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Mycoplankton

January 06, 2023

Mycoplankton are saprotrophic members of the plankton communities of marine and freshwater ecosystems.[1][2] They are composed of filamentous free-living fungi and yeasts that are associated with planktonic particles or phytoplankton.[3] Similar to bacterioplankton, these aquatic fungi play a significant role in heterotrophicmineralization and nutrient cycling.[4] Mycoplankton can be up to 20 mm in diameter and over 50 mm in length.[5]

In a typical milliliter of seawater, there are approximately 103 to 104 fungal cells.[6] This number is greater in coastal ecosystems and estuaries due to nutritional runoff from terrestrial communities. Aquatic fungi are found in a myriad of ecosystems, from mangroves, to wetlands, to the open ocean.[7] The greatest diversity and number of species of mycoplankton is found in surface waters (< 1000 m), and the vertical profile depends on the abundance of phytoplankton.[8][9] Furthermore, this difference in distribution may vary between seasons due to nutrient availability.[10] Aquatic fungi survive in a constant oxygen deficient environment, and therefore depend on oxygen diffusion by turbulence and oxygen generated by photosynthetic organisms.[11]

Classification

There is a large amount of diversity among aquatic fungi. These fungi may be classified using three groups:[11]

The majority of mycoplankton species are higher fungi, found in the Ascomycota and Basidiomycota phyla.[8]

Genome sequencing is a common way to assess and categorize aquatic fungi. Fungi are Eukaryotes, and as such it is often the 18s rDNA which is sequenced.[7]

According to fossil records, fungi date back to the late Proterozoic era, 900-570 million years ago. It is hypothesized that mycoplankton evolved from terrestrial fungi, likely in the Paleozoic era (390 million years ago).[2] The methods and pathways of terrestrial fungi's adaption to the marine environment are still under study.

Biogeochemical contributions

There are multiple biogeochemical cycles in the Earth's oceans in which Mycoplankton play a role.[12] They are a part of the microbial loop and other forms of nutrient cycling, including the mycoplankton specific mycoflux and mycoloop.[13]

Cycling of organic nutrients

Mycoplankton, like all fungi, play an essential roll in the degradation of detritus and organic matter from plants, as well as other larger organisms.[14][15] By working with other microbial communities, mycoplankton efficiently convert particulate organic matter to dissolved organic matter as part of biogeochemical cycling.[12] Mycoplankton and heterotrophic bacteria mediate carbon, nitrogen, oxygen, and other nutrient fluxes in marine ecosystems.[16] The incorporation of dissolved organic carbon into microbe biomass is what is known as the microbial loop.[13]

Mycoplankton are often found in higher abundances near the surface, as well as in shallow waters. This is indicative of a connection between mycoplankton and the upwelling of organic matter. Phytoplankton communities are also abundant in the euphotic zone, which provides further evidence for the role of Mycoplankton in consumption of organic matter.[3][10]

Mycoloop and mycoflux

Mycoplankton are important in controlling phytoplankton and zooplankton populations. The mycoloop is very similar to the microbial loop, as the basis of both is for microbes to make material accessible to organisms that occupy higher trophic levels. Through the mycoloop phytoplankton are transformed such that they are able to be grazed upon by zooplankton. This function is performed by parasitic marine fungi (mycoplankton).[13]

The mycoflux is understudied, but believed to be a part of carbon capture in aquatic habitats. Functionally, this process involves aquatic fungi breaking down organic matter.[13]

Benthic shunt

Another process which mycoplankton take part in is known as the benthic shunt. This process takes place in the benthic zone, the sediments at the bottom of the water. The benthic shunt is typically referred to in relation to freshwater aquatic environments, but the concept is relevant and takes place in marine habitats as well. The benthic shunt is basically energy and nutrient flow as directed by lower trophic level organisms, such as mycoplankton.[13]

Role in food webs

Due to their significant contributions to nutrient cycling, mycoplankton play a large role in regulation of food webs. Aquatic fungi such as mycoplankton degrade and convert organic matter into other forms. In a way, mycoplankton contributions to aquatic food webs are the biogeochemical services that they perform. The grazer food chain and the microbial food chain are inherently intertwined, as the dissolved organic carbon at the base of the microbial food chain originally comes from material excreted by grazers from the grazer food chain.[8] Not only are the new forms of organic matter more palatable by macro plankton, but the process of conversion releases substrates which support bacterial growth.[7] This in turn allows for the bacteria and macro plankton to support even higher trophic levels. This is a form of bottom-up control of aquatic food webs.

Communities

While mycoplankton are found in a variety of aquatic environments, their distribution, abundance, and diversity vary throughout these environments.[7] There is typically a greater amount of diversity and a larger abundance of mycoplankton in coastal waters, due to the extra availability of nutrients. There also exists variation in community composition and diversity at different depths. The control factors for the distribution of mycoplankton is thought to be variable.[8]

See also

References

  1. ^ Jones EG, Hyde KD, Pang KL, eds. (2014-08-27). Freshwater Fungi: and Fungal-like Organisms. Walter de Gruyter GmbH & Co KG. ISBN 978-3-11-033348-0.
  2. ^ a b Jones EG, Hyde KD, Pang KL (2012-08-31). Marine Fungi: and Fungal-like Organisms. Walter de Gruyter. ISBN 978-3-11-026406-7.
  3. ^ a b Wang X, Singh P, Gao Z, Zhang X, Johnson ZI, Wang G (2014-07-03). "Distribution and diversity of planktonic fungi in the West Pacific Warm Pool". PLOS ONE. 9 (7): e101523. Bibcode:2014PLoSO...9j1523W. doi:10.1371/journal.pone.0101523. PMC 4081592. PMID 24992154.
  4. ^ Raghukumar C, ed. (2012). "Biology of Marine Fungi". Progress in Molecular and Subcellular Biology. 53. doi:10.1007/978-3-642-23342-5. ISBN 978-3-642-23341-8. ISSN 0079-6484. S2CID 39378040.
  5. ^ Damare S, Raghukumar C (July 2008). "Fungi and macroaggregation in deep-sea sediments". Microbial Ecology. 56 (1): 168–177. doi:10.1007/s00248-007-9334-y. PMID 17994287. S2CID 21288251.
  6. ^ Kubanek J, Jensen PR, Keifer PA, Sullards MC, Collins DO, Fenical W (June 2003). "Seaweed resistance to microbial attack: a targeted chemical defense against marine fungi". Proceedings of the National Academy of Sciences of the United States of America. 100 (12): 6916–6921. Bibcode:2003PNAS..100.6916K. doi:10.1073/pnas.1131855100. PMC 165804. PMID 12756301.
  7. ^ a b c d Jobard M, Rasconi S, Sime-Ngando T (2010-06-01). "Diversity and functions of microscopic fungi: a missing component in pelagic food webs". Aquatic Sciences. 72 (3): 255–268. doi:10.1007/s00027-010-0133-z. ISSN 1420-9055. S2CID 36789070.
  8. ^ a b c d Gao Z, Johnson ZI, Wang G (January 2010). "Molecular characterization of the spatial diversity and novel lineages of mycoplankton in Hawaiian coastal waters". The ISME Journal. 4 (1): 111–120. doi:10.1038/ismej.2009.87. PMID 19641535. S2CID 2395339.
  9. ^ Panzer K, Yilmaz P, Weiß M, Reich L, Richter M, Wiese J, et al. (2015-07-30). "Identification of Habitat-Specific Biomes of Aquatic Fungal Communities Using a Comprehensive Nearly Full-Length 18S rRNA Dataset Enriched with Contextual Data". PLOS ONE. 10 (7): e0134377. Bibcode:2015PLoSO..1034377P. doi:10.1371/journal.pone.0134377. PMC 4520555. PMID 26226014.
  10. ^ a b "First record of flamentous fungi in the coastal upwelling ecosystem off central Chile". Gayana (Concepción). 68 (2). 2004. doi:10.4067/s0717-65382004000200001. ISSN 0717-6538.
  11. ^ a b Sridhar KR (2009). Aquatic fungi – Are they planktonic? Plankton Dynamics of Indian Waters. Jaipur, India: Pratiksha Publications. pp. 133–148.
  12. ^ a b Kiørboe T, Jackson G (2001). "Marine snow, organic solute plumes, and optimal chemosensory behavior of bacteria". Limnology and Oceanography. 46 (6): 1309–1318. Bibcode:2001LimOc..46.1309K. doi:10.4319/lo.2001.46.6.1309. S2CID 86713938.
  13. ^ a b c d e Grossart HP, Van den Wyngaert S, Kagami M, Wurzbacher C, Cunliffe M, Rojas-Jimenez K (June 2019). "Fungi in aquatic ecosystems". Nature Reviews. Microbiology. 17 (6): 339–354. doi:10.1038/s41579-019-0175-8. PMID 30872817. S2CID 77395296.
  14. ^ Carlile MJ, Watkinson SC, Gooday GW (2001). The Fungi. San Diego: Academic Press.
  15. ^ Pang KL, Mitchell JI (December 2005). "Molecular approaches for assessing fungal diversity in marine substrata". Botanica Marina. 48 (5): 332–347. doi:10.1515/BOT.2005.046. ISSN 1437-4323.
  16. ^ Buesing N, Gessner MO (January 2006). "Benthic bacterial and fungal productivity and carbon turnover in a freshwater marsh". Applied and Environmental Microbiology. 72 (1): 596–605. Bibcode:2006ApEnM..72..596B. doi:10.1128/AEM.72.1.596-605.2006. PMC 1352256. PMID 16391096.

January 06, 2023
mycoplankton, saprotrophic, members, plankton, communities, marine, freshwater, ecosystems, they, composed, filamentous, free, living, fungi, yeasts, that, associated, with, planktonic, particles, phytoplankton, similar, bacterioplankton, these, aquatic, fungi. Mycoplankton are saprotrophic members of the plankton communities of marine and freshwater ecosystems 1 2 They are composed of filamentous free living fungi and yeasts that are associated with planktonic particles or phytoplankton 3 Similar to bacterioplankton these aquatic fungi play a significant role in heterotrophicmineralization and nutrient cycling 4 Mycoplankton can be up to 20 mm in diameter and over 50 mm in length 5 In a typical milliliter of seawater there are approximately 103 to 104 fungal cells 6 This number is greater in coastal ecosystems and estuaries due to nutritional runoff from terrestrial communities Aquatic fungi are found in a myriad of ecosystems from mangroves to wetlands to the open ocean 7 The greatest diversity and number of species of mycoplankton is found in surface waters lt 1000 m and the vertical profile depends on the abundance of phytoplankton 8 9 Furthermore this difference in distribution may vary between seasons due to nutrient availability 10 Aquatic fungi survive in a constant oxygen deficient environment and therefore depend on oxygen diffusion by turbulence and oxygen generated by photosynthetic organisms 11 Contents 1 Classification 2 Biogeochemical contributions 2 1 Cycling of organic nutrients 2 2 Mycoloop and mycoflux 2 3 Benthic shunt 3 Role in food webs 4 Communities 5 See also 6 ReferencesClassification EditThere is a large amount of diversity among aquatic fungi These fungi may be classified using three groups 11 Lower fungi adapted to marine habitats zoosporic fungi including mastigomycetes oomycetes amp chytridiomycetes Higher fungi filamentous modified to planktonic lifestyle hyphomycetes ascomycetes basidiomycetes Terrestrial fungi contain appendages of marine fungi trichomycetes The majority of mycoplankton species are higher fungi found in the Ascomycota and Basidiomycota phyla 8 Genome sequencing is a common way to assess and categorize aquatic fungi Fungi are Eukaryotes and as such it is often the 18s rDNA which is sequenced 7 According to fossil records fungi date back to the late Proterozoic era 900 570 million years ago It is hypothesized that mycoplankton evolved from terrestrial fungi likely in the Paleozoic era 390 million years ago 2 The methods and pathways of terrestrial fungi s adaption to the marine environment are still under study Biogeochemical contributions EditThere are multiple biogeochemical cycles in the Earth s oceans in which Mycoplankton play a role 12 They are a part of the microbial loop and other forms of nutrient cycling including the mycoplankton specific mycoflux and mycoloop 13 Cycling of organic nutrients Edit Mycoplankton like all fungi play an essential roll in the degradation of detritus and organic matter from plants as well as other larger organisms 14 15 By working with other microbial communities mycoplankton efficiently convert particulate organic matter to dissolved organic matter as part of biogeochemical cycling 12 Mycoplankton and heterotrophic bacteria mediate carbon nitrogen oxygen and other nutrient fluxes in marine ecosystems 16 The incorporation of dissolved organic carbon into microbe biomass is what is known as the microbial loop 13 Mycoplankton are often found in higher abundances near the surface as well as in shallow waters This is indicative of a connection between mycoplankton and the upwelling of organic matter Phytoplankton communities are also abundant in the euphotic zone which provides further evidence for the role of Mycoplankton in consumption of organic matter 3 10 Mycoloop and mycoflux Edit Mycoplankton are important in controlling phytoplankton and zooplankton populations The mycoloop is very similar to the microbial loop as the basis of both is for microbes to make material accessible to organisms that occupy higher trophic levels Through the mycoloop phytoplankton are transformed such that they are able to be grazed upon by zooplankton This function is performed by parasitic marine fungi mycoplankton 13 The mycoflux is understudied but believed to be a part of carbon capture in aquatic habitats Functionally this process involves aquatic fungi breaking down organic matter 13 Benthic shunt Edit Another process which mycoplankton take part in is known as the benthic shunt This process takes place in the benthic zone the sediments at the bottom of the water The benthic shunt is typically referred to in relation to freshwater aquatic environments but the concept is relevant and takes place in marine habitats as well The benthic shunt is basically energy and nutrient flow as directed by lower trophic level organisms such as mycoplankton 13 Role in food webs EditDue to their significant contributions to nutrient cycling mycoplankton play a large role in regulation of food webs Aquatic fungi such as mycoplankton degrade and convert organic matter into other forms In a way mycoplankton contributions to aquatic food webs are the biogeochemical services that they perform The grazer food chain and the microbial food chain are inherently intertwined as the dissolved organic carbon at the base of the microbial food chain originally comes from material excreted by grazers from the grazer food chain 8 Not only are the new forms of organic matter more palatable by macro plankton but the process of conversion releases substrates which support bacterial growth 7 This in turn allows for the bacteria and macro plankton to support even higher trophic levels This is a form of bottom up control of aquatic food webs Communities EditWhile mycoplankton are found in a variety of aquatic environments their distribution abundance and diversity vary throughout these environments 7 There is typically a greater amount of diversity and a larger abundance of mycoplankton in coastal waters due to the extra availability of nutrients There also exists variation in community composition and diversity at different depths The control factors for the distribution of mycoplankton is thought to be variable 8 See also EditAlgae Diverse group of photosynthetic eukaryotic organisms Biological pump Carbon capture process in oceans Marine fungiReferences Edit Jones EG Hyde KD Pang KL eds 2014 08 27 Freshwater Fungi and Fungal like Organisms Walter de Gruyter GmbH amp Co KG ISBN 978 3 11 033348 0 a b Jones EG Hyde KD Pang KL 2012 08 31 Marine Fungi and Fungal like Organisms Walter de Gruyter ISBN 978 3 11 026406 7 a b Wang X Singh P Gao Z Zhang X Johnson ZI Wang G 2014 07 03 Distribution and diversity of planktonic fungi in the West Pacific Warm Pool PLOS ONE 9 7 e101523 Bibcode 2014PLoSO 9j1523W doi 10 1371 journal pone 0101523 PMC 4081592 PMID 24992154 Raghukumar C ed 2012 Biology of Marine Fungi Progress in Molecular and Subcellular Biology 53 doi 10 1007 978 3 642 23342 5 ISBN 978 3 642 23341 8 ISSN 0079 6484 S2CID 39378040 Damare S Raghukumar C July 2008 Fungi and macroaggregation in deep sea sediments Microbial Ecology 56 1 168 177 doi 10 1007 s00248 007 9334 y PMID 17994287 S2CID 21288251 Kubanek J Jensen PR Keifer PA Sullards MC Collins DO Fenical W June 2003 Seaweed resistance to microbial attack a targeted chemical defense against marine fungi Proceedings of the National Academy of Sciences of the United States of America 100 12 6916 6921 Bibcode 2003PNAS 100 6916K doi 10 1073 pnas 1131855100 PMC 165804 PMID 12756301 a b c d Jobard M Rasconi S Sime Ngando T 2010 06 01 Diversity and functions of microscopic fungi a missing component in pelagic food webs Aquatic Sciences 72 3 255 268 doi 10 1007 s00027 010 0133 z ISSN 1420 9055 S2CID 36789070 a b c d Gao Z Johnson ZI Wang G January 2010 Molecular characterization of the spatial diversity and novel lineages of mycoplankton in Hawaiian coastal waters The ISME Journal 4 1 111 120 doi 10 1038 ismej 2009 87 PMID 19641535 S2CID 2395339 Panzer K Yilmaz P Weiss M Reich L Richter M Wiese J et al 2015 07 30 Identification of Habitat Specific Biomes of Aquatic Fungal Communities Using a Comprehensive Nearly Full Length 18S rRNA Dataset Enriched with Contextual Data PLOS ONE 10 7 e0134377 Bibcode 2015PLoSO 1034377P doi 10 1371 journal pone 0134377 PMC 4520555 PMID 26226014 a b First record of flamentous fungi in the coastal upwelling ecosystem off central Chile Gayana Concepcion 68 2 2004 doi 10 4067 s0717 65382004000200001 ISSN 0717 6538 a b Sridhar KR 2009 Aquatic fungi Are they planktonic Plankton Dynamics of Indian Waters Jaipur India Pratiksha Publications pp 133 148 a b Kiorboe T Jackson G 2001 Marine snow organic solute plumes and optimal chemosensory behavior of bacteria Limnology and Oceanography 46 6 1309 1318 Bibcode 2001LimOc 46 1309K doi 10 4319 lo 2001 46 6 1309 S2CID 86713938 a b c d e Grossart HP Van den Wyngaert S Kagami M Wurzbacher C Cunliffe M Rojas Jimenez K June 2019 Fungi in aquatic ecosystems Nature Reviews Microbiology 17 6 339 354 doi 10 1038 s41579 019 0175 8 PMID 30872817 S2CID 77395296 Carlile MJ Watkinson SC Gooday GW 2001 The Fungi San Diego Academic Press Pang KL Mitchell JI December 2005 Molecular approaches for assessing fungal diversity in marine substrata Botanica Marina 48 5 332 347 doi 10 1515 BOT 2005 046 ISSN 1437 4323 Buesing N Gessner MO January 2006 Benthic bacterial and fungal productivity and carbon turnover in a freshwater marsh Applied and Environmental Microbiology 72 1 596 605 Bibcode 2006ApEnM 72 596B doi 10 1128 AEM 72 1 596 605 2006 PMC 1352256 PMID 16391096 Retrieved from https en wikipedia org w index php title Mycoplankton amp oldid 1121404007, wikipedia, wiki, book, books, library,

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