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长波敏感视蛋白基因在孔雀鱼(Poecilia reticulata)中的基因复制和分化。

Gene duplication and divergence of long wavelength-sensitive opsin genes in the guppy, Poecilia reticulata.

机构信息

Department of Biological Sciences, Simon Fraser University, Burnaby, BC V5A 1S6, Canada.

出版信息

J Mol Evol. 2011 Feb;72(2):240-52. doi: 10.1007/s00239-010-9426-z. Epub 2010 Dec 18.

DOI:10.1007/s00239-010-9426-z
PMID:21170644
Abstract

Female preference for male orange coloration in the genus Poecilia suggests a role for duplicated long wavelength-sensitive (LWS) opsin genes in facilitating behaviors related to mate choice in these species. Previous work has shown that LWS gene duplication in this genus has resulted in expansion of long wavelength visual capacity as determined by microspectrophotometry (MSP). However, the relationship between LWS genomic repertoires and expression of LWS retinal cone classes within a given species is unclear. Our previous study in the related species, Xiphophorus helleri, was the first characterization of the complete LWS opsin genomic repertoire in conjunction with MSP expression data in the family Poeciliidae, and revealed the presence of four LWS loci and two distinct LWS cone classes. In this study we characterized the genomic organization of LWS opsin genes by BAC clone sequencing, and described the full range of cone cell types in the retina of the colorful Cumaná guppy, Poecilia reticulata. In contrast to X. helleri, MSP data from the Cumaná guppy revealed three LWS cone classes. Comparisons of LWS genomic organization described here for Cumaná to that of X. helleri indicate that gene divergence and not duplication was responsible for the evolution of a novel LWS haplotype in the Cumaná guppy. This lineage-specific divergence is likely responsible for a third additional retinal cone class not present in X. helleri, and may have facilitated the strong sexual selection driven by female preference for orange color patterns associated with the genus Poecilia.

摘要

雌性偏爱波西米亚鱼类属雄性的橙色颜色,这表明长波敏感(LWS)视蛋白基因的重复在这些物种的配偶选择相关行为中发挥了作用。先前的工作表明,该属中的 LWS 基因重复导致了长波视觉能力的扩展,这是通过微分光光度法(MSP)确定的。然而,LWS 基因库与特定物种中 LWS 视锥细胞类别的表达之间的关系尚不清楚。我们之前在相关物种 Xiphophorus helleri 中的研究是首次对 Poeciliidae 家族中 LWS 视蛋白基因的完整基因组库进行的特征描述,并结合 MSP 表达数据,揭示了存在四个 LWS 基因座和两个不同的 LWS 视锥细胞类。在这项研究中,我们通过 BAC 克隆测序对 LWS 视蛋白基因的基因组组织进行了特征描述,并描述了多彩库马纳孔雀鱼视网膜中所有类型的视锥细胞。与 X. helleri 相反,来自库马纳孔雀鱼的 MSP 数据显示存在三个 LWS 视锥细胞类。对库马纳孔雀鱼的 LWS 基因组组织与 X. helleri 的比较表明,基因分化而不是重复导致了库马纳孔雀鱼中新型 LWS 单倍型的进化。这种谱系特异性分化可能是导致第三个额外的视锥细胞类不存在于 X. helleri 中的原因,并且可能促进了由雌性偏爱与波西米亚鱼类属相关的橙色图案引起的强烈性选择。

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