Genomic organization and evolution of ruminant lysozyme c genes 被引量：5

Genomic organization and evolution of ruminant lysozyme c genes

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摘要 Ruminant stomach lysozyme is a long established model of adaptive gene evolution. Evolution of stomach lysozyme function required changes in the site of expression of the lysozyme c gene and changes in the enzymatic properties of the enzyme. In ruminant mammals, these changes were associated with a change in the size of the lysozyme c gene family. The recent release of near complete genome sequences from several ruminant species allows a more complete examination of the evolution and diversification of the lysozyme c gene family. Here we characterize the size of the lysozyme c gene family in extant ruminants and demonstrate that their pecoran ruminant ancestor had a family of at least 10 lysozyme c genes, which included at least two pseudogenes. Evolutionary analysis of the ruminant lysozyme c gene sequences demonstrate that each of the four exons of the lysozyme c gene has a unique evolutionary history, indicating that they participated independently in concerted evolution. These analyses also show that episodic changes in the evolutionary constraints on the protein sequences occurred, with lysozyme c genes expressed in the abomasum of the stomach of extant ruminant species showing the greatest levels of selective constraints. Ruminant stomach lysozyme is a long established model of adaptive gene evolution. Evolution of stomach lysozyme function required changes in the site of expression of the lysozyme c gene and changes in the enzymatic properties of the enzyme. In ruminant mammals, these changes were associated with a change in the size of the lysozyme c gene family. The recent release of near complete genome sequences from several ruminant species allows a more complete examination of the evolution and diversification of the lysozyme c gene family. Here we characterize the size of the lysozyme c gene family in extant ruminants and demonstrate that their pecoran ruminant ancestor had a family of at least 10 lysozyme c genes, which included at least two pseudogenes. Evolutionary analysis of the ruminant lysozyme c gene sequences demonstrate that each of the four exons of the lysozyme c gene has a unique evolutionary history, indicating that they participated independently in concerted evolution. These analyses also show that episodic changes in the evolutionary constraints on the protein sequences occurred, with lysozyme c genes expressed in the abomasum of the stomach of extant ruminant species showing the greatest levels of selective constraints.

作者 David M.IRWIN

机构地区 Department of Laboratory Medicine and Pathobiology Banting and Best Diabetes Centre

出处《Zoological Research》 CAS CSCD 2015年第1期1-17,共17页 动物学研究（英文）

基金 supported by grants from the Natural Sciences and Engineering Research Council(RGPIN 183701)

关键词 lysozyme ruminant evolutionary Genomic extant stomach genomic constraints Ailuropoda duplication lysozyme ruminant evolutionary Genomic extant stomach genomic constraints Ailuropoda duplication

分类号 Q55 [生物学—生物化学]

作者简介 Corresponding author, E-mail： david.irwin@utoronto.ca

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参考文献46

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Genomic organization and evolution of ruminant lysozyme c genes 被引量：5

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