Bacterial population-level trade-offs between drought tolerance and resource acquisition traits impact decomposition.

IF 10.8 1区 环境科学与生态学 Q1 ECOLOGY
Ashish A Malik, Jennifer B H Martiny, Antonio Ribeiro, Paul O Sheridan, Claudia Weihe, Eoin L Brodie, Steven D Allison
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Abstract

Microbes drive fundamental ecosystem processes such as decomposition. Environmental stressors are known to affect microbes, their fitness, and the ecosystem functions that they perform, yet understanding the causal mechanisms behind this influence has been difficult. We used leaf litter on soil surface as a model in situ system to assess changes in bacterial genomic traits and decomposition rates over 18 months with drought as a stressor. We hypothesized that genome-scale trade-offs due to investment in stress tolerance traits under drought reduce the capacity for bacterial populations to carry out decomposition, and that these population-level trade-offs scale up to impact emergent community traits thereby reducing decomposition rates. We observed drought tolerance mechanisms that were heightened in bacterial populations under drought, identified as higher gene copy numbers in metagenome-assembled genomes. A subset of populations under drought had reduced carbohydrate-active enzyme genes which suggested - as a trade-off - a decline in decomposition capabilities. These trade-offs were driven by community succession and taxonomic shifts as distinct patterns appeared in populations. We show that trait-tradeoffs in bacterial populations under drought could scale up to reduce overall decomposition capabilities and litter decay rates. Using a trait-based approach to assess the population ecology of soil bacteria, we demonstrate genome-level trade-offs in response to drought with consequences for decomposition rates.

细菌种群在耐旱性和资源获取性状之间的权衡对分解产生了影响。
微生物驱动着分解等基本生态系统过程。众所周知,环境胁迫因素会影响微生物、它们的适应性以及它们所发挥的生态系统功能,但要了解这种影响背后的因果机制却很困难。我们以土壤表面的落叶层为原位模型系统,评估了以干旱为压力源的 18 个月中细菌基因组性状和分解率的变化。我们假设,在干旱条件下,由于对抗逆性状的投资而导致的基因组范围内的权衡会降低细菌种群进行分解的能力,而这些种群层面的权衡会扩大到影响新出现的群落性状,从而降低分解率。我们观察到,在干旱条件下,细菌种群的耐旱机制增强了,这在元基因组组装的基因组中表现为更高的基因拷贝数。在干旱条件下,一部分种群的碳水化合物活性酶基因减少,这表明作为一种权衡,分解能力下降。这些权衡是由群落演替和分类转移驱动的,因为种群中出现了不同的模式。我们的研究表明,干旱条件下细菌种群的性状权衡可能会扩大到降低整体分解能力和垃圾腐烂率。利用基于性状的方法来评估土壤细菌的种群生态学,我们证明了基因组水平的权衡在应对干旱时对分解率的影响。
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来源期刊
ISME Journal
ISME Journal 环境科学-生态学
CiteScore
22.10
自引率
2.70%
发文量
171
审稿时长
2.6 months
期刊介绍: The ISME Journal covers the diverse and integrated areas of microbial ecology. We encourage contributions that represent major advances for the study of microbial ecosystems, communities, and interactions of microorganisms in the environment. Articles in The ISME Journal describe pioneering discoveries of wide appeal that enhance our understanding of functional and mechanistic relationships among microorganisms, their communities, and their habitats.
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