Sexually dimorphic gene expression in the developing mouse gonad

Over the course of a few days, the bipotential embryonic mouse gonad differentiates into either a testis or an ovary. Though a few gene expression differences that underlie gonadal sex differentiation have been identified, additional components of the testicular and ovarian developmental pathways must be identified to understand this process. Here we report the use of a PCR-based cDNA subtraction to investigate expression differences that arise during gonadal sex differentiation. Subtraction of embryonic day 12.5 (E12.5) XY gonadal cDNA with E12.5 XX gonadal cDNA yielded 19 genes that are expressed at significantly higher levels in XY gonads. These genes display a variety of expression patterns within the embryonic testis and encode a broad range of proteins. A reciprocal subtraction (of E12.5 XX gonadal cDNA with E12.5 XY gonadal cDNA) yielded two genes, follistatin and Adamts19, that are expressed at higher levels in XX gonads. Follistatin is a well-known antagonist of TGFbeta family members while Adamts19 encodes a new member of the ADAMTS family of secreted metalloproteases.     

Evidence for gonadotropin-releasing hormone peptides in the ovary and testis of rainbow trout.

GnRH is usually classified as a neuropeptide that is synthesized in the brain. Recent evidence indicates that GnRH mRNA is present also in the ovary and testis. However, isolation of the peptide from testis has not been reported. We used HPLC and specific RIAs to determine whether the GnRH peptide can be detected in gonads, the developmental stage at which the peptide is expressed, and the number of molecular forms of GnRH that are present in the ovary and testis. Extracts of immature and mature ovarian and testicular tissue were examined from 17- to 21-mo-old rainbow trout (Oncorhynchus mykiss). For the first time, GnRH peptides were isolated from testis and identified by HPLC-RIA with specific antisera and by elution position compared with synthetic standards. GnRH peptides were also present in the ovary. In addition, multiple forms of GnRH, including a form not normally detected in the brain of trout, were shown to be present in the gonads. During development, GnRH peptides were expressed only at specific stages in the gonads, which may explain the inability to detect and isolate the GnRH peptides from gonads in earlier studies.     

养殖施氏鲟的性腺转录组特征分析

鲟是目前世界上最古老的软骨硬鳞鱼类之一,雌雄个体之间无明显的第二性征。为了解人工养殖下鲟性腺发育的分子特征,研究以人工养殖2龄施氏鲟(Acipenser schrenckii Brandt)为研究对象,对其精巢与卵巢进行转录组测序分析。结果发现,雌雄性腺中共有19690个差异表达基因转录本,其中与性别分化相关基因包括转录因子Dmrt1、Sox9、Foxl2等和生长转化因子Amh、Bmp15、Gdf9等。另外,通过差异表达基因KEGG代谢通路富集分析发现了4条与卵巢发育相关的通路,分别为黄体酮介导的卵母细胞成熟、卵母细胞减数分裂、卵巢类固醇合成、促性腺激素释放激素信号通路。其中,卵巢类固醇合成通路中18个差异表达基因的表达模式暗示了2龄施氏鲟限制卵巢雌激素的合成,但精巢中雄激素的合成未受影响。研究结果为研究鲟性腺分化和发育机制以及今后在m RNA表达水平上鉴定鲟性别提供了基础。     

Identification of novel markers of mouse fetal ovary development

In contrast to the developing testis, molecular pathways driving fetal ovarian development have been difficult to characterise. To date no single master regulator of ovarian development has been identified that would be considered the female equivalent of Sry. Using a genomic approach we identified a number of novel protein-coding as well as non-coding genes that were detectable at higher levels in the ovary compared to testis during early mouse gonad development. We were able to cluster these ovarian genes into different temporal expression categories. Of note, Lrrc34 and AK015184 were detected in XX but not XY germ cells before the onset of sex-specific germ cell differentiation marked by entry into meiosis in an ovary and mitotic arrest in a testis. We also defined distinct spatial expression domains of somatic cell genes in the developing ovary. Our data expands the set of markers of early mouse ovary differentiation and identifies a classification of early ovarian genes, thus providing additional avenues with which to dissect this process.     

Antagonism of the testis- and ovary-determining pathways during ovotestis development in mice

Ovotestis development in B6-XY^POS mice provides a rare opportunity to study the interaction of the testis- and ovary-determining pathways in the same tissue. We studied expression of several markers of mouse fetal testis (SRY, SOX9) or ovary (FOXL2, Rspo1) development in B6-XY^POS ovotestes by immunofluorescence, using normal testes and ovaries as controls. In ovotestes, SOX9 was expressed only in the central region where SRY is expressed earliest, resulting in testis cord formation. Surprisingly, FOXL2-expressing cells also were found in this region, but individual cells expressed either FOXL2 or SOX9, not both. At the poles, even though SOX9 was not up-regulated, SRY expression was down-regulated normally as in XY testes, and FOXL2 was expressed from an early stage, demonstrating ovarian differentiation in these areas. Our data (1) show that SRY must act within a specific developmental window to activate Sox9; (2) challenge the established view that SOX9 is responsible for down-regulating Sry expression; (3) disprove the concept that testicular and ovarian cells occupy discrete domains in ovotestes; and (4) suggest that FOXL2 is actively suppressed in Sertoli cell precursors by the action of SOX9. Together these findings provide important new insights into the molecular regulation of testis and ovary development.     

Functional analysis of Sox8 and Sox9 during sex determination in the mouse

Sex determination in mammals directs an initially bipotential gonad to differentiate into either a testis or an ovary. This decision is triggered by the expression of the sex-determining gene Sry, which leads to the activation of male-specific genes including the HMG-box containing gene Sox9. From transgenic studies in mice it is clear that Sox9 is sufficient to induce testis formation. However, there is no direct confirmation for an essential role for Sox9 in testis determination. The studies presented here are the first experimental proof for an essential role for Sox9 in mediating a switch from the ovarian pathway to the testicular pathway. Using conditional gene targeting, we show that homozygous deletion of Sox9 in XY gonads interferes with sex cord development and the activation of the male-specific markers Mis and P450scc, and leads to the expression of the female-specific markers Bmp2 and follistatin. Moreover, using a tissue specific knock-out approach, we show that Sox9 is involved in Sertoli cell differentiation, the activation of Mis and Sox8, and the inactivation of Sry. Finally, double knock-out analyses suggest that Sox8 reinforces Sox9 function in testis differentiation of mice.     

Expression of inhibin α-subunit gene during mouse gametogenesis

Mammalian gametogenesis is regulated through complex interactions between germ and somatic cells. To investigate the mechanism underlying the differentiation of functional gametes, some genes specifically expressed during gametogenesis have been isolated and characterized. In a search for further examples of such genes, we have isolated from a newborn mouse testis cDNA library, a clone corresponding to mouse inhibin alpha-subunit. Although it is known that the inhibin alpha-subunit molecule is abundantly produced in ovarian follicle and in testicular Sertoli cells, the spatial and temporal patterns of expression of this gene remain to be elucidated. In this study, the patterns of expression of inhibin alpha-subunit mRNA during mouse gametogenesis were examined by RNA blot, cytoplasmic dot and in situ hybridization techniques. In the testis, the concentration of inhibin alpha-subunit mRNA increased from about 16 dpc (days post coitum), peaked at birth and then gradually decreased, paralleling testicular development. Inhibin alpha-subunit mRNA was localized in Sertoli cells of wild type as well as W/Wv testes. In adult testis, mRNA was restricted to the perinuclear cytoplasm of Sertoli cells. Inhibin alpha-subunit mRNA was expressed in follicle cells of adult ovary more abundantly than in adult testis. Analysis of expression during folliculogenesis showed that the accumulation of this mRNA began in preantrum follicles and the level of expression reached a maximum in Graafian follicles.     

Sex inversion as a model for the study of sex determination in vertebrates

As a consequence of genetic sex determination, the indifferent gonadal blastema normally becomes either a testis or an ovary. This applies to mammals and to the majority of non-mammalian vertebrates. With the exception of placental mammals, however, partial or complete sex inversion can be induced in one sex by sexual steroid hormones of the opposite sex during a sensitive period of gonadogenesis. There is evidence that also during normal gonadogenesis in these species, in the XY/XX mechanism of sex determination testicular differentiation is induced by androgens, and in the ZZ/ZW mechanism, ovarian differentiation by oestrogens. In either case, the hormones may act via serological H-Y antigen as a morphogenetic factor. In contrast, in placental mammals including man, primary gonadal differentiation is independent of sexual steroid hormones, and factors directing differential gonadal development have not yet been conclusively identified. However, various mutations at the chromosome or gene level, resulting respectively in sex inversion or intersexuality, have provided clues as to some genes involved and their possible nature. In this context also, serological H-Y antigen is discussed as a possible factor acting on primordial gonadal cells and inducing differential growth or morphogenesis or both. The data available at present allow a tentative outline of the genetics of sex determination in placental mammals.