TY - JOUR
T1 - Fungal community response to long-term soil warming with potential implications for soil carbon dynamics
AU - Pec, Gregory J.
AU - van Diepen, Linda T.A.
AU - Knorr, Melissa
AU - Grandy, A. Stuart
AU - Melillo, Jerry M.
AU - DeAngelis, Kristen M.
AU - Blanchard, Jeffrey L.
AU - Frey, Serita D.
N1 - Funding Information:
Thanks to Brian Godbois and Chris Cook at the University of New Hampshire for soil sample collection. Sequencing was done at the Joint Genome Institute as part of a Community Sequencing Program (under contract no. DE-AC02-05CH11231 CSP-1058) award. Thanks to Toni Westbrook at UNH for assistance with bioinformatics. The soil warming plots at Harvard Forest are maintained through support from the NSF Long-term Ecological Research (DEB 1237491) and Long-term Research in Environmental Biology (DEB 1456528) Programs.
Funding Information:
Thanks to Brian Godbois and Chris Cook at the University of New Hampshire for soil sample collection. Sequencing was done at the Joint Genome Institute as part of a Community Sequencing Program (under contract no. DE‐AC02‐05CH11231 CSP‐1058) award. Thanks to Toni Westbrook at UNH for assistance with bioinformatics. The soil warming plots at Harvard Forest are maintained through support from the NSF Long‐term Ecological Research (DEB 1237491) and Long‐term Research in Environmental Biology (DEB 1456528) Programs.
Publisher Copyright:
© 2021 The Authors.
PY - 2021/5
Y1 - 2021/5
N2 - The direction and magnitude of climate warming effects on ecosystem processes such as carbon cycling remain uncertain. Soil fungi are central to these processes due to their roles as decomposers of soil organic matter, as mycorrhizal symbionts, and as determinants of plant diversity. Yet despite their importance to ecosystem functioning, we lack a clear understanding of the long-term response of soil fungal communities to warming. Toward this goal, we characterized soil fungal communities in two replicated soil warming experiments at the Harvard Forest (Petersham, Massachusetts, USA) which had experienced 5°C above ambient soil temperatures for 5 and 20 yr at the time of sampling. We assessed fungal diversity and community composition by sequencing the ITS2 region of rDNA using Illumina technology, along with soil C concentrations and chemistry. Three main findings emerged: (1) long-, but not short-term warming resulted in compositional shifts in the soil fungal community, particularly in the saprotrophic and unknown components of the community; (2) soil C concentrations and the total C stored in the organic horizon declined in response to both short- (5 yr) and long-term (20 yr) warming; and (3) following long-term warming, shifts in fungal guild relative abundances were associated with substantial changes in soil organic matter chemistry, particularly the relative abundance of lignin. Taken together, our results suggest that shifts with warming in the relative abundance of fungal functional groups and dominant fungal taxa are related to observed losses in total soil C.
AB - The direction and magnitude of climate warming effects on ecosystem processes such as carbon cycling remain uncertain. Soil fungi are central to these processes due to their roles as decomposers of soil organic matter, as mycorrhizal symbionts, and as determinants of plant diversity. Yet despite their importance to ecosystem functioning, we lack a clear understanding of the long-term response of soil fungal communities to warming. Toward this goal, we characterized soil fungal communities in two replicated soil warming experiments at the Harvard Forest (Petersham, Massachusetts, USA) which had experienced 5°C above ambient soil temperatures for 5 and 20 yr at the time of sampling. We assessed fungal diversity and community composition by sequencing the ITS2 region of rDNA using Illumina technology, along with soil C concentrations and chemistry. Three main findings emerged: (1) long-, but not short-term warming resulted in compositional shifts in the soil fungal community, particularly in the saprotrophic and unknown components of the community; (2) soil C concentrations and the total C stored in the organic horizon declined in response to both short- (5 yr) and long-term (20 yr) warming; and (3) following long-term warming, shifts in fungal guild relative abundances were associated with substantial changes in soil organic matter chemistry, particularly the relative abundance of lignin. Taken together, our results suggest that shifts with warming in the relative abundance of fungal functional groups and dominant fungal taxa are related to observed losses in total soil C.
KW - Illumina
KW - ectomycorrhizal fungi
KW - organic matter chemistry
KW - saprotrophic fungi
KW - soil carbon
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U2 - 10.1002/ecs2.3460
DO - 10.1002/ecs2.3460
M3 - Article
AN - SCOPUS:85106936259
SN - 2150-8925
VL - 12
JO - Ecosphere
JF - Ecosphere
IS - 5
M1 - e03460
ER -