两种淡水鱼类的Sox基因

ＴＨＥＳＯＸＧＥＮＥＳＩＮＴＷＯＳＰＥＣＩＥＳＯＦＦＲＥＳＨＷＡＴＥＲＦＩＳＨＥＳ两种淡水鱼类的Ｓｏｘ基因ＫｅｙｗｏｒｄｓＳｅｘ,Ｉｎｔｒｏｎ,Ｆｒｅｓｈｗａｔｅｒｆｉｓｈ关键词性别内含子淡水鱼类ＴｈｅＳｒｙｉｓｔｈｅｓｅｘｄｅｔｅｒｍｉｎｉ...     

Related function of mouse SOX3, SOX9, and SRY HMG domains assayed by male sex determination

Sox genes encode proteins related to each other, and to the sex determining gene Sry, by the presence of a DNA binding motif known as the HMG domain. Although HMG domains can bind to related DNA sequences, Sox gene products may achieve target gene specificity by binding to preferred target sequences or by interacting with specific partner proteins. To assess their functional similarities, we replaced the HMG box of Sry with the HMG box of Sox3 or Sox9 and tested whether these constructs caused sex reversal in XX mice. Our results indicate that such chimeric transgenes can functionally replace Sry and elicit development of testis cords, male patterns of gene expression, and elaboration of male secondary sexual characteristics. This implies that chimeric SRY proteins with SOX HMG domains can bind to and regulate SRY target genes and that potential SRY partner factor interactions are not disrupted by HMG domain substitutions. genesis 28:111-124, 2000.     

Evolution of the Sry genes

Existing DNA sequence data on the Sry gene, the mammalian sex- determining locus in the Y chromosome, were analyzed for primates, rodents, and bovids. In all three taxonomic groups, the terminal sequences evolved faster than the HMG (high mobility group) boxes, and this applies both to synonymous (Ks) and nonsynonymous (Ka) nucleotide substitutions. Similar intragenic correlation between synonymous and nonsynonymous substitution rates was not found either in other mammalian genes that contain a conservative box (Sox, Msx) or in the MADS-box genes of plants. The rate of nonsynonymous substitutions exceeds significantly that of synonymous substitutions in the terminal Sry sequences of apes. We did not find good support for the hypothesis that the high evolutionary rate of Sry would be associated with a promiscuous mating system.      

Sry-negative XX sex reversal in the American cocker spaniel dog

The Sry gene product serves an important function in male sex determination through testis induction. However, testicular development has been reported in SRY-negative XX sex reversed humans. XX sex reversal of the American cocker spaniel, inherited as an autosomal recessive trait, may be a homolog of this disorder. The purpose of this study was to determine whether the Sry high mobility group (HMG) box is present in genomic DNA of affected dogs. Conserved Sry HMG box and hypoxanthine phosphoribosyltransferase (HPRT) sequences were used as primers in polymerase chain reactions. A 167 bp Y-specific canine Sry HMG box sequence was cloned from genomic DNA of normal male dogs. Internal primers generated a 104 bp Sry HMG box product from normal males, but not from females or XX sex reversed dogs. Parallel reactions generated an HPRT product from all dogs. Results indicate that the Sry HMG box is absent in genomic DNA of XX sex reversed dogs. We speculate that activation of the testis differentiation cascade in the absence of Sry in this model is due to a mutant autosomal gene. © 1995 Wiley-Liss, Inc.     

哺乳动物的性别决定相关基因的作用机理

哺乳动物的性别决定是以Sry基因为主导,其它多个基因参与的级联调控的机制。近年来的研究表明,Sry、Sox9、Wt1、Sf1、Amh、Dax1、Dmrt1、Wnt4等基因都参与性别决定的级联过程。哺育动物性别决定相关基因的研究,对性分化与生殖发育过程的了解具有十分重要的意义。主要论述了参与哺乳动物性别决定与调控的相关基因、可能作用机制及其研究进展等。     

PCR扩增Sry基因进行鲸类动物性别的鉴定

哺乳动物Y染色体短臂上的Sry 基因决定雄性发育方向。本研究参照哺乳动物Sry 基因保守区序列设计引物, 以非性别特异性的线粒体DNA 细胞色素b 基因作为阳性对照, 用PCR 扩增江豚、长喙真海豚等鲸类动物的Sry 基因片断并对其进行凝胶电泳分析来鉴定鲸类动物的性别。通过此方法对87 个已知性别鲸类动物标本的检验, 结果完全正确, 并进一步应用此方法成功地完成了另外33 个未知性别鲸类标本的性别鉴定。由此建立了一套简单、快速、可靠的鲸类动物的性别鉴定方法。     

Sox15 is up regulated in the embryonic mouse testis

The mammalian sex determining region on the Y chromosome, SRY, is the founding member of the SOX gene family. SOX genes share a common DNA-binding motif termed the HMG box and have diverse roles in vertebrate embryonic development and tissue differentiation. Sox15 expression was analysed during mouse embryogenesis by whole-mount in situ hybridisation and Real Time RT-PCR. Sox15 was found to be expressed in developing mouse gonads from 11.5 dpc to 13.5 dpc with a peak of expression at 12.5 dpc. Expression was approximately twice as high in the male gonad as in the female gonad.     

牛Sry亚细胞定位及其对Sox9基因表达的影响

为鉴别牛Sry基因的下游目的基因,并确定Sry蛋白在细胞内的定位区域, 本试验构建pcDNA3.1-Sry表达载体和pEGFP-N1-Sry亚细胞定位表达载体, 在原代培养的生殖嵴细胞和卵巢颗粒细胞中进行Sry过表达,并对性别控制相关基因在Sry过表达前后的表达水平变化进行检测,包括Sf1 (Steroidogenic fator-1)、Gata4 (GATA binding protein 4)、Wt1 (Wilms'tumor gene)、Sox9 (Sry-related HMG box-9)、Amh (Anti Mullerian Hormone)和Dax1 (Dosage sensitive sex reversal locus-1);并在两种细胞中进行了Sry亚细胞定位研究.Sry在两种细胞中过表达后,在生殖嵴细胞中Sox9的表达水平被显著上调,但在卵巢颗粒细胞中未观察到Sox9基因被上调,而其他几个基因的表达水平未受Sry影响;亚细胞定位结果表明牛Sry主要分布在细胞核内.本试验说明牛Sry可能间接调控Sox9表达,或存在其他不需要Sry参与的调控通路调控Sox9表达;牛Sry蛋白起转录因子作用.     

Delayed Sry and Sox9 expression in developing mouse gonads underlies B6-Y(DOM) sex reversal

The phenomenon of B6-Y(DOM) sex reversal arises when certain variants of the Mus domesticus Y chromosome are crossed onto the genetic background of the C57BL/6J (B6) inbred mouse strain, which normally carries a Mus musculus-derived Y chromosome. While the sex reversal has been assumed to involve strain-specific variations in structure or expression of Sry, the actual cause has not been identified. Here we used in situ hybridization to study expression of Sry, and the critical downstream gene Sox9, in strains containing different chromosome combinations to investigate the cause of B6-Y(DOM) sex reversal. Our findings establish that a delay of expression of Sry(DOM) relative to Sry(B6) underlies B6-Y(DOM) sex reversal and provide the first molecular confirmation that Sry must act during a critical time window to appropriately activate Sox9 and effect male testis determination before the onset of the ovarian-determining pathway.     

Sox genes in grass carp (Ctenopharyngodon idella) with their implications for genome duplication and evolution

The Sox gene family is found in a broad range of animal taxa and encodes important gene regulatory proteins involved in a variety of developmental processes. We have obtained clones representing the HMG boxes of twelve Sox genes from grass carp (Ctenopharyngodon idella), one of the four major domestic carps in China. The cloned Sox genes belong to group B1, B2 and C. Our analyses show that whereas the human genome contains a single copy of Sox4, Sox11 and Sox14, each of these genes has two co-orthologs in grass carp, and the duplication of Sox4 and Sox11 occurred before the divergence of grass carp and zebrafish, which support the "fish-specific whole-genome duplication" theory. An estimation for the origin of grass carp based on the molecular clock using Sox1, Sox3 and Sox11 genes as markers indicates that grass carp (subfamily Leuciscinae) and zebrafish (subfamily Danioninae) diverged approximately 60 million years ago. The potential uses of Sox genes as markers in revealing the evolutionary history of grass carp are discussed.     

From SRY to SOX9: mammalian testis differentiation

Sry (sex-determining region on the Y chromosome) is a master gene that initiates testis differentiation of the bipotential indifferent gonad in mammals. In mice, Sry expression is transiently activated in a center-to-pole wave along the anteroposterior (AP) axis of developing XY gonads. Shortly after the onset of Sry activation, Sox9 (Sry-related HMG box-9), a fundamental testis-differentiation gene common to all vertebrates, is also activated in a center-to-pole pattern similar to the initial Sry expression profile. Several male-specific cellular events, such as glycogenesis, coelomic epithelium proliferation, mesonephric migration and vasculogenesis, are induced in XY gonads following the onset of Sry and Sox9 expression. This paper mainly focuses on recent advances in elucidating the regulatory mechanisms of Sry and Sox9 expression and male-specific cellular events immediately downstream of SRY action during the initial phases of testis differentiation.     

HUMAN CHROMOSOME Y AND SRY

The precise location of the SRY gene on the human Y chromosome has been revealed through studies of sex reversal cases involving deletion, cross-linking and mutations of the SRY gene. Its DNA sequence and mechanism of action are being understood. Similarity of SRY with Sry of mice and its interaction with other genes in male sex determination are discussed.