A 11.7-kb deletion triggers intersexuality and polledness in goats.

Mammalian sex determination is governed by the presence of the sex determining region Y gene (SRY) on the Y chromosome. Familial cases of SRY-negative XX sex reversal are rare in humans, often hampering the discovery of new sex-determining genes. The mouse model is also insufficient to correctly apprehend the sex-determination cascade, as the human pathway is much more sensitive to gene dosage. Other species might therefore be considered in this respect. In goats, the polled intersex syndrome (PIS) mutation associates polledness and intersexuality. The sex reversal affects exclusively the XX individuals in a recessive manner, whereas the absence of horns is dominant in both sexes. The syndrome is caused by an autosomal gene located at chromosome band 1q43 (ref. 9), shown to be homologous to human chromosome band 3q23 (ref. 10). Through a positional cloning approach, we demonstrate that the mutation underlying PIS is the deletion of a critical 11.7-kb DNA element containing mainly repetitive sequences. This deletion affects the transcription of at least two genes: PISRT1, encoding a 1.5-kb mRNA devoid of open reading frame (ORF), and FOXL2, recently shown to be responsible for blepharophimosis ptosis epicanthus inversus syndrome (BPES) in humans. These two genes are located 20 and 200 kb telomeric from the deletion, respectively.

Mammalian sex reversal and intersexuality: deciphering the sex-determination cascade.

The sex-determination cascade constitutes a model of the exquisite mechanisms of gene regulation that lead to the development of mammalian embryos. The discovery of the sex-determining region of the Y chromosome (SRY) in the early 1990s was the first crucial step towards a general understanding of sex determination. Since then, several genes that encode proteins with a role in this cascade, such as WT1, SF-1, SOX9, DAX-1 and WNT4, have been identified. Many of the interactions between these proteins have still to be elucidated, while, no-doubt, others are still to be identified. The study of mammalian intersexes forms a promising way towards the identification of the still-missing genes and a comprehensive view of mammalian sex determination. Intersexuality in the goat, studied for over a century, will, presumably, bring to light new genes involved in the female sex-determination pathway.

Amplification of R-spondin1 signaling induces granulosa cell fate defects and cancers in mouse adult ovary.

R-spondin1 is a secreted regulator of WNT signaling, involved in both embryonic development and homeostasis of adult organs. It can have a dual role, acting either as a mitogen or as a tumor suppressor. During ovarian development, Rspo1 is a key factor required for sex determination and differentiation of the follicular cell progenitors, but is downregulated after birth. In human, increased RSPO1 expression is associated with ovarian carcinomas, but it is not clear whether it is a cause or a consequence of the tumorigenic process. To address the role of Rspo1 expression in adult ovaries, we generated an Rspo1 gain-of-function mouse model. Females were hypofertile and exhibited various ovarian defects, ranging from cysts to ovarian tumors. Detailed phenotypical characterization showed anomalies in the ovulation process. Although follicles responded to initial follicle-stimulating hormone stimulation and developed normally until the pre-ovulatory stage, they did not progress any further. Although non-ovulated oocytes degenerated, the surrounding follicular cells did not begin atresia. RSPO1-induced expression not only promotes canonical WNT signaling but also alters granulosa cell fate decisions by maintaining epithelial-like traits in these cells. This prevents follicle cells from undergoing apoptosis, leading to the accumulation of granulosa cell tumors that reactivates the epithelial program from their progenitors. Taken together, our data demonstrate that activation of RSPO1 is sufficient in promoting ovarian tumors and thus supports a direct involvement of this gene in the commencement of ovarian cancers.

Cloning and characterization of a full-length cDNA coding for ovine aldolase B from fetal mesonephros.

An ovine aldolase B cDNA was isolated from mesonephros (29 d pc). The sequence covers 1649 nucleotides. Comparison with human liver aldolase B cDNA shows a homology of about 86%. The deduced amino acid sequence is composed of 364 residues and exhibits 92% homology to the human protein. Northern blot analysis and in situ hybridization data show that during the first third of gestation in sheep, aldolase B expression is restricted to the mesonephros.

Characterization of ovine SRY transcript and developmental expression of genes involved in sexual differentiation.

In mammals, the presence of SRY, the sex-determining gene located on the Y chromosome is required to induce the gonadal anlage to differentiate as a testis, whereas its absence leads to the development of an ovary. We report here the characterization by 5' and 3' RACE analysis of several SRY transcripts which are expressed in the ovine male developing gonads. These transcripts were not detected in any other fetal tissues and were expressed only in the genital portion of the urogenital ridge. The temporal profile of SRY expression analyzed by RT-PCR suggests that in the sheep fetus the role of SRY is not limited to initiating Sertoli cell differentiation as in mice. Indeed, SRY transcripts persist after the full differentiation of the testis. In addition to SRY, other genes are known to be involved in mammalian sex determination: Wilms' tumor gene WT-1, steroidogenic factor gene Ftz-F1 (SF-1) and anti-Müllerian hormone (AMH). We investigated the expression patterns of these genes by RT-PCR during fetal development in sheep gonads. Concerning WT-1 and SF-1, our results are consistent with those described in mice where the earliest expression was detected before the sexual differentiation in both sexes. In male, the ontogenesis of AMH transcription corresponds to the seminiferous cords formation (30 dpc). In female, we have observed the presence of SF-1 transcripts from the undifferentiated stage until birth. In addition, P450 aromatase expression is detected from 30 dpc and is correlated with the presence of 17-beta estradiol in sheep ovary. These data reveal significant differences between rodent and ruminant models concerning the sex-determining pathway.

The ovine SOX2 gene: sequence, chromosomal localization and gonadal expression.

The SOX gene family consists of a large number of embryonically expressed genes capable of encoding putative transcription factors and related by a DNA-binding domain, the HMG-box. We cloned and characterized the ovine SOX2 transcript using the screening of a testis (12dpp) cDNA library with a probe containing the SRY-HMG-box and we performed 3'RACE experiments. The ovine SOX2 sequence is strongly conserved in comparison to the human, mouse and chicken homologues and is located on sheep chromosome 1q33. The SOX2 expression pattern in developing gonads is consistent with the hypothesis that this gene plays a role in the germ cell line.

Lack of expression of the mRNA encoding a major protein of the mouse vas deferens after neonatal exposure to oestrogens.

We have previously characterized an androgen-inducible secretory protein from the mouse vas deferens (MVDP), and a cDNA to its mRNA has been obtained. This report describes altered MVDP gene expression after neonatal exposure to oestrogens. As shown by immunohistochemistry and Western blot analysis, MVDP was missing in the vas deferens from adult mice neonatally exposed to oestrogens. Northern blot analysis showed that the expression of MVDP mRNA was also suppressed. Exogenous testosterone was unable to stimulate MVDP production (either message or protein) in neonatally oestrogenized males. The results suggest that the alterations in gene expression in the oestrogen-exposed vas deferens reflect changes in the programme of differentiation of the organ itself.

Expression studies of the PIS-regulated genes suggest different mechanisms of sex determination within mammals.

In mammals, the Y-located SRY gene is known to induce testis formation from the indifferent gonad. A related gene, SOX9, also plays a critical role in testis differentiation in mammals, in birds and reptiles. It is now assumed that SRY acts upstream of SOX9 in the sex determination cascade, but the regulatory link which should exist between these two genes remains unknown. Studies on XX sex reversal in polled goats (PIS mutation: Polled Intersex Syndrome) have led to the discovery of a female-specific locus crucial for ovarian differentiation. This genomic region is composed of at least two genes, FOXL2 and PISRT1, which share a common transcriptional regulatory region, PIS. In this review, we present the expression pattern of these PIS-regulated genes in mice. The FOXL2 expression profile of mice is similar to that described in goats in accordance with a conserved role of this ovarian differentiating gene in mammals. On the contrary, the PISRT1 expression profile is different between mice and goats, suggesting different mechanisms of the primary switch in the testis determination process within mammals. A model based on two different modes of SOX9 regulation in mice and other mammals is proposed in order to integrate our results into the current scheme of gonad differentiation.

Androgen dependence during development of the mouse vas deferens protein mRNA.

The mRNA encoding a major protein of the mouse vas deferens (MVDP) was first detected in 10-day-old males and its concentration increased sharply between 10 and 20 days, reaching adult levels at 40 days. This increase was not associated with an increase in tissular androgen concentrations. In 30-day-old mice castrated at birth or treated with cyproterone acetate over 29 days, MVDP mRNA levels were not abolished and were similar to those measured in 10- and 20-day-old controls. These results suggest that the neonatal expression of MVDP gene is independent of androgens. In addition, precocious accumulation of MVDP mRNA could be induced by injection of excess amounts of androgens in 20- but not in 10-day-old animals. The prepubertal increase in MVDP mRNA levels is androgen-dependent but other factors may be necessary for MVDP expression.

Androgen regulation of the mRNA encoding a major protein of the mouse vas deferens.

A cDNA encoding the major mouse vas deferens protein (MVDP) has been cloned and characterized. Using in situ hybridization we have identified the epithelial cells of the vas deferens as the site of synthesis of MVDP mRNA. Northern blot analysis suggests that a high level of an mRNA corresponding to the MVDP gene is present in the mouse vas deferens whereas the amount of MVDP mRNA in vas deferens of other species studied, or in other mouse tissues, even if present, is undetectable. Steady-state levels of MVDP mRNA are decreased by approximately 42% 3 days after castration but a significant hybridization signal is still observed even 50 days after castration. Testosterone treatment for 2 weeks is necessary to completely reverse the effect of castration. In vitro transcription assays on isolated nuclei showed that the hormonal induction of the MVDP gene is achieved mainly at transcriptional level.

Porcine Dax-1 gene: isolation and expression during gonadal development.

The identification of XY females carrying a duplication of a region of the X chromosome (Xp21) led to the hypothesis that a double dose of a gene in the duplicated region causes sex reversal (DSS; dosage sensitive sex reversal). A gene isolated from this region, named DAX-1 (DSS-AHC critical region on the X), encodes a new member of the nuclear hormone receptor family. Here, we describe the isolation of porcine Dax-1 and the analysis of its pattern of expression both during foetal development and in several adult tissues. Dax-1 is expressed in the adrenals, the pituitary gland and the gonads at various stages of differentiation. In gonads, Dax-1 expression starts between 21 and 23 days post coitum in both XX and XY urogenital ridges then continues to be expressed until adult age. The expression in these tissues indicates the involvement of DAX-1 in the development and the function of the reproductive system at multiple levels.

Testis determination in mammals: more questions than answers.

In humans, testis development depends on a regulated genetic hierarchy initiated by the Y-linked SRY gene. Failure of testicular determination results in the condition termed 46,XY gonadal dysgenesis (GD). Several components of the testis determining pathway have recently been identified though it has been difficult to articulate a cascade with the known elements of the system. It seems, however, that early gonadal development is the result of a network of interactions instead of the outcome of a linear cascade. Accumulating evidence shows that testis formation in man is sensitive to gene dosage. Haploinsufficiency of SF1, WT1 and SOX9 is responsible for 46,XY gonadal dysgenesis. Besides, data on SRY is consistent with possible dosage anomalies in certain cases of male to female sex reversal. 46,XY GD due to monosomy of distal 9p and 10q might also be associated with an insufficient gene dosage effect. Duplications of the locus DSS can lead to a failure of testicular development and a duplication of the region containing SOX9 has been implicated in XX sex reversal. Transgenic studies in mouse have shown, however, that this mammal is less sensitive to gene dosage than man. Here, we will try to put in place the known pieces of the jigsaw puzzle that is sex determination in mammals, as far as current knowledge obtained from man and animal models allows. We are certain that from this attempt more questions than answers will arise.

The genomic organization and DNA sequence of the mouse vas deferens androgen-regulated protein gene.

The gene for mouse vas deferens protein (MVDP) is expressed, under androgenic control, exclusively in the epithelial cells of the deferent duct. As a first step in correlating cell-specific and hormonal regulations with the structure of the gene, the complete sequence of the MVDP gene (11 kb) and 0.5 kb of the 5' flanking region have been determined. The size range for the 10 exons is 78 to 168 bp, whereas that of introns is 292 to 2833 bp. A major site of transcription is located on an A residue 46 nucleotides upstream from the A of the ATG initiation codon. A TATA (CATAA) box, a CAAT box, a GC-rich motif and a (5'-TGTTCT-3') element that closely resembles the consensus sequence of the androgen response elements are present in the 5' flanking region of the MVDP gene.

[Characterization of cDNA and of the gene corresponding to androgen-dependent protein of the vas deferens in mice]. / Caractérisation de l'ADNc et du gène correspondant à une protéine androgéno-dépendante du canal déférent de souris.

A 34.5 kDa abundant protein named MVDP (Mouse Vas Deferens Protein) is produced and secreted by vas deferens epithelial cells from adult mice. Steady-state levels of MVDP and its 1.4 kb mRNA are markedly decreased 30 days after castration. Testosterone treatment for 2 weeks is necessary to completely reverse the effect of castration. A cDNA encoding MVDP has been cloned and entirely sequenced. A protein of 316 amino acids encoded by an open reading frame of 948 nucleotides shows 82% homology with a human placental aldose reductase. A gene corresponding to MVDP cDNA has been recently isolated ans characterized. The gene extends over approximately 11 kb and consists of 10 exons. Its structure is very similar to that of the human aldose reductase gene. The promotor region of MVDP gene contains an androgen responsive element consensus located 97 nucleotides upstream the transcription initiation site.

Telling the story of XX sex reversal in the goat: highlighting the sex-crossroad in domestic mammals.

The conditions for sex reversal in vertebrate species have been studied extensively and have highlighted numerous key factors involved in sex differentiation. We review here the history of the development of knowledge, referring to one example of complete female-to-male XX sex reversal associated with a polled phenotype in the goat. The results and hypotheses concerning this polled intersex syndrome (PIS) are then presented, firstly with respect to the transcriptional regulatory effects of the PIS mutation, and secondly regarding the role of the main ovarian-differentiating factor in this PIS locus, the FOXL2 gene.

Attempt to rescue sex-reversal by transgenic expression of the PISRT1 gene in XX PIS-/- goats.

The Polled Intersex Syndrome (PIS mutation) in goats leads to an absence of horn and to an early sex-reversal of the XX gonads. This mutation is a deletion of an 11.7-kb DNA fragment showing a tissue-specific regulatory activity. Indeed, in XX PIS(-/-) gonads the deletion of PIS leads to the transcriptional extinction of at least 3 neighboring genes, FOXL2, PFOXic and PISRT1. Among them, only FOXL2 is a 'classical' gene, encoding a highly conserved transcription factor. On the other hand, knock-out of Foxl2 in mice results in an early blocking of follicle formation without sex-reversal. This phenotype discrepancy leads to two hypotheses, either FOXL2 is responsible for XX sex-reversal in goat assuming distinct functions of its protein during ovarian differentiation in different mammals, or other PIS-regulated genes are involved. To assess the second possibility, PISRT1 expression was constitutively restored in XX PIS(-/-) gonads. Six transgenic fetuses were obtained by nuclear transfer and studied at 2 developmental stages, 41 and 46 days post-reconstruction. The gonads of these fetuses appear phenotypically identical to those of cloned non-transgenic controls. Conclusively, this result argues for FOXL2 being responsible for the PIS gonad-associated phenotype. Its invalidation in goat will help to better understand this complex syndrome.

Goat PRND expression pattern suggests its involvement in early sex differentiation.

Expression of the goat prion protein gene locus was assessed by reverse transcriptase-polymerase chain reaction on testes and ovaries at various developmental stages. A weak and stochastic expression of the PRNP and PRNT genes was observed. For PRNT, it is consistent with the detected deletions of two single nucleotides within its open reading frame in ruminant genes. PRND was expressed in both tissues at all stages. Whereas its expression is constant in the ovaries, it increases in testes between 36 and 46 days postcoitum (dpc) and remains high thereafter. In testes, Doppel was found in the nucleus of germinal cells and in the cytoplasm of Leydig cells at 44 dpc. It was detected in the cytoplasm of Leydig cells and of some Sertoli and germinal cells at 62 dpc. In the ovaries, it was observed in the nucleus of germinal cells at 44 dpc and mainly in their cytoplasm at 62 dpc. This expression pattern was shown to parallel that of C-kit and suggests Doppel involvement in early testis differentiation.

Reverse transcription-polymerase chain reaction analysis of genes involved in gonadal differentiation in pigs.

In mammals, testis development is initiated in the embryo as a response to the expression of the sex-determining gene, SRY. The time course of SRY expression during gonadal differentiation in the male has been described in detail only in mice and sheep. In this study, we used reverse transcription-polymerase chain reaction analysis to define the SRY transcription profile in pig genital ridges. SRY transcripts were first detectable from 23 days postcoitum (dpc), then declined sharply after 35 dpc. None were detected at 60 dpc. In addition, we analyzed temporal expression of other genes known to be involved in mammalian sex determination: WT-1, SF-1, SOX9, and AMH. A key stage seems to be 28 dpc, in which SOX9 expression switches between the male and female, and AMH expression begins to attest to Sertoli cell differentiation and to correspond to seminiferous cord formation in the male. Expression of gonadotropin receptors and aromatase was also investigated in porcine gonads, and we showed that their transcripts were detected very early on, especially in the male: 25 dpc for the LH receptor (rLH) and aromatase, and 28 dpc for the FSH receptor (rFSH). In the female, aromatase transcripts were not detected until 70 dpc, and rFSH expression occurred later: at 45 dpc at the onset of meiosis. Moreover, no difference was observed between the sexes for the onset of rLH transcription at 25 dpc. Such a thorough study has never been performed on pigs; developmental analysis will be useful for investigating sex-reversed gonads and determining ontogeny in intersexuality, a common pathology in pigs.

Mammalian gonadal differentiation: the pig model.

In mammals, testicular differentiation is initiated by SRY (the sex-determining region of the Y chromosome) gene expression in Sertoli cell precursors, followed by upregulation of the SOX9 gene (SRY-related HMG box gene 9). Subsequently, differentiated testis produces two hormones that induce sexual differentiation of the internal and external genital tract. Knowledge of the molecular mechanisms involved in gonadal differentiation has increased greatly over the past decade. Several genes are involved in genital ridge formation in both sexes, and others act specifically in testicular or ovarian developmental pathways. As for other mammals, relatively few data are available on the first steps of ovarian differentiation in pigs. In this review, the expression profiles of most genes known to be involved in gonadal differentiation in pigs will be presented and compared with those observed in mice. The main feature of gonadal differentiation in the pig is fetal steroidogenesis, especially cytochrome P450 aromatase gene organization and expression. Another specific feature of gonadal differentiation in pigs is the appearance of numerous cases of XX sex-reversed animals. This intersex condition occurs as early as day 50 after coitus, during embryogenesis, and appears to be triggered genetically. It leads to a wide range of phenotypes, strikingly similar to those observed in humans. Identification of the genes involved in this pathology will improve our knowledge of mammalian gonadal differentiation and may allow the eradication of this genetic disease in pigs.