雌激素对中华鳖性腺分化及DMRT1、SOX9基因表达的影响

中华鳖（Pelodiscus sinensis）性别决定的方式一直存在较大的争议,分子机制更是不清楚。在大部分脊椎动物中,雌激素在性别决定和性腺分化中扮演重要的调控作用。实验通过对性别分化前胚胎进行雌二醇（E2）和芳香化酶抑制剂（AI）处理,研究雌激素在中华鳖性腺分化中的作用及机理。实验结果显示,与对照组（雌性比例49%）相比,E2处理组中雌性中华鳖仔鳖比例显著增加,高达92.3%;而在AI处理组中,雌性比例显著下调至13.1%。HE染色分析表明,ZZ（雄性）和ZW（雌性）胚胎分别经过E2和AI处理后,ZZ和ZW性腺结构呈现明显的雌性化和雄性化特征。同时,通过RT-PCR和免疫荧光染色发现,E2能显著降低雄性性别关键因子DMRT1和SOX9 mRNA和蛋白表达水平;AI则表现相反的调节作用。综上所述,雌激素通过抑制雄性性别关键因子DMRT1和SOX9的表达来抑制雄性分化,促进雌性分化,揭示雌激素在中华鳖雌性性别分化中起着重要的调控作用。       

DMRT1/Dmrt1, the sex determining or sex differentiating gene in Vertebrata

Although the phenomenon of sexual dimorphism is widespread in vertebrates, the molecular mechanism of sex-determination is not the same across animal phyla, in contrast to other areas of developmental biology. Recent extensive studies, however, have given proof of evolutionarily conserved function in genes which share a novel DNA binding DM domain, primarily identified in two invertebrate sex regulatory genes: doublesex of Drosophila melanogaster and mab-3 of Caenorhabditis elegans. Their mammalian autosomal homologue, DMRT1, first isolated in humans, was further discovered in genomes of various vertebrate species and appears to be involved in similar aspects of sexual development. Its precise role is still speculated, thus identification of sex reversal mutations, functional studies as well as determination of the sex-specific expression profile during embryogenesis are still being undertaken. Is this a sex determining rather than a sex differentiating gene? Is it involved in a dosage-sensitive mechanism? On what level does it function in the hierarchy of the sexual regulatory gene cascade? Recent results are discussed in this paper.     

Turning on the male--SRY, SOX9 and sex determination in mammals

The decision of the bi-potential gonad to develop into either a testis or ovary is determined by the presence or absence of the Sex-determining Region gene on the Y chromosome (SRY). Since its discovery, almost 13 years ago, the molecular role that SRY plays in initiating the male sexual development cascade has proven difficult to ascertain. While biochemical studies of clinical mutants and mouse genetic models have helped in our understanding of SRY function, no direct downstream targets of SRY have yet been identified. There are, however, a number of other genes of equal importance in determining sexual phenotype, expressed before and after expression of SRY. Of these, one has proven of central importance to mammals and vertebrates, SOX9. This review describes our current knowledge of SRY and SOX9 structure and function in the light of recent key developments.     

Conserved regulatory modules in the Sox9 testis-specific enhancer predict roles for SOX,TCF/LEF,Forkhead, DMRT,and GATA proteins in vertebrate sex determination

While the primary sex determining switch varies between vertebrate species, a key downstream event in testicular development, namely the male-specific up-regulation of Sox9, is conserved. To date, only two sex determining switch genes have been identified, Sry in mammals and the Dmrt1-related gene Dmy (Dmrt1bY) in the medaka fish Oryzias latipes. In mice, Sox9 expression is evidently up-regulated by SRY and maintained by SOX9 both of which directly activate the core 1.3 kb testis-specific enhancer of Sox9 (TESCO). How Sox9 expression is up-regulated and maintained in species without Sry (i.e. non-mammalian species) is not understood. In this study, we have undertaken an in-depth comparative genomics approach and show that TESCO contains an evolutionarily conserved region (ECR) of 180 bp which is present in marsupials, monotremes, birds, reptiles and amphibians. The ECR contains highly conserved modules that predict regulatory roles for SOX, TCF/LEF, Forkhead, DMRT, and GATA proteins in vertebrate sex determination/differentiation. Our data suggest that tetrapods share common aspects of Sox9 regulation in the testis, despite having different sex determining switch mechanisms. They also suggest that Sox9 autoregulation is an ancient mechanism shared by all tetrapods, raising the possibility that in mammals, SRY evolved by mimicking this regulation. The validation of ECR regulatory sequences conserved from human to frogs will provide new insights into vertebrate sex determination.     

Sex-specific expression of an evolutionarily conserved male regulatory gene, DMRT1, in birds

Based on its Z-sex-chromosomal location and its structural homology to male sexual regulatory factors in humans (DMRT1 and DMRT2), Drosophila (Dsx), and Caenorhabditis elegans (Mab-3), chicken DMRT1 is an excellent candidate for a testis-determining factor in birds. The data we present provide further strong support for this hypothesis. By whole mount in situ hybridization chicken DMRT1 is expressed at higher levels in the male than in the female genital ridges during early stages of embryogenesis. Its expression becomes testis-specific after onset of sexual differentiation. Northern blot and RT PCR analysis showed that in adult birds DMRT1 is expressed exclusively in the testis. We propose that two gene dosages are required for testis formation in ZZ males, whereas expression from a single Z chromosome in ZW females leads to female sexual differentiation.     

The COP9 signalosome (CSN): an evolutionary conserved proteolysis regulator in eukaryotic development

The COP9 signalosome (CSN) is a multiprotein complex of the ubiquitin-proteasome pathway. CSN is typically composed of eight subunits, each of which is related to one of the eight subunits that form the lid of the 26S proteasome regulatory particle. CSN was first identified in Arabidopsis where it is required for the repression of photomorphogenic seedling development in the dark. CSN or CSN-related complexes have by now been reported from most eukaryotic model organisms and CSN has been implicated in a vast array of biological processes. It is widely accepted that CSN directly interacts with cullin-containing E3 ubiquitin ligases, and that CSN is required for their proper function. The requirement of CSN for proper E3 function may at least in part be explained by the observation that CSN subunit 5 (CSN5) is the isopeptidase that deconjugates the essential ubiquitin-like Nedd8 modification from the E3 cullin subunit. In addition to its interaction with E3s, CSN may also regulate proteolysis by its association with protein kinases and deubiquitylating enzymes. This review provides a summary of the role of CSN in regulating protein degradation and in eukaryotic development.