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Posidonia oceanica

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Posidonia oceanica
Scientific classification Edit this classification
Kingdom: Plantae
Clade: Tracheophytes
Clade: Angiosperms
Clade: Monocots
Order: Alismatales
Family: Posidoniaceae
Genus: Posidonia
Species:
P. oceanica
Binomial name
Posidonia oceanica
Posidonia oceanica range

Posidonia oceanica, commonly known as Neptune grass or Mediterranean tapeweed, is a seagrass species that is endemic to the Mediterranean Sea.[2] It forms large underwater meadows that are an important part of the ecosystem. The fruit is free floating and known in Italy as "the olive of the sea" (l'oliva di mare[3]). Balls of fibrous material from its foliage, known as egagropili or Neptune balls,[4] wash up to nearby shorelines.

The Posidonia has a very high carbon absorption capacity, being able to soak up 15 times more carbon dioxide every year than a similar sized piece of the Amazon rainforest.[5]

Morphology

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Posidonia oceanica has roots (which mainly serve to anchor the plant to the substrate), rhizome and tapeform leaves.

The rhizomes, up to 1 cm thick, grow both horizontally (plagiotropic rhizomes), and vertically (orthotropic rhizomes). The former, thanks to the presence at the bottom of lignited roots up to 15 cm long, anchor the plant to the substrate. The latter, which increase height, have the function of combatting sanding due to continuous sedimentation. The two types of growth give rise to the so-called "kill", a terrace formation that consists of a network of strata of rhizomes, roots and trapped sediments. In this way, posidonias colonise an environment that algae could hardly occupy due to the lack of roots.

The leaves arise from orthotropic rhizomes, are cyntiform and bright green in colour that turns brown over time. They can reach a length of approximately 1.5 metres high. On average they have a width of 1 cm and have 13 to 17 parallel ribs. The apexes are rounded and are often lost by the action of waves and currents.

They are organised in bushes of 6 or 7 leaves, with the oldest on the outside and the youngest on the inside. The leaves are divided into three categories:

  • Adult leaves, which have a lamina with photosynthetic function and a base separated from the foliar edge by a concave structure called "ligula";
  • Intermediate leaves, which have no basis;
  • Young leaves, which normally have a length of less than 50 mm. In autumn the plant loses the outermost adult leaves, which become brown and are photosynthetically inactive. During the winter, new leaves are produced.

Reproduction

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Posidonia oceanica reproduces both sexually and asexually (by stolons).

Sexual reproduction occurs through the production of flowers and fruits. The flowers are hermaphrodite and are grouped in a herringbone-shaped inflorescence, green in colour and contained between floral bracts. The peduncle binds to the rhizome in the centre of the bunch. The gynaecium is formed by a unilocular ovary that continues with a style and ends in the stigma. The androecium consists of three stamens with short anthers. Flowering depends on environmental factors (light and temperature) and endogenous factors (age and size of the plant) and takes place in September and October in the meadows closest to the sea surface, while in the deepest ones it is postponed for two months. Pollen inside the anthers is spherical in shape, but becomes filamentous as soon as it is released into the water. There are no recognition mechanisms between pollen and stigma that prevent self-fertilisation. Pollination is hydrophilic and can lead to fruit formation, although some of them do not reach maturation, which occurs after six months. Once ripe, the fruits separate and float on the surface.

The fruit, slightly fleshy and called in some places "sea olive", is similar to a drupe and has a porous pericarp and rich in an oily substance that allows flotation. When it rots, it releases a seed (coated by a thin membrane, but without a true and proper tegument), which falls to the bottom and, if it finds the right conditions of depth, stability and type of sediment, germinates and gives rise to a new plant. In order for it to be consolidated, it is necessary that in finds a moisturised substrate. Humidification consists of the degradation of plant remains, so the plant can be implanted in "soils" previously colonised by other plants, such as macroalgae or other phanerogams. Thus, a true ecological succession is generated in which posidonia represents the last stage. Germination begins with the release of a small white root of radical pole and a leaf of the apical pole. With sexual reproduction, the plant colonises new areas, diffuses meadows in other areas and guarantees genetic variability.

Asexual reproduction by stolons, which allows the expansion of meadows, is carried out through plagiargiotropic rhizomes, which grow about 7 cm a year and colonise new spaces. The high accumulation of sediments and the reduction of the space available for horizontal growth stimulates the vertical growth of the rhizomes, thus forming the bushes.

Growth

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Posidonia growth rate is amongst the lowest of marine angiosperm with its horizontal rhizomes growing from 1 to 6 centimetres per year, whilst the vertical rhizomes grow from 0.1 to 4 centimetres per year. To grow a new leaf it takes approximately 50.68 days, exceptionally lower than other types of seagrass like Zostera noltii, which takes an approximate 13.71 days.

Taxonomy

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The genus Posidonia is named after Poseidon, the Greek god of the seas, while oceanica refers to its former wide distribution. Carl Linnaeus gave the first botanical description of this species in Systema Naturae, although the genus was then named Zostera. The APG system (1998) and APG II system (2003) accept the genus as constituting the sole genus in the family Posidoniaceae, which it places in the order Alismatales, in the clade monocots. The Angiosperm Phylogeny Website concludes that the three families Cymodoceaceae, Posidoniaceae and Ruppiaceae form a monophyletic group.[6] Earlier systems classified this genus in the family Potamogetonaceae or in the family Posidoniaceae but belonging to order Zosterales. It was published in: A. R. Delile, Description de l'Égypte, in 1813.[7]

Description

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Ball of fibrous material on shore

Posidonia oceanica is a flowering plant which grows in dense meadows or along sandy channels in the waters of the Mediterranean. It is found at depths of 1–35 metres (3.3–114.8 ft),[8] depending on water clarity. Subsurface rhizomes and roots stabilize the plant, while erect rhizomes and leaves reduce silt accumulation.

The leaves are ribbon-like, appearing in tufts of 6 or 7, and up to 1.5 metres (4.9 ft) long.[citation needed] Average leaf width is around 10 millimetres (0.39 in).[citation needed] The leaves are bright green, perhaps turning brown with age, and have 13 to 17 parallel veins. The leaf terminus is rounded, at times absent, usually because of damage or wear. Leaves are arranged in groups, with older leaves on the outside, longer and differing in form from the younger leaves they surround.

The rhizomatous stems have a dual growth habit—one grows down 150 centimetres (59 in) or so beneath the substrate, and the other grows above it. All the stems are approximately 10 millimetres (0.39 in) thick and upright in habit. This arrangement of the rhizomes eventually forms a mat; the surface contains the active parts of the plant, whereas the center is a dense network of roots and decomposing stems.[citation needed]

P. oceania's common name is 'Neptune grass'.[9]

In 2006 a huge clonal colony of P. oceanica was discovered south of the island of Ibiza and stretches as far south as La Savina and Es Pujols on the island of Formentera. At 8 kilometres (5.0 mi) across, and estimated at 100,000 years old,[10] it may be one of the largest and oldest clonal colonies on Earth.[11][12][13]

Dead rhizomes with olive-mill waste are used for compost.[14]

Posidonia oceanica (L.) Delile at Naxos, Greece

Distribution and habitat

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Drawing of seabed, showing plants and fish swimming above
Illustration of P. oceanica habitat

This species is found only in the Mediterranean Sea, where it is in decline, occupying an area of about 3% of the basin. This corresponds to a surface area of about 38,000 square kilometres (15,000 sq mi). Posidonia grows best in clean waters, and its presence is a marker for lack of pollution.[15] The presence of Posidonia can be detected by the masses of decomposing leaves on beaches. Such plant material has been used for composting, but Italian laws prohibit the use of marine algae and plants for this purpose.[16]

The UNESCO World Heritage Site around the Balearic Islands of Mallorca and Formentera includes about 55,000 hectares (140,000 acres) of Posidonia oceanica, which has global significance because of the amount of carbon dioxide it absorbs, given the effect of carbon dioxide on climate change. However, the meadows are being threatened by rising temperatures, which slows down its growth, as well as damage from anchors.[17]

Communities associated with P. oceanica

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The characteristics of the Posidonia plant, its growth dynamics and the large amount of biomass produced, are factors that can sustain very diverse plant and animal communities. Distinguished are: epiphytic communities (that is, bacteria, algae and bryozoa that colonise the surface of the leaves and rhizomes of the plant), vagile and sessile animal communities and communities of detritivorous organisms.

Epiphytic communities

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Along the leaf, successions and neighbourhoods that follow the age of the leaf can be identified. Diatoms and bacteria are implanted near the base of the leaf and on the young leaves. Subsequently, in the central part, red and brown fouling algae are implanted, while above the incrustants and in the apical area live erect filamentous algae.

Epiphytic communities are consumed by gastropod molluscs, amphipod crustaceans and polychaetes, and play a very important role in the food chain of Posidonia meadows, taking into account the fact that few organisms are able to feed directly from the plant tissue, little appetising for herbivores due to the high percentage [of what?]

Epiphytes, however, can also damage the plant. In fact, by increasing weight, they can cause premature fall of the leaves, decrease light and also hinder gas exchanges and the absorption of nutrients through the leaves.

As a bioindicator

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Posidonia has been used for about twenty years as a biological indicator. In fact, the plant has all the characteristics of a good bioindicator:

  • It is a benthic species;
  • Has a long life cycle;
  • Is widespread throughout the Mediterranean;
  • Has a high capacity to concentrate polluting substances in its tissues;
  • Is very sensitive to environmental changes.

Therefore, through the study of meadows it is possible to know quite reliably the environmental quality of coastal marine waters.

Generally, the methods of studying Posidonia meadows are four:

  • Analysis and monitoring of the lower limit;
  • Analysis of the density of grasslands;
  • Phenological analysis;
  • Lepidochronological analysis.

Lower limit analysis

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There is a close relationship between the depth of the lower limit and the transparency of water.

Density of the foliar fascicles

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As for density, it depends on the depth at which the meadow is located, the luminous intensity and the type of substrate. According to the density of the foliar fascicles, measured in number of bushes / m2, meadows are divided into 5 classes.

  • Meadows in equilibrium: density is normal or exceptional;
  • Altered meadows: the density is low;
  • Greatly altered meadows: the density is abnormal.

Phenological analyses

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Phenological analyses allow to study different useful parameters to describe the state of health of plants:

  • Average number of leaves by age (adult, intermediate, young), by foliar fascicle.
  • Length and average width of the leaves by age and foliar fascicle.
  • Percentage of brown tissue: represents the % of adult leaves that have non photosynthesising tissue.
  • LAI Index (Leaf Area Index): measures the leaf surface per m2 of meadow.
  • Coefficient "A": percentage of leaves that have lost their apex.

Lepidochronological analyses

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Lepidochronological analysis consists of the study of the life cycles of P. oceanica leaves, which at the time of their separation, once dead, leave the basal part on the rhizome of the plant. These residues, which over time become splinters, have variable thicknesses with annual cyclical trends, useful for the study of environmental variables. Their objectives can be summarised as follows:

  • Estimate the biomass produced per year, both in terms of elongation of the rhizomes, and in leaf production.
  • Estimate the production of flowers and, therefore, estimate information on the number of sexual reproduction phenomena produced over the years.
  • Measure the concentration of heavy metals in the fabrics of the plant.

Secondary metabolites

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To date 51 natural products have been reported from P. oceanica, including natural phenols, phenylmethane derivatives, phenylethane derivatives, phenylpropane derivatives and their esters, chalkones, flavonols, 5-alpha-cholestanes, and cholest-5-enes. Many of the compounds reported for P. oceanica were, however, not detected by appropriate phytochemical methods and some most probably represent artifacts and are not genuine natural products of P. oceanica.[18]hi

Ecology

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Underwater photo of four clumps of leafy plants
Mattae along a channel

Preventing the erosion of the Mediterranean Coast

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Posidonia oceanica has similar characteristics to terrestrial plants, such as roots, rhizomatous stem and cintiform leaves up to one metre long arranged in clumps of 6 to 7. It flowers in autumn and produces floating fruits in spring, commonly known as sea olives.

It forms underwater meadows of considerable ecological importance. It constitutes the climax community of the Mediterranean Sea and plays an important role in protecting the coastline from erosion. It is home to many animal and plant organisms that find food and protection in the meadows. It is considered a good.

Functions

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  • They fix CO2 and produce oxygen.
  • They protect the sandy coastline against erosion.
  • They are a reserve of biodiversity due to the large number of animal and plant species that find within the habitat a place for feeding, protection and nursery for juveniles.
  • They produce a large part of the sediment that forms part of the sand on our beaches.

See also

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References

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  1. ^ Pergent, G., Semroud, R., Djellouli, A., Langar, H. & Duarte, C. 2010. Posidonia oceanica. In: IUCN 2012. IUCN Red List of Threatened Species. Version 2012.2. <www.iucnredlist.org>. Downloaded on 9 January 2013.
  2. ^ Pansini, Arianna; Deroma, Mario; Guala, Ivan; Monnier, Briac; Pergent-Martini, Christine; Piazzi, Luigi; Stipcich, Patrizia; Ceccherelli, Giulia (1 April 2024). "The resilience of transplanted seagrass traits encourages detection of restoration success". Journal of Environmental Management. 357: 120744. Bibcode:2024JEnvM.35720744P. doi:10.1016/j.jenvman.2024.120744. ISSN 0301-4797. PMID 38552518.
  3. ^ "Posidonia oceanica" (PDF) (in Italian). Archived from the original (PDF) on 16 May 2006. Retrieved 8 April 2008. Dopo essere fecondato, in estate fa crescere e maturare il suo frutto, l'oliva di mare (si chiama così perché ha una forma arrotondata).
  4. ^ "Seagrass 'Neptune balls' sieve millions of plastic particles from water, study finds". TheGuardian.com. 15 January 2021. Retrieved 16 January 2021. Underwater seagrass in coastal areas appear to trap plastic pollution in natural bundles of fibre known as "Neptune balls", researchers have found.
  5. ^ "Climate change: 'Forever plant' seagrass faces uncertain future". BBC News. 13 March 2021. Retrieved 21 March 2021.
  6. ^ "Alismatales". Mobot.org. Retrieved 11 February 2012.
  7. ^ "Posidonia oceanica (Linnaeus) Delile 1813 :: Algaebase". www.algaebase.org. Retrieved 19 May 2021.
  8. ^ Telesca, Luca; Belluscio, Andrea; Criscoli, Alessandro; Ardizzone, Giandomenico; Apostolaki, Eugenia T.; Fraschetti, Simonetta; Gristina, Michele; Knittweis, Leyla; Martin, Corinne S.; Pergent, Gérard; Alagna, Adriana (28 July 2015). "Seagrass meadows ( Posidonia oceanica ) distribution and trajectories of change". Scientific Reports. 5 (1): 12505. Bibcode:2015NatSR...512505T. doi:10.1038/srep12505. ISSN 2045-2322. PMC 4516961. PMID 26216526.
  9. ^ "Posidonia oceanis". www.divesitedirectory.co.uk. Retrieved 16 May 2024.
  10. ^ "Portuguese scientists discover world's oldest living organism". www.theportugalnews.com. Archived from the original on 16 December 2012.
  11. ^ Ibiza Spotlight (28 May 2006). "Ibiza's Monster Marine Plant". Archived from the original on 27 August 2006. Retrieved 9 May 2007.
  12. ^ Pearlman, Jonathan (7 February 2012). "'Oldest living thing on earth' discovered". The Telegraph. Archived from the original on 7 February 2012. Retrieved 11 February 2012.
  13. ^ Arnaud-Haond, Sophie; Duarte, Carlos M.; Diaz-Almela, Elena; Marbà, Núria; Sintes, Tomas; Serrão, Ester A.; Bruun, Hans Henrik (2012). "Implications of Extreme Life Span in Clonal Organisms: Millenary Clones in Meadows of the Threatened Seagrass Posidonia oceanica". PLOS ONE. 7 (2): e30454. Bibcode:2012PLoSO...730454A. doi:10.1371/journal.pone.0030454. PMC 3270012. PMID 22312426.
  14. ^ Posidonia – an overview | ScienceDirect Topics. ISBN 978-0-12-805068-2. Retrieved 19 May 2021.
  15. ^ Pergent-Martini, Christine (1998). "Posidonia oceanica: a biological indicator of past and present mercury contamination in the mediterranean sea". Marine Environmental Research. 45 (2): 101–111. Bibcode:1998MarER..45..101P. doi:10.1016/S0141-1136(97)00023-8.
  16. ^ "Decreto Legislativo 29 aprile 2010, n. 75" (PDF). Gazzetta Ufficiale della Repubblica Italiana. Supplemento ordinario n. 106/L (121). 26 May 2010. Archived from the original (PDF) on 24 February 2014.
  17. ^ McGrath, Matt (13 March 2021). "Climate change: 'Forever plant' seagrass faces uncertain future". BBC News. Retrieved 20 April 2021.
  18. ^ Heglmeier, A; Zidorn, C (October 2010). "Secondary metabolites of Posidonia oceanica". Biochemical Systematics and Ecology. 38 (5). Amsterdam: 964–70. doi:10.1016/j.bse.2010.07.001. ISSN 0305-1978.
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