how it can work.
(01:23:44) So it’s not that big a deal to evolve an eye. But once you have one, then there’s nowhere to hide. Again, we’re back to predator-prey relationships. We’re back to all the benefits that being able to see brings you. And if you think philosophically what bats are doing with ecolocation and so on, I have no idea, but I suspect that they form an image of the world in pretty much the same way that we do. It’s just a matter of mental reconstruction.
(01:24:10) So I suppose the other thing about sight, there are single-celled organisms that have got a lens and a retina and a cornea and so on. Basically they’ve got a camera-type eye in a single cell. They don’t have a brain; what they understand about their world is impossible to say, but they’re capable of coming up with the same structures to do so. So I suppose then, is that once you’ve got things like eyes, then you have a big driving pressure on the central nervous system to figure out what it all means.
(01:24:44) And then we come around to your other point about manipulation, sensory input, and so on about now you have a huge requirement to understand what your environment is and what it means and how it reacts and how you should run away and where you should stay put.
Lex Fridman (01:24:59) Actually on that point, let me… I don’t know if you know the work of Donald Hoffman, who uses the argument, the mechanism of evolution, to say that there’s not necessarily a strong evolutionary value to seeing the world as it is, so objective reality, that our perception actually is very different from what’s objectively real. We’re living inside an illusion and we’re basically… The entire set of species on Earth, I think, I guess, are competing in a space that’s an illusion that’s distinct from, that’s far away from physical reality as defined by physics.
Nick Lane (01:25:46) I’m not sure it’s an illusion so much as a bubble. We have a sensory input, which is a fraction of what we could have a sensory input on, and we interpret it in terms of what’s useful for us to know to stay alive. So, yes, it’s an illusion in that sense, but-
Lex Fridman (01:26:00) So it’s a subset-
Nick Lane (01:26:02) … a tree is physically there, and if you walk into that tree, it’s not purely a delusion. There’s some physical reality to it.
Lex Fridman (01:26:10) So it’s a sensory slice into reality as it is, but because it’s just a slice, you’re missing a big picture. But he says that that slice doesn’t necessarily need to be a slice. It could be a complete fabrication that’s just consistent amongst the species, which is an interesting, or at least it’s a humbling realization that our perception is limited and our cognitive abilities are limited. And at least to me, his argument from evolution, I don’t know how strong that is as an argument, but I do think that life can exist in the mind.
Nick Lane (01:26:55) Yes.
Lex Fridman (01:26:56) In the same way that you can do a virtual reality video game and you can have a vibrant life inside that place, and that place is not real in some sense, but you could still have a vibe… All the same forces of evolution, all the same competition, the dynamics between humans you can have, but I don’t know if there’s evidence for that being the thing that happened on Earth. It seems that Earth-
Nick Lane (01:27:25) I think in either environment, I wouldn’t deny that you could have exactly the world that you talk about, and it would be very difficult to… the idea in Matrix movies and so on, that the whole world is completely a construction, and we’re fundamentally deluded. It’s difficult to say that’s impossible or couldn’t happen, and certainly we construct in our minds what the outside world is. But we do it on input, and that input, I would hesitate to say it’s not real because it’s precisely how we do understand the world. We have eyes, but if you keep someone, and apparently this kind of thing happens, someone kept in a dark room for five years or something like that, they never see properly again because the neural wiring that underpins how we interpret vision never developed.
(01:28:19) When you watch a child develop, it walks into a table. It bangs its head on the table and it hurts. Now you’ve got two inputs. You’ve got one pain from this sharp edge, and number two, probably you’ve touched it and realized it’s there, it’s a sharp edge, and you’ve got the visual input. And you put the three things together and think, “I don’t want to walk into a table again.” So you’re learning, and it’s a limited reality, but it’s a true reality. And if you don’t learn that properly, then you will get eaten, you will get hit by a bus, you will not survive. And same if you’re in some kind of, let’s say, computer construction of reality. I’m not in my ground here, but if you construct the laws that this is what reality is inside this, then you play by those laws.
Lex Fridman (01:29:05) Yeah. Well, as long as the laws are consistent. So just like you said in the lab, the interesting thing about the simulation question, yes, it’s hard to know if we’re living inside a simulation, but also, yes, it’s possible to do these kinds of experiments in the lab now more and more. To me, the interesting question is, how realistic does a virtual reality game need to be for us to not be able to tell the difference? A more interesting question to me is, how realistic or interesting does the virtual reality world need to be in order for us to want to stay there forever or much longer than physical reality, prefer that place, and also prefer it not as we prefer hard drugs, but prefer it in a deep, meaningful way in the way we enjoy life itself?
Nick Lane (01:29:59) I suppose the issue with the matrix, I imagine that it’s possible to delude the mind sufficiently that you genuinely in that way do think that you are interacting with the real world, when in fact, the whole thing’s a simulation. How good does a simulation need to be able to do that? Well, it needs to convince you that all your sensory input is correct and accurate and joins up and make sense. Now, that sensory input is not something that we’re born with. We’re born with a sense of touch. We’re born with eyes and so on, but we don’t know how to use them. We don’t know what to make of them. We go around, we bump into trees. We cry a lot. We’re in pain a lot. We’re basically booting up the system so that it can make head or tail of the sensory input that it’s getting. And that sensory input’s not just a one-way flux of things. It’s also you have to walk into things. You have to hear things. You have to put it together.
(01:30:53) Now, if you’ve got just babies in the matrix who are slotted into this, I don’t think they have that kind of sensory input. I don’t think they would have any way to make sense of New York as a world that they’re part of. The brain is just not developed in that way.
Lex Fridman (01:31:10) Well, I can’t make sense of New York in this physical reality either. But yeah, but you said pain and the walking into things. Well, you can create a pain signal, and as long as it’s consistent that certain things result in pain, you can start to construct a reality. Maybe you disagree with this, but I think we are born almost with a desire to be convinced by our reality, like a desire to make sense of our reality.
Nick Lane (01:31:39) Oh, I’m sure we are, yes.
Lex Fridman (01:31:40) So there’s an imperative… So whatever that reality is given to us, like the table hurts, fire is hot, I think we want to be deluded in the sense that we want to make a simple… Einstein’s simple theory of the thing around us, we want that simplicity. So maybe the hunger for the simplicity is the thing that could be used to construct a pretty dumb simulation that tricks us. So maybe tricking humans doesn’t require building a universe.
Nick Lane (01:32:11) No, this is not what I work on, so I don’t know how close to it we are-
Lex Fridman (01:32:16) I don’t think anyone works on this.
Nick Lane (01:32:16) But I agree with you-
Lex Fridman (01:32:16) Mark Zuckerberg.
Nick Lane (01:32:18) Yeah, I’m not sure that it’s a morally justifiable thing to do, but is it possible in principle? I think it’d be very difficult, but I don’t see why in principle it wouldn’t be possible. And I agree with you that we try to understand the world, we try to integrate the sensory inputs that we have, and we try to come up with a hypothesis that explains what’s going on. I think, though, that we have huge input from the social context that we’re in. We don’t do it by ourselves. We don’t kind of blunder around in a universe by ourself and understand the whole thing. We’re told by the people around us what things are and what they do, and the languages coming in here and so on. So it would have to be an extremely impressive simulation to simulate all of that.

Consciousness

Lex Fridman (01:33:08) Yeah. Simulate all of that, including the social construct, the spread of ideas and the exchange of ideas. I don’t know. But those questions are really important to understand as we become more and more digital creatures. It seems like the next step of evolution is us becoming partial… All the same mechanisms we’ve talked about are becoming more and more plugged in into the machine. We’re becoming cyborgs. And there’s an interesting interplay between wires and biology, zeroes and ones and the biological systems, and I don’t think we’ll have the luxury to see humans as disjoint from the technology we’ve created for much longer. We are, in organisms, that’s [inaudible 01:33:56].
Nick Lane (01:33:56) Yeah. I agree with you, but we come really with this to consciousness, and is there a distinction there? Because what you are saying, the natural end point says we are indistinguishable, that if you are capable of building an AI, which is sufficiently close and similar, that we merge with it, then to all intents and purposes, that AI is conscious as we know it. And I don’t have a strong view, but I have a view, and I wrote about it in the epilogue to my last book.
(01:34:37) Because 10 years ago I wrote a chapter in a book called Life Ascending about consciousness. And the subtitle of Life Ascending was The Ten Great Inventions of Evolution, and I couldn’t possibly write a book with a subtitle like that that did not include consciousness, and specifically consciousness as one of the great inventions. And it was in part because I was just curious to know more and I read more for that chapter. I never worked on it, but I’ve always… How can anyone not be interested in the question?
(01:35:09) And I was left with the feeling that, A, nobody knows, and B, there are two main schools of thought out there with a big kind of skew in distribution. One of them says, oh, it’s a property of matter. It’s an unknown law of physics. Panpsychism, everything is conscious. The sun is conscious. It’s just a matter… A rock is conscious. It’s just a matter of how much. And I find that very unpersuasive. I can’t say that it’s wrong. It’s just that I think we somehow can tell the difference between something that’s living and something that’s not. And then the other end is it’s an emergent property of a very complex, central nervous system. I never quite understand what people mean by words like emergence. There are genuine examples, but I think we very often tend to-
Nick Lane (01:36:00) …and examples, but I think we very often tend to use it to plaster over ignorance. As a biochemist. The question for me then was, okay, so it’s a concoction of a central nervous system. A depolarizing neuron gives rise to a feeling, to a feeling of pain or to a feeling of love or anger, or whatever it may be. So what is then a feeling in biophysical terms in the central nervous system, which bit of the wiring gives rise to, and I’ve never seen anyone answer that question in a way that makes sense to me.
Lex Fridman (01:36:41) And that’s an important question to answer.
Nick Lane (01:36:43) I think if we want to understand consciousness, that’s the only question to answer because certainly an AI is capable of out-thinking and it is only a matter of time. Maybe it’s already happened in terms of just information processing and computational skill. I don’t think we have any problem in designing a mind, which is at least the equal of the human mind. But in terms of what we value the most as humans, which is to say our feelings, our emotions, our sense of what the world is in a very personal way that I think means as much or more to people than their information processing. And that’s where I don’t think that AI necessarily will become conscious because I think it’s the property of life.
Lex Fridman (01:37:33) Well, let’s talk about it more. You’re an incredible writer, one of my favorite writers. So let me read from your latest book, Transformer is what you write about consciousness. “‘I think therefore I am,’ said Descartes is one of the most celebrated lines ever written. But what am I, exactly? And artificial intelligence can think too by definition and therefore is yet few of us could agree whether AI is capable in principle of anything resembling human emotions, of love or hate, fear and joy, of spiritual yearning, for oneness or oblivion, or corporeal pangs of thirst and hunger. The problem is we don’t know what emotions are,” as you were saying, “What is the feeling in physical terms? How does a discharging neuron give rise to a feeling of anything at all? This is the ‘hard problem’ of consciousness, the seeming duality of mind and matter, the physical makeup of our innermost self. We can understand in principle how an extremely sophisticated parallel processing system could be capable of wondrous feats of intelligence. But we can’t answer in principle whether such a supreme intelligence would experience joy or melancholy. What is the quantum of solace?”
(01:38:54) Speaking to the question of emergence, there’s just technical… There’s an excellent paper on this recently about this phase transition emergence of performance in neural networks on problem of NLP, natural language processing. So language models, there seems to be this question of size. At some point, there is a phase transition as you grow the size of the neural network. So the question is, this is somewhat of a technical question that you can philosophize over.
(01:39:32) The technical question is, is there a size of a neural network that starts to be able to form the kind of representations that can capture a language and therefore be able to not just language, but linguistically capture knowledge that’s sufficient to solve a lot of problems in language? Like be able to have a conversation and there seems to be not a gradual increase, but a phase transition and they’re trying to construct the science of where that is, what is a good size of a neural network and why does such a face transition happen. Anyway, that points to emergence that there could be stages where a thing goes from being you’re very intelligent toaster to a toaster that’s feeling sad today and turns away and looks out the window sighing having an existential crisis.
Nick Lane (01:40:30) I’m thinking of Marvin The Paranoid Android.
Lex Fridman (01:40:33) Well, no, Marvin is simplistic because Marvin is just cranky.
Nick Lane (01:40:38) Yes.
Lex Fridman (01:40:39) He’s-
Nick Lane (01:40:40) So easily programmed.
Lex Fridman (01:40:41) Yeah. Easily programmed. Non-stop existential crisis. You’re almost basically… What is it? Notes From Underground by Dostoevsky like just constantly complaining about life. No, capturing the full rollercoaster of human emotion, the excitement, the bliss, the connection, the empathy, and all that kind of stuff. And then the selfishness, the anger, the depression, all that kind of stuff. Capturing all of that and be able to experience it deeply. It’s the most important thing you could possibly experience today. The highest highs. The lowest lows. This is it. My life will be over. I cannot possibly go on that feeling and then after a nap, you’re feeling amazing. That might be something that emerges.
Nick Lane (01:41:33) So why would a nap make an AI being feel better?
Lex Fridman (01:41:42) First of all, we don’t know that for a human either, right?
Nick Lane (01:41:45) But we do know that that’s actually true for many people much of the time. Maybe you’re utterly depressed and you have a nap and you do in fact feel better.
Lex Fridman (01:41:53) Oh, you are actually asking the technical question there is… So there’s a biological answer to that. And so the question is whether AI needs to have the same kind of attachments to its body, bodily function, and preservation of the brain’s successful function. Self-preservation essentially in some deep biological sense.
Nick Lane (01:42:17) I mean to my mind it comes back round to the problem we were talking about before about simulations and sensory input and learning what all of this stuff means and life and death. That biology, unlike society, has a death penalty over everything. And natural selection works on that death penalty that if you make this decision wrongly, you die. And the next generation is represented by beings that made a slightly different decision on balance. And that is something that’s intrinsically difficult to simulate in all its richness I would say. So what is-
Lex Fridman (01:43:09) Death in all its richness. Our relationship with death or the whole of it? So when you say richness, of course, there’s a lot in that which is hard to simulate. What’s part of the richness that’s hard to simulate?
Nick Lane (01:43:27) I suppose the complexity of the environment and your position or the position of an organism in that environment, in the full richness of that environment over its entire life, over multiple generations with changes in gene sequence over those generations. So slight changes in the makeup of those individuals over generations. But if you take it back to the level of single cells, which I do in the book, and ask how does a single cell in effect know it exists as a unit, as an entity. I mean, ‘no’, obviously it doesn’t know anything, but it acts as a unit and it acts with astonishing precision as a unit. And I had suggested that that’s linked to the electrical fields on the membranes themselves and that they give some indication of how am I doing in relation to my environment as a real-time feedback on the world.
(01:44:28) And this is something physical which can be selected over generations that if you get this wrong, it’s linked with this set of circumstances that I’ve just… As an individual, I have a moment of blind panic and run. As a bacterium or something you have some electrical discharge that says blind panic and it runs whatever it may be. And you associate over generations, multiple generations that this electrical phase that I’m in now is associated with a response like that. And it’s easy to see how feelings come in through the back door almost with that kind of giving real-time feedback on your position in the world in relation to how am I doing?
(01:45:22) And then you complexify the system and yes, I have no problem with phase transition. And can all of this be done purely by the language, by the issues with how the system understands itself? Maybe it can, I honestly don’t know, but the philosophers for a long time have talked about the possibility that you can have zombie intelligence and that there are no feelings there, but everything else is the same. I mean I have to throw this back to you really. How do you deal with the zombie intelligence?
Lex Fridman (01:46:03) So first of all, I can see that from a biologist perspective, you think of all the complexities that led up to the human being, the entirety of the history of four billion years that in some deep sense integrated the human being into this environment and that dance of the organism and the environment. You could see how emotions arise from that and then our emotions are deeply connected and creating a human experience and from that you mix in consciousness and the full mess of it. But from a perspective of an intelligent organism that’s already here like a baby that learns it doesn’t need to learn how to be a collection of cells or how to do all the things he needs to do. The basic function of a baby, as it learns, is to interact with its environment, to learn from its environment, to learn how to fit into the social society.
Nick Lane (01:47:03) And the basic response of the baby is to cry a lot of the time.
Lex Fridman (01:47:07) Cry. Well maybe convinced the humans to protect it or to discipline it, to teach it, whatever. I mean we’ve developed a bunch of different tricks, how to get our parents to take care of us, to educate us, to teach us about the world. Also, we’ve constructed the world in such a way that it’s safe enough for us to survive in and yet dangerous enough to learn the valuable lessons they are still hard with corners, so we can still run into them. It hurts like hell. So AI needs to solve that problem, not the problem of constructing this super complex organism that leads up to run the whole… To make an apple pie, to build the whole universe. You need to build a whole universe. I think the zombie question is, it’s something I would leave to the philosophers because, and I will also leave to them the definition of love and what happens between two human beings when there’s a magic that just grabs them like nothing else matters in the world.
(01:48:20) And somehow you’ve been searching for this feeling, this moment, this person your whole life, that feeling. The philosophers can have a lot of fun with that one. And also say that that’s just… You could have a biological explanation, you could have all kinds of… It’s all fake. It’s actually Ayn Rand will say it’s all selfish. There’s a lot of different interpretations. I’ll leave it to the philosophers. The point is the feeling sure as hell feels very real. And if my toaster makes me feel like it’s the only toaster in the world, and when I leave and I miss the toaster and when I come back, I’m excited to see the toaster and my life is meaningful and joyful and the friends I have around me get a better version of me because that toaster exists. That sure as hell feels-
Nick Lane (01:49:12) I mean-
Lex Fridman (01:49:12) …conscious toaster.
Nick Lane (01:49:13) …is that psychologically different to having a dog?
Lex Fridman (01:49:16) No.
Nick Lane (01:49:16) Because I mean most people would dispute whether we can say a dog… I would say a dog is undoubtedly conscious, but some people would say-
Lex Fridman (01:49:24) But there’s degrees of consciousness and so on. But people are definitely much more uncomfortable saying a toaster can be conscious than a dog. And there’s still a deep connection. And you could say our relationship with the dog has more to do with anthropomorphism. Like we kind of project the human being onto it.
Nick Lane (01:49:42) Maybe.
Lex Fridman (01:49:43) We can do the same damn thing with a toaster.
Nick Lane (01:49:45) Yes, but you can look into the dog’s eyes and you can see that it’s sad, that it’s delighted to see you again. I don’t have a dog by the way. It’s not that I’m a dog person. I’m a cat person-
Lex Fridman (01:49:55) And dogs are actually incredibly good at using their eyes to do just that.
Nick Lane (01:49:59) They are. Now, I don’t imagine that a dog is remotely as close to being intelligent as an AI intelligence, but it’s certainly capable of communicating emotionally with us.
Lex Fridman (01:50:12) But here’s what I would venture to say. We tend to think because AI plays chess well and is able to fold proteins now, well that it’s intelligent. I would argue that in order to communicate with humans, in order to have emotional intelligence, it actually requires another order of magnitude of intelligence. It’s not easy to be flawed. Solving a mathematical puzzle is not the same as the full complexity of human-to-human interaction. That’s actually we humans just take for granted the things we’re really good at. Nonstop people tell me how shitty people are at driving. No, humans are incredible at driving. Bipedal walking, walking, object, manipulation. We’re incredible at this. And so people tend to-
Nick Lane (01:51:04) Discount the things we all just take for granted.
Lex Fridman (01:51:07) And one of those things that they discount is our ability, the dance of conversation and interaction with each other, the ability to morph ideas together, the ability to get angry at each other and then to miss each other, to create a tension that makes life fun and difficult and challenging in a way that’s meaningful, that is a skill that’s learned and AI would need to solve that problem.
Nick Lane (01:51:33) I mean, in some sense what you’re saying is AI cannot become meaningfully emotional, let’s say, until it experiences some kind of internal conflict that it’s unable to reconcile these various aspects of reality or its reality with a decision to make. And then it feels sad necessarily because it doesn’t know what to do. I certainly can’t dispute that. That may very well be how it works. I think the only way to find out is to do it and-
Lex Fridman (01:52:05) And to build it and leave it to the philosophers if it actually feels sad or not. The point is the robot will be sitting there alone having an internal conflict, an existential crisis, and that’s required for it to have a deep meaningful connection with another human being. Now does it actually feel that? I don’t know.
Nick Lane (01:52:24) But I’d like to throw something else at you which troubles me on reading it. Noah Harari’s book 21 Lessons for the 21st Century. And he’s written about this kind of thing on various occasions and he sees biochemistry as an algorithm and then AI will necessarily be able to hack that algorithm and do it better than humans. So there will be AI better at writing music that we appreciate, the Mozart ever could, or writing better than Shakespeare ever did, and so on, because biochemistry is algorithmic and all you need to do is figure out which bits of the algorithm to play to make us feel good or bad or appreciate things. And as a biochemist, I find that argument close to irrefutable and not very enjoyable. I don’t like the sound of it, that’s just my reaction as a human being. You might like the sound of it because that says that AI is capable of the same kind of emotional feelings about the world as we are because the whole thing is an algorithm and you can program an algorithm and there you are. He then has a peculiar final chapter where he talks about consciousness in rather separate terms and he’s talking about meditating and so on and getting in touch with his inner conscious. I don’t meditate, I don’t know anything about that. But he wrote in very different terms about it as if somehow it’s a way out of the algorithm. Now it seems to me that consciousness in that sense is capable of scuppering the algorithm. I think in terms of the biochemical feedback loops and so on, it is undoubtedly algorithmic. But in terms of what we decide to do, it can be much more… Based on an emotion we can just think, ah, I don’t care. I can’t resolve this complex situation.
(01:54:20) I’m going to do that. And that can be based on in effect a different currency, which is the currency of feelings and something where we don’t have very much personal control over. And then it comes back around to you and what are you trying to get at with AI? Do we need to have some system which is capable of overriding a rational decision which cannot be made because there’s too much conflicting information by effectively an emotional judgmental decision that just says do this and see what happens? That’s what consciousness is really doing in my view.
Lex Fridman (01:54:53) Yeah. And the question is whether it’s a different process or just a higher-level process. The idea that biochemistry is an algorithm is to me an oversimplistic view. There’s a lot of things that the moment you say it it’s irrefutable, but it simplifies-
Nick Lane (01:55:17) I’m sure it’s an extremely complex-
Lex Fridman (01:55:18) …and in the process loses something fundamental. So for example, calling a universe an information processing system. Sure, yes, you can make that. It’s a computer that’s performing computations, but you’re missing the process of the entropy somehow leading to pockets of complexity that creates these beautiful artifacts that are incredibly complex and they’re like machines. And then those machines are through the process of evolution are constructing even further complexity. Like in calling universe information a processing machine, you’re missing those little local pockets and how difficult it’s to create them.
(01:56:05) So the question to me is if biochemistry is an algorithm, how difficult is it to create a software system that runs the human body, which I think is incorrect? I think that is going to take so long, I mean, that’s going to be centuries from now to be able to reconstruct a human. Now what I would venture to say, to get some of the magic of a human being, what we’re saying with the emotions and the interactions and like a dog makes a smile and joyful and all those kinds of things, that will come much sooner. But that doesn’t require us to reverse engineer the algorithm of biochemistry.
Nick Lane (01:56:44) Yes, but the toaster is making you happy.
Lex Fridman (01:56:47) Yes.
Nick Lane (01:56:48) It’s not about whether you make the toaster happy.
Lex Fridman (01:56:51) No, it has to be. It has to be. It has to be. The toaster has to be able to leave me happy.
Nick Lane (01:56:58) The toaster has to be happy. Yes. But it’s the toaster is the AI in this case is a very intelligent-
Lex Fridman (01:57:00) Yeah. The toaster has to be able to be unhappy and leave me. That’s essential.
Nick Lane (01:57:06) Yeah.
Lex Fridman (01:57:07) That’s essential for my being able to miss the toaster. If the toaster is just my servant that’s not, or a provider of services like tells me the weather makes toast, that’s not going to deep connection. It has to have internal conflict. You write about life and death. It has to be able to be conscious of its mortality and the finiteness of its existence and that life is for its temporary and therefore it needs to be more selective with the kind of people it hangs out with.
Nick Lane (01:57:38) One of the most moving moments in the movies from when I was a boy was the unplugging of HAL in 2001 where that was the death of a sentient being and HAL knew it. So I think we all kind of know that a sufficiently intelligent being is going to have some form of consciousness, but whether it would be like biological consciousness, I just don’t know. And if you’re thinking about how do we bring together, I mean obviously we’re going to interact more closely with AI, but are we really? Is a dog really like a toaster or is there really some kind of difference there? You were talking biochemistry is algorithmic, but it’s not single algorithm and it’s very complex. Of course, it is. So it may be that there are again conflicts in the circuits of biochemistry, but I have a feeling that the level of complexity of the total biochemical system at the level of a single cell is less complex than the level of neural networking in the human brain or in an AI.
Lex Fridman (01:58:52) Well, I guess I assumed that we were including the brain in the biochemistry algorithm because you have to-
Nick Lane (01:58:59) I would see that as a higher level of organization of neural networks. They’re all using the same biochemical wiring within themselves.
Lex Fridman (01:59:06) Yeah. But the human brain is not just neurons, it’s the immune system. It’s the whole package. I mean, to have a biochemical algorithm that runs an intelligent biological system, you have to include the whole damn thing. And it’s pretty fascinating. It comes from an embryo. The whole… I mean boy. I mean if you can… What is the human being? Because it’s-
Nick Lane (01:59:33) But if you look-
Lex Fridman (01:59:34) …just some code. And then, so DNA doesn’t just tell you what to build, but how to build it. I mean the thing is impressive and the question is how difficult is it to reverse engineer the whole shebang?
Nick Lane (01:59:52) Very difficult.
Lex Fridman (01:59:54) I would say it’s… I don’t want to say impossible, but it’s much easier to build a human than to reverse engineer… To build a fake human, human-like thing than to reverse engineer the entirety of the process, the evolution of that.
Nick Lane (02:00:15) I’m not sure if we are capable of reverse-engineering the whole thing. If the human mind is capable of doing that. I mean I wouldn’t be a biologist if I wasn’t trying, But I know I can’t understand the whole problem. I’m just trying to understand the rudimentary outlines of the problem. There’s another aspect though, you’re talking about developing from a single cell to the human mind and all the subsystems that are part of the immune system and so on. This is something that you’ll talk about I imagine with Michael Levin, but so little is known about… You talk about reverse engineers. So little is known about the developmental pathways that go from a genome to going to a fully wired organism. And a lot of it seems to depend on the same electrical interactions that I was talking about happening at the level of single cells and its interaction with the environment. There’s a whole electrical field side to biology that is not yet written into any of the textbooks, which is about how does an embryo develop into or a single cell develop into these complex systems.
(02:01:32) What defines the head, what defines the immune system, what defines the brain, and so on? That really is written in a language that we’re only just beginning to understand. And frankly biologists, most biologists are still very reluctant to even get themselves tangled up in questions like electrical fields influencing development. It seems like mumbo jumbo to a lot of biologists and it should not be because this is the 21st century biology. This is where it’s going, but we’re not going to reverse engineer a human being or the mind or any of these subsystems until we understand how this developmental processes work, how electricity and biology really works, and if it is linked with feelings or with consciousness and so on. In the meantime, we have to try, but I think that’s where the answer lies.
Lex Fridman (02:02:22) So you think it’s possible that the key to things like consciousness are some of the more tricky aspects of cognition might lie in that early development, the interaction of electricity and biology? Electrical fields, oh God.
Nick Lane (02:02:40) But we already know the EEG and so on is telling us a lot about brain function, but we don’t know which cells, which parts of a neural network is giving rise to the EEG. We don’t know the basics. The assumption is, I mean we know it’s neural networks, we know it’s multiple cells, hundreds or thousands of cells involved in it, and we assume that it’s to do with depolarization during action potentials and so on. But the mitochondria which are in there have much more membranes than the plasma membrane of the neuron.
(02:03:08) And there’s a much greater membrane potential and it’s formed in, very often parallel Christi, which are capable of reinforcing a field and generating fields over longer distances. And nobody knows if that plays a role in consciousness or not. There’s reasons to argue that it could, but frankly, we simply do not know and it’s not taken into consideration. You look at the structure of the mitochondrial membranes in the brains of simple things like Drosophila, the fruit fly, and they have amazing structures. You can see lots of little rectangular things all lined up in amazing patterns. What are they doing? Why are they like that? We haven’t the first clue.
Lex Fridman (02:03:52) What do you think about organoids and brain organoids and so in a lab trying to study the development of these in the Petri dish development of organs, do you think that’s promising or do you have to look at the whole systems?
Nick Lane (02:04:08) I’ve never done anything like that. I don’t know much about it. The people who I’ve talked to who do work on it say amazing things can happen and a bit of a brain grown in a dish is capable of experiencing some kind of feelings or even memories of its former brain. Again, I have a feeling that until we understand how to control the electrical fields that control development, we’re not going to understand how to turn an organoid into a real functional system.

AI and biology

Lex Fridman (02:04:36) But how do we get that understanding? It’s so incredibly difficult. I mean, you would have to… One promising direction, I’d love to get your opinion on this. I don’t know if you’re familiar with the work of DeepMind and AlphaFold with protein folding and so on. Do you think it’s possible that that will give us some breakthroughs in biology trying to basically simulate and model the behavior of trivial biological systems as they become complex biological systems?
Nick Lane (02:05:11) I’m sure it will. The interesting thing to me about protein folding is that for a long time, my understanding, this is not what I work on, so I may have got this wrong, but my understanding is that you take the sequence of a protein and you try to fold it, and there are multiple ways in which it can fold. And to come up with the correct confirmation is not a very easy thing because you’re doing it from first principles from a string of letters, which specify the string of amino acids. But what actually happens is when a protein is coming out of a ribosome, it’s coming out of a charged tunnel and it’s in a very specific environment which is going to force this to go there now and then this one to go there and this one to come like that. And so you’re forcing a specific conformational set of changes onto it as it comes out of the ribosome.
(02:05:58) So by the time it’s fully emerged, it’s already got its shape. And that shape depended on the immediate environment that it was emerging into one letter, one amino acid at a time. And I don’t think that the field was looking at it that way. And if that’s correct, then that’s very characteristic of science, which is to say it asks very often the wrong question and then does really amazingly sophisticated analyses on something having never thought to actually think, well, what is biology doing? And biology is giving you a charged electrical environment that forces you to be this way. Now did DeepMind come up through patterns with some answer that was like that? I’ve got absolutely no idea. It ought to be possible to deduce that from the shapes of proteins. It would require much greater skill than the human mind has. But the human mind is capable of saying, “Well, hang on, let’s look at this exit tunnel and try and work out what shape is this protein going to take.” And we can figure that out.
Lex Fridman (02:07:00) Well, that’s really interesting about the exit tunnel. But sometimes we get lucky and just like in science, the simplified view or the static view will actually solve the problem for us. So in this case, it’s very possible that the sequence of letters has a unique mapping to our structure without considering how it unraveled. So without considering the tunnel, that seems to be the case in this situation where the cool thing about proteins, all the different shapes that it can possibly take, it actually seems to take very specific unique shapes given the sequence.
Nick Lane (02:07:36) That’s forced on you by an exit tunnel. So the problem is actually much simpler than you thought. And then there’s a whole army of proteins which changed the conformational state, chaperone proteins, and they’re only used when there’s some presumably issue with how it came out of the exit tunnel, and you want to do it differently to that. So very often the chaperone proteins will go there and will influence the way in which it folds. So-
Nick Lane (02:08:00) … go there and will influence the way in which it falls. So there’s two ways of doing it. Either you can look at the structures and the sequences of all the proteins, and you can apply an immense mind to it, and figure out what the patterns are and figure out what… Or, you can look at the actual situation where it is and say, “Well, hang on, it was actually quite simple.” It’s got a charged environment and then of course, it’s forced to come out this way. And then, the question will be, “Well, do different ribosomes have different charged environments? What happens if a chaperone…” You’re asking a different set of questions to come to the same answer, in a way which is telling you a much simpler story, and explains why it is. Rather than saying, “It could be. This is one in a billion different possible conformational states that this protein could have,” you’re saying, “Well, it has this one because that was the only one it could take, given its setting.”
Lex Fridman (02:08:48) Well, yeah, I mean, currently humans are very good at that kind of first principles thinking, of stepping back.
Nick Lane (02:08:54) Yeah.
Lex Fridman (02:08:54) But I think AI is really good at collecting a huge amount of data, and a huge amount of data of observation of planets, and figure out that Earth is not at the center of the universe, that there’s actually a sun, we’re orbiting the Sun. But then, you can, as a human being ask, “Well, how do solar systems come to be? What are the different forces that are required to make this kind of pattern emerge?” And then, you start to invent things like gravity. I mean, obviously-
Nick Lane (02:09:26) Is it something [inaudible 02:09:26]-
Lex Fridman (02:09:26) I mixed up the ordering of gravity wasn’t considered as a thing that connects planets, but we are able to think about those big picture things as human beings. AI is just very good to infer simple models from a huge amount of data. And the question is, with biology, we kind of go back and forth how we solve biology. Listen, protein folding was thought to be impossible to solve. And there’s a lot of brilliant PhD students that worked one protein at a time, trying to figure out the structure, and the fact that it was able to do that…
Nick Lane (02:10:03) Oh, I’m not knocking it at all, but I think that people have been asking the wrong question.
Lex Fridman (02:10:09) But then, as the people start to ask better and bigger questions, the AI kind of enters the chat and says, “I’ll help you out with that.”
Nick Lane (02:10:22) Can I give you another example from my own work? The risk of getting a disease as we get older, there are genetic aspects to it. If you spend your whole life overeating, and smoking, and whatever, that’s a whole separate question, but there’s a genetic side to the risk, and we know a few genes that increase your risk of certain things. And for probably 20 years now, people have been doing what’s called GWAS, which is genome-wide association studies.
(02:10:55) So you effectively scan the entire genome for any single nucleotide polymorphisms, which is to say a single letter change in one place that has a higher association of being linked with a particular disease or not. And you can come out with thousands of these things across the genome. And if you add them all up and try and say, “Well, so do they add up to explain the known genetic risk of this disease?” And the known genetic risk often comes from twin studies, and you can say that if this twin gets epilepsy, there’s a 40 or 50% risk that the other twin, identical twin, will also get epilepsy. Therefore, the genetic factor is about 50%, and so the gene similarities that you see should account for 50% of that known risk.
(02:11:46) Very often, it accounts for less than a 10th of the known risk. And there’s two possible explanations, and there’s one which people tend to do, which is to say, “Ah, well, we don’t have enough statistical power. Maybe there’s a million. We’ve only found a 1,000 of them, but if we find the other million, they’re weakly related, but there’s a huge number of them, and so we’ll account for that whole risk.” Maybe there’s a billion of them, [inaudible 02:12:10]. So that’s one way. The other way is to say, “Well, hang on a minute. You’re missing a system here. That system is the mitochondrial DNA,” which people tend to dismiss, because it’s small and it doesn’t change very much.
(02:12:27) But a few single letter changes in that mitochondrial DNA, it controls some really basic processes. It controls not only all the energy that we need to live, and to move around, and do everything we do, but also biosynthesis, to make the new building blocks, to make new cells. And cancer cells very often take over the mitochondria and rewire them, so that instead of using them for making energy, they’re effectively using them as precursors for the building blocks, for biosynthesis. You need to make new amino acids, new nucleotides for DNA. You want to make new lipids to make your membranes and so on. So they kind of rewire metabolism.
(02:13:06) Now, the problem is that we’ve got all these interactions between mitochondrial DNA and the genes in the nucleus that are overlooked completely, because people literally throw away the mitochondrial genes, and we can see in fruit flies that they interact and produce big differences in risk. So you can set AI onto this question of exactly how many of these base changes there are, and that’s just one possible solution, that maybe there are a million of them and it does account for the greater part of the risk, or the other one is they aren’t. It’s just not there, that actually the risk lies in something you weren’t even looking at. And this is where human intuition is very important, and there’s this feeling that, “Well, I’m working on this, and I think it’s important, and I’m bloody minded about it.” And in the end, some people are right. It turns out that it was important. Can you get AI to do that, to be bloody minded?
Lex Fridman (02:14:03) And that, “Hang on a minute, you might be missing a whole other system here that’s much bigger,” that’s the moment of discovery, of scientific revolution. I’m giving up on saying AI can’t do something. I’ve said it enough times about enough things. I think there’s been a lot of progress. And instead, I’m excited by the possibility of AI helping humans. But at the same time, just like I said, we seem to dismiss the power of humans.
Nick Lane (02:14:37) Yes, yes.
Lex Fridman (02:14:38) We’re so limited in so many ways that kind of, in what we feel like dumb ways, like we’re not strong, we’re kind of, our attention, our memory is limited, our ability to focus on things is limited, in our own perception of what limited is. But that, actually, there’s an incredible computer behind the whole thing that makes this whole system work. Our ability to interact with the environment, to reason about the environment, there’s magic there.
Nick Lane (02:14:38) Yeah.
Lex Fridman (02:15:14) And I am hopeful that AI can capture some of that same magic, but that magic is not going to look like a Deep Blue playing chess.
Nick Lane (02:15:22) No.
Lex Fridman (02:15:23) It’s going to be more interesting.
Nick Lane (02:15:24) But I don’t think it’s going to look like pattern finding, either. I mean, that’s essentially what you’re telling me it does very well at the moment. And my point is it works very well where you’re looking for the right pattern, but we are storytelling animals. And a hypothesis is a story. It’s a testable story, but a new hypothesis is a leap into the unknown, and it’s a new story, basically. And it says, “This leads to this, leads to that.” It’s a causal set of storytelling.
Lex Fridman (02:15:54) It’s also possible that the leap into the unknown has a pattern of its own.
Nick Lane (02:15:58) Yes, it is.
Lex Fridman (02:15:59) And it’s possible that it’s learnable.
Nick Lane (02:15:59) I’m sure it is. There’s a nice book by Arthur Koestler on the nature of creativity, and he likens it to a joke where the punchline goes off in a completely unexpected direction, and says that this is the basis of human creativity, that some creative switch of direction to an unexpected place is similar to a… I’m not saying that’s how it works, but it’s a nice idea, and there must be some truth in it. Most of the stories we tell are probably the wrong story, and probably going nowhere, and probably not helpful, and we definitely don’t do as well at seeing patterns in things.
(02:16:41) But some of the most enjoyable human aspects is finding a new story that goes to an unexpected place. And again, these are all aspects of what being human means to me. And maybe these are all things that AI figures out for itself, or maybe they’re just aspects… But I just have the feeling sometimes that the people who are trying to understand what we are like, if we wish to craft an AI system which is somehow human-like, that we don’t have a firm enough grasp of what humans really are like, in terms of how we are built,
Lex Fridman (02:17:21) But we get a better understanding of that. I agree with you completely. We try to build a thing and then we go, “Hang on in a minute, there’s another system here.” And that’s, actually, the attempt to build AI that’s human-like is getting us to a deeper understanding of human beings. The funny thing that I recently talked to Magnus Carlsen, widely considered to be the greatest chess player of all time, and he talked about AlphaZero, which is a system from DeepMind that plays chess. And he had a funny comment, he has a kind of dry sense of humor, but he was extremely impressed when he first saw AlphaZero play, and he said that it did a lot of things that could easily be mistaken for creativity.
(02:18:09) So he refused, as a typical human, refused to give the system sort of its due, because he came up with a lot of things that a lot of people are extremely impressed by, not just the sheer calculation, but the brilliance of play. So one of the things that it does in really interesting ways is it sacrifices pieces. So in chess, that means you basically take a few steps back in order to take a step forward. You give away pieces for some future reward. And that, for us humans, is where art is in chess. You take big risks that, for us humans, those risks are especially painful, because you have a fog of uncertainty before you. So to take a risk now based on intuition of, “I think this is the right risk to take, but there’s so many possibilities,” that that’s where it takes guts. That’s where art is, that’s that danger.
(02:19:14) And then, AlphaZero takes those same kind of risks, and does them even greater degree, but of course, it does it from where you could easily reduce down to a cold calculation over patterns. But boy, when you see the final result, it sure looks like the same kind of magic that we see, and creativity, when we see creative play on the chess board. But the chess board is very limited, and the question is, as we get better and better, can we do that same kind of creativity in mathematics, in programming, and then eventually in biology, psychology, and expand into more and more complex systems?
Nick Lane (02:20:04) I used to go running when I was a boy, and fell running, which is to say running up and down mountains, and I was never particularly great at it, but there were some people who were amazingly fast, especially at running down. And I realized, in trying to do this, that there’s three possible ways of doing it, and there’s only two that work. Either, you go extremely slowly and carefully, and you figure out, “Okay, there’s a stone. I’ll put my foot on this stone, and then there’s a muddy puddle I’m going to avoid.” And it’s slow, it’s laborious. You figure it out, step by step, or you can just go incredibly fast, and you don’t think about it at all. The entire conscious mind is shut out of it, and it’s probably the same playing table tennis or something. There’s something in the mind which is doing a whole lot of subconscious calculations about exactly…
(02:20:54) And it’s amazing. You can run at astonishing speed down a hillside, with no idea how you did it at all. And then, you panic and you think, “I’m going to break my leg if I keep doing this. I’ve got to think about where I’m going to put my foot.” So you slow down a bit and try to bring this conscious mind in, and then you do, you crash. You cannot think consciously while running downhill. And so it’s amazing how many calculations the mind is able to make.
(02:21:21) Now, the problem with playing chess or something, if you were able to make all of those subconscious, forward calculations about what is the likely outcome of this move now in the way that we can by running down a hillside or something, it’s partly about what we have adapted to do. It’s partly about the reality of the world that we’re in. Running fast downhill is something that we better be bloody good at, otherwise we’re going to be eaten. Whereas, trying to calculate multiple, multiple moves into the future is not something we’ve ever been called on to do. Two or three, four moves into the future is quite enough for most of us, most of the time.
Lex Fridman (02:22:00) Yeah, yeah. So yeah, just solving chess, we may not be as far towards solving the problem of downhill running as we might think, just because we solved chess. Still, it’s beautiful to see creativity. Humans create machines. They’re able to create art, and art on the chessboard and art otherwise. Who knows how far that takes us? So I mentioned Andrej Karpathy earlier. Him and I are big fans of yours. If you’re taking votes, his suggestion was you should write your next book on the Fermi paradox. So let me ask you, on the topic of alien life, since we’ve been talking about life and we’re a kind of aliens, how many alien civilizations are out there, do you think?
Nick Lane (02:22:58) Well, the universe is very big, but not as many as most people would like to think is my view, because the idea that there is a trajectory going from simple cellular life like bacteria, all the way through to humans, seems to me there’s some big gaps along that way, that the eukaryotic cell, the complex cell that we have is the biggest of them. But also, photosynthesis is another. Another interesting gap is a long gap from the origin of the eukaryotic cell to the first animals. That was about a billion years, maybe more than that, and a long delay in where oxygen began to accumulate in the atmosphere.
(02:23:42) So from the first appearance of oxygen in the Great Oxidation Event to enough for animals to respire was close to 2 billion years. Why so long? It seems to be planetary factors. It seems to be geology, as much as anything else, and we don’t really know what was going on. So the idea that there’s a kind of an inevitable march towards complexity and sentient life I don’t think is right. Not to say it’s not going to happen, but I think it’s not going to happen often.
Lex Fridman (02:24:17) So if you think of Earth, given the geological constraints and all that kind of stuff, do you have a sense that life, complex life, intelligent life happened really quickly on Earth, or really long? So just to get a sense of are you more sort of saying that it’s very unlikely to get the kind of conditions required to create humans, or is it, even if you have the condition, it’s just statistically difficult?
Nick Lane (02:24:46) I think, I mean, the problem, the single great problem at the center of all of that, to my mind, is the origin of the eukaryotic cell, which happened once, and without eukaryotes, nothing else would’ve happened, and that is something that-
Lex Fridman (02:24:59) Because you’re saying it’s super important, the eukaryotes, but-
Nick Lane (02:25:02) I’m saying tantamount of saying that it is impossible to build something as complex as a human being from bacterial cells.
Lex Fridman (02:25:09) Totally agree in some deep, fundamental way, but it’s just like one cell going inside another. Is that so difficult to get to work right, that like [inaudible 02:25:18]-
Nick Lane (02:25:18) Well, again, it happened once, and if you think about, I’m in a minority view in this position, most biologists probably wouldn’t agree with me anyway, but if you think about the starting point, we’ve got a simple cell, it’s an archaeal cell, we can be fairly sure about that. So it looks a lot like a bacterium, but is in fact from this other domain of life. So it looks a lot like a bacterial cell. That means it doesn’t have anything. It doesn’t have a nucleus, it doesn’t really have complex endomembrane. It has a little bit of stuff, but not that much, and it takes up an endosymbiont. So what happens next? And the answer is basically everything to do with complexity.
(02:26:02) To me, there’s a beautiful paradox here. Plants, and animals, and fungi all have exactly the same type of cell, but they all have really different ways of living. So a plant cell is photosynthetic, they started out as algae in the oceans and so on. So think of algal bloom, single-cell things. The basic cell structure that it’s built from is exactly the same, with a couple of small differences. It’s got chloroplasts as well, it’s got a vacuole, it’s got a cell wall, but that’s about it. Pretty much everything else is exactly the same in a plant cell and an animal cell. And yet, the ways of life are completely different. So this cell structure did not evolve in response to different ways of life, different environments. I’m in the ocean doing photosynthesis, I’m on land running around as part of an animal, I’m a fungus in a soil, spinning out long kind of shoots into whatever it may be, mycelium.
(02:27:03) So they all have the same underlying cell structure. Why? Almost certainly, it was driven by adaptation to the internal environment, of having these pesky endosymbionts that forced all kinds of change on the host cell. Now, in one way, you could see that as a really good thing, because it may be that there’s some inevitability to this process. It’s as soon as you’ve got endosymbionts, you’re more or less bound to go in that direction. Or, it could be that there’s a huge fluke about it, and it’s almost certain to go wrong in just about every case possible, that the conflict will lead to, effectively, war, leading to death and extinction, and it simply doesn’t work out. So maybe it happened millions of times and it went wrong every time, or maybe it only happened once, and it worked out because it was inevitable. And actually, we simply do not know enough now to say which of those two possibilities is true, but both of them are a bit grim.
Lex Fridman (02:27:52) But you’re leaning towards we just got really lucky in that one leap. So do you have a sense that our galaxy, for example, has just maybe millions of planets with bacteria living on it?
Nick Lane (02:28:07) I would expect billions, tens of billions of planets with bacteria living on it, practically. I mean, there’s probably what, 5 to 10 planets per star, of which I would hope that at least one would have bacteria on. So I expect bacteria to be very common. I simply can’t put a number otherwise. I mean, I expect it will happen elsewhere. It’s not that I think we’re living in a completely empty universe.
Lex Fridman (02:28:31) That’s so fascinating.
Nick Lane (02:28:32) But I think that it’s not going to happen inevitably, and there’s something… That’s not the only problem with complex life on Earth. I mentioned oxygen, and animals, and so on as well. And even humans, we came along very late. You go back 5 million years, and would we be that impressed if we came across a planet full of giraffes? I mean, you’d think, “Hey, there’s life here. There’s a nice planet to colonize or something.” We wouldn’t think, “Oh, let’s try and have a conversation with this giraffe.”
Lex Fridman (02:29:00) Yeah, I’m not sure what exactly we would think. I’m not exactly sure what makes humans so interesting from an alien perspective or how they would notice. I’ll talk to you about cities, too, because an interesting perspective of how to look at human civilization. But your suns… I mean, of course you don’t know, but it’s an interesting world, it’s an interesting galaxy, and it’s an interesting universe to live in, that’s just like every sun, like 90% of solar systems have bacteria in it. Imagine that world, and the galaxy maybe has just a handful, if not one intelligent civilization. That’s a wild world.
Nick Lane (02:29:00) It’s a wild world.
Lex Fridman (02:29:53) I didn’t even think about that world. There’s a kind of thought that one of the reasons it would be so exciting to find life on Mars, or Titan, or whatever is like if life is elsewhere, then surely, statistically, that life, no matter how unlikely you curry us multicellular organisms, sex, violence, what else is extremely difficult? I mean, photosynthesis, is figuring out some machinery that involves the chemistry and the environment to allow the building up of complex organisms, surely that would arise. But man, I don’t know how I would feel about just bacteria everywhere.
Nick Lane (02:30:38) Well, it would be depressing, if it was true. I suppose, depressing-
Lex Fridman (02:30:42) [inaudible 02:30:42].
Nick Lane (02:30:42) I don’t think-
Lex Fridman (02:30:43) I don’t know what’s more depressing, bacteria everywhere, nothing everywhere.
Nick Lane (02:30:47) Yes, either of them are chilling. But whether it’s chilling or not I don’t think should force us to change our view about whether it’s real or not.
Lex Fridman (02:30:57) Yes, yes.
Nick Lane (02:30:58) And what I’m saying may or may not be true.
Lex Fridman (02:31:00) So how would you feel if we discovered life on Mars? It sounds like you would be less excited than some others, because you’re like, “Well…”
Nick Lane (02:31:09) What I would be most interested in is how similar to life on Earth it would be. It would actually turn into quite a subtle problem, because the likelihood of life having gone to and fro between Mars and the Earth is quite… I wouldn’t say high, but it’s not low. It’s quite feasible. And so if we found life on Mars and it had very similar genetic code, but it was slightly different, most people would interpret that immediately as evidence that there’d been transit one way or the other, and that it was a common origin of life on Mars or on the Earth, and it went one way or the other way.
(02:31:43) The other way to see that question, though, would be to say, “Well, actually the whole beginnings of life lie in deterministic chemistry and thermodynamics, starting with the most likely abundant materials, CO₂, and water, and wet, rocky planet,” and Mars was wet and rocky at the beginning and will, I won’t say inevitably, but potentially almost inevitably come up with a genetic code which is not very far away from the genetic code that we already have. So we see subtle differences in the genetic code, what does it mean? It could be very difficult to interpret.
Lex Fridman (02:32:14) Is it possible, do you think, to tell the difference of something that truly originated…
Nick Lane (02:32:19) I think if the stereochemistry was different, we have sugars, for example, that are the L form or the D form, and we have D sugars and L amino acids right across all of life. But lipids, the bacteria have one stereoisomer and the bacteria have the other, the opposite stereoisomer. So it’s perfectly possible to use one or the other one. And the same would almost certainly go for… And I think George Church has been trying to make life based on the opposite stereoisomer. So it’s perfectly possible to do, and it will work. And if we were to find life on Mars that was using the opposite stereoisomer, that would be unequivocal evidence that life had started independently there.
Lex Fridman (02:33:09) So hopefully, the life we find will be on Titan, on Europa or something like that, where it’s less likely that we shared… And it’s harsher conditions, so there’s going to be weirder kind of life?
Nick Lane (02:33:20) I wouldn’t count on that, because-
Lex Fridman (02:33:22) Of water.
Nick Lane (02:33:22) … life started in deep sea hydrothermal vents here.
Lex Fridman (02:33:22) It’s a harsh-
Nick Lane (02:33:27) It’s pretty harsh, yeah. So Titan is different. Europa is probably quite similar to Earth, in the sense that we’re dealing with an ocean. It’s an acidic ocean there, as the early Earth would’ve been. And it almost certainly has hydrothermal systems. Same with Enceladus. We can tell that from these plumes coming from the surface, through the ice. We know there’s a liquid ocean and we can tell roughly what the chemistry is. For Titan, we’re dealing with liquid methane and things like that. So that would really, if there really is life there, it would really have to be very, very different to anything that we know on Earth.

Evolution

Lex Fridman (02:34:00) So the hard leap, the hardest leap, the most important leap is from prokaryotes to eukaryotes. What’s the second, if we were ranking? You gave a lot of emphasis on photosynthesis.
Nick Lane (02:34:17) Yeah, and that would be my second one, I think. But it’s not so much… I mean, photosynthesis is part of the problem. It’s a difficult thing to do. Again, we know it happened once, we don’t know why it happened once, but the fact that it was kind of taken on board completely by plants, and algae, and so on as chloroplasts, and did very well in completely different environments, and then on land and whatever else, seems to suggest that there’s no problem with exploring. You could have a separate origin that explored this whole domain over there that the bacteria had never gone into.
(02:34:59) So that kind of says that the reason that it only happened once is probably because it’s difficult, because the wiring is difficult. But then, it happened at least 2.2 billion years ago, right before the GOE, maybe as long as 3 billion years ago, when some people say there are whiffs of oxygen, there’s just kind of traces in the fossil, in the geochemical record that say maybe there was a bit of oxygen then. That’s really disputed. Some people say it goes all the way back 4 billion years ago, and that it was the common ancestor of life on Earth was photosynthetic. So immediately, you’ve got groups of people who disagree over a 2 billion-year period of time about when it started.
(02:35:41) But let’s take the latest date when it’s unequivocal. That’s 2.2 billion years ago, through to around about the time of the Cambrian explosion, when oxygen levels definitely got close to modern levels, which was around about 550 million years ago. So we’ve gone more than one and a half billion years, where the Earth was in stasis. Nothing much changed. It’s known as the Boring Billion, in fact. Probably, stuff was… That was when Eukaryotes arose somewhere in there, but it’s… So this idea that the world is constantly changing, that we’re constantly evolving, that we’re moving up some ramp, it’s a very human idea, but in reality, there are kind of tipping points to a new stable equilibrium, where the cells that are producing oxygen are precisely counterbalanced by the cells that are consuming that oxygen, which is why it’s 21% now and has been that way for hundreds of millions of years. We have a very precise balance.
(02:36:46) You go through a tipping point, and you don’t know where the next stable state’s going to be, but it can be a long way from here. And so if we change the world with global warming, there will be a tipping point. Question is where, and when, and what’s the next stable state? It may be uninhabitable to us. It’ll be habitable to life, for sure, but there may be something like the Permian extinction, where 95% of species go extinct, and there’s a 5-to-10 million year gap, and then life recovers, but without humans.
Lex Fridman (02:37:16) And the question, statistically, well, without humans, but statistically, does that ultimately lead to greater complexity, more interesting life, more intelligent life?
Nick Lane (02:37:25) Well, after the first appearance of oxygen with the GOE, there was a tipping point which led to a long-term stable state that was equivalent to the Black Sea today, which is to say oxygenated at the very surface and stagnant, sterile… Not sterile, but sulfurous lower down. And that was stable, certainly around the continental margins, for more than a billion years. It was not a state that led to progression in an obvious way.
Lex Fridman (02:37:55) Yeah, I mean, it’s interesting to think about evolution, like what leads to stable states, and how often are evolutionary pressures emerging from the environment? So maybe other planets are able to create evolutionary pressures, chemical pressures, whatever, some kind of pressure that say, “You’re screwed unless you get your shit together in the next 10,000 years.”
Nick Lane (02:38:23) Yeah.
Lex Fridman (02:38:23) Like, a lot of pressure. It seems like Earth, the Boring Billion might be explained in two ways. One, it’s super difficult to take any kind of next step. And the second way it could be explained is there’s no reason to take the next step.
Nick Lane (02:38:39) No, I think there is no reason. But at the end of it, there was a snowball Earth. So there was a planetary catastrophe on a huge scale, where the ice, the sea was frozen at the equator, and that forced change in one way or another. It’s not long after that, a hundred million years, perhaps after that, so not a short time, but this is when we begin to see animals. There was a shift, again, another tipping point that led to catastrophic change that led to a takeoff then. We don’t really know why, but one of the reasons why that I discussed in the book is about sulfate being washed into the oceans, which sounds incredibly parochial.
(02:39:23) But the issue is, I mean, what the data is showing, we can track roughly how oxygen was going into the atmosphere from carbon isotopes. So there’s two main isotopes of carbon that we need to think about here. One is carbon-12, 99% of carbon is carbon-12, and then 1% of carbon is carbon-13, which is a stable isotope. And then, there’s carbon-14, which is a trivial radioactive, it’s trivial amount. So carbon-13 is 1%, and life and enzymes, generally, you can think of carbon atoms as little balls bouncing around, ping-pong balls bouncing around. Carbon-12 moves a little bit faster than carbon-13.
Nick Lane (02:40:00) … bouncing around, ping-pong balls bouncing around. carbon-12 moves a little bit faster than carbon-13 because it’s lighter and it’s more likely to encounter an enzyme, and so it’s more likely to be fixed into organic matter. Organic matter is enriched, and this is just an observation. It’s enriched in Carbon-12 by a few percent compared to carbon-13 relative to what you would expect if it was just equal. If you then bury organic matter as coal or oil or whatever it may be, then it’s no longer oxidized. Some oxygen remains left over in the atmosphere and that’s how oxygen accumulates in the atmosphere.
(02:40:37) You can work out historically how much oxygen there must’ve been in the atmosphere by how much carbon was being buried. You think, well, how can we possibly know how much carbon was being buried? The answer is, well, if you’re burying carbon-12, what you’re leaving behind is more Carbon-13 in the oceans, and that precipitates out into limestone. You can look at limestones over these ages and work out what’s the Carbon-13 signal. That gives you a feedback on what the oxygen content.
(02:41:03) Right before the Cambrian explosion, there was what’s called a negative isotope anomaly excursion, which is basically the carbon-13 goes down by a massive amount and then back up again 10 million years later. What that seems to be saying is the amount of carbon-12 in the oceans was disappearing, which is to say it was being oxidized. If it’s being oxidized, it’s consuming oxygen and that should … A big carbon-13 signal says the ratio of carbon-12 to carbon-13 is really going down, which means there’s much more carbon-12 being taken out and being oxidized.
(02:41:44) Sorry, this is getting too complex, but-
Lex Fridman (02:41:46) Well, it’s a good way to estimate the amount of oxygen.
Nick Lane (02:41:49) If you calculate the amount of oxygen based on the assumption that all this carbon-12 that’s being taken out is being oxidized by oxygen, the answer is all the oxygen in the atmosphere gets stripped out, there is none left. Yet the rest of the geological indicators say, no, there’s oxygen in the atmosphere. It’s a paradox and the only way to explain this paradox just on mass balance of how much stuff is in the air, how much stuff is in the oceans and so on, is to assume that oxygen was not the oxygen, it was sulfate. Sulfate was being washed into the oceans. It’s used as an electron acceptor by sulfate-reducing bacteria just as we use oxygen as an electron acceptor, so they pass their electrons to sulfate instead of oxygen.
Lex Fridman (02:42:32) Bacteria did?
Nick Lane (02:42:33) Yeah, so these are bacteria. They’re oxidizing carbon, organic carbon with sulfate passing the electrons onto sulfate, that reacts with iron to form iron pyrites or fool’s gold, sinks down to the bottom, gets buried out of the system. This can account for the mass balance. Why does it matter? It matters because what it says is there was a chance event. Tectonically, there was a lot of sulfate sitting on land as some kind of mineral. Calcium sulfate minerals, for example are evaporitic and because there happened to be some continental collisions, mountain building, the sulfate was pushed up the side of a mountain and happened to get washed into the ocean.
Lex Fridman (02:43:24) I wonder how many happy accidents like that are possible.
Nick Lane (02:43:27) Yeah, statistically it’s really hard. Maybe you can rule that in statistically or rule out, but this is the course of life on Earth. Without all that sulfate being raised up, the Cambrian explosion almost certainly would not have happened and then we wouldn’t have had animals and so on and so on.
Lex Fridman (02:43:44) This explanation of the Cambrian explosion. Let me actually say in several ways, so folks who challenge the validity of the theory of evolution will give us an example that the Cambrian explosion is like this thing is weird. Now I’m not well studied in this.
Nick Lane (02:44:02) Oh, it’s weird. Yeah.
Lex Fridman (02:44:11) The question I would have is what’s the biggest mystery or gap in understanding about evolution? Is it the Cambrian explosion? If so, first of all, what is it? In my understanding, in the short amount of time, maybe 10 million years, 100 million years, something like that, a huge number of animals, a variety, diversity of animals were created. Anyway, there’s five questions in there. Is that the biggest mystery to you about evolution?
Nick Lane (02:44:44) No, I don’t think it’s particularly a big mystery really anymore. There are still mysteries about why then? I’ve just said being washed into the oceans is one. It needs oxygen and oxygen levels rose around that time. Probably before that, they weren’t high enough for animals. What we’re seeing with the Cambrian explosion is the beginning of predators and prey relationships. We’re seeing modern ecosystems and we’re seeing arms races, and we’re seeing the full creativity of evolution unleashed. I talked about the boring billion. Nothing happens for one and a half, one billion years, one and a half billion years.
(02:45:29) The assumption and this is completely wrong, this assumption is then that evolution works really slowly and that you need billions of years to affect some small change and then another billion years to do something. It’s completely wrong. Evolution gets stuck in a stasis and it stays that way for tens of millions, hundreds of millions of years. Stephen J. Gould used to argue this, he called it punctuated equilibrium, but he was doing it to do with animals and to do with the last 500 million years or so where it’s much less obvious than if you think about the entire planetary history. Then you realize that the first 2 billion years was bacteria only. You have the origin of life, 2 billion years of just bacteria, oxygenic, photosynthesis arising here. Then you have a global catastrophe, snowball Earths, and great oxidation event, and then another billion years of nothing happening, and then some period of upheavals and then another snowball Earth. Then suddenly you see the Cambrian explosion.
(02:46:23) This is long periods of stasis where the world is in a stable state and is not geared towards increasing complexity. It’s just everything is in balance. Only when you have a catastrophic level of global level problem, like of snowball Earth, it forces everything out of balance and there’s a tipping point and you end up somewhere else. Now, the idea that evolution is slow is wrong. It can be incredibly fast. I mentioned earlier on that in theory it would take half a million years to invent an eye, for example, from a light sensitive spot. It doesn’t take long to convert one kind of tube into a tube with nobbles on it into a tube with arms on it, and then multiple arms, and then one end is a head with it starts out as a swelling. It’s not difficult intellectually to understand how these things can happen.
(02:47:18) It boggles the mind that it can happen so quickly, but we’re used to human time scales. What we need to talk about is generations of things that live for a year in the ocean, and then a million years is a million generations. The amount of change that you can do can affect in that period of time is enormous. We’re dealing with large populations of things where selection is sensitive to pretty small changes. Again, as soon as you throw in the competition of predators and prey and you’re ramping up the scale of evolution, it’s not very surprising that it happens very quickly when the environment allows it to happen.
(02:47:58) I don’t think there’s a big mystery. There’s lots of details that need to be filled in. The big mystery in biology is consciousness.
Lex Fridman (02:48:11) The big mystery in biology is consciousness? Well, intelligence is a mystery too. You said biology, not psychology, because from a biology perspective, it seems like intelligence and consciousness all are the same weird, all the brain stuff.
Nick Lane (02:48:37) I don’t see intelligence as necessarily that difficult, I suppose. I see it as a form of computing, and I don’t know much about computing.
Lex Fridman (02:48:46) Well, you don’t know much about consciousness either. Oh, I see, I see, I see, I see. That consciousness you do know a lot about as a human being.
Nick Lane (02:49:00) No, no. I can understand the wiring of a brain in pretty much the same way as a computer in theory, in terms of the circuitry of it. The mystery to me is how this system gives rise to feelings, as we were talking about earlier on.
Lex Fridman (02:49:23) Yeah, I think we oversimplify intelligence. I think the dance, the magic of reasoning is as interesting as the magic of feeling. We tend to think of reasoning as running a very simplistic algorithm. I think reasoning is the interplay between memory, whatever the hell is going on, the unconscious mind, all of that.
Nick Lane (02:49:55) I’m not trying to diminish it in any way at all. Obviously, it’s extraordinarily exquisitely complex, but I don’t see a logical difficulty with how it works.
Lex Fridman (02:50:06) Yeah, no, I agree with you, but sometimes, yeah, there’s a big cloak of mystery around consciousness.
Nick Lane (02:50:16) Let me compare it with classical versus quantum physics. Classical physics is logical and you can understand the language we’re dealing with. It’s almost at the human level, we’re dealing with stars and things that we can see. When you get to quantum mechanics and things, it’s practically impossible for the human mind to compute what just happened there.
Lex Fridman (02:50:39) Yeah, that is the same. It’s like you understand mathematically the notes of a musical composition, that’s intelligence. But why it makes you feel a certain way? That is much harder to understand. Yeah, that’s really, but it was an interesting framing that that’s a mystery at the core of biology. I wonder who solves consciousness. I tend to think consciousness will be solved by the engineer, meaning the person who builds it, who keeps trying to build the thing, versus biology is such a complicated system. I feel like the building blocks of consciousness from a biological perspective are that’s the final creation of a human being, so you have to understand the whole damn thing. You said the electrical fields, but electrical fields plus, plus everything, the whole shebang.
Nick Lane (02:51:47) I’m inclined to agree. My feeling is from my meager knowledge of the history of science is that the biggest breakthrough has usually come through from a field that was not related to. If anyone is not going to be a biologist who solves consciousness, just because biologists are too embedded in the nature of the problem. Then nobody’s going to believe you when you’ve done it because nobody’s going to be able to prove that this AI is in fact conscious and sad in any case and any more than you can prove that a dog is conscious and sad, so it tells you that it is in good language and you must believe it.
(02:52:24) But I think most people will accept if faced with that, that that’s what it is. All of this probability though of complex life. In one way, I think why it matters is that my expectation I suppose is that we will be over the next 100 years or so, if we survive it all, that AI will increasingly dominate. Pretty much anything that we put out into space looking for the universe, for what’s out there will be AI. It won’t be us, we won’t be doing that, or when we do, it will be on a much more limited scale. I suppose the same would apply to any alien civilization.
(02:53:12) Perhaps rather than looking for signs of life out there, we should be looking for AI out there, but then we face the problem that I don’t see how a planet is going to give rise directly to AI. I can see how a planet can give rise directly to organic life, and if the principles that govern the evolution of life on Earth apply to other planets as well. I think a lot of them would, then the likelihood of ending up with a human-like civilization capable of giving rise to AI in the first place is massively limited. Once you’ve done it once, perhaps it takes over the universe and maybe there’s no issue, but it seems to me that the two are necessarily linked, that you’re not going to just turn a sterile planet into an AI life form without the intermediary of the organics first.
Lex Fridman (02:54:09) You have to run the full evolutionary computation with your organics to create AI?
Nick Lane (02:54:15) How does AI bootstrap itself up without the aid, if you like, of an intelligent designer?

Fermi paradox

Lex Fridman (02:54:20) The origin of AI is going to have to be in the chemistry of a planet, but that’s not a limiting factor. Let me ask the Fermi Paradox question. Let’s say we live in this incredibly dark and beautiful world of just billions of planets with bacteria on it and very few intelligent civilizations, and yet there’s a few out there. Why haven’t we at scale seen them visit us? What’s your sense? Is it because they don’t exist? It it because-
Nick Lane (02:55:02) Well, they don’t exist in the right part of the universe at the right time. That’s the simplest answer for it.
Lex Fridman (02:55:08) Is that the one you find the most compelling or is there some other explanation?
Nick Lane (02:55:14) No, it’s not that I find it more compelling, it’s that I find more probable and I find all of them. There’s a lot of hand waving in this, we just don’t know. I’m trying to read out from what I know about life on Earth to what might happen somewhere else. It gives to my mind a bit of a pessimistic view of bacteria everywhere and only occasional intelligent life. Running forward, humans only once on Earth and nothing else that you would necessarily be any more excited about making contact with than you would be making contact with them on Earth.
(02:55:50) I think the chances are pretty limited and the chances of us surviving are pretty limited too. The way we’re going on at the moment, the likelihood of us not making ourselves extinct within the next few 100 years, possibly within the next 50 or 100 years seems quite small. I hope we can do better than that. Maybe the only thing that will survive from humanity will be AI and maybe AI once it exists, and once it’s capable of effectively copying itself and cutting humans out of the loop, then maybe that will take over the universe.
Lex Fridman (02:56:24) There’s an inherent sadness to the way you described that, but isn’t that also potentially beautiful that that’s the next step of life? I suppose from your perspective, as long as it carries the flame of consciousness somehow.
Nick Lane (02:56:41) I think yes, there can be some beauty to it being the next step of life. I don’t know if consciousness matters or not from that point of view, to be honest with you, but there’s some sadness, yes, probably because I think it comes down to the selfishness that we were talking about earlier on. I am an individual with a desire not to be displaced from life. I want to stay alive, I want to be here. I suppose the threat that a lot of people would feel is that we will just be wiped out, so there will be potential conflicts between AI and humans, and that AI will win because it’s a lot smarter.
Lex Fridman (02:57:25) Boy, would that be a sad state of affairs if consciousness is just an intermediate stage between bacteria and AI.
Nick Lane (02:57:34) Well, I would see bacteria as being potentially a primitive form of consciousness anyway. The whole of life on Earth to my mind-
Lex Fridman (02:57:43) Is conscious.
Nick Lane (02:57:44) … Is capable of some form of feelings in response to the environment. That’s not to say it’s intelligent, though it’s got his own algorithms for intelligence, but nothing comparable with us. I think it’s beautiful what a sterile planet can come up with. It’s astonishing that it’s come up with all of this stuff that we see around us and that either we or whatever we produce is capable of destroying all of that is a sad thought, but it’s also hugely pessimistic. I’d like to think that we’re capable of giving rise to something which is at least as good, if not better than us as AI.
Lex Fridman (02:58:24) Yeah, I have that same optimism, especially a thing that is able to propagate throughout the universe more efficiently than humans can or extensions of humans, some merger with AI and humans, whether that comes from bioengineering of the human body to extend its life somehow to carry that flame of consciousness and that personality and the beautiful tension that’s within all of us, carry that through to multiple planets, to multiple solar systems all out there in the universe. That’s a beautiful vision. Whether AI can do that or bio engineered humans can, that’s an exciting possibility. Especially meeting other alien civilizations in that same way.
(02:59:14) Do you think aliens have consciousness?
Nick Lane (02:59:16) If they’re organic, yes.
Lex Fridman (02:59:18) Organic, connected to consciousness?
Nick Lane (02:59:20) I think any system which is going to bootstrap itself up from planetary origins. Let me finish this and then I come onto something else … but from planetary origins is going to face similar constraints, and those constraints are going to be addressed in similar basic engineering ways. I think it will be cellular, and I think it will have electrical charges, and I think it will have to be selected in populations over time. All of these things will tend to give rise to the same processes as the simplest fix to a difficult problem. I would expect it to be conscious, yes, and I would expect it to resemble life on Earth in many ways. When I was about 15 or 16, I remember reading a book by Fred Hoyle called The Black Cloud, which I was a budding biologist at the time and this was the first time I’d come across someone really challenging the heart of biology and saying, “You are far too parochial. You’re thinking about life as carbon-based. Here’s a life form which is kind of dust, interstellar dust on a solar system scale.”
(03:00:28) It’s a novel, but I felt enormously challenged by that novel because it hadn’t occurred to me how limited my thinking was, how narrow-minded I was being. Here was a great physicist with a completely different conception of what life be. Since then, I’ve seen him attacked in various ways. I’m reluctant to say the attacks make more sense to me than the original story, which is to say even in terms of information processing, if you’re on that scale and there’s a limit of the speed of how quickly can something think, if you’re needing to broadcast across the solar system, it is going to be slow.
(03:01:16) It’s not going to hold a conversation with you on the timelines that Fred Hoyle was imagining, or at least not by any easy way of doing it, assuming that the speed of light is a limit. Then again, you really can’t. This is something Richard Dawkins argued long ago and I do think he’s right. There is no other way to generate this level of complexity than natural selection. Nothing else can do it. You need populations and you need selection in populations and an isolated interstellar cloud. Again, there’s unlimited time and maybe there’s no problems with distance, but you need to have a certain frequency of generational time to generate a serious level of complexity. I just have a feeling it’s never going to work.
Lex Fridman (03:02:11) Well, as far as we know. Natural selection, evolution is really a powerful tool here on Earth, but there could be other mechanisms. I don’t know if you’re familiar with cellular automaton, but complex systems that have really simple components and seemingly move based on simple rules when they’re taken as a whole, really interesting complexity emerges. I don’t know what the pressures on that are. It’s not really selection, but interesting complexity seems to emerge, and that’s not well understood exactly why that complexity emerges.
Nick Lane (03:02:46) I think there’s a difference between complexity and evolution. Some of the work we’re doing on the origin of life is thinking about how do genes arise? How does information arise in biology? Thinking about it from the point of view of reacting CO₂ with hydrogen, what do you get? Well, what you’re going to get is carboxylic acids, then amino acids. It’s quite hard to make nucleotides. It’s possible to make them, and it’s been done and it’s being done following this pathway as well, but you make trace amounts. The next question, assuming that this is the right way of seeing the question, which maybe it’s just not, but let’s assume it is well, how do you reliably make more nucleotides? How do you become more complex and better at becoming a nucleotide generating machine? The answer is, well, you need positive feedback loops, some form of autocatalysis.
(03:03:40) That can work and we know it happens in biology. If this nucleotide, for example, catalyzes CO₂ fixation, then you’re going to increase the rate of flux through the whole system, and you’re going to effectively steepen the driving force to make more nucleotides. This can be inherited because there are forms of membrane heredity that you can have and there are effectively, if a cell divides in two and it’s got a lot of stuff inside it and that stuff is basically bound as a network which is capable of regenerating itself, then it will inevitably regenerate itself.
(03:04:17) You can develop greater complexity, but everything that I’ve said depends on the underlying rules of thermodynamics. There is no evolvability about that. It’s simply an inevitable outcome of your starting point, assuming that you’re able to increase the driving force through the system. You will generate more of the same, you’ll expand on what you can do, but you’ll never get anything different than that. It’s only when you introduce information into that as a gene, as a small stretch of RNA, which can be random stretch, then you get real evolvability. Then you get biology as we know it, but you’ll also have selection as we know it.
Lex Fridman (03:05:00) Yeah. I don’t know how to think about information. That’s the memory of the system. At the local level, it’s propagation of copying yourself and changing and improving your adaptability to the environment, but if you look at Earth as a whole, it has a memory. That’s the key feature of it.
Nick Lane (03:05:25) In what way?
Lex Fridman (03:05:27) It remembers the stuff it tries. If you were to describe Earth, I think evolution is something that we experience as individual organisms. That’s how the individual organisms interact with each other, there’s a natural selection. But when you look at Earth as an organism in its entirety, how would you describe it?
Nick Lane (03:05:56) Well, not as an organism. The idea of Gaia is lovely and James Lovelock originally put Gaia out as an organism that had somehow evolved and he was immediately attacked by lots of people. He’s not wrong, but he backpedaled somewhat because that was more of a poetic vision than the science. The science is now called Earth systems science, and it’s really about how does the world regulate itself so it remains within the limits which are hospitable to life, and it does it amazingly well. It is working at a planetary level of integration of regulation, but it’s not evolving by natural selection. It can’t because there’s only one of it. It can change over time, but it’s not evolving. All the evolution is happening in the parts of the system.
Lex Fridman (03:06:50) Yeah, but it’s a self-sustaining organism.
Nick Lane (03:06:53) No, it’s self-sustained by the sun.
Lex Fridman (03:06:56) Right, you don’t think it’s possible to see Earth as its own organism?
Nick Lane (03:07:03) I think it’s poetic and beautiful, and I often refer to the Earth as a living planet, but it’s not in biological terms an organism, no.
Lex Fridman (03:07:14) If aliens were to visit Earth, what would they notice? What would be the basic unit of light that would notice?
Nick Lane (03:07:24) Trees probably, it’s green and it’s green and blue. I think that’s the first thing you’d notice is it stands out from space as being different to any of the other planets.
Lex Fridman (03:07:33) Would notice the trees at first because the green?
Nick Lane (03:07:36) Well, I would. I notice the green, yes.
Lex Fridman (03:07:38) Yeah. Then probably notice to figure out the photosynthesis and then-
Nick Lane (03:07:43) Probably notice cities a second there, I suspect. Maybe first. If they arrived at night, they noticed cities first, that’s for sure.

Cities

Lex Fridman (03:07:50) Yeah, it depends the time. You write quite beautifully in Transformers. Once again, I think you opened the book in this way. I don’t remember. From space describing Earth, it’s such an interesting idea of what Earth is. Hitchhiker’s Guide summarizing it as harmless or mostly harmless. It’s a beautifully poetic thing.
(03:08:15) You open Transformers with “From space, it looks gray and crystalline, obliterating the blue-green colors of the living Earth. It is crisscrossed by regular patterns and convergence striations. There’s a central amorphous density where these scratches seem lighter. This ‘growth’ does not look alive, although it has extended out along some lines and there is something grasping and parasitic about it. Across the globe, there are thousands of them varying in shape and detail, but all of them, gray, angular, inorganic, spreading. Yet at night they light up, glowing up the dark sky, suddenly beautiful. Perhaps these cankers on the landscape are in some sense living. There’s a controlled flow of energy. There must be information and some form of metabolism, some turnover of materials. Are they alive? No, of course not. They are cities.”
(03:09:17) Is there some sense that cities are living beings? You think aliens would think of them as living beings?
Nick Lane (03:09:25) Well, it’d be easy to see it that way, wouldn’t it?
Lex Fridman (03:09:29) It wakes up at night, they wake up at night.
Nick Lane (03:09:33) Strictly nocturnal, yes. I imagine that any aliens that are smart enough to get here would understand that they’re not living beings. My reason for saying that is that we tend to think of biology in terms of information and forget about the cells. I was trying to draw a comparison between the cell as a city and the energy flow through the city and the energy flow through cells and the turnover of materials. An interesting thing about cities is that they’re not really exactly governed by anybody. There are regulations and systems and whatever else, but it’s pretty loose. They have their own life, their own way of developing over time.
(03:10:24) In that sense, they’re quite biological. There was a plan after the Great Fire of London, Christopher Wren was making plans not only for St. Paul’s Cathedral, but also to rebuild in large Parisian-type boulevards, a large part of the area of central London that was burnt. It never happened because they didn’t have enough money I think, but it’s interesting what was in the plan. There were all these boulevards, but there were no pubs and no coffee houses or anything like that. The reality was London just grew up in a set of jumbled streets.
(03:11:03) It was the coffee houses and the pubs where all the business of the City of London was being done. That was where the real life of the city was. No one had planned it. The whole thing was unplanned and works much better that way. In that sense, the cell is completely unplanned. It’s not controlled by the genes in the nucleus in the way that we might like to think that it is, but it’s an evolved entity that has the same flux, the same animation, the same life. I think it’s a beautiful analogy, but I wouldn’t get too stuck with it as a metaphor.
Lex Fridman (03:11:32) See, I disagree with you. I disagree with you. I think you are so steeped. Actually, the entirety of science, the history of science is steeped in a biological framework of thinking about what is life. Not just biological, is very human-centric too, that the human organism is the epitome of life on Earth. I don’t know, I think there is some deep fundamental way-
Lex Fridman (03:12:00) On earth, I don’t know. I think there is some defundimental way in which a city is a living being in the same way that a-
Nick Lane (03:12:10) It doesn’t give rise to an offspring city. So it doesn’t work by natural selection, it works by, if anything, memes, it works by.
Lex Fridman (03:12:19) Yeah. But isn’t it-
Nick Lane (03:12:20) Copying itself conceptually as a mode of being?
Lex Fridman (03:12:24) So, maybe memes, maybe ideas are the organisms that are really essential to life on Earth. Maybe it’s much more important about the collective aspect of human nature, the collective intelligence than the individual intelligence. Maybe the collective humanity is the organism and the thing that defines the collective intelligence of humanity is the ideas. And maybe the way that manifests itself is cities maybe, or societies or geographically constrained societies or nations and all that kind of stuff. From an alien perspective, it’s possible that that is the more deeply noticeable thing, not from a place of ignorance.
Nick Lane (03:13:08) Yes, but what’s noticeable doesn’t tell you how it works. I don’t have any problem with what you’re saying really, except that it’s not possible without the humans. We went from a hunter-gatherers type economy, if you like, without cities, through to cities. And as soon as we get into human evolution and culture and society and so on, then yes, there are other forms of evolution, other forms of change. But cities don’t directly propagate themselves, they propagate themselves through human societies. And human societies only exist because humans as individuals propagate themselves. So there is a hierarchy there. And without the humans in the first place, none of the rest of it exists.
Lex Fridman (03:13:54) So for you, life is primarily defined by the basic unit on which evolution can operate on Earth.
Nick Lane (03:14:02) I think it’s really important thing. Yes.
Lex Fridman (03:14:04) Yeah. And we don’t have any other better ideas than evolution for how to create life.
Nick Lane (03:14:10) I never came across a better idea than evolution. Maybe I’m just ignorant and I don’t know. And you mentioned that’s automator and so on, and I don’t think specifically about that, but I have thought about it in terms of selective units at the origin of life and the difference between evolvability and complexity or just increasing complexity, but within very narrowly defined limits. The great thing about genes and about selection is it just knocks down all those limits. It gives you a world of information in the end, which is limited only by the biophysical reality of what kind of an organism you are, what kind of a planet you live on and so on. And cities and all these other forms that look alive and could be described as alive, because they can’t propagate themselves can only exist as the product of something that did propagate itself.
Lex Fridman (03:15:05) Yeah, there’s a deeply compelling truth to that kind of way of looking at things, but I just hope that we don’t miss the giant cloud among us.
Nick Lane (03:15:18) I kind of hope that I’m wrong about a lot of this because I can’t say that my worldview is particularly uplifting, but in some sense it doesn’t matter if it’s uplifting or not, science is about what’s reality. What’s out there? Why is it this way? And I think there’s beauty in that too.

Depression

Lex Fridman (03:15:39) There’s beauty in darkness. You write about life and death sort of at the biological level. Does the question of suicide, why live? Does the question of why the human mind is capable of depression? Are you able to introspect that from a place of biology? Why our minds, why we humans can go to such dark places? Why can we commit suicide? Why can we go suffer? Suffer, period, but also suffer from a feeling of meaninglessness of going to a dark place that depression can take you? Is this a feature of life or is it a bug?
Nick Lane (03:16:30) I don’t know. If it’s a feature of life, then I suppose it would have to be true of other organisms as well. And I don’t know. We were talking about dogs earlier on and they can certainly be very sad and upset and may mooch for days after their owner died or something like that. So I suspect in some sense it’s a feature of biology. It is probably a feature of mortality. It’s probably a… But beyond all of that, I guess there’s two ways you could come at it. One of them would be to say, well, you can effectively do the math and come to the conclusion that it’s all pointless and that there’s really no point in me being here any longer. And maybe that’s true in the greater scheme of things. You can justify yourself in terms of society, but society will be gone soon enough as well. And you end up with a very bleak place just by logic.
Lex Fridman (03:17:26) In some sense, it’s surprising that we can find any meaning at all.
Nick Lane (03:17:30) Well, maybe this is where consciousness comes in that we have transient joy, but with transient joy, we have transient misery as well. And sometimes with everything in biology, getting the regulation right is practically impossible. You will always have a bell-shaped curve where some people unfortunately are at the joy end and some people are at the misery end, and that’s the way brains are wired. And I doubt there’s ever an escape from that. It’s the same with sex and everything else as well, where dealing with you can’t regulate it. So anything goes. It’s all part of biology.

Writing

Lex Fridman (03:18:12) Amen to that. Let me, on writing in your book, Power, Sex and Suicide. First of all, can I just read off the books you’ve written, if there’s any better titles and topics to be covered, I don’t know what they are. It makes me look forward to whatever you’re going to write next. I hope there’s things you write next. So first you wrote Oxygen: The Molecule that Made the World as we’ve talked about this idea of the role of oxygen in life on Earth. Then wait for it, Power, Sex, Suicide: Mitochondria and the Meaning of Life. Then Life Ascending: The 10 Great Inventions of Evolution. The Vital Question, the first book I’ve read of yours, the Vital Question: Why is Life the Way It Is? And the new book Transformer: The Deep Chemistry of Life and Death. In Power, sex and Suicide, you write about writing or about a lot of things, but I have a question about writing.
(03:19:13) You write in the Hitchhiker’s Guide to the Galaxy Ford Prefect spends 15 years researching his revision to the Guide’s entry on the Earth, which originally read, “Harmless,” by the way, I would also as a side question, I would like to ask you what would be your summary of what Earth is.
(03:19:34) But you write, “His long essay on the subject is edited down by the guide to read “Mostly Harmless.” I suspect that too many new editions suffer similar fate, if not through absurd editing decisions, at least through a lack of meaningful change in content. As it happens, nearly 15 years have passed since the first edition of Power, Sex, Suicide was published, and I am resisting the temptation to make any lame revisions. Some say that even Darwin lessened the power of his arguments in the Origin of species through his multiple revisions in which he dealt with criticisms and sometimes shifted his views in the wrong direction. I prefer my original to speak for itself even if it turns out to be wrong.”
(03:20:23) Let me ask the question about writing, both your students in the academic setting, but also writing some of the most brilliant writings on science and humanity I’ve ever read. What’s the process of writing? How do you advise other humans? If you were to talk to young Darwin or the young you and just young anybody and give advice about how to write and how to write well about these big topics, what would you say?
Nick Lane (03:20:57) I suppose there’s a couple of points. One of them is, what’s the story? What do I want to know? What do I want to convey? Why does it matter to anybody? And very often the biggest, most interesting questions, the childlike questions are the one that actually everybody wants to ask, but daren’t quite do it in case they look stupid. And one of the nice things about being in science is the longer you’re in, the more you realize that everybody doesn’t know the answer to these questions and it’s not so stupid to ask them after all.
(03:21:36) So trying to ask the questions that I would’ve been asking myself at the age of 15, 16 when I was really hungry to know about the world and didn’t know very much about it and wanted to go to the edge of what we know but be helped to get there. I don’t want too much terminology. And so I want someone to keep a clean eye on what the question is. Beyond that, I’ve wondered a lot about who am I writing for? And that was in the end, the only answer I had was myself at the age of 15 or 16. Because even if you just don’t know who’s reading it, but also where are they reading it? Are they reading it in the bath or in bed or on the metro or are they listening to an audiobook? Do you want to have a recapitulation every few pages because you read three pages at a time?
(03:22:41) Or are you really irritated by that? You’re going to get criticism from people who are irritated by what you’re doing and you don’t know who they are or what you’re going to do that’s going to irritate people. And in the end, all you can do is just try and please yourself. And that means what are these big, fun, fascinating, big questions, and what do we know about it? And can I convey that? And I kind of learned in trying to write, first of all, say what we know. And I was shocked in the first couple of books how often I came up quickly against all the stuff we don’t know.
(03:23:21) And if you’re trying to… I realized later on in supervising various physicists and mathematicians who are PhD students and I know their math is way beyond what I can do. But the process of trying to work out what are we actually going to model here, what’s going into this equation? It’s a very similar one to writing, what am I going to put on a page? What’s the simplest possible way I can encapsulate this idea so that I now have it as a unit that I can kind of see how it interacts with the other units? And you realize that, well, if this is like that and this is like this, then that can’t be true.
(03:23:58) So you end up navigating your own path through this landscape and that can be thrilling because you don’t know where it’s going. And I’d like to think that that’s one of the reasons my books have worked for people because this sense of thrilling adventure ride, I don’t know where it’s going either.
Lex Fridman (03:24:14) So finding the simplest possible way to explain the things we know and the simplest possible way to explain the things we don’t know and the tension between those two, that’s where the story emerges. What about the edit? Do you find yourself to the point of this editing down to most harmless. To arrive at simplicity, do you find the edit is productive or does it destroy the magic that was originally there?
Nick Lane (03:24:44) No, I usually find… I think I’m perhaps a better editor than I’m a writer. I write and rewrite and rewrite and rewrite.
Lex Fridman (03:24:51) Put a bunch of crap on the page first and then see where the edit takes it.
Nick Lane (03:24:56) But then there’s the professional editors who come along as well. And in Transformer, the editor came back to me after I’d sent… Two months after I sent the first edition, he’d read the whole thing and he said, “The first two chapters prevent a formidable hurdle to the general reader, go and do something about it.” And that was the last thing I really wanted to hear.
Lex Fridman (03:25:18) But your editor sounds very eloquent in speech.
Nick Lane (03:25:21) Yeah. Well, this was an email, but I thought about it. The bottom line is he was right. And so I put the whole thing aside for about two months, spent the summer, this would’ve been I guess last summer, and then turned to it with full attention in about September or something and rewrote those chapters almost from scratch. I kept some of the material, but it took me a long time to process it, to work out what needs to change, where does it need to… I wasn’t writing in this time, how am I going to tell this story better so it’s more accessible and interesting. And in the end, I think it worked. It is still difficult, it’s still biochemistry, but he ended up saying, “Now it’s got a barreling energy to it.” And because he’d told me the truth the first time I decided to believe that he was telling me the truth the second time as well and was delighted.

Advice for young people

Lex Fridman (03:26:13) Could you give advice to young people in general, folks in high school, folks in college, how to take on some of the big questions you’ve taken on. Now you’ve done that in the space of biology and expand it out, how can they have a career they can be proud of or have a life they can be proud of?
Nick Lane (03:26:35) Gosh, that’s a big question.
Lex Fridman (03:26:40) I’m sure you’ve gathered some wisdom that you can impart.
Nick Lane (03:26:46) So the only advice that I actually ever give to my students is follow what you’re interested in. Because they’re often worried that if they make this decision now and do this course instead of that course, then they’re going to restrict their career opportunities. And there isn’t a career path in science. There is but isn’t. There’s a lot of competition. There’s a lot of death symbolically. So who survives? The people who survive are the people who care enough to still do it. And they’re very often the people who don’t worry too much about the future and are able to live in the present. If you do a PhD, you’ve competed hard to get onto the PhD, then you have to compete hard to get a post-doc job and you have the next bond maybe on another continent, and it’s only two years anyway, and there’s no guarantee you’re going to get a faculty position at the end of it.
Lex Fridman (03:27:51) And there’s always the next step to compete. If you get a faculty position, you get a tenure, and with tenure you go full professor and full professor, then you go to some kind of whatever the discipline is, there’s an award. If you’re in physics, you’re always competing for the Nobel Prize, there’s different awards and then eventually you’re all competing to… There’s always a competition.
Nick Lane (03:28:12) So there is no happiness. Happiness does not lie.
Lex Fridman (03:28:15) If you’re looking into the future, yes.
Nick Lane (03:28:16) And if what you’re caring about is a career, then it’s probably not the one for you. If though, you can put that aside. And I’ve also worked in industry for a brief period and I was made redundant twice, so I know that there’s no guarantee that you’ve got a career that way either.
Lex Fridman (03:28:37) Yes.
Nick Lane (03:28:40) So live in the moment and try and enjoy what you’re doing. And that means really go to the themes that you’re most interested in and try and follow them as well as you can. And that tends to pay back in surprising ways. I don’t know if you’ve found this as well, but I found that people will help you often, if they see some light shining in the eye and you are excited about their subject and just want to talk about it. And they know that their friend in California’s got a job coming up, they’ll say, “Go for this. This guy’s all right.” They’ll use the network to help you out if you really care. And you’re not going to have a job two years down the line, but what you really care about is what you’re doing now, then it doesn’t matter if you have a job in two years time or not. It’ll work itself out if you’ve got the light in your eye. And so that’s the only advice I can give. And most people probably drop out through that system because the fight is just not worth it for them.
Lex Fridman (03:29:49) Yeah, when you have the light in your eye, when you have the excitement for the thing, what happens is you start to surround yourself with others that are interested in that same thing that also have the light. If you really are rigorous about this, I think it takes effort to make…
Nick Lane (03:30:07) Oh, you’ve got to be obsessive. But if you’re doing what you really love doing, then it’s not work anymore, it’s what you do.
Lex Fridman (03:30:13) But I also mean the surrounding yourself with other people that are obsessed about the same thing because depending on-
Nick Lane (03:30:19) Oh, that takes some work as well.
Lex Fridman (03:30:20) Yes.
Nick Lane (03:30:21) And luck
Lex Fridman (03:30:21) Finding the right mentors, the collaborators. Because I think one of the problem with the PhD process is people are not careful enough in picking their mentors. Those are people… Mentors and colleagues and so on, those people are going to define the direction of your life, how much you love a thing. The power of just the few little conversations you have in the hallway is incredible. So you have to be a little bit careful in that sometimes you just get randomly almost assigned. Really pursue, I suppose, the subject as much as you pursue the people that do that subject. So both the whole dance of it.
Nick Lane (03:31:09) They kind of go together really.
Lex Fridman (03:31:10) Yeah, they do. They really do. But take that part seriously, and probably in the way you’re describing it, careful how you define success because-
Nick Lane (03:31:22) You’ll never find happiness in success. I think there’s a lovely quote from Robert Louis, Stevenson, I think, who said, “Nothing in life is so disenchanting as attainment.”
Lex Fridman (03:31:33) Yeah. So in some sense, the true definition of success is getting to do today, what you really enjoy doing, just what fills you with joy. And that’s ultimately success. Success isn’t the thing beyond the horizon, the big trophy, the financial-
Nick Lane (03:31:54) I think it’s as close as we can get to happiness. That’s not to say you’re full of joy all the time, but it’s as close as we can get to a sustained human happiness is by getting some fulfillment from what you’re doing on a daily basis. And if what you’re looking for is the world giving you the stamp of approval with a Nobel Prize or a fellowship or whatever it is, then I’ve known people like this who they’re eaten away by the anger, the kind of caustic resentment that they’ve not been awarded this prize that they deserve.
Lex Fridman (03:32:30) And the other way, if you put too much value into those kinds of prizes and you win them, I’ve gotten the chance to see that the more “successful” you are in that sense, the more you run the danger of growing ego so big that you don’t get to actually enjoy the beauty of this life. You start to believe that you figured it all out, as opposed to, I think what ultimately the most fun thing is being curious about everything around you, being constantly surprised and these little moments of discovery, of enjoying beauty in small and big ways all around you.
(03:33:12) And I think the bigger your ego grows, the more you start to take yourself seriously, the less you’re able to enjoy that.
Nick Lane (03:33:17) Oh man, I couldn’t agree more.

Earth

Lex Fridman (03:33:20) So the summary from harmless to mostly harmless in Hitchhiker’s Guide to the Galaxy, how would you try to summarize Earth? And if you had to summarize the whole thing in a couple of sentences and maybe throw in meaning of life in there, why? Maybe is that a defining thing about humans that we care about the meaning of the whole thing? I wonder if that should be part of the… These creatures seem to be very lost.
Nick Lane (03:33:58) Yes. They’re always asking why. That’s my defining question is why. People used to made a joke, I have a small scar on my forehead from a climbing accident years ago, and the guy I was climbing with had dislodged a rock and he shouted something, he shouted, “Below,” I think, meaning that the rock was coming down and I hadn’t caught what he said. So I looked up and he went smashed straight on my forehead, and everybody around me took the piss saying, “He looked up to ask why.”
Lex Fridman (03:34:32) Yeah, but that’s a human imperative, that’s part of what it means to be human. Look up to the sky and ask why.
Nick Lane (03:34:42) So your question, define the Earth. I’m not sure I can do that. The first word that comes to mind is living, I wouldn’t like to say mostly living, but perhaps.
Lex Fridman (03:34:57) Mostly living. Well, it’s interesting because if you were to write The Hitchhiker’s Guide to the Galaxy, I suppose say our idea that we talked about, the bacteria is the most prominent form of life throughout the galaxy in the universe. I suppose that Earth would be kind of unique and would require-
Nick Lane (03:35:22) There’s abundance in that case.
Lex Fridman (03:35:24) Yeah.
Nick Lane (03:35:25) It’s profligate, it’s rich. It’s enormously, enormously living.
Lex Fridman (03:35:29) So how would you describe that it’s not bacteria, it’s…
Nick Lane (03:35:36) Eukaryotic.
Lex Fridman (03:35:39) Yeah.
Nick Lane (03:35:39) Well that’s the technical term, but it is basically.
Lex Fridman (03:35:46) Yeah. [inaudible 03:35:47]
Nick Lane (03:35:47) How would I describe that? I’ve actually really struggled with that term because the word… There’s few words quite as good as eukaryotic to put everybody off immediately. You start using words like that and maybe they’ll leave the room. Krebs cycle is another one that gets people to leave the room.
Lex Fridman (03:36:06) That’s interesting.
Nick Lane (03:36:07) So I’m trying to think, is there another word for eukaryotic that I can use? And really the only word that I’ve been able to use is complex, complex cells, complex life and so on. And that word, it serves one immediate purpose, which is to convey an impression, but then it means so many different things to everybody that actually is lost immediately. And so it is kind of…
Lex Fridman (03:36:36) Well, that’s a noticeable from the perspective of other planets, that is a noticeable face transition of complexity is the eukaryotic. What about the harmless and the mostly harmless? Is that kind of…
Nick Lane (03:36:51) Probably accurate on a universal kind of scale. I don’t think that humanity is in any danger of disturbing the universe at the moment.
Lex Fridman (03:37:02) At the moment, which is why the mostly, we don’t know. Depends what Elon is up to. Depends how many rockets. I think-
Nick Lane (03:37:10) It’ll be still even then a while, I think, before we disturb the fabric of time and space.
Lex Fridman (03:37:17) Was the aforementioned Andrej Karpathy. I think he summarized earth as a system where you hammer it with a bunch of photons. The input is like photons and the output is rockets. If you just-
Nick Lane (03:37:37) Well, that’s a hell of a lot of photons before it was a rocket.
Lex Fridman (03:37:40) But maybe in the span of the universe, it’s not that much time. And I do wonder what the future is, whether we’re just in the early beginnings of this Earth, which is important when you try to summarize it or we’re at the end where humans have finally gained the ability to destroy the entirety of this beautiful project we’ve got going on now with nuclear weapons, with engineered viruses, with all those kinds of things.
Nick Lane (03:38:10) Or just inadvertently through global warming and pollution and so on. We’re quite capable. We just need to pass the point.
Lex Fridman (03:38:18) [inaudible 03:38:18]
Nick Lane (03:38:18) I think we’re more likely to do it inadvertently than through a nuclear war, which could happen at any time. But my fear is we just don’t know where the tipping points are and we will kind of think we’re smart enough to fix the problem quickly if we really need to. I think that’s the overriding assumption that, “We’re all right for now. Maybe in 20 years time it’s going to be a calamitous problem, and then we’ll really need to put some serious mental power into fixing it.” Without seriously worrying that perhaps that is too late and that however brilliant we are, we miss the boat.
Lex Fridman (03:38:59) And just walk off the cliff. I don’t know. I have optimism in humans being clever descendants.
Nick Lane (03:39:05) Oh, I have no doubt that we can fix the problem, but it’s an urgent problem and we need to fix it pretty sharpish.
Lex Fridman (03:39:14) And-
Nick Lane (03:39:14) I do have doubts about whether politically we are capable of coming together enough to not just in any one country, but around the planet to… I know we can do it, but do we have the will? Do we have the vision to accomplish it?
Lex Fridman (03:39:31) That’s what makes this whole ride fun. We don’t know, not only do we not know if we can handle the crises before us, we don’t even know all the crises that are going to be before us in the next 20 years. The ones, I think, that will most likely challenge us in the 21st century are the ones we don’t even expect. People didn’t expect World War II at the end of World War I.
Nick Lane (03:39:57) Not at the end of World War I, but by the late 1920s, I think people were beginning to worry about it.
Lex Fridman (03:40:03) Yeah, no, there’s always people worrying about everything. So if you focus on the thing that-
Nick Lane (03:40:08) People worry about, yes.
Lex Fridman (03:40:09) Because there’s a million things people worry about and 99.99999% of them don’t come to be. Of course, the people that turn out to be right, they’ll say, I knew all along,” but that’s not an accurate way of knowing what you could have predicted. I think rationally speaking, you can worry about it, but nobody thought you could have another world war, the war to end all wars. Why would you have another war? And the idea of nuclear weapons just technologically is a very difficult thing to anticipate, to create a weapon that just jumps orders of magnitude and destructive capability. And of course, we can intuit all the things like engineered viruses, nanobots, artificial intelligence. Yes, all the different complicated global effects of global warming. So how that changes the allocation of resources, the flow of energy, the tension between countries, the military conflict between countries, the reallocation of power.
(03:41:06) Then looking at the role of China and this whole thing with Russia and growing influence of Africa and the weird dynamics of Europe and then America falling apart through the political division, fueled by recommender systems through Twitter and Facebook. The whole beautiful mess is just fun. And I think there’s a lot of incredible engineers, incredible scientists, incredible human beings, that while everyone is bickering and so on online for the fun of it, on the weekends, they’re actually trying to build solutions. And those are the people that will create something beautiful. At least that’s the process of evolution. It all started with a Chuck Norris single cell organism that went out from the vents and was the parent to all of us. And for that guy or lady or both, I guess, is a big thank you. And I can’t wait to what happens next. And I’m glad there’s incredible humans writing and studying it like you are. Nick, it’s a huge honor that you would talk to me.
Nick Lane (03:42:12) This has been fantastic.
Lex Fridman (03:42:13) This is really amazing. I can’t wait to read what you write next. Thank you for existing and thank you for talking today.
Nick Lane (03:42:24) Thank you.
Lex Fridman (03:42:26) Thanks for listening to this conversation with Nick Lane. To support this podcast, please check out our sponsors in the description. And now let me leave you with some words from Steve Jobs. “I think the biggest innovations of the 21st century will be at the intersection of biology and technology. A new era is beginning.” Thank you for listening and hope to see you next time.