The Contribution of Genetic and Environmental Effects to Bergmann's Rule and Allen's Rule in House Mice.

IF 1.3 4区 社会学 Q1 AREA STUDIES
Asian Survey Pub Date : 2022-05-01 Epub Date: 2022-03-24 DOI:10.1086/719028
Mallory A Ballinger, Michael W Nachman
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引用次数: 0

Abstract

AbstractDistinguishing between genetic, environmental, and genotype × environment effects is central to understanding geographic variation in phenotypic clines. Two of the best-documented phenotypic clines are Bergmann's rule and Allen's rule, which describe larger body sizes and shortened extremities in colder climates, respectively. Although numerous studies have found inter- and intraspecific evidence for both ecogeographic patterns, we still have a poor understanding of the extent to which these patterns are driven by genetics, environment, or both. Here, we measured the genetic and environmental contributions to Bergmann's rule and Allen's rule across introduced populations of house mice (Mus musculus domesticus) in the Americas. First, we documented clines for body mass, tail length, and ear length in natural populations and found that these conform to both Bergmann's rule and Allen's rule. We then raised descendants of wild-caught mice in the lab and showed that these differences persisted in a common environment and are heritable, indicating that they have a genetic basis. Finally, using a full-sib design, we reared mice under warm and cold conditions. We found very little plasticity associated with body size, suggesting that Bergmann's rule has been shaped by strong directional selection in house mice. However, extremities showed considerable plasticity, as both tails and ears grew shorter in cold environments. These results indicate that adaptive phenotypic plasticity as well as genetic changes underlie major patterns of clinal variation in house mice and likely facilitated their rapid expansion into new environments across the Americas.

遗传和环境对家鼠伯格曼法则和艾伦法则的影响
摘要区分遗传、环境和基因型×环境效应对于理解表型连锁的地理变异至关重要。表型克隆中记录得最好的两种是伯格曼规则和艾伦规则,它们分别描述了寒冷气候下较大的体型和较短的四肢。尽管大量研究发现了这两种生态地理模式在种间和种内的证据,但我们对这些模式在多大程度上受遗传、环境或两者的驱动仍缺乏了解。在这里,我们测量了美洲引进家鼠(Mus musculus domesticus)种群的遗传和环境对伯格曼规则和艾伦规则的贡献。首先,我们记录了自然种群中体重、尾长和耳长的克隆,发现它们都符合伯格曼规则和艾伦规则。然后,我们在实验室中饲养了野外捕获的小鼠后代,结果表明这些差异在共同环境中持续存在,并且具有遗传性,这表明它们具有遗传基础。最后,我们采用全兄妹设计,在温暖和寒冷条件下饲养小鼠。我们发现,与体型相关的可塑性很小,这表明伯格曼法则在家鼠中是通过强烈的定向选择形成的。然而,四肢却表现出相当大的可塑性,因为在寒冷环境中尾巴和耳朵都会变短。这些结果表明,适应性表型可塑性和遗传变化是家鼠支系变异主要模式的基础,很可能促进了家鼠在美洲新环境中的快速扩张。
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来源期刊
Asian Survey
Asian Survey AREA STUDIES-
CiteScore
1.80
自引率
22.20%
发文量
38
期刊介绍: The only academic journal of its kind produced in the United States, Asian Survey provides a comprehensive retrospective of contemporary international relations within South, Southeast, and East Asian nations. As the Asian community’s matrix of activities becomes increasingly complex, it is essential to have a sourcebook for sound analysis of current events, governmental policies, socio-economic development, and financial institutions. In Asian Survey you’ll find that sourcebook. Asian Survey consistently publishes articles by leading American and foreign scholars, whose views supplement and contest meanings disseminated by the media.
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