Project description:The main goal of our study is to identify the molecular events that determine the gonadal identity in mammals. Although testis and ovary arise from a common embryonic primordium, they represent outcomes of opposing fate determination. This decision to differentiate into a testis or an ovary hinges upon the balance between two antagonizing factors, pro-testis SOX9 and pro-ovary β-catenin. This microarray analysis led to the identification of the genes involved in the fate of XX and XY gonads in absence of SOX9 and beta-catenin We developed mouse genetic models that lack either Sox9, β-catenin, or both specifically in the somatic cells. All embryos used in this study resulted from the crossing between Ctnnb1f/f; Sox9f/f females with Sf1-cre+/Tg ; Ctnnb1+/f; Sox9+/f males. XX and XY fetal gonads were collected at embryonic day E14.5

Project description:The main goal of our study is to identify the molecular events that determine the gonadal identity in mammals. Although testis and ovary arise from a common embryonic primordium, they represent outcomes of opposing fate determination. This decision to differentiate into a testis or an ovary hinges upon the balance between two antagonizing factors, pro-testis SOX9 and pro-ovary β-catenin. This microarray analysis led to the identification of the genes involved in the fate of XX and XY gonads in absence of SOX9 and beta-catenin

Project description:In mammals, male fate is under the control of the master transcriptional regulator, SOX9: in its presence, somatic precursor cells of the embryonic gonads differentiate into Sertoli cells, the main organizers of testicular differentiation. Therefore, analyzing target genes of this transcription factor allows understanding mechanisms of cellular commitment at the genomic level. With the use of ChIP-seq in murine and bovine wild-type testes combined with RNAseq from mouse testes lacking SOX9, we identified SOX9 target genes in the mammalian fetal gonad. SOX9 in murine and bovine fetal testes binds to a large set of genes conserved among mammals, including those with well-established roles in testis and ovary development. RNAseq analysis shows that testis and ovary display sex specific RNA splicing and that SOX9 mediates both target gene transcription and differential splicing. Regions bound by SOX9 are predominantly 5’ proximal or intra-genic, and display a specific genomic features that we call "Sertoli cell signatures" or SCS. The SCS is conserved among mammals and comprises multiple binding motifs for the Sertoli reprogramming factors SOX9, GATA4 and DMRT1; indeed, independent DMRT1 ChIP-seq confirms the enrichment of the SCS. Bioinformatic analysis of SCSs regions predicts novel regulatory mechanisms prompting functional validation. For example, we detected SCS in target genes of the nuclear factor TRIM28 and we show experimentally that SOX9 and TRIM28 proteins interact in fetal testis.

Project description:In mammals, male fate is under the control of the master transcriptional regulator, SOX9: in its presence, somatic precursor cells of the embryonic gonads differentiate into Sertoli cells, the main organizers of testicular differentiation. Therefore, analyzing target genes of this transcription factor allows understanding mechanisms of cellular commitment at the genomic level. With the use of ChIP-seq in murine and bovine wild-type testes combined with RNAseq from mouse testes lacking SOX9, we identified SOX9 target genes in the mammalian fetal gonad. SOX9 in murine and bovine fetal testes binds to a large set of genes conserved among mammals, including those with well-established roles in testis and ovary development. RNAseq analysis shows that testis and ovary display sex specific RNA splicing and that SOX9 mediates both target gene transcription and differential splicing. Regions bound by SOX9 are predominantly 5’ proximal or intra-genic, and display a specific genomic features that we call "Sertoli cell signatures" or SCS. The SCS is conserved among mammals and comprises multiple binding motifs for the Sertoli reprogramming factors SOX9, GATA4 and DMRT1; indeed, independent DMRT1 ChIP-seq confirms the enrichment of the SCS. Bioinformatic analysis of SCSs regions predicts novel regulatory mechanisms prompting functional validation. For example, we detected SCS in target genes of the nuclear factor TRIM28 and we show experimentally that SOX9 and TRIM28 proteins interact in fetal testis.

Project description:The identity of the gonads is determined by which fate, ovarian granulosa cell or testicular Sertoli cell, the bipotential somatic cell precursors choose to follow. In most vertebrates, the fate of granulosa cells is controlled by a conserved regulator FOXL2. To understand how FOXL2 elicits its fate-determining action, we performed genome-wide analysis of FOXL2 chromatin occupancy in fetal ovaries. Combining genome-wide analysis of FOXL2 binding in the fetal ovary with transcriptomic analyses of Foxl2 gain-of-function and Foxl2 loss-of-function models, we identified potential pathways responsible for the feminizing action of FOXL2. Finally, comparison of FOXL2 genome-wide occupancy in the fetal ovary with testis-determining factor SOX9 genome-wide occupancy in the fetal testis revealed extensive overlaps, implying that antagonistic signals between FOXL2 and SOX9 occur at the chromatin level.

Project description:Retinoic acid (RA) is a potent inducer of cell differentiation and plays an essential role in sex-specific germ cell development in the mammalian gonad. RA is essential for male gametogenesis and hence fertility. However, RA can also disrupt sexual cell fate in somatic cells of the testis, promoting transdifferentiation of male Sertoli cells to female granulosa-like cells when the male sexual regulator Dmrt1 is absent. The feminizing ability of RA in the somatic testis suggests that RA might normally play a role in somatic cell differentiation or cell fate maintenance in the ovary. To test for this possibility we disrupted RA signaling in somatic cells of the early fetal ovary using three genetic strategies and one pharmaceutical approach. We found that deleting all three RA receptors (RARs) in the XX somatic gonad at the time of sex determination did not significantly affect ovarian differentiation, follicle development, or female fertility. Transcriptome analysis of adult triple mutant ovaries revealed remarkably little effect on gene expression in the absence of somatic RAR function. Likewise, deletion of three RA synthesis enzymes (Aldha1-3) at the time of sex determination did not masculinize the ovary. A dominant-negative RAR transgene altered granulosa cell proliferation, likely due to interference with a non-RA signaling pathway, but did not affect granulosa cell specification or fertility. Finally, culture of fetal XX gonads with an RAR antagonist blocked germ cell meiotic initiation but did not disrupt sex-biased gene expression. We conclude that RA signaling, although crucial in the ovary for meiotic initiation, is not required for granulosa cell specification, differentiation, or reproductive function.

Project description:Zebrafish males undergo a juvenile ovary to testis type gonadal transformation process. To understand how juvenile ovary-to-testis transformation in zebrafish is genetically regulated, we compared the transcriptomes of juvenile ovary (JO) and juvenile ovotestis (JOT) samples at 35 dpf using the Gonad Uniclone Microarray v1 (ArrayExpress ID: A-MEXP-838). We also analyzed the transcriptomes of the 32 dpf JO, 32 dpf JOT, 34 dpf JOT, and 36 dpf JOT gonads using the slightly modified Gonad Uniclone Microarray v2 and together with the 35 dpf JO and 35 dpf JOT samples, compared the JO samples against the JOT samples to identify genes that could be potentially involved in the gonad transformation process.

Project description:Gonadal sex determination represents a unique model for studying cell fate decisions. However, a complete understanding of the different cell lineages forming the developing testis and ovary remains elusive. Here, we investigated the origin, specification, and subsequent sex-specific differentiation of a previously uncharacterized population of supporting-like cells (SLCs) in the developing mouse gonads. The SLC lineage is closely related to the coelomic epithelium and specified as early as E10.5, making it the first somatic lineage to be specified in the bipotential gonad. SLC progenitors are localized within the genital ridge at the interface with the mesonephros and initially coexpress Wnt4 and Sox9. SLCs become sexually dimorphic around E12.5, progressively acquire a more Sertoli- or pregranulosa-like identity and contribute to the formation of the rete testis and rete ovarii. Last, we found that WNT4 is a crucial regulator of the SLC lineage and is required for normal development of the rete testis. In the present study, we built a transcriptomic atlas of the entire cell population of the developing female and male gonads during the process of mouse sex determination. We identified a previously uncharacterized population of supporting-like cells (SLC) and shed light on the origin and the developmental trajectory of this important cell lineage during the process of testis and ovary development.

Project description:Foxl2 is a forkhead transcription factor essential for proper reproductive function in females. It is expressed in the somatic cell population of the gonad (granulosa cells) which forms the follicles of the ovary, the structures responsible for embedding and nurturing the oocytes during their development. FOXL2 directly regulate the aromatase that synthesizes estrogens CYP19A1, thus promoting female differentiation, as well as acting as a repressor of the male factors SOX9 and DMRT1.Expression is also found in the eyelids, pituitary gland and uterus. In the goat, frog and many fish species FOXL2 is a sex-determining gene which, when deleted, leads to female-to-male sex reversal.

Project description:This study describes a temporal profile of gene expression from normal human fetal testes and ovaries. Gonads from 34 fetuses between 9 weeks and 20 weeks of gestation were obtained from the Department of Pathology and the Birth Defects Research Laboratory at the University of Washington. Relative transcript levels were determined using the Affymetrix Human Genome U133A Plus 2.0 arrays. Sex determination occurs in the human gonad at approximately 6 weeks gestation with development of the testis driven by expression of SRY. In this study, SRY transcript was present and elevated at 9 weeks gestation in the testis but absent in the ovary. The transcript levels of other testis-specific factors SOX9, AMH, and the steroidogenic genes CYP17a1, CYP11a1, STAR and HSD17β3 were all significantly higher in the testis. In contrast, transcripts known to be involved in meiosis including STRA8, SPO11, SYCP3, TEX11, TEX14 and STAG3 showed highest expression in the fetal ovary beginning at week 12. These gene expression profiles will be a resource for understanding and defining normal gonad development and provide the opportunity to dissect abnormal development.