An energetic approach to the evolution of growth curve plasticity

IF 1.2 4区 环境科学与生态学 Q4 ECOLOGY Theoretical Ecology Pub Date : 2023-11-29 DOI:10.1007/s12080-023-00571-3
Jasper C. Croll, Tobias van Kooten, André M. de Roos
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Abstract

Growth in individual body size amongst different species can to a greater or lesser extent depend on environmental factors such as resource availability. Individual growth curves can therefore be largely fixed or more plastic. Classic theory about phenotypic plasticity assumes that such plasticity has associated costs. In contrast, according to dynamic energy budget theory, maintaining a fixed growth rate in the face of variable resource availability would incur additional energetic costs. In this article, we explore the simultaneous evolution of the degree of plasticity in individual growth curves and the rate of non-plastic, environment-independent individual growth. We explore different relations between possible additional energetic costs and the degree of growth curve plasticity. To do so, we use adaptive dynamics to analyze a size-structured population model that is based on dynamic energy budget theory to account for the energetic trade-offs within an individual. We show that simultaneous evolution of the degree of growth curve plasticity and the rate of non-plastic individual growth will drive these traits to intermediate values at first. Afterwards, the degree of growth curve plasticity might evolve slowly towards extreme values depending on whether energetic costs increase or decrease with the degree of plasticity. In addition, the analysis shows that it is unlikely to encounter species in which individual growth is entirely fixed or entirely plastic, opposing general assumptions in dynamic energy budget theory.

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生长曲线塑性演化的能量方法
不同物种个体体型的增长或多或少取决于资源供应等环境因素。因此,个体生长曲线在很大程度上可以是固定的,或者更具可塑性。关于表型可塑性的经典理论认为,这种可塑性有相关的成本。相比之下,根据动态能量预算理论,在资源可用性变化的情况下,保持固定的增长率会产生额外的能量成本。在本文中,我们探讨了个体生长曲线的可塑性程度与非塑性、不依赖环境的个体生长速率的同步演变。我们探讨了可能的额外能量成本与生长曲线可塑性程度之间的不同关系。为此,我们使用自适应动力学来分析基于动态能量预算理论的规模结构种群模型,以解释个体内部的能量权衡。研究表明,生长曲线的可塑性程度和非塑性个体生长速率的同步演化将首先使这些性状趋于中间值。之后,生长曲线的塑性程度可能会随着能量成本随塑性程度的增加或减少而缓慢地向极值演化。此外,分析表明,不太可能遇到个体生长完全固定或完全可塑的物种,这与动态能量收支理论的一般假设相反。
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来源期刊
Theoretical Ecology
Theoretical Ecology 环境科学-生态学
CiteScore
3.30
自引率
6.20%
发文量
23
审稿时长
>12 weeks
期刊介绍: Theoretical Ecology publishes innovative research in theoretical ecology, broadly defined. Papers should use theoretical approaches to answer questions of ecological interest and appeal to and be readable by a broad audience of ecologists. Work that uses mathematical, statistical, computational, or conceptual approaches is all welcomed, provided that the goal is to increase ecological understanding. Papers that only use existing approaches to analyze data, or are only mathematical analyses that do not further ecological understanding, are not appropriate. Work that bridges disciplinary boundaries, such as the intersection between quantitative social sciences and ecology, or physical influences on ecological processes, will also be particularly welcome. All areas of theoretical ecology, including ecophysiology, population ecology, behavioral ecology, evolutionary ecology, ecosystem ecology, community ecology, and ecosystem and landscape ecology are all appropriate. Theoretical papers that focus on applied ecological questions are also of particular interest.
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