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Neuston

From Wikipedia, the free encyclopedia
Organisms that live at the surface of a body of water
Thewater strider, a common freshwater neuston

Neuston, also calledpleuston, areorganisms that live at thesurface of abody of water, such as anocean,estuary,lake,river,wetland orpond. Neuston can live on top of the water surface or submersed just below the water surface. In addition,microorganisms can exist in thesurface microlayer that forms between the top- and the under-side of the water surface. Neuston has been defined as "organisms living at the air/water interface of freshwater, estuarine, and marine habitats or referring to the biota on or directly below the water’s surface layer."[1]

Neustons can be informally separated into two groups: thephytoneuston, which areautotrophs floating at the water surface includingcyanobacteria, filamentousalgae andfree-floating aquatic plant (e.g.mosquito fern,duckweed andwater lettuce); and thezooneuston, which are floatingheterotrophs such asprotists (e.g.ciliates) andmetazoans (aquatic animals). This article mainly concerns with metazoan zooneustons.

The word "neuston" comes fromGreekneustos, meaning "swimming", and thenounsuffix-on (as in "plankton").[2] This term first appears in the biological literature in 1917.[3] The alternative term pleuston comes from the Greekplein, meaning "to sail or float". The first known use of this word was in 1909, before the first known use of neuston.[4] In the past various authors have attempted distinctions between neuston and pleuston, but these distinctions have not been widely adopted. As of 2021, the two terms are usually used somewhat interchangeably, and neuston is used more often than pleuston.

Overview

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Portuguese man o' war
emblematic figure of the marine pleuston
Marine neuston (organisms that live at the ocean surface) can be contrasted withplankton (organisms that drift with water currents),nekton (organisms that can swim against water currents) andbenthos (organisms that live at the ocean floor)

The neuston of the surface layer is one of the lesser known aquatic ecological groups.[5] The term was first used in 1917 by Naumann to describe species associated with the surface layer of freshwater habitats.[3] Later in 1971, Zaitsev identified neuston composition in marine waters.[6] These populations would include microscopic species, plus various plant and animal taxa, such asphytoplankton andzooplankton, living in this region.[6][7] In 2002, Gladyshev further characterised the major physical and chemical dynamics of the surface layer influencing the composition and relationships with various neustonic populations"[8][7]

The neustonic community structure is conditioned by sunlight and an array ofendogenous (organic matter, respiratory, photosynthetic, decompositional processes) andexogenous (atmospheric deposition, inorganic matter, winds, wave action, precipitation, UV radiation, oceanic currents, surface temperature) variables and processes affecting nutrient inputs and recycling.[7][9][10] Furthermore, the neuston provides a food source to thezooplankton migrating from deeper layers to the surface,[11] as well as toseabirds roaming over the oceans.[12] For these reasons, the neustonic community is believed to play a critical role on the structure and function ofmarine food webs. Yet, research on neuston communities to date focused predominantly on geographically limited regions of the ocean [13][11][14][15][10] or coastal areas.[16][17][18] Consequently, neuston complexity is still poorly understood as studies on the community structure and the taxonomical composition of organisms inhabiting this ecological niche remain few,[10] and global scale analyses are yet lacking.[5]

Types

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Neuston net

There are different ways neuston can be categorised. Kennish divides them by their physical position into two groups:[1]

  • epineuston: organisms living on the water's surface
  • hyponeuston: organisms within a region of specified depth directly below the surface layer

To this can be added the organisms living in the microlayer at the interface between air and water:

  • microlayer neuston: organisms (microorganisms) living in thesurface microlayer sandwiched between the upper and under surface.

Marshall and Burchardt divide neuston into three ecological categories:[7][5]

  • euneuston: organisms with maximum abundance in the vicinity of the surface on which they reside day and night
  • facultative neuston: organisms concentrating at the surface only during certain hours of the day, usually during darkness
  • pseudoneuston: organisms with maximum concentrations at deeper layers but reaching the surface layer at least during certain hours.

Freshwater neuston

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Freshwater neuston, organisms living at lake or pond surfaces or slow moving parts of rivers and streams, includebeetles (seewhirligig beetle),protozoans,bacteria andspiders (seefishing spider anddiving bell spider).Springtails in the generaPodura andSminthurides are almost exclusively neustonic, whileHypogastrura species often aggregate on pond surfaces.Water striders such asGerris are common examples of insects that support their weight on water'ssurface tension.

Floods

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Raft of red fire ants floating over a pond bank submerged by heavy rain
Fire Ants Turn Into a Stinging Life Raft
YouTube

There are different terrestrial environmental factors such as flood pulses and droughts, and these environmental factors affect species such as neuston, whether the effects lead to more or less variations in the species. When flood pulses (an abiotic factor) occur, connectivity between different aquatic environments occur. Species that live in environments with irregular flood patterns tend to have more variations, or even decrease species and variations; similar idea to what happens when droughts occur.[19]

Red fire ants have adapted to contend with both flooding and drought conditions. If the ants sense increased water levels in their nests, they link together and form a ball or raft that floats, with the workers on the outside and the queen inside.[20][21][22] The brood is transported to the highest surface.[23] They are also used as the founding structure of the raft, except for the eggs and smaller larvae. Before submerging, the ants will tip themselves into the water and sever connections with the dry land. In some cases, workers may deliberately remove all males from the raft, resulting in the males drowning.

The longevity of a raft can be as long as 12 days. Ants that are trapped underwater escape by lifting themselves to the surface using bubbles which are collected from submerged substrate.[23] Owing to their greater vulnerability to predators, red imported fire ants are significantly more aggressive when rafting. Workers tend to deliver higher doses of venom, which reduces the threat of other animals attacking. Due to this, and because a higher workforce of ants is available, rafts are potentially dangerous to those that encounter them.[24]

Marine neuston

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Further information:Ocean surface ecosystem andSea surface microlayer

The marine neuston, organisms living at the ocean surface, are one of the least studied planktonic groups. Neuston occupies a restricted ecological niche and is affected by a wide range of endogenous and exogenous processes while also being a food source to zooplankton and fish migrating from the deep layers and seabirds.[5]

The neustonic animals form a subset of the zooplankton community, which plays a pivotal role in the functioning of marine ecosystems. Zooplankton are partially responsible for the activeenergy flux between superficial and deep layers of the ocean.[25][26][27] Zooplanktonspecies composition, biomass, and secondary production influence a wide range of trophic levels in marine communities, as they constitute a link between primary production and secondary consumers.[28][29][30]Copepods constitute the most abundant zooplankton taxon in terms ofbiomass anddiversity worldwide.[31][32] Consequently, changes in their community composition can impact thebiogeochemical cycles[33] and might be indicative of climate variability impacts on ecosystem functioning.[34][5]

Historically, zooplankton assemblages research has focused mainly on taxonomic studies and those related to community structure.[35] However, recently, research has veered toward an alternativetrait-based approach,[35][29][36] providing a perspective more focused on groups of species with analogousfunctional traits. This allows individuals to be classified into types characterized by the presence/absence of certainalleles of agene, into size classes,ecological guilds, orfunctional groups (FGs).[37] Functional traits arephenotypes affecting organism fitness, growth, survival, and reproductive ability.[38][30] These are regulated by the expression of genes within species, and the expression of traits regulate, in turn, the species fitness under contrastingbiotic andabiotic circumstances.[39] Moreover, a specific functional trait can also develop from the interactions between other traits and environmental conditions,[31] leading to a given trait grouping being favoured under certain conditions. Zooplankton traits can be classified in accordance to ecological functions – feeding, growth, reproduction, survival, and other characteristics such asmorphology,physiology, behaviour, or life history.[28][40][41] Particularly,feeding strategies andtrophic groups are relevant to establish feeding efficiency and associated predation risk.[42] Additionally, they facilitate the understanding ofecosystem services associated with zooplankton, such as the distribution of fisheries or biogeochemical cycling [43] while also allowing the positioning of zooplankton taxa in the food web.[29][44][5]

Coral-treaders are a genus of quite rare wingless marine bugs known only from coral reefs in the Indo-Pacific region. During low tide they move over water surfaces around coral atolls and reefs similar to the more familiar water-striders, staying submerged in reef crevices during high tide.

See also

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References

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  1. ^abKennish, Michael J., ed. (2016). "Encyclopedia of Estuaries".Encyclopedia of Earth Sciences Series. Dordrecht: Springer Netherlands.doi:10.1007/978-94-017-8801-4.ISBN 978-94-017-8800-7.ISSN 1388-4360.S2CID 129770661.
  2. ^Merriam-Webster Dictionary:neuston. Accessed 18 December 2021.
  3. ^abNaumann, E. (1917) "Beiträge zur Kenntnis des Teichnannoplanktons. II. Über das Neuston des Süsswassers",Biologisches Zentralblatt,37: 98–106.
  4. ^Merriam-Webster Dictionary:pleuston. Accessed 18 December 2021.
  5. ^abcdefAlbuquerque, Rui; Bode, Antonio; González-Gordillo, Juan Ignacio; Duarte, Carlos M.; Queiroga, Henrique (2021)."Trophic Structure of Neuston Across Tropical and Subtropical Oceanic Provinces Assessed with Stable Isotopes".Frontiers in Marine Science.7.doi:10.3389/fmars.2020.606088.hdl:10754/667566. Material was copied from this source, which is available under aCreative Commons Attribution 4.0 International License.
  6. ^abZaitsev, Y. P. (1971) "Marine Neustonology".National Marine Fisheries Service,NOAA andNSF, Washington DC.
  7. ^abcdMarshall, Harold G.; Burchardt, Lubomira (2005). "Neuston: Its definition with a historical review regarding its concept and community structure".Archiv für Hydrobiologie.164 (4):429–448.doi:10.1127/0003-9136/2005/0164-0429.
  8. ^Gladyshev, Michail (2002).Biophysics of the surface microlayer of aquatic ecosystems. London: IWA.ISBN 978-1-900222-17-4.OCLC 49871862.
  9. ^Barnes, D. K.A.; Davenport, J.; Rawlinson, K. A. (2005). "Temporal Variation in Diversity and Community Structure of a Semi-Isolated Neuston Community".Biology and Environment: Proceedings of the Royal Irish Academy.105 (2):107–122.doi:10.3318/bioe.2005.105.2.107.S2CID 84508946.
  10. ^abcRezai, Hamid; Kabiri, Keivan; Arbi, Iman; Amini, Nafiseh (2019). "Neustonic zooplankton in the northeastern Persian Gulf".Regional Studies in Marine Science.26: 100473.Bibcode:2019RSMS...2600473R.doi:10.1016/j.rsma.2018.100473.S2CID 135269465.
  11. ^abHempel, G. and Weikert, H. (1972) "The neuston of the subtropical and boreal North-eastern Atlantic Ocean. A review".Marine Biology,13(1): 70–88.
  12. ^Cheng, L., Spear, L. and AINLEY, D.G. (2010) "Importance of marine insects (Heteroptera: Gerridae, Halobates spp.) as prey of eastern tropical Pacific seabirds".Marine Ornithology,38": 91–95.
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  15. ^Ebberts, B. D., and Wing, B. L. (1997). "Diversity and abundance of neustonic zooplankton in the North Pacific subarctic frontal zone". U.S. Department of Commerce, NOAA Technical Memorandum NMFS-AFSC-70.
  16. ^Brodeur, Richard D. (1989). "Neustonic feeding by juvenile salmonids in coastal waters of the Northeast Pacific".Canadian Journal of Zoology.67 (8):1995–2007.doi:10.1139/z89-284.
  17. ^Le Fèvre, J.; Bourget, E. (1991). "Neustonic niche for cirripede larvae as a possible adaptation to long-range dispersal".Marine Ecology Progress Series.75:185–194.Bibcode:1991MEPS...75..185L.doi:10.3354/meps075185.
  18. ^Padmavati, G. and Goswami, S.C. (1996). "Zooplankton distribution in neuston and water column along west coast of India from Goa to Gujarat".Indian J. Mar. Species,25: 85–90.
  19. ^Conceição, E. de O. da, Higuti, J., Campos, R. de, & Martens, K. (2018). Effects of flood pulses on persistence and variability of pleuston communities in a tropical floodplain lake. Hydrobiologia, 807(1), 175–188.
  20. ^Mlot, N.J.; Craig, A.T.; Hu, D.L. (2011)."Fire ants self-assemble into waterproof rafts to survive floods".Proceedings of the National Academy of Sciences.108 (19):7669–7673.Bibcode:2011PNAS..108.7669M.doi:10.1073/pnas.1016658108.PMC 3093451.PMID 21518911.
  21. ^Morrill, W.L. (1974). "Dispersal of red imported fire ants by water".The Florida Entomologist.57 (1):39–42.doi:10.2307/3493830.JSTOR 3493830.
  22. ^Hölldobler & Wilson 1990, p. 171. sfn error: no target: CITEREFHölldoblerWilson1990 (help)
  23. ^abAdams, B.J.; Hooper-Bùi, L.M.; Strecker, R.M.; O'Brien, D.M. (2011)."Raft formation by the red imported fire ant,Solenopsis invicta".Journal of Insect Science.11 (171): 171.doi:10.1673/031.011.17101.PMC 3462402.PMID 22950473.
  24. ^Haight, K.L. (2006). "Defensiveness of the fire ant,Solenopsis invicta, is increased during colony rafting".Insectes Sociaux.53 (1):32–36.doi:10.1007/s00040-005-0832-y.S2CID 24420242.
  25. ^Turner, JT (2002)."Zooplankton fecal pellets, marine snow and sinking phytoplankton blooms".Aquatic Microbial Ecology.27:57–102.doi:10.3354/ame027057.
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  29. ^abcBenedetti, Fabio; Gasparini, Stéphane; Ayata, Sakina-Dorothée (2016)."Identifying copepod functional groups from species functional traits".Journal of Plankton Research.38 (1):159–166.doi:10.1093/plankt/fbv096.PMC 4722884.PMID 26811565.
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