Evaluating thermal performance of closely related taxa: Support for hotter is not better, but for unexpected reasons

IF 7.1 1区 环境科学与生态学 Q1 ECOLOGY Ecological Monographs Pub Date : 2022-03-21 DOI:10.1002/ecm.1517
David J. S. Montagnes, Qing Wang, Zhao Lyu, Chen Shao
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引用次数: 5

Abstract

Temperature drives performance and therefore adaptation; to interpret and understand these, thermal performance curves (TPC) are used, often through meta-analyses, revealing trends across divergent taxa. Four discrete hypotheses—thermodynamic-constraint; biochemical-adaptation (hotter is not better); specialist-generalist; thermal-trade-off—have arisen to explain cross-phyletic trends. In contrast, detailed comparisons of closely related taxa are rare, yet trends arising from these should reveal mechanisms of adaptation, as taxa diverge. Here, we combine experimental work with TPC theory to assess if the current hypotheses apply equally to closely related taxa. We established TPC for six species (and two strains of one species) of the animal model Tetrahymena (Ciliophora)—characterized by SSU rDNA/COX1 sequences—by examining specific growth rate (r), size (V), production (P = rV), and metabolic rate (rV−0.25) across 15–20 temperatures. Using parameters derived from the mechanistic “Sharpe and DeMichele” function, we established a framework to test which hypothesis best represented the data. We conclude that superficially the “hotter is not better” hypothesis is best but argue that the mechanistic theory underlying it cannot apply at the genus level: trends are likely to arise from little rather than substantial adaptation. Our further analysis suggests: (1) upward shift in the maximum-functioning temperature (Tmax) is more constrained than the optimal temperature (Topt), leading to a decreased safety margin (ToptTmax) and suggesting that species initially succeed in warmer environments through an increase in Topt, followed by increasing Tmax; and (2) thermal performance traits are correlated with phylogeny for closely related species, suggesting that species gradually adapt to new thermal environments.

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近缘类群热性能评价:对热的支持不是更好,而是由于意想不到的原因
温度驱动性能,因此适应;为了解释和理解这些,通常通过荟萃分析使用热性能曲线(TPC)来揭示不同分类群的趋势。四个离散假设-热力学约束;生化适应(越热并不越好);specialist-generalist;为了解释跨种进化趋势,出现了热权衡。相比之下,密切相关的分类群的详细比较很少,但由此产生的趋势应该揭示适应机制,随着分类群的分化。在这里,我们将实验工作与TPC理论结合起来,评估当前的假设是否同样适用于密切相关的分类群。我们通过检测特定生长速率(r)、大小(V)、产量(P = rV)和代谢率(rV - 0.25),在15-20个温度下建立了以SSU rDNA/COX1序列为特征的动物模型四膜虫(Ciliophora)的6种(和一种的2株)的TPC。使用从机制的“Sharpe和DeMichele”函数派生的参数,我们建立了一个框架来检验哪个假设最能代表数据。我们的结论是,从表面上看,“越热不是越好”的假设是最好的,但我们认为,其背后的机械理论不能适用于属的水平:趋势可能是由很少的适应而不是大量的适应产生的。进一步分析表明:(1)最大功能温度(Tmax)的上移比最优温度(Topt)更受约束,导致安全裕度(Topt - Tmax)减小,表明物种最初通过增加Topt,然后增加Tmax在温暖环境中成功生存;(2)亲缘物种的热性能特征与系统发育相关,表明物种逐渐适应新的热环境。
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来源期刊
Ecological Monographs
Ecological Monographs 环境科学-生态学
CiteScore
12.20
自引率
0.00%
发文量
61
审稿时长
3 months
期刊介绍: The vision for Ecological Monographs is that it should be the place for publishing integrative, synthetic papers that elaborate new directions for the field of ecology. Original Research Papers published in Ecological Monographs will continue to document complex observational, experimental, or theoretical studies that by their very integrated nature defy dissolution into shorter publications focused on a single topic or message. Reviews will be comprehensive and synthetic papers that establish new benchmarks in the field, define directions for future research, contribute to fundamental understanding of ecological principles, and derive principles for ecological management in its broadest sense (including, but not limited to: conservation, mitigation, restoration, and pro-active protection of the environment). Reviews should reflect the full development of a topic and encompass relevant natural history, observational and experimental data, analyses, models, and theory. Reviews published in Ecological Monographs should further blur the boundaries between “basic” and “applied” ecology. Concepts and Synthesis papers will conceptually advance the field of ecology. These papers are expected to go well beyond works being reviewed and include discussion of new directions, new syntheses, and resolutions of old questions. In this world of rapid scientific advancement and never-ending environmental change, there needs to be room for the thoughtful integration of scientific ideas, data, and concepts that feeds the mind and guides the development of the maturing science of ecology. Ecological Monographs provides that room, with an expansive view to a sustainable future.
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