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在冲绳刺鼠德氏姬鼠(Tokudaia muenninki)中,祖先的Y连锁基因通过易位到与一对常染色体融合的X和Y染色体上得以保留。

Ancestral Y-linked genes were maintained by translocation to the X and Y chromosomes fused to an autosomal pair in the Okinawa spiny rat Tokudaia muenninki.

作者信息

Murata Chie, Kuroki Yoko, Imoto Issei, Kuroiwa Asato

机构信息

Department of Human Genetics, Institute of Biomedical Sciences, Tokushima University Graduate School, 3-18-15 Kuramoto-cho, Tokushima, 770-8503, Japan.

RIKEN, Center for Integrative Medical Sciences, 1-7-22 Suehiro-cho, Tsurumi, Yokohama, Kanagawa, 230-0045, Japan.

出版信息

Chromosome Res. 2016 Sep;24(3):407-19. doi: 10.1007/s10577-016-9531-y. Epub 2016 Jun 22.

DOI:10.1007/s10577-016-9531-y
PMID:27333765
Abstract

Two species of the genus Tokudaia lack the Y chromosome and SRY, but several Y-linked genes have been rescued by translocation or transposition to other chromosomes. Tokudaia muenninki is the only species in the genus that maintains the Y owing to sex chromosome-autosome fusions. According to previous studies, many SRY pseudocopies and other Y-linked genes have evolved by excess duplication in this species. Using RNA-seq and RT-PCR, we found that ZFY, EIF2S3Y, TSPY, UTY, DDX3Y, USP9Y, and RBMY, but not UBA1Y, had high deduced amino acid sequence similarity and similar expression patterns with other rodents, suggesting that these genes were functional. Based on FISH and quantitative real-time PCR, all of the genes except for UTY and DDX3Y were amplified on the X and Y chromosomes with approximately 10-66 copies in the male genome. In a comparative analysis of the 372.4-kb BAC sequence and Y-linked gene transcripts from T. muenninki with the mouse Y genomic sequence, we observed that multiple-copy genes in the ancestral Y genome were nonfunctional, indicating that the gene functions were assumed by amplified copies. We also found a LTR sequence at the distal end of a SRY duplication unit, suggesting that unequal sister chromatid exchange mediated by retrotransposable elements could have been involved in SRY amplification. Our results revealed that the Y-linked genes were rescued from degeneration via translocations to other sex chromosomal regions and amplification events in T. muenninki.

摘要

德久田鼠属的两个物种缺少Y染色体和SRY基因,但一些Y连锁基因已通过易位或转座到其他染色体上而得以保留。德久田鼠是该属中唯一因性染色体与常染色体融合而保留Y染色体的物种。根据先前的研究,该物种中许多SRY假基因拷贝和其他Y连锁基因是通过过度复制而进化的。通过RNA测序和逆转录聚合酶链反应,我们发现ZFY、EIF2S3Y、TSPY、UTY、DDX3Y、USP9Y和RBMY(但不包括UBA1Y)与其他啮齿动物具有高度推导的氨基酸序列相似性和相似的表达模式,表明这些基因具有功能。基于荧光原位杂交和定量实时聚合酶链反应,除UTY和DDX3Y外,所有基因在X和Y染色体上均有扩增,雄性基因组中约有10 - 66个拷贝。在对德久田鼠372.4 kb的细菌人工染色体序列和Y连锁基因转录本与小鼠Y基因组序列进行比较分析时,我们观察到祖先Y基因组中的多拷贝基因无功能,这表明基因功能由扩增的拷贝承担。我们还在SRY重复单元的远端发现了一个长末端重复序列,表明逆转座元件介导的不等姐妹染色单体交换可能参与了SRY的扩增。我们的结果表明,在德久田鼠中,Y连锁基因通过易位到其他性染色体区域和扩增事件而免于退化。

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