社区背景改变了热性能的演变

IF 4.3 3区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC
Joseph Westley, Francisca C García, R. Warfield, G. Yvon‐Durocher
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引用次数: 0

摘要

微生物是全球生物地球化学循环的主要驱动力,其功能作用取决于温度。庞大的种群规模和快速的更替率意味着微生物对环境变暖的主要反应很可能是进化反应,然而我们对微生物系统对温度变化的进化反应的了解还很有限。自然微生物群落是由相互作用的类群组成的多样化集合体。然而,大多数调查细菌对温度变化的进化反应的研究都集中在单一培养物上。在这里,我们利用高通量实验方法,沿着热梯度对单一培养和群落背景下的细菌进行进化,以确定种间相互作用如何影响群落成员的热适应性。我们发现,在整个温度梯度范围内,群落进化的分离菌与单培养进化的分离菌相比,往往具有更高的最大生长率。我们还发现,沿温度梯度细菌耐热性曲线的形状几乎没有系统进化变化的迹象。然而,群落背景和选择温度对耐热性曲线进化的影响是多变的,而且具有高度的分类群特异性,一些分类群表现出明显的耐热性变化,而另一些分类群受到的影响较小。我们还发现,温度起到了很强的环境过滤作用,导致沿热梯度的分类群局部灭绝,这意味着温度驱动的生态变化是形成群落背景的一个关键因素,而进化选择可以在群落背景上发挥作用。这些发现为了解群落背景如何影响热适应提供了新的视角。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
The community background alters the evolution of thermal performance
Microbes are key drivers of global biogeochemical cycles, and their functional roles arey dependent on temperature. Large population sizes and rapid turnover rates mean that the predominant response of microbes to environmental warming is likely to be evolutionary, yet our understanding of evolutionary responses to temperature change in microbial systems is rudimentary. Natural microbial communities are diverse assemblages of interacting taxa. However, most studies investigating the evolutionary response of bacteria to temperature change are focused on monocultures. Here, we utilize high-throughput experimental evolution of bacteria in both monoculture and community contexts along a thermal gradient to determine how interspecific interactions influence the thermal adaptation of community members. We found that community-evolved isolates tended toward higher maximum growth rates across the temperature gradient compared to their monoculture-evolved counterparts. We also saw little evidence of systematic evolutionary change in the shapes of bacterial thermal tolerance curves along the thermal gradient. However, the effect of community background and selection temperature on the evolution of thermal tolerance curves was variable and highly taxon-specific,with some taxa exhibiting pronounced changes in thermal tolerance while others were less impacted. We also found that temperature acted as a strong environmental filter, resulting in the local extinction of taxa along the thermal gradient, implying that temperature-driven ecological change was a key factor shaping the community background upon which evolutionary selection can operate. These findings offer novel insight into how community background impacts thermal adaptation.
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来源期刊
CiteScore
7.20
自引率
4.30%
发文量
567
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