Temperature and interspecific interactions drive differences in carbon use efficiencies and biomass stoichiometry among aquatic fungi

Abstract Saprotrophic fungi play important roles in transformations of carbon (C), nitrogen (N), and phosphorus (P) in aquatic environments. However, it is unclear how warming will alter fungal cycling of C, N, and P. We conducted an experiment with four aquatic hyphomycetes (Articulospora tetraclad...

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Bibliographic Details
Published in:FEMS microbiology ecology 2023-02, Vol.99 (3)
Main Authors: Tomczyk, Nathan J, Rosemond, Amy D, Whiteis, Ally M, Benstead, Jonathan P, Gulis, Vladislav
Format: Article
Language:English
Subjects:
Aquatic environment
Aquatic fungi
Aquatic hyphomycetes
Biomass
Carbon
Carbon 13
Cycles
Ecosystem
Fractionation
Fungi
Fungi - genetics
Interspecific relationships
Isotope fractionation
Monoculture
Nitrogen
Nutrient cycles
Plant Leaves - microbiology
Stoichiometry
Taxa
Temperature
Temperature gradients
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Summary:Abstract Saprotrophic fungi play important roles in transformations of carbon (C), nitrogen (N), and phosphorus (P) in aquatic environments. However, it is unclear how warming will alter fungal cycling of C, N, and P. We conducted an experiment with four aquatic hyphomycetes (Articulospora tetracladia, Hydrocina chaetocladia, Flagellospora sp., and Aquanectria penicillioides), and an assemblage of the same taxa, to test how temperature alters C and nutrient use. Specifically, we evaluated biomass accrual, C:N, C:P, δ13C, and C use efficiency (CUE) over a 35-d experiment with temperatures ranging from 4ºC to 20ºC. Changes in biomass accrual and CUE were predominantly quadratic with peaks between 7ºC and 15ºC. The C:P of H. chaetocladia biomass increased 9× over the temperature gradient, though the C:P of other taxa was unaffected by temperature. Changes in C:N were relatively small across temperatures. Biomass δ13C of some taxa changed across temperatures, indicating differences in C isotope fractionation. Additionally, the 4-species assemblage differed from null expectations based on the monocultures in terms of biomass accrual, C:P, δ13C, and CUE, suggesting that interactions among taxa altered C and nutrient use. These results highlight that temperature and interspecific interactions among fungi can alter traits affecting C and nutrient cycling. Temperature and interactions among different taxa drive differences in carbon and nutrient use of aquatic fungi.
ISSN:1574-6941
0168-6496
1574-6941
DOI:10.1093/femsec/fiad021