超级基因并不是解释复杂替代表型维持的必要条件。

IF 3.8 1区 生物学 Q1 BIOLOGY Proceedings of the Royal Society B: Biological Sciences Pub Date : 2024-10-01 Epub Date: 2024-10-16 DOI:10.1098/rspb.2024.1715
Sarah P Flanagan, Suzanne H Alonzo
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引用次数: 0

摘要

进化生物学旨在解释自然界的多样性。进化理论提供了理解简单多态性或连续变异如何维持的框架,但作为离散的成套数量性状遗传的表型却很难纳入这一框架。有人提出了超级基因来解决这个问题--如果因果基因位于同一位置,它们就可以像单个基因一样遗传,从而弥补了简单多态性和连续性状之间的差距。我们建立模型的目的是:超级基因是如何维持表型多样性的?在我们最简单的模型中,没有明确的遗传结构,在我们评估的许多参数组合中,都能维持三种可供选择的生殖形态。对于这些相同的参数值,具有人口随机性、重组和突变(但没有明确的遗传结构)的模型只能维持这三种形态中的两种,随机性决定了哪种形态会持续存在。有了明确的遗传结构,无论因果基因座是共存于一个超级基因中还是随机分布,形态维持的随机性都会降低。即使表型变异消失了,遗传多样性却得以保持。总之,具有多基因基础的分类性状与由超级基因决定的性状表现出相似的进化动态。我们的研究表明,超级基因并不是解决离散多基因表型变异如何维持这一难题的唯一答案。
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Supergenes are not necessary to explain the maintenance of complex alternative phenotypes.

Evolutionary biology aims to explain the diversity seen in nature. Evolutionary theory provides frameworks to understand how simple polymorphisms or continuous variation are maintained, but phenotypes inherited as discrete suites of quantitative traits are difficult to fit into this framework. Supergenes have been proposed as a solution to this problem-if causal genes are co-located, they can be inherited as if a single gene, thus bridging the gap between simple polymorphisms and continuous traits. We develop models to ask: how are critical supergenes for maintaining phenotypic diversity? In our simplest model, without explicit genetic architectures, three alternative reproductive morphs are maintained in many of the parameter combinations we evaluated. For these same parameter values, models with demographic stochasticity, recombination and mutation (but without explicit genetic architecture) maintained only two of these three morphs, with stochasticity determining which morphs persisted. With explicit genetic architectures, regardless of whether causal loci were co-located in a supergene or distributed randomly, this stochasticity in which morphs are maintained was reduced. Even when phenotypic variation was lost, genetic diversity was maintained. Altogether, categorical traits with polygenic bases exhibited similar evolutionary dynamics to those determined by supergenes. Our work suggests that supergenes are not the only answer to the puzzle of how discrete polygenic phenotypic variation is maintained.

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来源期刊
CiteScore
7.90
自引率
4.30%
发文量
502
审稿时长
1 months
期刊介绍: Proceedings B is the Royal Society’s flagship biological research journal, accepting original articles and reviews of outstanding scientific importance and broad general interest. The main criteria for acceptance are that a study is novel, and has general significance to biologists. Articles published cover a wide range of areas within the biological sciences, many have relevance to organisms and the environments in which they live. The scope includes, but is not limited to, ecology, evolution, behavior, health and disease epidemiology, neuroscience and cognition, behavioral genetics, development, biomechanics, paleontology, comparative biology, molecular ecology and evolution, and global change biology.
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