控制自然中复杂性状和适应性的功能获得性多态性。
A gain-of-function polymorphism controlling complex traits and fitness in nature.
机构信息
Department of Biology, Institute for Genome Sciences and Policy, Duke University, Durham, NC 27708, USA.
出版信息
Science. 2012 Aug 31;337(6098):1081-4. doi: 10.1126/science.1221636.
Abstract
Identification of the causal genes that control complex trait variation remains challenging, limiting our appreciation of the evolutionary processes that influence polymorphisms in nature. We cloned a quantitative trait locus that controls plant defensive chemistry, damage by insect herbivores, survival, and reproduction in the natural environments where this polymorphism evolved. These ecological effects are driven by duplications in the BCMA (branched-chain methionine allocation) loci controlling this variation and by two selectively favored amino acid changes in the glucosinolate-biosynthetic cytochrome P450 proteins that they encode. These changes cause a gain of novel enzyme function, modulated by allelic differences in catalytic rate and gene copy number. Ecological interactions in diverse environments likely contribute to the widespread polymorphism of this biochemical function.
摘要
鉴定控制复杂性状变异的因果基因仍然具有挑战性,这限制了我们对影响自然界多态性的进化过程的认识。我们克隆了一个控制植物防御化学物质、昆虫食草动物损伤、在这个多态性进化的自然环境中的生存和繁殖的数量性状位点。这些生态效应是由控制这种变异的 BCMA(支链蛋氨酸分配)基因座的重复以及它们编码的芥子油苷生物合成细胞色素 P450 蛋白中的两个被选择性有利的氨基酸变化驱动的。这些变化导致了一种新的酶功能的获得,这种功能受到等位基因差异的催化速率和基因拷贝数的调节。不同环境中的生态相互作用可能促成了这种生化功能的广泛多态性。
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