Molecular cloning and expression in gonad of Rana rugosa WT1 and Fgf9

Sry (sex-determining region on the Y chromosome) is required for testicular differentiation in mammals. In addition to Sry, other genes such as WT1, Fgf9, Dax1, Dmrt1 and Sox9 are widely accepted to be involved in the sex determination in vertebrates. However, the roles of these genes during sex determination still remain unclear in amphibians. This study was undertaken to examine the expression of WT1 and Fgf9 in the developing gonad of amphibians. We first isolated the WT1 cDNA from the frog Rana rugosa. Like WT1 in mice, R. rugosa WT1 showed 2 isoforms; i.e., one had an additional 3 amino acids, KTS, included between the third and fourth zinc fingers. However, 17 amino acids in exon 5 of mammalian WT1 could not be found in R. rugosa WT1, which is also the case in turtle and chicken. The mRNA of both isoforms (+KTS, -KTS) was detected in the lung, kidney and testis, but not in the ovary and muscle of adult frogs. The 2 isoforms were expressed first in the embryos at stage 23. Thereafter, the expressions remained constant in the gonad attached to mesonephros of both sexes during sex determination. We next isolated the R. rugosa Fgf9 cDNA encoding 208 amino acids. The amino acid sequence of Fgf9 had similarity greater than 92% with chicken, mouse and human Fgf9s, suggesting that Fgf9 is highly conserved among vertebrate classes. Fgf9 was expressed in the ovary of an adult frog strongly, but in the lung weakly. In contrast, the Fgf9 mRNA was hardly detected in the kidney, testis and muscle. Moreover, Fgf9 did not show a sexually dimorphic expression pattern during sex determination in R. rugosa. The results, taken together, suggest that both WT1 and Fgf9 are expressed in the indifferent gonad prior to sex determination without any difference in the expression between males and females. Thus, it seems unlikely that they are a key factor to initiate the divergence leading to testicular or ovarian differentiation in R. rugosa.     

Sex-related differences in developmental rates of bovine embryos produced and cultured in vitro.

The classical concept of sex determination in mammals is that a Y chromosomal gene controls the development of the indifferent gonad into a testis. Subsequent divergence of sexual phenotypes is secondary to this gonadal determination. The most likely candidate gene is SRY (sex-determining region Y) in humans, and Sry in mouse. However, several lines of evidence indicate that sexual dimorphism occurs even before the indifferent gonad appears. Here we present evidence that bovine male embryos generally develop to more advanced stages than do females during the first 8 days after insemination in vitro. Corresponding relationships between both cell numbers and mitotic indices and sex were also seen. Although it is not clear whether this phenomenon involves factors originating before or after fertilization, these findings suggest that sex-related gene expression affects the development of embryos soon after activation of the embryonic genome and well before gonadal differentiation.     

Wnt4 expression in the differentiating gonad of the frog Rana rugosa

Wnt4, a member of the Wnt family, is known to influence the sex-determination cascade. In mice having a targeted deletion of Wnt4, masculinization occurs in XX pups. Therefore, in addition to Sry, Wnt4 is also involved in sex determination in mice. In humans, a chromosomal duplication of the WNT4 causes feminization of XY-individuals. Thus, for better understanding of the mechanism of sex determination in vertebrates, it is necessary to examine the expression of Wnt4 at early gonadal development stages in non-mammalians. We first isolated the Wnt4 cDNA from the tetsis of the frog Rana rugosa. R. rugosa Wnt4 had a high similarity (>86%) at the amino acid level with zebra fish, chicken, mouse, and human Wnt4s. We next employed RT-PCR analysis to examine whether Wnt4 was expressed in a sexually dimorphic fashion at early stages of gonadal development in R. rugosa. Wnt4 was transcribed first in the embryos at the late gastrula stage, and its expression was maintained until the indifferent gonad differentiated into a testis or an ovary. Wnt4 expression in the differentiating gonad appeared in a non-sexually dimorphic pattern. The results, taken together, suggest that Wnt4 is highly conserved through evolution, and that its expression in the indifferent gonad takes place with no sexual dimorphism. Thus, Wnt4 is not a key factor to initiate the development of a testis or an ovary from the indifferent gonads in R. rugosa. However, this gene probably forms part of a gonadal-development pathway in this species.     

中华鳖Dmrt1基因的克隆、表达及在性逆转中的变化分析

在大部分脊椎动物中,Dmrt1基因在雄性性别决定和性腺分化中起重要的调控作用.本文从m RNA和蛋白水平分析Dmrt1基因的组织差异性表达、在不同发育阶段性腺中的细胞定位及在性逆转中的表达变化,研究Dmrt1基因在中华鳖性别分化中的调控作用.Rapid-amplification of c DNA ends(RACE)结果显示,Dmrt1基因c DNA序列全长2409 bp,其中5′非编码区为230 bp,3′非编码区为1072 bp,开放阅读框为1107 bp,编码368个氨基酸,具有一个高度保守的DM结构域.荧光定量PCR和免疫组化结果显示,Dmrt1在性腺分化之前的第16期雄性性腺中开始表达,先于Amh和Sox9基因表达.随着性腺的发育,Dmrt1蛋白主要定位于性腺Sertoli细胞的细胞核上,在雌性性腺发育过程中并未见其表达.此外,在雌二醇诱导的雄性转雌性性逆转胚胎性腺中,Dmrt1表达显著下调;在芳香化酶抑制剂诱导的雌性转雄性性腺中,Dmrt1表达则显著上升.上述研究表明,Dmrt1基因是中华鳖雄性特异性基因,参与雄性性腺的发育过程,可能在中华鳖早期性别决定中起重要的调控作用.     

Response of candidate sex-determining genes to changes in temperature reveals their involvement in the molecular network underlying temperature-dependent sex determination

Gonadogenesis, the process of forming an ovary or a testis from a bipotential gonad, is critical to the development of sexually reproducing adults. Although the molecular pathway underlying vertebrate gonadogenesis is well characterized in organisms exhibiting genotypic sex determination, it is less well understood in vertebrates whose sex is determined by environmental factors. We examine the response of six candidate sex-determining genes to sex-reversing temperature shifts in a species with temperature-dependent sex determination (TSD). For the first time, we report the regulation of FoxL2, Wnt4, Dmrt1, and Mis by temperature, confirming their involvement in the molecular pathway underlying TSD and placing them downstream of the action of temperature. We find evidence that FoxL2 plays an ovarian-specific role in development, whereas Wnt4 appears to be involved in both testis and ovary formation. Dmrt1 expression shows rapid activation in response to a shift to male-producing temperature, whereas Mis up-regulation is delayed. Furthermore, early repression of Mis appears critical to ovarian development. We also investigate Dax1 and Sox9 and reveal that at the level of gene expression, response to temperature is comparatively later in gonadogenesis. By examining the role of these genes in TSD, we can begin to elucidate elements of conservation and divergence between sex-determining mechanisms.     

Gene structure, multiple alternative splicing, and expression in gonads of zebrafish Dmrt1

Many basic cellular processes are shared across vast phylogenetic distances, whereas sex-determining mechanisms are highly variable between phyla although the existence of two sexes is nearly universal in the animal kingdom. The only molecular similarity in sex determination found so far between phyla is among the fly doublesex, worm mab-3, and vertebrate Dmrt1/DMY, which contain a zinc-finger-like DNA-binding motif, DM domain. Here we report that three isoforms of the zebrafish Dmrt1 were generated in gonads by multiple alternative splicing, which encoded predicted proteins with 267, 246, and 132 amino acids, respectively. By cDNA cloning and genomic structure analysis, we found that there were seven exons of Dmrt1, which were alternatively spliced to generate the Dmrt1 isoforms. Northern blotting analysis revealed that expression of zebrafish Dmrt1 was higher in testis than ovary. Real time fluorescent quantitative RT-PCR indicated that expression of isoform a of Dmrt1 was dominantly higher than those of Dmrt1 b and c. Furthermore, in situ hybridization to gonads sections showed that Dmrt1 was expressed in developing germ cells of both testis and ovary, suggesting that the Dmrt1 gene is not only associated with testis development, but also, may be important in ovary differentiation of zebrafish.     

The expression pattern of a mouse doublesex-related gene is consistent with a role in gonadal differentiation

The signal for somatic sex determination in mammals, Caenorhabditis elegans and Drosophila melanogaster is chromosomal, but the overall mechanisms do not appear to be conserved between the phyla. However it has been found quite recently that the C. elegans sex-determining gene Mab-3 contains a domain highly homologous to the Drosophila sex-determining gene doublesex (dsx) and shares a similar role. These data suggest that at least some aspects of the regulation of sex determination might be conserved. In humans, a doublesex-related gene (DMRT1) was identified at less than 30 kb from the critical region for sex reversal on chromosome 9p24 (TD9). In order to get insights into the role of DMRT1 in sex determination/differentiation, we have isolated DMRT1 mouse homologue (Dmrt1) and analysed its expression pattern. The gene is expressed in the genital ridges of both sexes during the sex-determining switch and it shows male/female dimorphism at late stages of sex differentiation.     

Sex and the singular DM domain: insights into sexual regulation, evolution and plasticity

Most animals reproduce sexually, but the genetic and molecular mechanisms that determine the eventual sex of each embryo vary remarkably. DM domain genes, which are related to the insect gene doublesex, are integral to sexual development and its evolution in many metazoans. Recent studies of DM domain genes reveal mechanisms by which new sexual dimorphisms have evolved in invertebrates and show that one gene, Dmrt1, was central to multiple evolutionary transitions between sex-determining mechanisms in vertebrates. In addition, Dmrt1 coordinates a surprising array of distinct cell fate decisions in the mammalian gonad and even guards against transdifferentiation of male cells into female cells in the adult testis.     

Immunohistochemical detection and biological activities of CYP17 (P450c17) in the indifferent gonad of the frog Rana rugosa

Sex steroids play a crucial role in the gonad differentiation in various species of vertebrates. However, little is known regarding the localization and biological activity of steroid-metabolizing enzymes during gonadal sex differentiation in amphibians. In the present study, we showed by real-time RT-PCR analysis that the expression of CYP17, one of the key steroidogenic enzymes, was higher in the indifferent gonad during sex differentiation in male than in female tadpoles of Rana rugosa but that there was no difference detected in the 3betaHSD mRNA level between the male and female gonads. We next examined the localization of CYP17, 3betaHSD and 17betaHSD in the indifferent and differentiating gonads by using three kinds of antibodies specific for CYP17, 3betaHSD and 17betaHSD, respectively. Positive signals for CYP17, 3betaHSD and 17betaHSD were observed in somatic cells of the indifferent gonad of males and in the interstitial cell of the testis. The enzymatic activity of CYP17 was also examined in the gonad during sex differentiation in this species. [(3)H]Progesterone (Prog) was converted to [(3)H]androstenedione (AE) in the indifferent gonad in males and females, but the rate of its conversion was higher in males than in females. Moreover, fluorescence in situ hybridization (FISH) analysis revealed that the CYP17 gene was located on the q arm of chromosome 9, indicating that CYP17 was autosomal in R. rugosa. Taken together, the results demonstrate that the CYP17 protein is synthesized in somatic cells of the indifferent gonad during gonadal sex differentiation in R. rugosa and that it is more active in converting Prog to AE in males than in females. The data suggest that CYP17 may be involved in testicular formation during sex differentiation in this species.