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Phase Separation: Falling Walls Breakthrough Conversation with Anthony Hyman
Anthony Hyman, winner of the Körber European Science Prize 2022, about his research on the role of phase separation in the formation of biological compartments. Hyman shares how his findings can contribute to the treatment of degenerative diseases such as amyotrophic lateral sclerosis (ALS) and Alzheimer's disease. Digital participants had the unique chance to engage in the live conversation.
Speaker:
Anthony Hyman – https://falling-walls.com/people/anthony-hyman/
Moderation:
Engi Hassaan – https://falling-walls.com/people/engi-hassaan/
_____
Falling Walls Breakthrough Conversations:
The Falling Walls Breakthrough Conversations provide an intimate personal atmosphere, in which high-level guests, speakers and panelists of the Falling Walls Science Summit 2022 talk about their individ...
published: 08 Dec 2022
-
Clifford Brangwynne and Anthony Hyman: 2023 Breakthrough Prize Life Sciences
https://breakthroughprize.org/News/73
2023 Breakthrough Prize Life Sciences
Clifford P. Brangwynne
Princeton University and Howard Hughes Medical Institute
Anthony A. Hyman
Max Planck Institute of Molecular Cell Biology and Genetics
For discovering a fundamental mechanism of cellular organization mediated by phase separation of proteins and RNA into membraneless liquid droplets.
published: 22 Sep 2022
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Anthony Hyman – Körber Prize Winner 2022: Research on Cell Droplets
The Körber European Science Prize 2022, endowed with one million euros, is to be awarded to the British cell biologist Anthony Hyman. In 2009, Hyman and his team – during studies on single-cell embryos of a threadworm – discovered a completely new state of biological matter: proteins can accumulate locally in high concentrations in the cell fluid. These "condensates" resemble tiny drops. They form dynamically, sometimes in a matter of seconds, and are usually also quickly broken down again. If the degradation is disturbed – often due to age – toxic substances can be deposited in affected cells, triggering degenerative diseases such as ALS or Alzheimer's disease. Hyman is now looking for new drugs that could cure these diseases.
http://www.koerber-prize.org
#KörberPrize #Biology #Science
published: 02 Sep 2022
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Experiments in Cellular Organization - Anthony Hyman (MPI - CBG)
Experimental design, methods and data used to study the organization of cells.
published: 02 Nov 2013
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Anthony Hyman (Max Planck Institute) Part 2: Building a polymer: microtubule dynamics
https://www.ibiology.org/cell-biology/cellular-organization/#part-2
A eukaryotic cell is often 5-6 orders of magnitude larger than the molecules that make it up. How is it that these molecules interact to organize the complex structures that constitute a cell?
In part 1 of his seminar, Dr. Hyman explains how cell division in a C. elegans embryo provides an excellent model for organization of cellular structures and processes and how RNA interference (RNAi) is an extremely useful tool to study this model. He describes how individual proteins can form complexes of varying size and complexity. Complexes can then organize to form compartments, or non-membrane bound organelles such as centrosomes or the cell cortex, and the organization of these compartments drives the organization of cells. ...
published: 22 Apr 2011
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Anthony Hyman (Max Planck Institute) Part 1: How does complexity arise from molecular interactions?
https://www.ibiology.org/cell-biology/cellular-organization/
A eukaryotic cell is often 5-6 orders of magnitude larger than the molecules that make it up. How is it that these molecules interact to organize the complex structures that constitute a cell?
In part 1 of his seminar, Dr. Hyman explains how cell division in a C. elegans embryo provides an excellent model for organization of cellular structures and processes and how RNA interference (RNAi) is an extremely useful tool to study this model. He describes how individual proteins can form complexes of varying size and complexity. Complexes can then organize to form compartments, or non-membrane bound organelles such as centrosomes or the cell cortex, and the organization of these compartments drives the organization of cells. In part...
published: 22 Apr 2011
-
Anthony (Tony) Hyman (MPI-CBG): Encouraging Innovation
https://www.ibiology.org/biomedical-workforce/encouraging-innovation/
Tony Hyman presents the case that most innovative research is done by young scientists early in their careers. In the USA, however, NIH funding for scientists under the age of 36 has dropped significantly for the last several decades. Hyman argues that expanding grants that are available only to young scientists and provide 5-10 years of funding would greatly encourage innovation in biomedical research.
Speaker Biography:
Tony Hyman received his BSc in Zoology from University College, London and his PhD from the Laboratory of Molecular Biology in Cambridge. He then moved to the University of California, San Francisco to pursue postdoctoral research. Hyman returned to Europe in 1993 when he joined the EMBL in Heidelbe...
published: 08 Aug 2016
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Anthony Hyman (Max Planck Institute) Part 4: Formation of P granules
https://www.ibiology.org/cell-biology/cellular-organization/#part-4
A eukaryotic cell is often 5-6 orders of magnitude larger than the molecules that make it up. How is it that these molecules interact to organize the complex structures that constitute a cell?
In part 1 of his seminar, Dr. Hyman explains how cell division in a C. elegans embryo provides an excellent model for organization of cellular structures and processes and how RNA interference (RNAi) is an extremely useful tool to study this model. He describes how individual proteins can form complexes of varying size and complexity. Complexes can then organize to form compartments, or non-membrane bound organelles such as centrosomes or the cell cortex, and the organization of these compartments drives the organization of cells. ...
published: 22 Apr 2011
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Anthony Hyman (Max Planck Institute) Part 3: Formation and duplication of centrioles
https://www.ibiology.org/cell-biology/cellular-organization/#part-3
A eukaryotic cell is often 5-6 orders of magnitude larger than the molecules that make it up. How is it that these molecules interact to organize the complex structures that constitute a cell?
In part 1 of his seminar, Dr. Hyman explains how cell division in a C. elegans embryo provides an excellent model for organization of cellular structures and processes and how RNA interference (RNAi) is an extremely useful tool to study this model. He describes how individual proteins can form complexes of varying size and complexity. Complexes can then organize to form compartments, or non-membrane bound organelles such as centrosomes or the cell cortex, and the organization of these compartments drives the organization of cells. ...
published: 22 Apr 2011
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Auszeichnung in Hamburg: Körber-Preis für Zellbiologe Anthony Hyman
Im Alter bekommen viele Menschen Alzheimer, leiden an Gedächtnisverlust. Weil die Nervenzellen im Gehirn die Informationen nicht mehr richtig weiterleiten. Doch was löst Erkrankungen wie diese aus? Der britische Zellbiologe Anthony Hyman forscht daran, diese Frage zu beantworten. Und das bereits seit 20 Jahren am Max-Planck-Institut für molekulare Zellbiologie und Genetik in Dresden. Für seine Leistungen wurde er heute in Hamburg mit dem Körber-Preis geehrt - eine der höchstdotierten Auszeichnungen in der Forschung weltweit.
Alle aktuellen Informationen und tagesschau24 im Livestream: https://www.tagesschau.de/
Alle Sendungen, Livestreams, Dokumentation und Reportagen auch in der ARD-Mediathek: https://www.ardmediathek.de/tagesschau
published: 02 Sep 2022
17:45
Phase Separation: Falling Walls Breakthrough Conversation with Anthony Hyman
Anthony Hyman, winner of the Körber European Science Prize 2022, about his research on the role of phase separation in the formation of biological compartments....
Anthony Hyman, winner of the Körber European Science Prize 2022, about his research on the role of phase separation in the formation of biological compartments. Hyman shares how his findings can contribute to the treatment of degenerative diseases such as amyotrophic lateral sclerosis (ALS) and Alzheimer's disease. Digital participants had the unique chance to engage in the live conversation.
Speaker:
Anthony Hyman – https://falling-walls.com/people/anthony-hyman/
Moderation:
Engi Hassaan – https://falling-walls.com/people/engi-hassaan/
_____
Falling Walls Breakthrough Conversations:
The Falling Walls Breakthrough Conversations provide an intimate personal atmosphere, in which high-level guests, speakers and panelists of the Falling Walls Science Summit 2022 talk about their individual research, career paths and experiences. The Falling Walls Breakthrough Conversations are supported by the German Federal Ministry of Education and Research and Springer Nature.
https://falling-walls.com/conversations/
_____
Twitter: https://twitter.com/falling_walls
Instagram: https://www.instagram.com/falling_walls/
Facebook: https://www.facebook.com/fallingwalls/
LinkedIn: https://www.facebook.com/fallingwalls/
____
About the Falling Walls Science Summit
Three days of intense scientific discussions, networking, and knowledge sharing in the incredible cosmopolitan city of Berlin!
The Falling Walls Science Summit is a leading international, interdisciplinary and intersectoral forum for scientific breakthroughs and science dialogue between global science leaders and society. The event takes place every year from 7–9 November in Berlin, commemorating the fall of the Berlin Wall. With formats Falling Walls Pitches (7 November), Falling Walls Circle (8 November) and Falling Walls Science Breakthroughs of the Year (9 November), the Falling Walls Science Summit is the leading forum for global science leaders from academia, business, politics, the media, and civil society to debate the potential of scientific breakthroughs to solve grand challenges and shape a sustainable future. The Falling Walls Science Summit is organised by the non-profit Falling Walls Foundation.
Falling Walls Foundation: https://falling-walls.com/
Newsletter: https://falling-walls.com/newsletter/
_____
Save the Date:
FALLING WALLS
SCIENCE SUMMIT
7 – 9 NOV 2023
https://wn.com/Phase_Separation_Falling_Walls_Breakthrough_Conversation_With_Anthony_Hyman
Anthony Hyman, winner of the Körber European Science Prize 2022, about his research on the role of phase separation in the formation of biological compartments. Hyman shares how his findings can contribute to the treatment of degenerative diseases such as amyotrophic lateral sclerosis (ALS) and Alzheimer's disease. Digital participants had the unique chance to engage in the live conversation.
Speaker:
Anthony Hyman – https://falling-walls.com/people/anthony-hyman/
Moderation:
Engi Hassaan – https://falling-walls.com/people/engi-hassaan/
_____
Falling Walls Breakthrough Conversations:
The Falling Walls Breakthrough Conversations provide an intimate personal atmosphere, in which high-level guests, speakers and panelists of the Falling Walls Science Summit 2022 talk about their individual research, career paths and experiences. The Falling Walls Breakthrough Conversations are supported by the German Federal Ministry of Education and Research and Springer Nature.
https://falling-walls.com/conversations/
_____
Twitter: https://twitter.com/falling_walls
Instagram: https://www.instagram.com/falling_walls/
Facebook: https://www.facebook.com/fallingwalls/
LinkedIn: https://www.facebook.com/fallingwalls/
____
About the Falling Walls Science Summit
Three days of intense scientific discussions, networking, and knowledge sharing in the incredible cosmopolitan city of Berlin!
The Falling Walls Science Summit is a leading international, interdisciplinary and intersectoral forum for scientific breakthroughs and science dialogue between global science leaders and society. The event takes place every year from 7–9 November in Berlin, commemorating the fall of the Berlin Wall. With formats Falling Walls Pitches (7 November), Falling Walls Circle (8 November) and Falling Walls Science Breakthroughs of the Year (9 November), the Falling Walls Science Summit is the leading forum for global science leaders from academia, business, politics, the media, and civil society to debate the potential of scientific breakthroughs to solve grand challenges and shape a sustainable future. The Falling Walls Science Summit is organised by the non-profit Falling Walls Foundation.
Falling Walls Foundation: https://falling-walls.com/
Newsletter: https://falling-walls.com/newsletter/
_____
Save the Date:
FALLING WALLS
SCIENCE SUMMIT
7 – 9 NOV 2023
- published: 08 Dec 2022
- views: 238
1:06
Clifford Brangwynne and Anthony Hyman: 2023 Breakthrough Prize Life Sciences
https://breakthroughprize.org/News/73
2023 Breakthrough Prize Life Sciences
Clifford P. Brangwynne
Princeton University and Howard Hughes Medical Institute
...
https://breakthroughprize.org/News/73
2023 Breakthrough Prize Life Sciences
Clifford P. Brangwynne
Princeton University and Howard Hughes Medical Institute
Anthony A. Hyman
Max Planck Institute of Molecular Cell Biology and Genetics
For discovering a fundamental mechanism of cellular organization mediated by phase separation of proteins and RNA into membraneless liquid droplets.
https://wn.com/Clifford_Brangwynne_And_Anthony_Hyman_2023_Breakthrough_Prize_Life_Sciences
https://breakthroughprize.org/News/73
2023 Breakthrough Prize Life Sciences
Clifford P. Brangwynne
Princeton University and Howard Hughes Medical Institute
Anthony A. Hyman
Max Planck Institute of Molecular Cell Biology and Genetics
For discovering a fundamental mechanism of cellular organization mediated by phase separation of proteins and RNA into membraneless liquid droplets.
- published: 22 Sep 2022
- views: 5587
7:12
Anthony Hyman – Körber Prize Winner 2022: Research on Cell Droplets
The Körber European Science Prize 2022, endowed with one million euros, is to be awarded to the British cell biologist Anthony Hyman. In 2009, Hyman and his tea...
The Körber European Science Prize 2022, endowed with one million euros, is to be awarded to the British cell biologist Anthony Hyman. In 2009, Hyman and his team – during studies on single-cell embryos of a threadworm – discovered a completely new state of biological matter: proteins can accumulate locally in high concentrations in the cell fluid. These "condensates" resemble tiny drops. They form dynamically, sometimes in a matter of seconds, and are usually also quickly broken down again. If the degradation is disturbed – often due to age – toxic substances can be deposited in affected cells, triggering degenerative diseases such as ALS or Alzheimer's disease. Hyman is now looking for new drugs that could cure these diseases.
http://www.koerber-prize.org
#KörberPrize #Biology #Science
https://wn.com/Anthony_Hyman_–_Körber_Prize_Winner_2022_Research_On_Cell_Droplets
The Körber European Science Prize 2022, endowed with one million euros, is to be awarded to the British cell biologist Anthony Hyman. In 2009, Hyman and his team – during studies on single-cell embryos of a threadworm – discovered a completely new state of biological matter: proteins can accumulate locally in high concentrations in the cell fluid. These "condensates" resemble tiny drops. They form dynamically, sometimes in a matter of seconds, and are usually also quickly broken down again. If the degradation is disturbed – often due to age – toxic substances can be deposited in affected cells, triggering degenerative diseases such as ALS or Alzheimer's disease. Hyman is now looking for new drugs that could cure these diseases.
http://www.koerber-prize.org
#KörberPrize #Biology #Science
- published: 02 Sep 2022
- views: 680
14:27
Experiments in Cellular Organization - Anthony Hyman (MPI - CBG)
Experimental design, methods and data used to study the organization of cells.
Experimental design, methods and data used to study the organization of cells.
https://wn.com/Experiments_In_Cellular_Organization_Anthony_Hyman_(Mpi_Cbg)
Experimental design, methods and data used to study the organization of cells.
- published: 02 Nov 2013
- views: 600
25:47
Anthony Hyman (Max Planck Institute) Part 2: Building a polymer: microtubule dynamics
https://www.ibiology.org/cell-biology/cellular-organization/#part-2
A eukaryotic cell is often 5-6 orders of magnitude larger than the molecules that make it u...
https://www.ibiology.org/cell-biology/cellular-organization/#part-2
A eukaryotic cell is often 5-6 orders of magnitude larger than the molecules that make it up. How is it that these molecules interact to organize the complex structures that constitute a cell?
In part 1 of his seminar, Dr. Hyman explains how cell division in a C. elegans embryo provides an excellent model for organization of cellular structures and processes and how RNA interference (RNAi) is an extremely useful tool to study this model. He describes how individual proteins can form complexes of varying size and complexity. Complexes can then organize to form compartments, or non-membrane bound organelles such as centrosomes or the cell cortex, and the organization of these compartments drives the organization of cells. In parts 2, 3 and 4 of his talk, Hyman explains what is known about the organization of increasingly larger and more complex cell structures: the microtubules of the mitotic spindle, centrioles, and finally, P granules. He also discusses the necessity of bringing the tools of physics, chemistry and molecular biology to bear, in addressing the complexity of the cell.
https://wn.com/Anthony_Hyman_(Max_Planck_Institute)_Part_2_Building_A_Polymer_Microtubule_Dynamics
https://www.ibiology.org/cell-biology/cellular-organization/#part-2
A eukaryotic cell is often 5-6 orders of magnitude larger than the molecules that make it up. How is it that these molecules interact to organize the complex structures that constitute a cell?
In part 1 of his seminar, Dr. Hyman explains how cell division in a C. elegans embryo provides an excellent model for organization of cellular structures and processes and how RNA interference (RNAi) is an extremely useful tool to study this model. He describes how individual proteins can form complexes of varying size and complexity. Complexes can then organize to form compartments, or non-membrane bound organelles such as centrosomes or the cell cortex, and the organization of these compartments drives the organization of cells. In parts 2, 3 and 4 of his talk, Hyman explains what is known about the organization of increasingly larger and more complex cell structures: the microtubules of the mitotic spindle, centrioles, and finally, P granules. He also discusses the necessity of bringing the tools of physics, chemistry and molecular biology to bear, in addressing the complexity of the cell.
- published: 22 Apr 2011
- views: 19420
27:58
Anthony Hyman (Max Planck Institute) Part 1: How does complexity arise from molecular interactions?
https://www.ibiology.org/cell-biology/cellular-organization/
A eukaryotic cell is often 5-6 orders of magnitude larger than the molecules that make it up. How ...
https://www.ibiology.org/cell-biology/cellular-organization/
A eukaryotic cell is often 5-6 orders of magnitude larger than the molecules that make it up. How is it that these molecules interact to organize the complex structures that constitute a cell?
In part 1 of his seminar, Dr. Hyman explains how cell division in a C. elegans embryo provides an excellent model for organization of cellular structures and processes and how RNA interference (RNAi) is an extremely useful tool to study this model. He describes how individual proteins can form complexes of varying size and complexity. Complexes can then organize to form compartments, or non-membrane bound organelles such as centrosomes or the cell cortex, and the organization of these compartments drives the organization of cells. In parts 2, 3 and 4 of his talk, Hyman explains what is known about the organization of increasingly larger and more complex cell structures: the microtubules of the mitotic spindle, centrioles, and finally, P granules. He also discusses the necessity of bringing the tools of physics, chemistry and molecular biology to bear, in addressing the complexity of the cell.
https://wn.com/Anthony_Hyman_(Max_Planck_Institute)_Part_1_How_Does_Complexity_Arise_From_Molecular_Interactions
https://www.ibiology.org/cell-biology/cellular-organization/
A eukaryotic cell is often 5-6 orders of magnitude larger than the molecules that make it up. How is it that these molecules interact to organize the complex structures that constitute a cell?
In part 1 of his seminar, Dr. Hyman explains how cell division in a C. elegans embryo provides an excellent model for organization of cellular structures and processes and how RNA interference (RNAi) is an extremely useful tool to study this model. He describes how individual proteins can form complexes of varying size and complexity. Complexes can then organize to form compartments, or non-membrane bound organelles such as centrosomes or the cell cortex, and the organization of these compartments drives the organization of cells. In parts 2, 3 and 4 of his talk, Hyman explains what is known about the organization of increasingly larger and more complex cell structures: the microtubules of the mitotic spindle, centrioles, and finally, P granules. He also discusses the necessity of bringing the tools of physics, chemistry and molecular biology to bear, in addressing the complexity of the cell.
- published: 22 Apr 2011
- views: 18065
13:38
Anthony (Tony) Hyman (MPI-CBG): Encouraging Innovation
https://www.ibiology.org/biomedical-workforce/encouraging-innovation/
Tony Hyman presents the case that most innovative research is done by young scientists ea...
https://www.ibiology.org/biomedical-workforce/encouraging-innovation/
Tony Hyman presents the case that most innovative research is done by young scientists early in their careers. In the USA, however, NIH funding for scientists under the age of 36 has dropped significantly for the last several decades. Hyman argues that expanding grants that are available only to young scientists and provide 5-10 years of funding would greatly encourage innovation in biomedical research.
Speaker Biography:
Tony Hyman received his BSc in Zoology from University College, London and his PhD from the Laboratory of Molecular Biology in Cambridge. He then moved to the University of California, San Francisco to pursue postdoctoral research. Hyman returned to Europe in 1993 when he joined the EMBL in Heidelberg as a young faculty member. After 6 years at the EMBL, he became a Director of the Max Planck Institute of Molecular Cell Biology and Genetics in Dresden. Hyman’s lab has studied the spatial organization of the cytoplasm for many years (see Hyman’s iBioSeminar). His lab is currently focused on understanding how cells form non-membrane bound compartments.
Learn more about Dr. Hyman’s research here:
http://hymanlab.mpi-cbg.de/hyman_lab/
https://wn.com/Anthony_(Tony)_Hyman_(Mpi_Cbg)_Encouraging_Innovation
https://www.ibiology.org/biomedical-workforce/encouraging-innovation/
Tony Hyman presents the case that most innovative research is done by young scientists early in their careers. In the USA, however, NIH funding for scientists under the age of 36 has dropped significantly for the last several decades. Hyman argues that expanding grants that are available only to young scientists and provide 5-10 years of funding would greatly encourage innovation in biomedical research.
Speaker Biography:
Tony Hyman received his BSc in Zoology from University College, London and his PhD from the Laboratory of Molecular Biology in Cambridge. He then moved to the University of California, San Francisco to pursue postdoctoral research. Hyman returned to Europe in 1993 when he joined the EMBL in Heidelberg as a young faculty member. After 6 years at the EMBL, he became a Director of the Max Planck Institute of Molecular Cell Biology and Genetics in Dresden. Hyman’s lab has studied the spatial organization of the cytoplasm for many years (see Hyman’s iBioSeminar). His lab is currently focused on understanding how cells form non-membrane bound compartments.
Learn more about Dr. Hyman’s research here:
http://hymanlab.mpi-cbg.de/hyman_lab/
- published: 08 Aug 2016
- views: 1686
32:29
Anthony Hyman (Max Planck Institute) Part 4: Formation of P granules
https://www.ibiology.org/cell-biology/cellular-organization/#part-4
A eukaryotic cell is often 5-6 orders of magnitude larger than the molecules that make it u...
https://www.ibiology.org/cell-biology/cellular-organization/#part-4
A eukaryotic cell is often 5-6 orders of magnitude larger than the molecules that make it up. How is it that these molecules interact to organize the complex structures that constitute a cell?
In part 1 of his seminar, Dr. Hyman explains how cell division in a C. elegans embryo provides an excellent model for organization of cellular structures and processes and how RNA interference (RNAi) is an extremely useful tool to study this model. He describes how individual proteins can form complexes of varying size and complexity. Complexes can then organize to form compartments, or non-membrane bound organelles such as centrosomes or the cell cortex, and the organization of these compartments drives the organization of cells. In parts 2, 3 and 4 of his talk, Hyman explains what is known about the organization of increasingly larger and more complex cell structures: the microtubules of the mitotic spindle, centrioles, and finally, P granules. He also discusses the necessity of bringing the tools of physics, chemistry and molecular biology to bear, in addressing the complexity of the cell.
https://wn.com/Anthony_Hyman_(Max_Planck_Institute)_Part_4_Formation_Of_P_Granules
https://www.ibiology.org/cell-biology/cellular-organization/#part-4
A eukaryotic cell is often 5-6 orders of magnitude larger than the molecules that make it up. How is it that these molecules interact to organize the complex structures that constitute a cell?
In part 1 of his seminar, Dr. Hyman explains how cell division in a C. elegans embryo provides an excellent model for organization of cellular structures and processes and how RNA interference (RNAi) is an extremely useful tool to study this model. He describes how individual proteins can form complexes of varying size and complexity. Complexes can then organize to form compartments, or non-membrane bound organelles such as centrosomes or the cell cortex, and the organization of these compartments drives the organization of cells. In parts 2, 3 and 4 of his talk, Hyman explains what is known about the organization of increasingly larger and more complex cell structures: the microtubules of the mitotic spindle, centrioles, and finally, P granules. He also discusses the necessity of bringing the tools of physics, chemistry and molecular biology to bear, in addressing the complexity of the cell.
- published: 22 Apr 2011
- views: 15082
23:10
Anthony Hyman (Max Planck Institute) Part 3: Formation and duplication of centrioles
https://www.ibiology.org/cell-biology/cellular-organization/#part-3
A eukaryotic cell is often 5-6 orders of magnitude larger than the molecules that make it u...
https://www.ibiology.org/cell-biology/cellular-organization/#part-3
A eukaryotic cell is often 5-6 orders of magnitude larger than the molecules that make it up. How is it that these molecules interact to organize the complex structures that constitute a cell?
In part 1 of his seminar, Dr. Hyman explains how cell division in a C. elegans embryo provides an excellent model for organization of cellular structures and processes and how RNA interference (RNAi) is an extremely useful tool to study this model. He describes how individual proteins can form complexes of varying size and complexity. Complexes can then organize to form compartments, or non-membrane bound organelles such as centrosomes or the cell cortex, and the organization of these compartments drives the organization of cells. In parts 2, 3 and 4 of his talk, Hyman explains what is known about the organization of increasingly larger and more complex cell structures: the microtubules of the mitotic spindle, centrioles, and finally, P granules. He also discusses the necessity of bringing the tools of physics, chemistry and molecular biology to bear, in addressing the complexity of the cell.
https://wn.com/Anthony_Hyman_(Max_Planck_Institute)_Part_3_Formation_And_Duplication_Of_Centrioles
https://www.ibiology.org/cell-biology/cellular-organization/#part-3
A eukaryotic cell is often 5-6 orders of magnitude larger than the molecules that make it up. How is it that these molecules interact to organize the complex structures that constitute a cell?
In part 1 of his seminar, Dr. Hyman explains how cell division in a C. elegans embryo provides an excellent model for organization of cellular structures and processes and how RNA interference (RNAi) is an extremely useful tool to study this model. He describes how individual proteins can form complexes of varying size and complexity. Complexes can then organize to form compartments, or non-membrane bound organelles such as centrosomes or the cell cortex, and the organization of these compartments drives the organization of cells. In parts 2, 3 and 4 of his talk, Hyman explains what is known about the organization of increasingly larger and more complex cell structures: the microtubules of the mitotic spindle, centrioles, and finally, P granules. He also discusses the necessity of bringing the tools of physics, chemistry and molecular biology to bear, in addressing the complexity of the cell.
- published: 22 Apr 2011
- views: 6710
1:31
Auszeichnung in Hamburg: Körber-Preis für Zellbiologe Anthony Hyman
Im Alter bekommen viele Menschen Alzheimer, leiden an Gedächtnisverlust. Weil die Nervenzellen im Gehirn die Informationen nicht mehr richtig weiterleiten. Doch...
Im Alter bekommen viele Menschen Alzheimer, leiden an Gedächtnisverlust. Weil die Nervenzellen im Gehirn die Informationen nicht mehr richtig weiterleiten. Doch was löst Erkrankungen wie diese aus? Der britische Zellbiologe Anthony Hyman forscht daran, diese Frage zu beantworten. Und das bereits seit 20 Jahren am Max-Planck-Institut für molekulare Zellbiologie und Genetik in Dresden. Für seine Leistungen wurde er heute in Hamburg mit dem Körber-Preis geehrt - eine der höchstdotierten Auszeichnungen in der Forschung weltweit.
Alle aktuellen Informationen und tagesschau24 im Livestream: https://www.tagesschau.de/
Alle Sendungen, Livestreams, Dokumentation und Reportagen auch in der ARD-Mediathek: https://www.ardmediathek.de/tagesschau
https://wn.com/Auszeichnung_In_Hamburg_Körber_Preis_Für_Zellbiologe_Anthony_Hyman
Im Alter bekommen viele Menschen Alzheimer, leiden an Gedächtnisverlust. Weil die Nervenzellen im Gehirn die Informationen nicht mehr richtig weiterleiten. Doch was löst Erkrankungen wie diese aus? Der britische Zellbiologe Anthony Hyman forscht daran, diese Frage zu beantworten. Und das bereits seit 20 Jahren am Max-Planck-Institut für molekulare Zellbiologie und Genetik in Dresden. Für seine Leistungen wurde er heute in Hamburg mit dem Körber-Preis geehrt - eine der höchstdotierten Auszeichnungen in der Forschung weltweit.
Alle aktuellen Informationen und tagesschau24 im Livestream: https://www.tagesschau.de/
Alle Sendungen, Livestreams, Dokumentation und Reportagen auch in der ARD-Mediathek: https://www.ardmediathek.de/tagesschau
- published: 02 Sep 2022
- views: 3460