A duplication in a patient with 46,XX ovo-testicular disorder of sex development refines the SOX9 testis-specific regulatory region to 24 kb.

A custom CGH microarray that covers the SOX9 regulatory region. Log2 ratio scatterplot showing individual data points. Blue box highlights copy number gain with 3' breakpoint region magnified.

DMRT1 is required for Müllerian duct formation in the chicken embryo.

DMRT1 is a conserved transcription factor with a central role in gonadal sex differentiation. In all vertebrates studied, DMRT1 plays an essential function in testis development and/or maintenance. No studies have reported a role for DMRT1 outside the gonads. Here, we show that DMRT1 is expressed in the paired Müllerian ducts in the chicken embryo, where it is required for duct formation. DMRT1 mRNA and protein are expressed in the early forming Müllerian ridge, and in cells undergoing an epithelial to mesenchyme transition during duct morphogenesis. RNAi-mediated knockdown of DMRT1 in ovo causes a greatly reduced mesenchymal layer, which blocks caudal extension of the duct luminal epithelium. Critical markers of Müllerian duct formation in mammals, Pax2 in the duct epithelium and Wnt4 in the mesenchyme, are conserved in chicken and their expression disrupted in DMRT1 knockdown ducts. We conclude that DMRT1 is required for the early steps of Müllerian duct development. DMRT1 regulates Müllerian ridge and mesenchyme formation and its loss blocks caudal extension of the duct. While DMRT1 plays an important role during testis development and maintenance in many vertebrate species, this is the first report showing a requirement for DMRT1 in Müllerian duct development.

Avian sex determination: what, when and where?

Sex is determined genetically in all birds, but the underlying mechanism remains unknown. All species have a ZZ/ZW sex chromosome system characterised by female (ZW) heterogamety, but the chromosomes themselves can be heteromorphic (in most birds) or homomorphic (in the flightless ratites). Sex in birds might be determined by the dosage of a Z-linked gene (two in males, one in females) or by a dominant ovary-determining gene carried on the W sex chromosome, or both. Sex chromosome aneuploidy has not been conclusively documented in birds to differentiate between these possibilities. By definition, the sex chromosomes of birds must carry one or more sex-determining genes. In this review of avian sex determination, we ask what, when and where? What is the nature of the avian sex determinant? When should it be expressed in the developing embryo, and where is it expressed? The last two questions arise due to evidence suggesting that sex-determining genes in birds might be operating prior to overt sexual differentiation of the gonads into testes or ovaries, and in tissues other than the urogenital system.

SOX8 expression during chick embryogenesis.

We have isolated the SOX8 gene from the chicken embryo. This gene shows a high degree of sequence homology to SOX9 and SOX10. Detailed analysis of SOX8 expression by whole-mount in situ shows a dynamic and restricted expression pattern during chick development. SOX8 is expressed in the somitic derivative, the dermomyotome, the developing heart, pancreas, enteric neurone system, limb and the neural tube. This is the first detailed expression analysis of SOX8 in any species

Isolation and expression of a novel member of the CITED family.

Chicken CITED3 (cCITED3) is a novel gene, which is expressed in the pre-somitic mesoderm, the mesonephric tubules, the Wolffian ducts and collecting tubules of the developing urogenital system and in the cranial sensory ganglia. Sequence analysis revealed that cCITED3 encodes a protein which contains two conserved domains that have been described for members of the CITED family.

Gene expression during gonadogenesis in the chicken embryo.

Genes implicated in vertebrate sex determination and differentiation were studied in embryonic chicken gonads using reverse transcription and the polymerase chain reaction (RT-PCR). Expression profiles were obtained during gonadal sex differentiation for AMH, SOX9, SOX3, the Wilm's Tumour gene, WT1, and the orphan nuclear receptor genes, SF1 and DAX1. Some of these genes showed sexually dimorphic expression profiles during gonadal development, whereas others were expressed at similar levels in both sexes. The gene encoding Anti-Müllerian hormone (AMH) was expressed in both sexes prior to and during sexual differentiation of the gonads, with levels of expression consistently higher in males than in females. SOX9 expression was male-specific, and was up-regulated after the detection of AMH transcripts. SOX3 expression was observed prior to clear SOX9 expression and was up-regulated in both sexes at the onset of gonadal sex differentiation (but declined later in development). The WT1 gene was highly expressed in both sexes, whereas SF1 expression was clearly higher in developing ovaries compared to testes. DAX1 transcripts were observed in both sexes at all stages examined, but expression appeared somewhat higher in developing ovaries. These expression profiles are analysed in terms of current theories of vertebrate sex determination.

Temperature-dependent sex determination in the American alligator: expression of SF1, WT1 and DAX1 during gonadogenesis.

Sex determination in mammals and birds is chromosomal, while in many reptiles sex determination is temperature dependent. Morphological development of the gonads in these systems is conserved, suggesting that many of the genes involved in gonad development are also conserved. The genes SF1, WT1 and DAX1 play various roles in the mammalian testis-determining pathway. SF1 and WT1 are thought to interact to cause male-specific gene expression during testis development, while DAX1 is believed to inhibit this male-specific gene expression. We have cloned SF1 and DAX1 from the American alligator, a species with temperature-dependent sex determination (TSD). SF1, DAX1 and WT1 are expressed in the urogenital system/gonad throughout the period of alligator gonadogenesis which is temperature sensitive. SF1 appears to be expressed at a higher level in females than in males. This SF1 expression pattern is concordant with the observed pattern during chicken gonadogenesis, but opposite to that observed during mouse gonadogenesis. Although the observed sexual dimorphism of gonadal SF1 expression in alligators and chickens is opposite that observed in the mouse, it is probable that SF1 is involved in control of gonadal steroidogenesis in all these vertebrates. DAX1 and WT1 are both expressed during stages 22-25 of both males and females. However, there appear to be no sex differences in the expression patterns of these genes. We conclude that DAX1, WT1 and SF1 may be involved in gonadal development of the alligator. These genes may form part of a gonadal-development pathway which has been conserved through vertebrate evolution.

Cloning and expression of a DAX1 homologue in the chicken embryo.

DAX1 is an unusual member of the orphan nuclear receptor family of transcription factors. Mutations in human DAX1 cause X-linked adrenal hypoplasia congenita, while abnormal duplication of the gene is responsible for male-to-female dosage-sensitive sex reversal. Based on these and other observations, DAX1 is thought to play a role in adrenal and gonadal development in mammals. As DAX1 has not previously been described in any other vertebrate, a putative avian DAX1 clone was isolated from an embryonic chicken (Gallus domesticus) urogenital ridge cDNA library. The expression profile of this cDNA was then examined during gonadogenesis. The clone included the conserved 3' ligand-binding motif identified in humans and mice but the 5' region lacked the repeat motif thought to specify a DNA-binding domain in mammals. Southern blot analysis and fluorescence in situ hybridisation mapping showed that the gene is autosomal, located on chromosome 1q. Sequence comparisons showed that the putative chicken DAX1 protein has 63 and 60% identity with the human and mouse proteins respectively over the region of the conserved ligand-binding domain. However, stronger identity (74%) exists with a putative alligator DAX1 sequence over the same region. Northern blotting detected a single 1.4 kb transcript in late embryonic chicken gonads, while RNase protection assays revealed expression in the embryonic gonads of both sexes during the period of sexual differentiation. Expression increased in both sexes during gonadogenesis, but was higher in females than in males. This is the first description of a DAX1 homologue in a non-mammalian vertebrate.

Gonadal sex differentiation in chicken embryos: expression of estrogen receptor and aromatase genes.

Estrogen is implicated in sexual differentiation of the avian gonad. Expression of the estrogen receptor and aromatase genes was therefore examined at the time of gonadal sex differentiation in chicken embryos, using reverse transcription and the polymerase chain reaction (RT-PCR). Estrogen receptor (cER) transcripts were detected in the gonads of both presumptive sexes at embryonic days 4.5, 5.5 and 6.5, and in female but not male urogenital tissues at day 3.5. Aromatase (cAROM) transcripts were detected in female but not male gonads from day 6.5 of embryogenesis, and in adult gonads of both sexes. Both female and male embryos thus express cER mRNA before morphological differentiation of the gonads, which begins on day 5, whereas cAROM expression begins at or shortly after the onset of differentiation and is female-specific. Examination of other tissues showed that, in 5.5-day-old embryos, cER expression was limited to the gonads; no transcripts were detected in the mesonephric kidney, liver, brain, hindlimb or heart of either sex. In 9.5-day-old female embryos, cER and cAROM transcripts were present in both the left (ovarian) and the right (regressing) gonads. Altogether, these observations imply that the gonads of both sexes develop the capacity to respond to estrogens early in embryogenesis, before morphological differentiation, whereas the capacity to synthesize estrogens is female-specific and occurs later, at the time of differentiation. These observations are consistent with estrogens having a key role in ovarian development.

Factors affecting the concentrations of lead in British wheat and barley grain.

The entry of Pb into the food chain is of concern as it can cause chronic health problems. The concentration of Pb was determined in cereal grain samples collected representatively from British Cereal Quality Surveys in 1982 and 1998 (n = 176, 250 and 233 for wheat collected in 1982 and 1998, and barley in 1998, respectively). In addition, paired soil and grain samples were collected from 377 sites harvested across Britain in 1998-2000. Wheat grain Pb ranged from below the analytical detection limit (0.02 mg kg(-1) dry weight, DW) to 1.63 mg kg(-1) DW, and barley grain Pb from <0.02 to 0.48 mg kg(-1) DW. The vast majority of samples (>99% for both wheat and barley, excluding Scottish barley samples collected in 2000) were well below the newly introduced EU limit for the maximum permissible concentration of Pb in cereals (0.2 mg kg(-1) fresh weight, equivalent to 0.235 mg kg(-1) DW). There was a significant reduction in wheat grain Pb in the 1998 survey compared with the 1982 survey. However, 40 barley samples collected from Scotland in 2000 in the paired soil and crop survey showed anomalously high concentrations of Pb, with 10 samples exceeding the EU limit. Washing experiments demonstrated that surface contamination, introduced during grain harvest and/or storage, was the main reason for the high concentrations in these samples. In the paired soil and crop surveys, there were no significant correlations between grain Pb concentrations with total soil Pb and other soil properties, indicating low bioavailability of Pb in the soils and limited uptake and transport of Pb to grain. The Pb in cereal grain is likely to originate mainly from atmospheric deposition and other routes of surface contamination during harvest and storage.

The molecular genetics of ovarian differentiation in the avian model.

In birds as in mammals, sex is determined at fertilization by the inheritance of sex chromosomes. However, sexual differentiation - development of a male or female phenotype - occurs during embryonic development. Sex differentiation requires the induction of sex-specific developmental pathways in the gonads, resulting in the formation of ovaries or testes. Birds utilize a different sex chromosome system to that of mammals, where females are the heterogametic sex (carrying Z and W chromosomes), while males are homogametic (carrying 2 Z chromosomes). Therefore, while some genes essential for testis and ovarian development are conserved, important differences also exist. Namely, the key mammalian male-determining factor SRY does not exist in birds, and another transcription factor, DMRT1, plays a central role in testis development. In contrast to our understanding of testis development, ovarian differentiation is less well-characterized. Given the presence of a female-specific chromosome, studies in chicken will provide insight into the induction and function of female-specific gonadal pathways. In this review, we discuss sexual differentiation in chicken embryos, with emphasis on ovarian development. We highlight genes that may play a conserved role in this process, and discuss how interaction between ovarian pathways may be regulated.

Redd1 is a novel marker of testis development but is not required for normal male reproduction.

In an effort to identify novel candidate genes involved in testis determination, we previously used suppression subtraction hybridisation PCR on male and female whole embryonic (12.0-12.5 days post coitum) mouse gonads. One gene to emerge from our screen was Redd1. In the current study, we demonstrate by whole-mount in situ hybridisation that Redd1 is differentially expressed in the developing mouse gonad at the time of sex determination, with higher expression in testis than ovary. Furthermore, Redd1 expression was first detected as Sry expression peaks, immediately prior to morphological sex determination, suggesting a potential role for Redd1 during testis development. To determine the functional importance of this gene during testis development, we generated Redd1-deficient mice. Morphologically, Redd1-deficient mice were indistinguishable from control littermates and showed normal fertility. Our results show that Redd1 alone is not required for testis development or fertility in mice. The lack of a male reproductive phenotype in Redd1 mice may be due to functional compensation by the related gene Redd2.

Expression of Wsb2 in the developing and adult mouse testis.

We present a detailed study of the expression pattern of WD repeat and SOCS box-containing 2 (Wsb2) in mouse embryonic and adult gonads. Wsb2 was previously identified in a differential screen aimed at identifying the genes involved in male- and female-specific gonadal development. Wsb2 expression was analysed during mouse gonadogenesis by real-time PCR, whole-mount and section in situ hybridisation and immunofluorescence. Wsb2 mRNA expression was initially detected in gonads of both sexes from 11.5 days post coitum (dpc) until 12.0 dpc. By 12.5 dpc and thereafter, Wsb2 expression rapidly decreased in the female, while persisting in the male gonads. In foetal, newborn and juvenile testes, Wsb2 mRNA and protein were readily detected in the seminiferous cords within both Sertoli and germ cells. Wsb2 mRNA was present in spermatogonia, spermatocytes and in Sertoli cells of the adult mouse testis. The differential expression of Wsb2 in male versus female embryonic gonads suggests some male-specific role in gonad development, and its expression in the first wave of spermatogenesis indicates a role in germ cells. Real-time analysis of adult mouse testis tubules cultured in the presence of the Hedgehog signalling inhibitor, cyclopamine, showed a downregulation of Wsb2 mRNA after treatment which suggests that Wsb2 may be a target of Hedgehog signalling.

Characterisation of urogenital ridge gene expression in the human embryonal carcinoma cell line NT2/D1.

The study of the mammalian sex-determining pathway has been hampered by the lack of cell culture systems to investigate the underlying molecular relationships between sex-determining genes. Recent approaches using high-throughput genome-wide studies have revealed a number of sexually dimorphic genes expressed in the developing mouse gonad. Here, we investigated a human testicular cell line in terms of its expression of known sex-determining genes and newly identified candidates. The human embryonal carcinoma cell line NT2/D1 was screened for the expression of 46 genes with known or potential roles in the sex-determining and differentiation pathway. Forty genes tested were expressed in NT2/D1 cells including the testis-determining genes SRY, SOX9, SF-1, DHH and FGF9. Genes not expressed included WT1, DAX1 and the ovary-specific genes FOXL2 and WNT4. Cell-specific markers demonstrate that NT2/D1 cells reflect a number of cell types in the gonad including Sertoli, Leydig and germ cells. Our results suggest that male pathways initiated by SRY, SOX9 and SF-1 remain intact in these cells. Lack of expression of ovary-specific genes is consistent with a commitment of these cells to the male lineage. Manipulation of gene expression in this cell line could be an important new in vitro tool for the discovery of new human sex-determining genes.

Novel scavenger receptor gene is differentially expressed in the embryonic and adult mouse testis.

In an effort to understand the mechanisms that underpin gonadal differentiation at the time of sex determination, we identified a cDNA encoding a putative novel testis expressed scavenger receptor, Tesr. Based on its domain structure, we hypothesize that the function of Tesr is similar to that of other scavenger receptors that play roles in phagocytosis of apoptotic cells, cell-cell adhesion, and defense. Tesr mRNA was detected in fetal mouse gonads of both sexes at 11.5 days post coitum (dpc). From 12.0 dpc, Tesr expression rapidly decreased in the female and was maintained in the male. Expression was seen in embryonic mouse sites other than the testis, such as in brain, eye, head, heart, neural arch, and cartilage primordium. Tesr expression in the newborn testis was faint to undetectable, but it increased from 2 days postpartum (dpp) until 15 dpp and was found in a subset of interstitial cells and in germ and Sertoli cells. Tesr mRNA in the adult mouse testis was observed in Sertoli cells, spermatogonia, spermatocytes, round spermatids, and in a subset of interstitial cells. We conclude that Tesr is differentially expressed in the male vs. female embryonic gonad and is expressed in both the ovary and the testes postnatally after 2 dpp.

Human sex determination.

Human sex determination is a fascinating topic, particularly at the level of molecular genetics, as it represents an excellent paradigm for mammalian organ development. Recent progress has seen the addition of several new pieces to this developmental jigsaw puzzle. In mammals, the Y chromosome is male determining, and encodes a gene referred to as TDF (testis-determining factor), which induces the indifferent embryonic gonad to develop as a testis. Subsequent male sexual differentiation is largely a consequence of hormonal secretion from the testis. In the absence of the Y chromosome, the testis-determining pathway fails to be initiated, and the embryonic gonad develops as an ovary, resulting in female development. (Ford et al. [1959] Lancet i:711; Jacobs and Strong [1959] Nature, 183:302-303; Jost et al. [1973] Rec. Prog. Horm. Res., 29:1-41).

Rapid DNA extraction and PCR-sexing of mouse embryos.

We have devised a PCR-based sexing method that is quick, simple, and highly reproducible. DNA is first extracted from embryonic mouse yolk sac via a 15 min, two-step incubation procedure utilizing PCR-compatible proteinase K buffer. Without any further manipulation the lysate is subjected to 30 cycles of PCR, optimized to run in less than 1 hr. The reaction includes multiplexed primer pairs for Sry and Myog (myogenin) that generate a male specific band of 441 bp and an internal control band of 245 bp, respectively. This robust method is used routinely in our laboratory and gives rapid genotyping results with 98% reliability and 100% accuracy.

Sex, genes, and heat: triggers of diversity.

In vertebrates, sex is determined by a surprising variety of mechanisms. In many reptiles, the primary testis or ovary-determining trigger is regulated by egg incubation temperature. This temperature dependent sex determining (TSD) mechanism occurs in all crocodilians and marine turtles examined to date and is common in terrestrial turtles and viviparous lizards (Ewert et al. 1994. J Exp Zool 270:3-15; Lang and Andrews. 1994. J Exp Biol 270:28-44; Mrosovsky. 1994. J Exp Zool 270:16-27; Pieau. 1996. Bioessays 18:19-26; Viets et al. 1994. J Exp Zool 270:45-56; Wibbels et al. 1998. J Exp Zool 281:409-416). In contrast, sex in mammals and birds is determined chromosomally (CSD). Despite these differences, morphological development of the gonads in all these vertebrate groups appears to have been conserved through evolution. Therefore, the genetic mechanisms triggering sex determination appear not to have been conserved through evolution, although the basic genetic pathway controlling the morphological differentiation of the gonads appears to have been conserved.

Sex determination in the chicken embryo.

The chicken embryo represents a suitable model for studying vertebrate sex determination and gonadal sex differentiation. While the basic mechanism of sex determination in birds is still unknown, gonadal morphogenesis is very similar to that in mammals, and most of the genes implicated in mammalian sex determination have avian homologues. However, in the chicken embryo, these genes show some interesting differences in structure or expression patterns to their mammalian counterparts, broadening our understanding of their functions. The novel candidate testis-determining gene in mammals, DMRT1, is also present in the chicken, and is expressed specifically in the embryonic gonads. In chicken embryos, DMRT1 is more highly expressed in the gonads and Müllerian ducts of male embryos than in those of females. Meanwhile, expression of the orphan nuclear receptor, Steroidogenic Factor 1 (SF1) is up-regulated during ovarian differentiation in the chicken embryo. This contrasts with the expression pattern of SF1 in mouse embryos, in which expression is down-regulated during female differentiation. Another orphan receptor initially implicated in mammalian sex determination, DAX1, is poorly conserved in the chicken. A chicken DAX1 homologue isolated from a urogenital ridge library lacked the unusual DNA-binding motif seen in mammals. Chicken DAX1 is autosomal, and is expressed in the embryonic gonads, showing somewhat higher expression in female compared to male gonads, as in mammals. However, expression is not down-regulated at the onset of testicular differentiation in chicken embryos, as occurs in mice. These comparative data shed light on vertebrate sex determination in general.

Gene mapping in marsupials: detection of an ancient autosomal gene cluster.

The genes HRAS, HBB, and CAT, which are located together on the short arm of human chromosome 11, appear to be part of a conserved synteny group found in many eutherian mammals. These genes were mapped to the chromosomes of two marsupial (metatherian) species by in situ hybridization. All three genes were located together on chromosome 3 in Macropus eugenii. Only HRAS and CAT were used to probe Dasykaluta rosamondae metaphases and these genes both mapped to chromosome 4. This suggests that the HRAS-HBB-CAT gene cluster has been conserved at least since the metatherians and eutherians diverged some 130 million years ago. These findings support the concept of a mammalian genome that has remained highly conserved throughout evolution.