Genetic assimilation, robustness and plasticity are key processes in the development and evolution of novel traits

IF 2.5 3区生物学 Q2 DEVELOPMENTAL BIOLOGY

Developmental biology Pub Date : 2025-04-18 DOI:10.1016/j.ydbio.2025.04.011

H. Frederik Nijhout

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Abstract

This is a commentary on how C.H. Waddington's experiments in the 1950's, first published in 1953 in a provocatively titled paper “Genetic assimilation of an acquired character,” laid the foundation for the field of phenotypic plasticity, and how the ideas he developed eventually led to new ways of understanding phenotypic robustness, plasticity, and how novel traits develop and evolve. The “acquired characters” that Waddington worked with were based on Goldschmidt's ideas of “phenocopies”: new phenotypes that develop after an environmental stress that resemble the phenotypes of known mutations. The idea behind genetic assimilation, first outlined by Waddington in 1942, is that existing developmental pathways can be rearranged and redirected through selection to stabilize the phenocopy phenotype, without requiring new mutations. In the short term, Waddington's work led to the discovery of heat shock proteins and the role of Hsp90 in masking defective proteins and allowing the accumulation of cryptic genetic variation. Subsequent studies revealed a host of stabilizing systems that operate at all levels of biological organization that make phenotypes robust to genetic and environmental variation. Many of these resemble homeostatic mechanisms that don't require a stress shock but operate under normal physiological conditions and allow for the accumulation of large amounts of cryptic genetic variation. This cryptic genetic variation can be revealed by mutations or environmental factors that destabilize a homeostatic mechanism. Selection can then act on the phenotypic variants that are produced. This scenario corresponds to the modern phenotype-first hypothesis for the evolution of novel traits that was foreseen by Waddington as early as 1942.

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遗传同化、鲁棒性和可塑性是新性状发育进化的关键过程

这是对C.H. Waddington在1950年代的实验的评论，该实验于1953年首次发表在一篇具有挑衅性的题为“获得性的遗传同化”的论文中，为表型可塑性领域奠定了基础，以及他发展的思想如何最终导致了理解表型稳健性，可塑性以及新特征如何发展和进化的新方法。沃丁顿研究的“获得性特征”是基于戈德施密特的“表型”概念：在环境压力下产生的新表型与已知突变的表型相似。沃丁顿在1942年首先提出了遗传同化背后的思想，即现有的发育途径可以通过选择重新排列和重定向，以稳定表型，而不需要新的突变。在短期内，Waddington的工作导致了热休克蛋白的发现，以及热休克蛋白90在掩盖缺陷蛋白和允许隐性遗传变异积累中的作用。随后的研究揭示了一系列稳定系统，这些系统在生物组织的各个层面上运作，使表型对遗传和环境变异具有强大的抵抗力。其中许多类似于稳态机制，不需要应激冲击，但在正常生理条件下运作，并允许大量隐性遗传变异的积累。这种隐性遗传变异可以通过破坏稳态机制的突变或环境因素来揭示。然后，选择可以作用于产生的表型变异。这种情况与沃丁顿早在1942年就预见到的关于新性状进化的现代表型优先假说相吻合。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Developmental biology 生物-发育生物学

CiteScore

5.30

自引率

3.70%

发文量

182

审稿时长

1.5 months

期刊介绍： Developmental Biology (DB) publishes original research on mechanisms of development, differentiation, and growth in animals and plants at the molecular, cellular, genetic and evolutionary levels. Areas of particular emphasis include transcriptional control mechanisms, embryonic patterning, cell-cell interactions, growth factors and signal transduction, and regulatory hierarchies in developing plants and animals.