Biological constraint, evolutionary spandrels and antagonistic pleiotropy

IF 12.5 1区医学 Q1 CELL BIOLOGY

Ageing Research Reviews Pub Date : 2024-10-05 DOI:10.1016/j.arr.2024.102527

David Gems, Carina C. Kern

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引用次数: 0

Abstract

Maximum lifespan differs greatly between species, indicating that the process of senescence is largely genetically determined. Senescence evolves in part due to antagonistic pleiotropy (AP), where selection favors gene variants that increase fitness earlier in life but promote pathology later. Identifying the biological mechanisms by which AP causes senescence is key to understanding the endogenous causes of aging and its attendant diseases. Here we argue that the frequent occurrence of AP as a property of genes reflects the presence of constraint in the biological systems that they specify. This arises particularly because the functionally interconnected nature of biological systems constrains the simultaneous optimization of coupled traits (interconnection constraints), or because individual traits cannot evolve (impossibility constraints). We present an account of aging that integrates AP and biological constraint with recent programmatic aging concepts, including costly programs, quasi-programs, hyperfunction and hypofunction. We argue that AP mechanisms of costly programs and triggered quasi-programs are consequences of constraint, in which costs resulting from hyperfunction or hypofunction cause senescent pathology. Impossibility constraint can also cause hypofunction independently of AP. We also describe how AP corresponds to Stephen Jay Gould’s constraint-based concept of evolutionary spandrels, and argue that pathologies arising from AP are bad spandrels. Biological constraint is a conceptual missing link between ultimate and proximate causes of senescence, including diseases of aging.

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生物制约因素、进化褶皱和拮抗多效性。

不同物种的最长寿命差别很大，这表明衰老过程在很大程度上是由基因决定的。衰老进化的部分原因是拮抗多效性（AP），在这种情况下，选择有利于那些在生命早期能提高适应能力，但在生命后期会促进病理变化的基因变异。确定拮抗多效性导致衰老的生物机制是了解衰老及其伴随疾病的内源性原因的关键。在这里，我们认为，AP 作为基因的一种特性频繁出现，反映了基因所指定的生物系统中存在制约因素。这主要是因为生物系统在功能上相互关联的特性限制了耦合性状的同时优化（相互关联限制），或者是因为单个性状无法进化（不可能性限制）。我们对衰老进行了阐述，将AP和生物约束与最新的程序性衰老概念相结合，包括代价高昂的程序、准程序、功能亢进和功能低下。我们认为，有代价的程序和触发的准程序的AP机制是制约的后果，其中功能亢进或功能低下导致的代价会引起衰老病理。不可能性约束也会导致功能低下，而与 AP 无关。我们还描述了AP如何与斯蒂芬-杰伊-古尔德（Stephen Jay Gould）基于约束的 "进化吝啬鬼"（evolutionary spandrels）概念相对应，并论证了由AP引起的病理现象是不好的吝啬鬼。生物约束是衰老（包括衰老疾病）的终极原因和近因之间的概念缺失环节。

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

Ageing Research Reviews 医学-老年医学

CiteScore

19.80

自引率

2.30%

发文量

216

审稿时长

55 days

期刊介绍： With the rise in average human life expectancy, the impact of ageing and age-related diseases on our society has become increasingly significant. Ageing research is now a focal point for numerous laboratories, encompassing leaders in genetics, molecular and cellular biology, biochemistry, and behavior. Ageing Research Reviews (ARR) serves as a cornerstone in this field, addressing emerging trends. ARR aims to fill a substantial gap by providing critical reviews and viewpoints on evolving discoveries concerning the mechanisms of ageing and age-related diseases. The rapid progress in understanding the mechanisms controlling cellular proliferation, differentiation, and survival is unveiling new insights into the regulation of ageing. From telomerase to stem cells, and from energy to oxyradical metabolism, we are witnessing an exciting era in the multidisciplinary field of ageing research. The journal explores the cellular and molecular foundations of interventions that extend lifespan, such as caloric restriction. It identifies the underpinnings of manipulations that extend lifespan, shedding light on novel approaches for preventing age-related diseases. ARR publishes articles on focused topics selected from the expansive field of ageing research, with a particular emphasis on the cellular and molecular mechanisms of the aging process. This includes age-related diseases like cancer, cardiovascular disease, diabetes, and neurodegenerative disorders. The journal also covers applications of basic ageing research to lifespan extension and disease prevention, offering a comprehensive platform for advancing our understanding of this critical field.