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Global contribution of pelagic fungi to protein degradation in the ocean
Breyer, E.; Zhao, Z.; Herndl, G.J.; Baltar, F. (2022). Global contribution of pelagic fungi to protein degradation in the ocean. Microbiome 10(1): 143. https://dx.doi.org/10.1186/s40168-022-01329-5
In: Microbiome. BIOMED CENTRAL LTD: London. e-ISSN 2049-2618, more
Peer reviewed article  

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Keywords
    Fungi [WoRMS]
    Marine/Coastal
Author keywords
    Pelagic fungi; Proteases; Metagenomics; Metatranscriptomics; Global ocean; Nitrogen cycle

Authors  Top 
  • Breyer, E.
  • Zhao, Z.
  • Herndl, G.J., more
  • Baltar, F.

Abstract
    BackgroundFungi are important degraders of organic matter responsible for reintegration of nutrients into global food chains in freshwater and soil environments. Recent evidence suggests that they are ubiquitously present in the oceanic water column where they play an active role in the degradation of carbohydrates. However, their role in processing other abundant biomolecules in the ocean in comparison with that of prokaryotes remains enigmatic. Here, we performed a global-ocean multi-omics analysis of all fungal-affiliated peptidases (main enzymes responsible for cleaving proteins), which constitute the major fraction (> 50%) of marine living and detrital biomass. We determined the abundance, expression, diversity, taxonomic affiliation, and functional classification of the genes encoding all pelagic fungal peptidases from the epi- and mesopelagic layers.ResultsWe found that pelagic fungi are active contributors to protein degradation and nitrogen cycling in the global ocean. Dothideomycetes are the main fungi responsible for protease activity in the surface layers, whereas Leotiomycetes dominate in the mesopelagic realm. Gene abundance, diversity, and expression increased with increasing depth, similar to fungal CAZymes. This contrasts with the total occurrence of prokaryotic peptidases and CAZymes which are more uniformly distributed in the oceanic water column, suggesting potentially different ecological niches of fungi and prokaryotes. In-depth analysis of the most widely expressed fungal protease revealed the potentially dominating role of saprotrophic nutrition in the oceans.ConclusionsOur findings expand the current knowledge on the role of oceanic fungi in the carbon cycle (carbohydrates) to the so far unknown global participation in nitrogen (proteins) degradation, highlighting potentially different ecological niches occupied by fungi and prokaryotes in the global ocean.

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