Climate Warming Restructures Seasonal Dynamics of Grassland Soil Microbial Communities

Overview

Journal mLife

Date 2024 May 31

PMID 38818216

Authors

Xue Guo

Mengting Yuan

Jiesi Lei

Zhou Shi

Xishu Zhou

Jiabao Li

Ye Deng

Yunfeng Yang

Liyou Wu

Yiqi Luo

James M Tiedje

Jizhong Zhou

Affiliations

Soon will be listed here.

Abstract

Soil microbial community's responses to climate warming alter the global carbon cycle. In temperate ecosystems, soil microbial communities function along seasonal cycles. However, little is known about how the responses of soil microbial communities to warming vary when the season changes. In this study, we investigated the seasonal dynamics of soil bacterial community under experimental warming in a temperate tall-grass prairie ecosystem. Our results showed that warming significantly ( = 0.001) shifted community structure, such that the differences of microbial communities between warming and control plots increased nonlinearly ( = 0.578, = 0.021) from spring to winter. Also, warming significantly ( < 0.050) increased microbial network complexity and robustness, especially during the colder seasons, despite large variations in network size and complexity in different seasons. In addition, the relative importance of stochastic processes in shaping the microbial community decreased by warming in fall and winter but not in spring and summer. Our study indicates that climate warming restructures the seasonal dynamics of soil microbial community in a temperate ecosystem. Such seasonality of microbial responses to warming may enlarge over time and could have significant impacts on the terrestrial carbon cycle.

Citing Articles

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