偶蹄目动物中催乳素受体（PRLR）基因和生长激素受体（GHR）基因胞质结构域的趋异进化。

Divergent evolution in the cytoplasmic domains of PRLR and GHR genes in Artiodactyla.

作者信息

Iso-Touru Terhi, Kantanen Juha, Li Meng-Hua, Gizejewski Zygmunt, Vilkki Johanna

机构信息

Biotechnology and Food Research, MTT Agrifood Research Finland,Jokioinen, Finland.

出版信息

BMC Evol Biol. 2009 Jul 22;9:172. doi: 10.1186/1471-2148-9-172.

DOI:10.1186/1471-2148-9-172

PMID:19622175

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2720954/

Abstract

BACKGROUND

Prolactin receptor (PRLR) and growth hormone receptor (GHR) belong to the large superfamily of class 1 cytokine receptors. Both of them have been identified as candidate genes affecting key quantitative traits, like growth and reproduction in livestock. We have previously studied the molecular anatomy of the cytoplasmic domain of GHR in different cattle breeds and artiodactyl species. In this study we have analysed the corresponding cytoplasmic signalling region of PRLR.

RESULTS

We sequenced PRLR gene exon 10, coding for the major part of the cytoplasmic domain, from cattle, American bison, European bison, yak, sheep, pig and wild boar individuals. We found different patterns of variation in the two receptors within and between ruminants and pigs. Pigs and bison species have no variation within GHR exon 10, but show high haplotype diversity for the PRLR exon 10. In cattle, PRLR shows lower diversity than GHR. The Bovinae PRLR haplotype network fits better the known phylogenetic relationships between the species than that of the GHR, where differences within cattle breeds are larger than between the different species in the subfamily. By comparison with the wild boar haplotypes, a high number of subsequent nonsynonymous substitutions seem to have accumulated in the pig PRLR exon 10 after domestication.

CONCLUSION

Both genes affect a multitude of traits that have been targets of selection after domestication. The genes seem to have responded differently to different selection pressures imposed by human artificial selection. The results suggest possible effects of selective sweeps in GHR before domestication in the pig lineage or species divergence in the Bison lineage. The PRLR results may be explained by strong directional selection in pigs or functional switching.

摘要

背景

催乳素受体（PRLR）和生长激素受体（GHR）属于1类细胞因子受体的大型超家族。它们都已被确定为影响关键数量性状的候选基因，如家畜的生长和繁殖。我们之前研究了不同牛品种和偶蹄目物种中GHR细胞质结构域的分子解剖学。在本研究中，我们分析了PRLR相应的细胞质信号区域。

结果

我们对牛、美洲野牛、欧洲野牛、牦牛、绵羊、猪和野猪个体的PRLR基因外显子10进行了测序，该外显子编码细胞质结构域的主要部分。我们在反刍动物和猪内部及之间的两种受体中发现了不同的变异模式。猪和野牛物种在GHR外显子10内没有变异，但PRLR外显子10表现出高单倍型多样性。在牛中，PRLR的多样性低于GHR。牛亚科PRLR单倍型网络比GHR更符合物种间已知的系统发育关系，牛品种内的差异大于亚科内不同物种间的差异。与野猪单倍型相比，猪PRLR外显子10在驯化后似乎积累了大量随后的非同义替换。

结论

这两个基因都影响了许多驯化后成为选择目标的性状。这些基因似乎对人类人工选择施加的不同选择压力有不同的反应。结果表明，猪谱系驯化前GHR可能受到选择性清除的影响，或者野牛谱系中发生了物种分化。PRLR的结果可能是由于猪中的强烈定向选择或功能转换所致。

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偶蹄目动物中催乳素受体（PRLR）基因和生长激素受体（GHR）基因胞质结构域的趋异进化。

Divergent evolution in the cytoplasmic domains of PRLR and GHR genes in Artiodactyla.

作者信息

机构信息

出版信息

BACKGROUND

RESULTS

CONCLUSION

背景

结果

结论

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