Qi Qi, Haowei Yue, Zhang Zhenhua, Van Nostrand Joy D, Wu Linwei, Guo Xue, Feng Jiajie, Wang Mengmeng, Yang Sihang, Zhao Jianshu, Gao Qun, Zhang Qiuting, Zhao Mengxin, Xie Changyi, Ma Zhiyuan, He Jin-Sheng, Chu Haiyan, Huang Yi, Zhou Jizhong, Yang Yunfeng
State Key Joint Laboratory of Environment Simulation and Pollution Control, School of Environment, Tsinghua University, Beijing, China.
Ecological Environment Bureau, Shenzhen, China.
mBio. 2021 Feb 23;12(1):e00761-20. doi: 10.1128/mBio.00761-20.
Soil microorganisms are sensitive to temperature in cold ecosystems, but it remains unclear how microbial responses are modulated by other important climate drivers, such as precipitation changes. Here, we examine the effects of six warming and/or precipitation treatments in alpine grasslands on microbial communities, plants, and soil carbon fluxes. These treatments differentially affected soil carbon fluxes, gross primary production, and microbial communities. Variations of soil CO and CH fluxes across all sites significantly (>0.70, < 0.050) correlated with relevant microbial functional abundances but not bacterial or fungal abundances. Given tight linkages between microbial functional traits and ecosystem functionality, we conclude that future soil carbon fluxes in alpine grasslands can be predicted by microbial carbon-degrading capacities. The warming pace in the Tibetan Plateau, which is predominantly occupied by grassland ecosystems, has been 0.2°C per decade in recent years, dwarfing the rate of global warming by a factor of 2. Many Earth system models project substantial carbon sequestration in Tibet, which has been observed. Here, we analyzed microbial communities under projected climate changes by 2100. As the soil "carbon pump," the growth and activity of microorganisms can largely influence soil carbon dynamics. However, microbial gene response to future climate scenarios is still obscure. We showed that the abundances of microbial functional genes, but not microbial taxonomy, were correlated with carbon fluxes and ecosystem multifunctionality. By identifying microbial traits linking to ecosystem functioning, our results can guide the assessment of future soil carbon fluxes in alpine grasslands, a critical step toward mitigating climate changes.
在寒冷生态系统中,土壤微生物对温度敏感,但目前尚不清楚微生物的反应是如何受到其他重要气候驱动因素(如降水变化)调节的。在此,我们研究了高寒草原六种增温及/或降水处理对微生物群落、植物和土壤碳通量的影响。这些处理对土壤碳通量、总初级生产力和微生物群落产生了不同的影响。所有样地土壤CO和CH通量的变化与相关微生物功能丰度显著相关(>0.70,<0.050),但与细菌或真菌丰度无关。鉴于微生物功能性状与生态系统功能之间的紧密联系,我们得出结论,高寒草原未来的土壤碳通量可通过微生物碳降解能力来预测。近年来,以草原生态系统为主的青藏高原的升温速度为每十年0.2°C,使全球变暖速度降低了一半。许多地球系统模型预测,西藏地区会出现大量碳固存,这一点已得到观测证实。在此,我们分析了到2100年预计气候变化下的微生物群落。作为土壤的“碳泵”,微生物的生长和活动在很大程度上会影响土壤碳动态。然而,微生物基因对未来气候情景的反应仍不清楚。我们发现,微生物功能基因的丰度而非微生物分类与碳通量和生态系统多功能性相关。通过识别与生态系统功能相关的微生物性状,我们的研究结果可指导对高寒草原未来土壤碳通量的评估,这是缓解气候变化的关键一步。
