Predation by a ciliate community mediates temperature and nutrient effects on a peatland prey prokaryotic community

Katrina DeWitt; Alyssa A. Carrell; Jennifer D. Rocca; Samantha Votzke; Andrea Yammine; Ariane L. Peralta; David J. Weston; Dale A. Pelletier; Jean P. Gibert

doi:10.1128/msphere.00309-25

Predation by a ciliate community mediates temperature and nutrient effects on a peatland prey prokaryotic community

Katrina DeWitt
, Alyssa A. Carrell
, Jennifer D. Rocca
, Samantha Votzke
, Andrea Yammine
, Ariane L. Peralta
, David J. Weston
, Dale A. Pelletier
, Jean P. Gibert

Research output: Contribution to journal › Article › peer-review

Abstract

Temperature significantly impacts microbial communities’ composition and function, which plays a vital role in the global carbon cycle that determines climate change. Nutrient influxes often accompany rising temperatures due to human activity. While ecological interactions between different microorganisms could shape their response to environmental change, we do not understand how predation may influence these responses in a warmer and increasingly nutrient-rich world. Here, we assess whether predation by a ciliate community of bacterial consumers influences changes in the diversity, biomass, and function of a freshwater prokaryotic community under different temperature and nutrient conditions. We found that predator presence mediates the effects of temperature and nutrients on the total prokaryotic community biomass and composition through various mechanisms, including direct and indirect effects. However, the total community function was resilient. Our study supports previous findings that temperature and nutrients are essential drivers of microbial community composition and function but also demonstrates how predation can mediate these effects, indicating that the biotic context is as important as the abiotic context to understanding microbial responses to novel climates.

Original language	English
Journal	mSphere
Volume	10
Issue number	7
DOIs	https://doi.org/10.1128/msphere.00309-25
State	Published - Jul 2025

Funding

This work was supported by the U.S. Department of Energy, Office of Science, Office of Biological and Environmental Research, Genomic Science Program grant award number DE-SC0020362, NSF DEB award number 2224819, and Simons Foundation Early Career Fellowship in Aquatic Microbial Ecology and Evolution number LS-ECIAMEE-00001588 to J.P.G. Additional support for prokaryotic and ciliate collection from SPRUCE was provided by the U.S. Department of Energy (DOE), grant/award number DE-AC05-00OR22725 to D.J.W. Simons Foundation LS-ECIAMEE-00001588 Jean P. Gibert Division of Environmental Biology NSF DEB 2224819 Jean P. Gibert U.S. Department of Energy DE-SC0020362 Jean P. Gibert U.S. Department of Energy DE-AC05-00OR22725 David J. Weston This work was supported by the U.S. Department of Energy, of Science, of Biological and Environmental Research, Genomic Science Program grant award number DE-SC0020362, NSF DEB award number 2224819, and Simons Foundation Early Career Fellowship in Aquatic Microbial Ecology and Evolution number LS-ECIAMEE-00001588 to J.P.G. Additional support for prokaryotic and ciliate collection from SPRUCE was provided by the U.S. Department of Energy (DOE), grant/award number DE-AC05-00OR22725 to D.J.W.

Keywords

ciliates
climate change
microbial food webs
protoctists
synthetic communities

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10.1128/msphere.00309-25

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title = "Predation by a ciliate community mediates temperature and nutrient effects on a peatland prey prokaryotic community",

abstract = "Temperature significantly impacts microbial communities{\textquoteright} composition and function, which plays a vital role in the global carbon cycle that determines climate change. Nutrient influxes often accompany rising temperatures due to human activity. While ecological interactions between different microorganisms could shape their response to environmental change, we do not understand how predation may influence these responses in a warmer and increasingly nutrient-rich world. Here, we assess whether predation by a ciliate community of bacterial consumers influences changes in the diversity, biomass, and function of a freshwater prokaryotic community under different temperature and nutrient conditions. We found that predator presence mediates the effects of temperature and nutrients on the total prokaryotic community biomass and composition through various mechanisms, including direct and indirect effects. However, the total community function was resilient. Our study supports previous findings that temperature and nutrients are essential drivers of microbial community composition and function but also demonstrates how predation can mediate these effects, indicating that the biotic context is as important as the abiotic context to understanding microbial responses to novel climates.",

keywords = "ciliates, climate change, microbial food webs, protoctists, synthetic communities",

author = "Katrina DeWitt and Carrell, \{Alyssa A.\} and Rocca, \{Jennifer D.\} and Samantha Votzke and Andrea Yammine and Peralta, \{Ariane L.\} and Weston, \{David J.\} and Pelletier, \{Dale A.\} and Gibert, \{Jean P.\}",

note = "Publisher Copyright: Copyright {\textcopyright} 2025 DeWitt et al.",

year = "2025",

month = jul,

doi = "10.1128/msphere.00309-25",

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AU - DeWitt, Katrina

AU - Carrell, Alyssa A.

AU - Rocca, Jennifer D.

AU - Votzke, Samantha

AU - Yammine, Andrea

AU - Peralta, Ariane L.

AU - Weston, David J.

AU - Pelletier, Dale A.

AU - Gibert, Jean P.

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N2 - Temperature significantly impacts microbial communities’ composition and function, which plays a vital role in the global carbon cycle that determines climate change. Nutrient influxes often accompany rising temperatures due to human activity. While ecological interactions between different microorganisms could shape their response to environmental change, we do not understand how predation may influence these responses in a warmer and increasingly nutrient-rich world. Here, we assess whether predation by a ciliate community of bacterial consumers influences changes in the diversity, biomass, and function of a freshwater prokaryotic community under different temperature and nutrient conditions. We found that predator presence mediates the effects of temperature and nutrients on the total prokaryotic community biomass and composition through various mechanisms, including direct and indirect effects. However, the total community function was resilient. Our study supports previous findings that temperature and nutrients are essential drivers of microbial community composition and function but also demonstrates how predation can mediate these effects, indicating that the biotic context is as important as the abiotic context to understanding microbial responses to novel climates.

AB - Temperature significantly impacts microbial communities’ composition and function, which plays a vital role in the global carbon cycle that determines climate change. Nutrient influxes often accompany rising temperatures due to human activity. While ecological interactions between different microorganisms could shape their response to environmental change, we do not understand how predation may influence these responses in a warmer and increasingly nutrient-rich world. Here, we assess whether predation by a ciliate community of bacterial consumers influences changes in the diversity, biomass, and function of a freshwater prokaryotic community under different temperature and nutrient conditions. We found that predator presence mediates the effects of temperature and nutrients on the total prokaryotic community biomass and composition through various mechanisms, including direct and indirect effects. However, the total community function was resilient. Our study supports previous findings that temperature and nutrients are essential drivers of microbial community composition and function but also demonstrates how predation can mediate these effects, indicating that the biotic context is as important as the abiotic context to understanding microbial responses to novel climates.

KW - ciliates

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KW - microbial food webs

KW - protoctists

KW - synthetic communities

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Predation by a ciliate community mediates temperature and nutrient effects on a peatland prey prokaryotic community

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