Heterogeneous viral contribution to dissolved organic matter processing in a long-term macrocosm experiment

Xiaowei Chen; Wei Wei; Xilin Xiao; Douglas Wallace; Chen Hu; Lianbao Zhang; John Batt; Jihua Liu; Michael Gonsior; Yao Zhang; Julie LaRoche; Paul Hill; Dapeng Xu; Jianning Wang; Nianzhi Jiao; Rui Zhang

doi:10.1016/j.envint.2021.106950

Heterogeneous viral contribution to dissolved organic matter processing in a long-term macrocosm experiment

Xiaowei Chen, Wei Wei, Xilin Xiao, Douglas Wallace, Chen Hu, Lianbao Zhang, John Batt, Jihua Liu, Michael Gonsior, Yao Zhang, Julie LaRoche, Paul Hill, Dapeng Xu, Jianning Wang, Nianzhi Jiao, Rui Zhang

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17 Citations (Scopus)

Abstract

Viruses saturate environments throughout the world and play key roles in microbial food webs, yet how viral activities affect dissolved organic matter (DOM) processing in natural environments remains elusive. We established a large-scale long-term macrocosm experiment to explore viral dynamics and their potential impacts on microbial mortality and DOM quantity and quality in starved and stratified ecosystems. High viral infection dynamics and the virus-induced cell lysis (6.23–64.68% d⁻¹) was found in the starved seawater macrocosm, which contributed to a significant transformation of microbial biomass into DOM (0.72–5.32 μg L⁻¹ d⁻¹). In the stratified macrocosm, a substantial amount of viral lysate DOM (2.43–17.87 μg L⁻¹ d⁻¹) was released into the upper riverine water, and viral lysis and DOM release (0.35–5.75 μg L⁻¹ d⁻¹) were reduced in the mixed water layer between riverine water and seawater. Viral lysis was stimulated at the bottom of stratified macrocosm, potentially fueled by the sinking of particulate organic carbon. Significant positive and negative associations between lytic viral production and different fluorescent DOM components were found in the starved and stratified macrocosm, indicating the potentially complex viral impacts on the production and utilization of DOM. Results also revealed the significant viral contribution to pools of both relatively higher molecular weight labile DOM and lower molecular weight recalcitrant DOM. Our study suggests that viruses have heterogeneous impact on the cycling and fate of DOM in aquatic environments.

Original language	English
Article number	106950
Journal	Environment international
Volume	158
DOIs	https://doi.org/10.1016/j.envint.2021.106950
Publication status	Published - Jan 2022

Bibliographical note

Funding Information:
This work was funded by the National Natural Science Foundation of China (91951209 and 41861144018) and the National Key Research and Development Program of China (2020YFA06083000). Xiaowei Chen was supported by the Ph.D. Fellowship of the State Key Laboratory of Marine Environmental Science at Xiamen University. The authors wish to thank Prof. Hugh Macintyre, Dr. Qiang Shi, Steve Fowler, Claire Normandeau, Jia Sun, Jiezhen Xie and Ran Li for their assistance in the experiment.

Funding Information:
This work was funded by the National Natural Science Foundation of China (91951209 and 41861144018) and the National Key Research and Development Program of China (2020YFA06083000). Xiaowei Chen was supported by the Ph.D. Fellowship of the State Key Laboratory of Marine Environmental Science at Xiamen University. The authors wish to thank Prof. Hugh Macintyre, Dr. Qiang Shi, Steve Fowler, Claire Normandeau, Jia Sun, Jiezhen Xie and Ran Li for their assistance in the experiment. N.J. and R.Z. designed and coordinated the study. X.C. X.X. C.H. and L.Z. performed the experiments. X.C. W.W. and R.Z. analyzed the data and wrote the manuscript with contributions from all co-authors. All authors contributed to the data set, discussed the results and suggested the improvements on the manuscript.

Publisher Copyright:
© 2021

ASJC Scopus Subject Areas

General Environmental Science

PubMed: MeSH publication types

Journal Article
Research Support, Non-U.S. Gov't

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10.1016/j.envint.2021.106950

Cite this

Chen, X., Wei, W., Xiao, X., Wallace, D., Hu, C., Zhang, L., Batt, J., Liu, J., Gonsior, M., Zhang, Y., LaRoche, J., Hill, P., Xu, D., Wang, J., Jiao, N., & Zhang, R. (2022). Heterogeneous viral contribution to dissolved organic matter processing in a long-term macrocosm experiment. Environment international, 158, Article 106950. https://doi.org/10.1016/j.envint.2021.106950

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title = "Heterogeneous viral contribution to dissolved organic matter processing in a long-term macrocosm experiment",

abstract = "Viruses saturate environments throughout the world and play key roles in microbial food webs, yet how viral activities affect dissolved organic matter (DOM) processing in natural environments remains elusive. We established a large-scale long-term macrocosm experiment to explore viral dynamics and their potential impacts on microbial mortality and DOM quantity and quality in starved and stratified ecosystems. High viral infection dynamics and the virus-induced cell lysis (6.23–64.68% d−1) was found in the starved seawater macrocosm, which contributed to a significant transformation of microbial biomass into DOM (0.72–5.32 μg L−1 d−1). In the stratified macrocosm, a substantial amount of viral lysate DOM (2.43–17.87 μg L−1 d−1) was released into the upper riverine water, and viral lysis and DOM release (0.35–5.75 μg L−1 d−1) were reduced in the mixed water layer between riverine water and seawater. Viral lysis was stimulated at the bottom of stratified macrocosm, potentially fueled by the sinking of particulate organic carbon. Significant positive and negative associations between lytic viral production and different fluorescent DOM components were found in the starved and stratified macrocosm, indicating the potentially complex viral impacts on the production and utilization of DOM. Results also revealed the significant viral contribution to pools of both relatively higher molecular weight labile DOM and lower molecular weight recalcitrant DOM. Our study suggests that viruses have heterogeneous impact on the cycling and fate of DOM in aquatic environments.",

author = "Xiaowei Chen and Wei Wei and Xilin Xiao and Douglas Wallace and Chen Hu and Lianbao Zhang and John Batt and Jihua Liu and Michael Gonsior and Yao Zhang and Julie LaRoche and Paul Hill and Dapeng Xu and Jianning Wang and Nianzhi Jiao and Rui Zhang",

note = "Funding Information: This work was funded by the National Natural Science Foundation of China (91951209 and 41861144018) and the National Key Research and Development Program of China (2020YFA06083000). Xiaowei Chen was supported by the Ph.D. Fellowship of the State Key Laboratory of Marine Environmental Science at Xiamen University. The authors wish to thank Prof. Hugh Macintyre, Dr. Qiang Shi, Steve Fowler, Claire Normandeau, Jia Sun, Jiezhen Xie and Ran Li for their assistance in the experiment. Funding Information: This work was funded by the National Natural Science Foundation of China (91951209 and 41861144018) and the National Key Research and Development Program of China (2020YFA06083000). Xiaowei Chen was supported by the Ph.D. Fellowship of the State Key Laboratory of Marine Environmental Science at Xiamen University. The authors wish to thank Prof. Hugh Macintyre, Dr. Qiang Shi, Steve Fowler, Claire Normandeau, Jia Sun, Jiezhen Xie and Ran Li for their assistance in the experiment. N.J. and R.Z. designed and coordinated the study. X.C. X.X. C.H. and L.Z. performed the experiments. X.C. W.W. and R.Z. analyzed the data and wrote the manuscript with contributions from all co-authors. All authors contributed to the data set, discussed the results and suggested the improvements on the manuscript. Publisher Copyright: {\textcopyright} 2021",

year = "2022",

month = jan,

doi = "10.1016/j.envint.2021.106950",

language = "English",

volume = "158",

journal = "Environment international",

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AU - Chen, Xiaowei

AU - Wei, Wei

AU - Xiao, Xilin

AU - Wallace, Douglas

AU - Hu, Chen

AU - Zhang, Lianbao

AU - Batt, John

AU - Liu, Jihua

AU - Gonsior, Michael

AU - Zhang, Yao

AU - LaRoche, Julie

AU - Hill, Paul

AU - Xu, Dapeng

AU - Wang, Jianning

AU - Jiao, Nianzhi

AU - Zhang, Rui

N1 - Funding Information: This work was funded by the National Natural Science Foundation of China (91951209 and 41861144018) and the National Key Research and Development Program of China (2020YFA06083000). Xiaowei Chen was supported by the Ph.D. Fellowship of the State Key Laboratory of Marine Environmental Science at Xiamen University. The authors wish to thank Prof. Hugh Macintyre, Dr. Qiang Shi, Steve Fowler, Claire Normandeau, Jia Sun, Jiezhen Xie and Ran Li for their assistance in the experiment. Funding Information: This work was funded by the National Natural Science Foundation of China (91951209 and 41861144018) and the National Key Research and Development Program of China (2020YFA06083000). Xiaowei Chen was supported by the Ph.D. Fellowship of the State Key Laboratory of Marine Environmental Science at Xiamen University. The authors wish to thank Prof. Hugh Macintyre, Dr. Qiang Shi, Steve Fowler, Claire Normandeau, Jia Sun, Jiezhen Xie and Ran Li for their assistance in the experiment. N.J. and R.Z. designed and coordinated the study. X.C. X.X. C.H. and L.Z. performed the experiments. X.C. W.W. and R.Z. analyzed the data and wrote the manuscript with contributions from all co-authors. All authors contributed to the data set, discussed the results and suggested the improvements on the manuscript. Publisher Copyright: © 2021

PY - 2022/1

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N2 - Viruses saturate environments throughout the world and play key roles in microbial food webs, yet how viral activities affect dissolved organic matter (DOM) processing in natural environments remains elusive. We established a large-scale long-term macrocosm experiment to explore viral dynamics and their potential impacts on microbial mortality and DOM quantity and quality in starved and stratified ecosystems. High viral infection dynamics and the virus-induced cell lysis (6.23–64.68% d−1) was found in the starved seawater macrocosm, which contributed to a significant transformation of microbial biomass into DOM (0.72–5.32 μg L−1 d−1). In the stratified macrocosm, a substantial amount of viral lysate DOM (2.43–17.87 μg L−1 d−1) was released into the upper riverine water, and viral lysis and DOM release (0.35–5.75 μg L−1 d−1) were reduced in the mixed water layer between riverine water and seawater. Viral lysis was stimulated at the bottom of stratified macrocosm, potentially fueled by the sinking of particulate organic carbon. Significant positive and negative associations between lytic viral production and different fluorescent DOM components were found in the starved and stratified macrocosm, indicating the potentially complex viral impacts on the production and utilization of DOM. Results also revealed the significant viral contribution to pools of both relatively higher molecular weight labile DOM and lower molecular weight recalcitrant DOM. Our study suggests that viruses have heterogeneous impact on the cycling and fate of DOM in aquatic environments.

AB - Viruses saturate environments throughout the world and play key roles in microbial food webs, yet how viral activities affect dissolved organic matter (DOM) processing in natural environments remains elusive. We established a large-scale long-term macrocosm experiment to explore viral dynamics and their potential impacts on microbial mortality and DOM quantity and quality in starved and stratified ecosystems. High viral infection dynamics and the virus-induced cell lysis (6.23–64.68% d−1) was found in the starved seawater macrocosm, which contributed to a significant transformation of microbial biomass into DOM (0.72–5.32 μg L−1 d−1). In the stratified macrocosm, a substantial amount of viral lysate DOM (2.43–17.87 μg L−1 d−1) was released into the upper riverine water, and viral lysis and DOM release (0.35–5.75 μg L−1 d−1) were reduced in the mixed water layer between riverine water and seawater. Viral lysis was stimulated at the bottom of stratified macrocosm, potentially fueled by the sinking of particulate organic carbon. Significant positive and negative associations between lytic viral production and different fluorescent DOM components were found in the starved and stratified macrocosm, indicating the potentially complex viral impacts on the production and utilization of DOM. Results also revealed the significant viral contribution to pools of both relatively higher molecular weight labile DOM and lower molecular weight recalcitrant DOM. Our study suggests that viruses have heterogeneous impact on the cycling and fate of DOM in aquatic environments.

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Heterogeneous viral contribution to dissolved organic matter processing in a long-term macrocosm experiment

Abstract

Bibliographical note

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PubMed: MeSH publication types

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