The Coupling Response between Different Bacterial Metabolic Functions in Water and Sediment Improve the Ability to Mitigate Climate Change

The Coupling Response between Different Bacterial Metabolic Functions in Water and Sediment Improve the Ability to Mitigate Climate Change

Extreme climatic events, such as heat wave and large temperature fluctuations, are predicted to increase in frequency and intensity during the next hundred years, which may rapidly alter the composition and function of lake bacterial communities. Here, we conducted a year-long experiment to explore...

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Bibliographic Details
Main Authors: Cheng, H. (Author), Feng, M. (Author), Shi, P. (Author), Wang, H. (Author), Xu, J. (Author), Yan, Y. (Author), Yang, Q. (Author), Zhang, M. (Author)
Format: Article
Language:English
Published: MDPI 2022
Subjects:
Aquatic ecosystems
bacteria
Bacteria
bacterium
biogeochemical cycle
Biogeochemical cycle
biogeochemical cycles
Biogeochemistry
Carbon
climate change
Climate change
climate warming
Climate warming
Coupling response
FAPROTAX function prediction
Fresh Water
freshwater
freshwater environment
Function prediction
heat wave
lake water
Lakes
Lows-temperatures
Metabolic function
Metabolism
Nitrification
nitrogen cycle
Nitrogen fixation
RNA
seasonal variation
Sediments
sediment-water interface
Temperature distribution
Temperature fluctuation
Water columns
Online Access:View Fulltext in Publisher
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Summary:Extreme climatic events, such as heat wave and large temperature fluctuations, are predicted to increase in frequency and intensity during the next hundred years, which may rapidly alter the composition and function of lake bacterial communities. Here, we conducted a year-long experiment to explore the effect of warming on bacterial metabolic function of lake water and sediment. Predictions of the metabolic capabilities of these communities were performed with FAPROTAX using 16S rRNA sequencing data. The results indicated that the increase in temperature changed the structure of bacterial metabolic functional groups in water and sediment. During periods of low temperature, the carbon degradation pathway decreased, and the synthesis pathway increased, under the stimulation of warming, especially under the conditions temperature fluctuation. We also observed that nitrogen fixation ability was especially important in the warming treatments during the summer season. However, an elevated temperature significantly led to reduced nitrogen fixation abilities in winter. Compared with the water column, the most predominant functional groups of nitrogen cycle in sediment were nitrite oxidation and nitrification. Variable warming significantly promoted nitrite oxidation and nitrification function in winter, and constant warming was significantly inhibited in spring, with control in sediments. Co-occurrence network results showed that warming, especially variable warming, made microbial co-occurrence networks larger, more connected and less modular, and eventually functional groups in the water column and sediment cooperated to resist warming. We concluded that warming changed bacterial functional potentials important to the biogeochemical cycling in the experimental mesocosms in winter and spring with low temperature. The effect of different bacteria metabolism functions in water column and sediment may change the carbon and nitrogen fluxes in aquatic ecosystems. In conclusion, the coupling response between different bacterial metabolic functions in water and sediment may improve the ability to mitigate climate change. © 2022 by the authors. Licensee MDPI, Basel, Switzerland.
ISBN:20734441 (ISSN)
DOI:10.3390/w14081203

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