Pfab Ferdinand, Gabriel Wilfried, Utz Margarete
Department of Biology II, Ludwig Maximilian University of Munich, Großhaderner Straße 2, 82152, Martinsried-Planegg, Germany.
Department of Mathematics, University of Trento, Via Sommarive 14, 38123, Povo, TN, Italy.
J Math Biol. 2016 Jan;72(1-2):435-66. doi: 10.1007/s00285-015-0890-3. Epub 2015 May 16.
We introduce a novel model for continuous reversible phenotypic plasticity. The model includes a one-dimensional environmental gradient, and we describe performance of an organism as a function of the environmental state by a Gaussian tolerance curve. Organisms are assumed to adapt their tolerance curve after a change of the environmental state. We present a general framework for calculating the genotype fitness if such adaptations happen in a continuous manner and apply the model to a periodically changing environment. Significant differences of our model with previous models for plasticity are the continuity of adaptation, the presence of intermediate phenotypes, that the duration of transformations depends on their extent, fewer restrictions on the distribution of the environment, and a higher robustness with respect to assumptions about environmental fluctuations. Further, we show that continuous reversible plasticity is beneficial mainly when environmental changes occur slow enough so that fully developed phenotypes can be exhibited. Finally we discuss how the model framework can be generalized to a wide variety of biological scenarios from areas that include population dynamics, evolution of environmental tolerance and physiology.
我们引入了一种用于连续可逆表型可塑性的新模型。该模型包含一个一维环境梯度,并且我们通过高斯耐受曲线将生物体的表现描述为环境状态的函数。假定生物体在环境状态发生变化后会调整其耐受曲线。如果这种适应以连续方式发生,我们提出了一个用于计算基因型适应性的通用框架,并将该模型应用于周期性变化的环境。我们的模型与先前的可塑性模型的显著差异在于适应的连续性、中间表型的存在、转变的持续时间取决于其程度、对环境分布的限制较少以及对环境波动假设具有更高的稳健性。此外,我们表明,连续可逆可塑性主要在环境变化足够缓慢以至于能够展现出充分发育的表型时才有益。最后,我们讨论了如何将模型框架推广到包括种群动态、环境耐受性进化和生理学等领域的各种生物学场景。
