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Benthos

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Seaweed and two chitons in a tide pool

Benthos (from Ancient Greek βένθος (bénthos) 'the depths [of the sea]'), also known as benthon, is the community of organisms that live on, in, or near the bottom of a sea, river, lake, or stream, also known as the benthic zone.[1] This community lives in or near marine or freshwater sedimentary environments, from tidal pools along the foreshore, out to the continental shelf, and then down to the abyssal depths.

Many organisms adapted to deep-water pressure cannot survive in the upper parts of the water column. The pressure difference can be very significant (approximately one atmosphere for every 10 metres of water depth).[2]

Because light is absorbed before it can reach deep ocean water, the energy source for deep benthic ecosystems is often organic matter from higher up in the water column that drifts down to the depths. This dead and decaying matter sustains the benthic food chain; most organisms in the benthic zone are scavengers or detritivores.

The term benthos, coined by Haeckel in 1891,[3] comes from the Greek noun βένθος 'depth of the sea'.[1][4] Benthos is used in freshwater biology to refer to organisms at the bottom of freshwater bodies of water, such as lakes, rivers, and streams.[5] There is also a redundant synonym, Benton.[6]

Overview

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Compared to the relatively featureless pelagic zone, the benthic zone offers physically diverse habitats. There is a huge range in how much light and warmth is available, and in the depth of water or extent of intertidal immersion. The seafloor varies widely in the types of sediment it offers. Burrowing animals can find protection and food in soft, loose sediments such as mud, clay and sand. Sessile species such as oysters and barnacles can attach themselves securely to hard, rocky substrates. As adults they can remain at the same site, shaping depressions and crevices where mobile animals find refuge. This greater diversity in benthic habitats has resulted in a higher diversity of benthic species. The number of benthic animal species exceeds one million. This far exceeds the number of pelagic animal species (about 5000 larger zooplankton species, 22,000 pelagic fish species and 110 marine mammal species).[7]

By size

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Macrobenthos

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Macrobenthos, prefix from Ancient Greek makrós 'long', comprises the larger, visible to the naked eye, benthic organisms greater than about 1 mm in size. In shallow waters, seagrass meadows, coral reefs and kelp forests provide particularly rich habitats for macrobenthos. Some examples are polychaete worms, bivalves, echinoderms, sea anemones, corals, sponges, sea squirts, turbellarians and larger crustaceans such as crabs, lobsters and cumaceans.[8]

Meiobenthos

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Meiobenthos, prefix from Ancient Greek meîon 'less', comprises tiny benthic organisms that are less than about 1 mm but greater than about 0.1 mm in size. Some examples are nematodes, foraminiferans, tardigrades, gastrotriches and smaller crustaceans such as copepods and ostracodes.

Microbenthos

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Microbenthos, prefix from the Greek mikrós 'small', comprises microscopic benthic organisms that are less than about 0.1 mm in size. Some examples are bacteria, diatoms, ciliates, amoeba, flagellates.

Marine microbenthos are microorganisms that live in the benthic zone of the ocean – that live near or on the seafloor, or within or on surface seafloor sediments. Microbenthos are found everywhere on or about the seafloor of continental shelves, as well as in deeper waters, with greater diversity in or on seafloor sediments. In photic zones benthic diatoms dominate as photosynthetic organisms. In intertidal zones changing tides strongly control opportunities for microbenthos.

Both foraminifera and diatoms have planktonic and benthic forms, that is, they can drift in the water column or live on sediment at the bottom of the ocean. Regardless of form, their shells sink to the seafloor after they die. These shells are widely used as climate proxies. The chemical composition of the shells are a consequence of the chemical composition of the ocean at the time the shells were formed. Past water temperatures can be also be inferred from the ratios of stable oxygen isotopes in the shells, since lighter isotopes evaporate more readily in warmer water leaving the heavier isotopes in the shells. Information about past climates can be inferred further from the abundance of forams and diatoms, since they tend to be more abundant in warm water.[9]

Benthic diatom

The sudden extinction event which killed the dinosaurs 66 million years ago also rendered extinct three-quarters of all other animal and plant species. However, deep-sea benthic forams flourished in the aftermath. In 2020 it was reported that researchers have examined the chemical composition of thousands of samples of these benthic forams and used their findings to build the most detailed climate record of Earth ever.[10][11]

Some endoliths have extremely long lives. In 2013 researchers reported evidence of endoliths in the ocean floor, perhaps millions of years old, with a generation time of 10,000 years.[12] These are slowly metabolizing and not in a dormant state. Some Actinomycetota found in Siberia are estimated to be half a million years old.[13][14][15]

By type

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Example zoobenthos
A variety of marine worms
Plate from Das Meer
by M. J. Schleiden (1804–1881)

Zoobenthos

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Zoobenthos, prefix from Ancient Greek zôion 'animal', animals belonging to the benthos. Examples include polychaete worms, starfish and anemones.

Phytobenthos

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Phytobenthos, prefix from Ancient Greek phutón 'plant', plants belonging to the benthos, mainly benthic diatoms and macroalgae (seaweed).

By location

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Endobenthos

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Endobenthos (or endobenthic), prefix from Ancient Greek éndon 'inner, internal', lives buried, or burrowing in the sediment, often in the oxygenated top layer, e.g., a sea pen or a sand dollar.

Epibenthos

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Epibenthos (or epibenthic), prefix from Ancient Greek epí 'on top of', lives on top of the sediments, e.g., sea cucumber or a sea snail.

Hyperbenthos

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Hyperbenthos (or hyperbenthic), prefix from Ancient Greek hupér 'over', lives just above the sediment, e.g., a rock cod.

Food sources

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Effect of eutrophication
on marine benthic life

The main food sources for the benthos are phytoplankton and organic detrital matter.[16][17] In coastal locations, organic run off from land provides an additional food source.[18] Meiofauna and bacteria consume and recycle organic matter in the sediments, playing an important role in returning nitrate and phosphate to the pelagic.[19]

The depth of water, temperature and salinity, and type of local substrate all affect what benthos is present. In coastal waters and other places where light reaches the bottom, benthic photosynthesizing diatoms can proliferate. Filter feeders, such as sponges and bivalves, dominate hard, sandy bottoms. Deposit feeders, such as polychaetes, populate softer bottoms. Fish, such as dragonets, as well as sea stars, snails, cephalopods, and crustaceans are important predators and scavengers.

Benthic organisms, such as sea stars, oysters, clams, sea cucumbers, brittle stars and sea anemones, play an important role as a food source for fish, such as the California sheephead, and humans.

Ecological role

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Benthos as bioindicators

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Benthic macro-invertebrates play a critical role in aquatic ecosystems. These organisms can be used to indicate the presence, concentration, and effect of water pollutants in the aquatic environment. Some water contaminants—such as nutrients, chemicals from surface runoff, and metals[20]—settle in the sediment of river beds, where many benthos reside. Benthos are highly sensitive to contamination, so their close proximity to high pollutant concentrations make these organisms ideal for studying water contamination.[21]

Benthos can be used as bioindicators of water pollution through ecological population assessments or through analyzing biomarkers. In ecological population assessments, a relative value of water pollution can be detected. Observing the number and diversity of macro-invertebrates in a waterbody can indicate the pollution level. In highly contaminated waters, a reduced number of organisms and only pollution-tolerant species will be found.[22] In biomarker assessments, quantitative data can be collected on the amount of and direct effect of specific pollutants in a waterbody. The biochemical response of macro-invertebrates' internal tissues can be studied extensively in the laboratory. The concentration of a chemical can cause many changes, including changing feeding behaviors,[23] inflammation, and genetic damage,[24] effects that can be detected outside of the stream environment. Biomarker analysis is important for mitigating the negative impacts of water pollution because it can detect water pollution before it has a noticeable ecological effect on benthos populations.[25]

Carbon processing

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Organic matter produced in the sunlit layer of the ocean and delivered to the sediments is either consumed by organisms or buried. The organic matter consumed by organisms is used to synthesize biomass (i.e. growth) converted to carbon dioxide through respiration, or returned to the sediment as faeces. This cycle can occur many times before either all organic matter is used up or eventually buried. This process is known as the biological pump.[26][27]

In the long-term or at steady-state, i.e., the biomass of benthic organisms does not change, the benthic community can be considered a black box diverting organic matter into either metabolites or the geosphere (burial).[27] The macrobenthos also indirectly impacts carbon cycling on the seafloor through bioturbation.[28]

Threats

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Benthos are negatively impacted by fishing, pollution and litter, deep-sea mining, oil and gas activities, tourism, shipping, invasive species, climate change (and its impacts such as ocean acidification, ocean warming and changes to ocean circulation) and construction such as coastal development, undersea cables, and wind farm construction.[29]

See also

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Benthos (organisms that live at the ocean floor) can be contrasted with neuston (organisms that live at the ocean surface) plankton (organisms that drift with water currents) and nekton (organisms that can swim against water currents)

Notes

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  1. ^ a b Benthos from the Census of Antarctic Marine Life website
  2. ^ US Department of Commerce, National Oceanic and Atmospheric Administration. "How does pressure change with ocean depth?". oceanservice.NOAA.gov.
  3. ^ Haeckel, E. 1891. Plankton-Studien. Jenaische Zeitschrift für Naturwissenschaft 25 / (Neue Folge) 18: 232–336. BHL.
  4. ^ βένθος. Liddell, Henry George; Scott, Robert; A Greek–English Lexicon at the Perseus Project.
  5. ^ "North American Benthological Society website". Archived from the original on 2008-07-05. Retrieved 2008-08-16.
  6. ^ Nehring, S. & Albrecht, U. (1997). Benthos und das redundant Benton: Neologismen in der deutschsprachigen Limnologie. Lauterbornia 31: 17-30, [1].
  7. ^ Lalli, Carol M.; Parsons, Timothy R. (1997). "Benthos". Biological Oceanography: An Introduction. Elsevier. pp. 177–195. doi:10.1016/b978-075063384-0/50063-3. ISBN 9780750633840.
  8. ^ Sokolova, M. N. (2000). Feeding and trophic structure of the deep-sea macrobenthos. Enfield, NH: Science Publishers. ISBN 978-1-57808-090-8. OCLC 46724477.
  9. ^ Bruckner, Monica (2020) "Paleoclimatology: How Can We Infer Past Climates?" SERC, Carleton College. Modified 23 July 2020. Retrieved 10 September 2020.
  10. ^ Earth barreling toward 'Hothouse' state not seen in 50 million years, epic new climate record shows LiveScience, 10 September 2020.
  11. ^ Westerhold, Thomas; Marwan, Norbert; Drury, Anna Joy; Liebrand, Diederik; Agnini, Claudia; Anagnostou, Eleni; Barnet, James S. K.; Bohaty, Steven M.; De Vleeschouwer, David; Florindo, Fabio; Frederichs, Thomas; Hodell, David A.; Holbourn, Ann E.; Kroon, Dick; Lauretano, Vittoria; Littler, Kate; Lourens, Lucas J.; Lyle, Mitchell; Pälike, Heiko; Röhl, Ursula; Tian, Jun; Wilkens, Roy H.; Wilson, Paul A.; Zachos, James C. (2020). "An astronomically dated record of Earth's climate and its predictability over the last 66 million years". Science. 369 (6509): 1383–1387. Bibcode:2020Sci...369.1383W. doi:10.1126/science.aba6853. hdl:11577/3351324. PMID 32913105. S2CID 221593388.
  12. ^ Bob Yirka 29 Aug 2013
  13. ^ Sussman: Oldest Plants, The Guardian, 2 May 2010
  14. ^ "It's Okay to be Smart • the oldest living thing in the world: These". Archived from the original on 2018-07-13. Retrieved 2018-07-13.
  15. ^ Willerslev, Eske; Froese, Duane; Gilichinsky, David; Rønn, Regin; Bunce, Michael; Zuber, Maria T.; Gilbert, M. Thomas P.; Brand, Tina; Munch, Kasper; Nielsen, Rasmus; Mastepanov, Mikhail; Christensen, Torben R.; Hebsgaard, Martin B.; Johnson, Sarah Stewart (4 September 2007). "Ancient bacteria show evidence of DNA repair". Proceedings of the National Academy of Sciences. 104 (36): 14401–14405. Bibcode:2007PNAS..10414401J. doi:10.1073/pnas.0706787104. PMC 1958816. PMID 17728401.
  16. ^ Smetacek, Victor (1984), Fasham, M. J. R. (ed.), "The Supply of Food to the Benthos", Flows of Energy and Materials in Marine Ecosystems: Theory and Practice, Boston, MA: Springer US, pp. 517–547, doi:10.1007/978-1-4757-0387-0_20, ISBN 978-1-4757-0387-0, retrieved 2024-09-23
  17. ^ Snelgrove, Paul V.R. (2013), "Marine Sediments", Encyclopedia of Biodiversity, Elsevier, pp. 105–115, ISBN 978-0-12-384720-1, retrieved 2024-09-23
  18. ^ "Benthos". Encyclopedia Britannica. Retrieved 2024-09-23.
  19. ^ Nunnally, Clifton C. (2019), "Benthic–Pelagic Coupling: Linkages Between Benthic Ecology and Biogeochemistry and Pelagic Ecosystems and Process", Encyclopedia of Ocean Sciences, Elsevier, pp. 660–662, doi:10.1016/B978-0-12-409548-9.11087-5, ISBN 978-0-12-813082-7, retrieved 2024-09-23
  20. ^ "Major Contaminants | Contaminated Sediments | US EPA". archive.epa.gov. Retrieved 2022-10-12.
  21. ^ Rodrigues, Carolina; Guimarães, Laura; Vieira, Natividade (2019-08-01). "Combining biomarker and community approaches using benthic macroinvertebrates can improve the assessment of the ecological status of rivers". Hydrobiologia. 839 (1): 1–24. doi:10.1007/s10750-019-03991-7. ISSN 1573-5117. S2CID 186207664.
  22. ^ US EPA, OW (2013-11-21). "Indicators: Benthic Macroinvertebrates". www.epa.gov. Retrieved 2022-10-14.
  23. ^ "Water Research". Water Research. 39 (20): II. 2005-12-01. doi:10.1016/S0043-1354(05)00684-6. ISSN 0043-1354.
  24. ^ "Online Submission and Review for Science of the Total Environment". Science of the Total Environment. 329 (1–3): 1. August 2004. Bibcode:2004ScTEn.329....1.. doi:10.1016/j.scitotenv.2004.06.001.
  25. ^ Damásio, Joana; Fernández-Sanjuan, Maria; Sánchez-Avila, Juan; Lacorte, Silvia; Prat, Narcís; Rieradevall, Maria; Soares, Amadeu M.V.M.; Barata, Carlos (June 2011). "Multi-biochemical responses of benthic macroinvertebrate species as a complementary tool to diagnose the cause of community impairment in polluted rivers". Water Research. 45 (12): 3599–3613. doi:10.1016/j.watres.2011.04.006. PMID 21571352.
  26. ^ Sigman, D.M.; Haug, G.H. (2003), "The Biological Pump in the Past", Treatise on Geochemistry, Elsevier, pp. 491–528, ISBN 978-0-08-043751-4, retrieved 2024-09-22
  27. ^ a b Middelburg, Jack J. (19 January 2018). "Reviews and syntheses: to the bottom of carbon processing at the seafloor". Biogeosciences. 15 (2). Copernicus GmbH: 413–427. Bibcode:2018BGeo...15..413M. doi:10.5194/bg-15-413-2018. ISSN 1726-4189. Material was copied from this source, which is available under a Creative Commons Attribution 4.0 International License.
  28. ^ Sun, Ming-Yi; Dai, Jihong (2005-09-01). "Relative influences of bioturbation and physical mixing on degradation of bloom-derived particulate organic matter: Clue from microcosm experiments". Marine Chemistry. 96 (3): 201–218. doi:10.1016/j.marchem.2004.11.003. ISSN 0304-4203.
  29. ^ Harris, Peter T. (2020-01-01), Harris, Peter T.; Baker, Elaine (eds.), "Chapter 3 - Anthropogenic threats to benthic habitats", Seafloor Geomorphology as Benthic Habitat (Second Edition), Elsevier, pp. 35–61, ISBN 978-0-12-814960-7, retrieved 2024-09-24

References

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