Structural and functional characterization of the mouse Sox9 promoter: implications for campomelic dysplasia. (1/758)

Mutations in SOX9 cause campomelic dysplasia (CD), a dominant skeletal dysmorphology and XY sex reversal syndrome. The CD phenotype is sensitive to dosage and expression levels of SOX9. Sox9 is expressed during chondrocyte differentiation and is up-regulated in male and down-regulated in female genital ridges during sex differentiation. In order to study the sex- and tissue-specific regulation of Sox9, we have defined the transcription start site and characterized the mouse Sox9 promoter region. The Sox9 proximal promoter shows moderately high nucleotide similarity between mouse and human. Transient transfection experiments using various deletion constructs of the 6.8 kb upstream region of mouse Sox9 fused to a luciferase reporter showed that the interval between 193 and 73 bp from the transcription start site is essential for maximal promoter activity in cell lines and in primary male and female gonadal somatic cells and liver cells isolated from 13.5 d.p.c. mouse embryos. This minimal promoter region was shown by DNase I hypersensitive site assay to be in an 'open' state of chromatin structure in gonads of both sexes, but not in the liver. Promoter activity was higher in testis than in ovary and liver, but deletion of the region from -193 to -73 bp abolished this difference. We conclude that the proximal promoter region is in part responsible for the sex- and tissue-specific expression of the Sox9 gene and that more distal positive and negative elements contribute to its regulation in vivo, consistent with the observation that translocations upstream from SOX9 can result in campomelic dysplasia.  (+info)

Temperature-dependent sex determination: upregulation of SOX9 expression after commitment to male development. (2/758)

In mammals, birds and reptiles the morphological development of the gonads appear to be conserved. This conservation is evident despite the different sex determining switches employed by these vertebrate groups. Mammals exhibit chromosomal sex determination (CSD) where the key sex determining switch is the Y-linked gene, SRY. Although SRY is the trigger for testis determination in mammals, it is not conserved in other vertebrate groups. However, a gene closely related to SRY, the highly conserved transcription factor, SOX9, plays an important role in the testis pathway of mammals and birds. In contrast to the CSD mechanism evident in mammals and birds, many reptiles exhibit temperature dependent sex determination (TSD) where the egg incubation temperature triggers sex determination. Here we examine the expression of SOX9 during gonadogenesis in the American alligator, (Alligator mississippiensis), a reptile that exhibits TSD. Alligator SOX9 is expressed in the embryonic testis but not in the ovary. However, the timing of SOX9 upregulation in the developing testis is not consistent with a role for this gene in the early stages of alligator sex determination. Since SOX9 upregulation in male embryos coincides with the structural organisation of the testis, SOX9 may operate farther downstream in the vertebrate sex differentiation pathway than previously postulated.  (+info)

Regulation and role of Sox9 in cartilage formation. (3/758)

The HMG-domain transcription factor Sox9 is a known regulator of the type II collagen gene, a major developmentally regulated protein of cartilage. In order to place Sox9 function in skeletogenesis we have investigated the regulation and misexpression of Sox9 in avian embryos. Application of exogenous BMP2 to chick limbs resulted in upregulation of Sox9, concomitant with induction of ectopic cartilage. Ectopic expression of the BMP antagonist Noggin in the limb resulted in loss of Sox9 expression from the developing digits, indicating that Sox9 expression during chondrogenesis is BMP dependent. Misexpression of Sox9 in vivo resulted in ectopic cartilage formation in limbs and in vitro was able to change the aggregation properties of limb mesenchymal cells, suggesting that Sox9 functions at the level of mesenchymal cell condensation. Misexpression of Sox9 in dermomyotomal cells, which normally give rise to the axial musculature and dermis, can result in the diversion of these cells from their normal fates towards the cartilage differentiation programme. These cells not only express type II collagen, but also Pax1, a marker of ventral fate in the developing somite. This suggests that the cell fate decision to follow the cartilage differentiation pathway is regulated at an early stage by Sox9.  (+info)

Mesonephric cell migration induces testis cord formation and Sertoli cell differentiation in the mammalian gonad. (4/758)

In mammals a single gene on the Y chromosome, Sry, controls testis formation. One of the earliest effects of Sry expression is the induction of somatic cell migration from the mesonephros into the XY gonad. Here we show that mesonephric cells are required for cord formation and male-specific gene expression in XY gonads in a stage-specific manner. Culturing XX gonads with an XY gonad at their surface, as a 'sandwich', resulted in cell migration into the XX tissue. Analysis of sandwich gonads revealed that in the presence of migrating cells, XX gonads organized cord structures and acquired male-specific gene expression patterns. From these results, we conclude that mesonephric cell migration plays a critical role in the formation of testis cords and the differentiation of XY versus XX cell types.  (+info)

Campomelic dysplasia translocation breakpoints are scattered over 1 Mb proximal to SOX9: evidence for an extended control region. (5/758)

Campomelic dysplasia (CD), a skeletal malformation syndrome with or without XY sex reversal, is usually caused by mutations within the SOX9 gene on distal 17q. Several CD translocation and inversion cases have been described with breakpoints outside the coding region, mapping to locations >130 kb proximal to SOX9. Such cases are generally less severely affected than cases with SOX9 coding-region mutations, as is borne out by three new translocation cases that we present. We have cloned the region extending 1.2 Mb upstream of the SOX9 gene in overlapping bacterial-artificial-chromosome and P1-artificial-chromosome clones and have established a restriction map with rare-cutter enzymes. With sequence-tagged-site-content mapping in somatic-cell hybrids, as well as with FISH, we have precisely mapped the breakpoints of the three new and of three previously described CD cases. The six CD breakpoints map to an interval that is 140-950 kb proximal to the SOX9 gene. With exon trapping, we could isolate five potential exons from the YAC 946E12 that spans the region, four of which could be placed in the contig in the vicinity of the breakpoints. They show the same transcriptional orientation, but only two have an open reading frame (ORF). We failed to detect expression of these fragments in several human and mouse cDNA libraries, as well as on northern blots. Genomic sequence totaling 1,063 kb from the SOX9 5'-flanking region was determined and was analyzed by the gene-prediction program GENSCAN and by a search of dbEST and other databases. No genes or transcripts could be identified. Together, these data suggest that the chromosomal rearrangements most likely remove one or more cis-regulatory elements from an extended SOX9 control region.  (+info)

Functional and structural studies of wild type SOX9 and mutations causing campomelic dysplasia. (6/758)

In humans, mutations in SOX9 result in a skeletal malformation syndrome, campomelic dysplasia (CD). The present study investigated two major classes of CD mutations: 1) point mutations in the high mobility group (HMG) domain and 2) truncations and frameshifts that alter the C terminus of the protein. We analyzed the effect of one novel mutation and three other point mutations in the HMG domain of SOX9 on the DNA binding and DNA bending properties of the protein. The F12L mutant HMG domain shows negligible DNA binding, the H65Y mutant shows minimal DNA binding, whereas the A19V mutant shows near wild type DNA binding and bends DNA normally. Interestingly, the P70R mutant has altered DNA binding specificity, but also bends DNA normally. The effects of the point mutations were interpreted using a molecular model of the SOX9 HMG domain. We analyzed the effects upon transcription of mutations resembling the truncation and frameshift mutations in CD patients, and found that progressive deletion of the C terminus causes progressive loss of transactivation. Maximal transactivation by SOX9 requires both the C-terminal domain rich in proline, glutamine, and serine and the adjacent domain composed entirely of proline, glutamine, and alanine. Thus, CD arises by mutations that interfere with DNA binding by SOX9 or truncate the C-terminal transactivation domain and thereby impede the ability of SOX9 to activate target genes during organ development.  (+info)

Reverse transcription-polymerase chain reaction analysis of genes involved in gonadal differentiation in pigs. (7/758)

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.  (+info)

Targeted mutagenesis of the endogenous mouse Mis gene promoter: in vivo definition of genetic pathways of vertebrate sexual development. (8/758)

Mutations were introduced into conserved steroidogenic factor 1 (SF1)- and SOX9-binding sites within the endogenous mouse Mullerian inhibiting substance (Mis) promoter. Male mice homozygous for the mutant SF1-binding site correctly initiated Mis transcription in fetal testes, although at significantly reduced levels. Surprisingly, sufficient MIS was produced to eliminate the MUllerian ducts. In contrast, males homozygous for the mutant SOX9-binding site did not initiate Mis transcription, resulting in pseudohermaphrodites. These studies suggest an essential role for SOX9 in the initiation of Mis transcription, whereas SF1 appears to act as a quantitative regulator of Mis transcript levels, perhaps for influencing non-Mullerian duct tissues. Comparative studies of Mis expression in vertebrates indicate that the Mis promoter receives transcriptional inputs that vary between species but result in the same functional readout.  (+info)