欧洲气候梯度中微生物对干旱的抵抗力和复原力

IF 9.8 1区 农林科学 Q1 SOIL SCIENCE
Sara Winterfeldt , Carla Cruz-Paredes , Johannes Rousk , Ainara Leizeaga
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引用次数: 0

摘要

随着气候变化,干旱和降雨事件将变得更加频繁和剧烈。同时,土壤湿度是控制土壤微生物过程(如碳循环)的主要因素之一。当遇到干旱时,微生物主要有两种生长反应:(1) 它们可以在干旱期间保持生长速度(即抵抗力);(2) 当干旱结束时,它们可以更快地恢复生长速度(即恢复力)。微生物群落受土壤环境中其他多种因素的影响,但这些因素如何影响干旱响应仍不清楚。在此,我们研究了气候(以干旱指数估算)和土壤特性如何在欧洲的气候梯度上决定微生物的生长抵抗力和对干旱的恢复力。为了验证这一点,我们在受控条件下将不同的土壤暴露于标准化的干旱周期。我们评估了土壤干燥期间的细菌生长、真菌生长和呼吸情况,以确定抗旱性,并对土壤复湿后三天内的抗旱性进行了高分辨率评估。我们发现,α多样性是细菌抗旱性和恢复力的最强驱动力,而这是通过土壤酸碱度的变化实现的。这表明了多样性在干旱胁迫期间维持细菌功能的重要性。干旱指数是细菌抗旱性和恢复力的次要驱动因素,也是一个重要的驱动因素,来自更干旱气候的细菌群落具有更高的抗旱性和恢复力。与细菌相比,真菌群落的抗旱性和恢复力都更强,但这与其他测量的环境因素无关。细菌的抗旱能力部分与群落组成的差异有关。我们的研究结果表明,如果研究地点因气候变化而变得更加干旱,或对其进行管理以促进细菌多样性,那么在干旱扰动期间,这些地点的细菌增长率会更高,从而有可能促进土壤碳储存。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Microbial resistance and resilience to drought across a European climate gradient

Drought and rainfall events will become more frequent and intense with climate change. At the same time, soil moisture is one of the major factors controlling soil microbial processes such as carbon cycling. When challenged with drought there are two main growth responses microorganisms can use: (1) they can maintain growth rates during drought (i.e., resistance) and (2) they can recover growth rates faster when the drought ends (i.e., resilience). Microbial communities are shaped by multiple other factors in the soil environment, however how those impact drought responses remain unclear. Here we investigate how climate (estimated as aridity index) and soil properties determine microbial growth resistance and resilience to drought across a climate gradient in Europe. To test this, we exposed the different soils to a standardised drought cycle in controlled conditions. We assessed bacterial growth, fungal growth and respiration during soil drying to determine resistance and in high resolution during three days after rewetting to estimate resilience to drought. We found that alpha diversity was the strongest driver of both bacterial drought resistance and resilience, which occurred via changes in soil pH. This shows the importance of diversity for sustaining bacterial functions during drought stress. A secondary driver of bacterial drought resistance and resilience was the aridity index was also an important driver, where bacterial communities from more arid climates had higher resistance and resilience to drought. Fungal communities were both more resistant and resilient compared to bacteria, but this was independent of other measured environmental factors. Bacterial resilience was partly linked with differences in community composition. Our results suggest that if sites are exposed to increased aridity due to climate change or are managed to promote bacterial diversity, they will have higher bacterial growth rates during drought perturbations, which could potentially promote soil carbon storage.

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来源期刊
Soil Biology & Biochemistry
Soil Biology & Biochemistry 农林科学-土壤科学
CiteScore
16.90
自引率
9.30%
发文量
312
审稿时长
49 days
期刊介绍: Soil Biology & Biochemistry publishes original research articles of international significance focusing on biological processes in soil and their applications to soil and environmental quality. Major topics include the ecology and biochemical processes of soil organisms, their effects on the environment, and interactions with plants. The journal also welcomes state-of-the-art reviews and discussions on contemporary research in soil biology and biochemistry.
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