Project description:Gonadectomy (GDX) induces sex steroid-producing adrenocortical tumors in certain mouse strains and in the domestic ferret. Complementary approaches, including DNA methylation mapping and microarray expression profiling, were used to identify novel genetic and epigenetic markers of GDX-induced adrenocortical neoplasia in female DBA/2J mice. Markers were validated by quantitative RT-PCR, laser capture microdissection, in situ hybridization, and immunohistochemistry. Two genes with hypomethylated promoters, Igfbp6 and Foxs1, were upregulated in post-GDX adrenocortical neoplasms. The neoplastic cells also exhibited hypomethylation of the fetal adrenal enhancer of Sf1, an epigenetic signature that typifies descendants of fetal adrenal rather than gonadal cells. Expression profiling demonstrated upregulation of gonadal-like genes, including Spinlw1, Insl3, and Foxl2, in GDX-induced adrenocortical tumors of the mouse. One of these markers, FOXL2, was detected in adrenocortical tumor specimens from gonadectomized ferrets. These new markers may prove useful for studies of steroidogenic cell development and for diagnostic testing. Total RNA extracted from whole adrenal glands of gonadectomized and non-gonadectomized mice.

Project description:FOXL2 is a transcription factor essential for female fertility, expressed in somatic cells of the ovary, notably granulosa cells. In the mouse, Foxl2 deletion leads to partial sex reversal postnatally, with mutants developing dysgenic ovaries devoid of oocytes. However, deletion of the gene in 8-week-old females leads to granulosa to Sertoli cell transdifferentiation and gonadal sex reversal. We hypothesise that different outcomes of Foxl2 deletion in embryonic versus adult ovary may depend on a different role played by FOXL2 across ovarian development. Therefore, in this study, we take a multi-omics approach to characterise the dynamics of gene expression and chromatin accessibility changes in purified murine granulosa cells across key developmental stages (E14.5, 1 and 8 weeks). We coupled these analyses with genome wide identification of FOXL2 target genes and on-chromatin interacting partners by ChIP-SICAP to reconstruct the gene regulatory networks underpinned by this essential transcription factor and to discover novel players. We found that, in the embryonic ovary, FOXL2 interacts with factors important for early stages of gonadal development, such as GATA4 and WT1, whilst postnatally it interacts with factors regulating primordial follicle activation, such as NR5A2, and with factors regulating steroidogenesis including AR and ESR2. Integration of chromatin landscape dynamics with gene expression changes and FOXL2 binding sites analysis revealed that its critical role in ovarian cell fate maintenance goes beyond repression of the Sertoli-specific gene Sox9. Our chromatome analysis revealed also that FOXL2 interacts with several proteins involved in chromatin remodelling, DNA repair, splicing and gene repression. We identified a FOXL2 interactor with a role in primordial follicle activation, Ubiquitin specific protease 7 (USP7). We showed that conditional deletion of this gene in granulosa cells leads to a blockage of primordial follicle activation, impairs ovary development and leads to complete sterility. In summary, in this study we identified target genes dynamically regulated by FOXL2 across ovarian development including known and newly identified FOXL2 targets with a role in embryonic ovarian development and folliculogenesis, as well as cofactors that point towards additional roles played by FOXL2 besides transcriptional regulation. This work constitutes a comprehensive resource for exploration of the molecular mechanisms of ovarian development and causes of female infertility.

Project description:FOXL2 is a transcription factor essential for female fertility, expressed in somatic cells of the ovary, notably granulosa cells. In the mouse, Foxl2 deletion leads to partial sex reversal postnatally, with mutants developing dysgenic ovaries devoid of oocytes. However, deletion of the gene in 8-week-old females leads to granulosa to Sertoli cell transdifferentiation and gonadal sex reversal. We hypothesise that different outcomes of Foxl2 deletion in embryonic versus adult ovary may depend on a different role played by FOXL2 across ovarian development. Therefore, in this study, we take a multi-omics approach to characterise the dynamics of gene expression and chromatin accessibility changes in purified murine granulosa cells across key developmental stages (E14.5, 1 and 8 weeks). We coupled these analyses with genome wide identification of FOXL2 target genes and on-chromatin interacting partners by ChIP-SICAP to reconstruct the gene regulatory networks underpinned by this essential transcription factor and to discover novel players. We found that, in the embryonic ovary, FOXL2 interacts with factors important for early stages of gonadal development, such as GATA4 and WT1, whilst postnatally it interacts with factors regulating primordial follicle activation, such as NR5A2, and with factors regulating steroidogenesis including AR and ESR2. Integration of chromatin landscape dynamics with gene expression changes and FOXL2 binding sites analysis revealed that its critical role in ovarian cell fate maintenance goes beyond repression of the Sertoli-specific gene Sox9. Our chromatome analysis revealed also that FOXL2 interacts with several proteins involved in chromatin remodelling, DNA repair, splicing and gene repression. We identified a FOXL2 interactor with a role in primordial follicle activation, Ubiquitin specific protease 7 (USP7). We showed that conditional deletion of this gene in granulosa cells leads to a blockage of primordial follicle activation, impairs ovary development and leads to complete sterility. In summary, in this study we identified target genes dynamically regulated by FOXL2 across ovarian development including known and newly identified FOXL2 targets with a role in embryonic ovarian development and folliculogenesis, as well as cofactors that point towards additional roles played by FOXL2 besides transcriptional regulation. This work constitutes a comprehensive resource for exploration of the molecular mechanisms of ovarian development and causes of female infertility.

Project description:FOXL2 is a transcription factor essential for female fertility, expressed in somatic cells of the ovary, notably granulosa cells. In the mouse, Foxl2 deletion leads to partial sex reversal postnatally, with mutants developing dysgenic ovaries devoid of oocytes. However, deletion of the gene in 8-week-old females leads to granulosa to Sertoli cell transdifferentiation and gonadal sex reversal. We hypothesise that different outcomes of Foxl2 deletion in embryonic versus adult ovary may depend on a different role played by FOXL2 across ovarian development. Therefore, in this study, we take a multi-omics approach to characterise the dynamics of gene expression and chromatin accessibility changes in purified murine granulosa cells across key developmental stages (E14.5, 1 and 8 weeks). We coupled these analyses with genome wide identification of FOXL2 target genes and on-chromatin interacting partners by ChIP-SICAP to reconstruct the gene regulatory networks underpinned by this essential transcription factor and to discover novel players. We found that, in the embryonic ovary, FOXL2 interacts with factors important for early stages of gonadal development, such as GATA4 and WT1, whilst postnatally it interacts with factors regulating primordial follicle activation, such as NR5A2, and with factors regulating steroidogenesis including AR and ESR2. Integration of chromatin landscape dynamics with gene expression changes and FOXL2 binding sites analysis revealed that its critical role in ovarian cell fate maintenance goes beyond repression of the Sertoli-specific gene Sox9. Our chromatome analysis revealed also that FOXL2 interacts with several proteins involved in chromatin remodelling, DNA repair, splicing and gene repression. We identified a FOXL2 interactor with a role in primordial follicle activation, Ubiquitin specific protease 7 (USP7). We showed that conditional deletion of this gene in granulosa cells leads to a blockage of primordial follicle activation, impairs ovary development and leads to complete sterility. In summary, in this study we identified target genes dynamically regulated by FOXL2 across ovarian development including known and newly identified FOXL2 targets with a role in embryonic ovarian development and folliculogenesis, as well as cofactors that point towards additional roles played by FOXL2 besides transcriptional regulation. This work constitutes a comprehensive resource for exploration of the molecular mechanisms of ovarian development and causes of female infertility.

Project description:Forkhead box L2 (FOXL2) is a single-exon gene encoding a forkhead transcription factor, which is mainly expressed in the ovary, eyelids and pituitary gland. FOXL2 plays an essential role in ovarian development. To reveal the effects of FOXL2 on biological process and gene expression of ovarian granulosa cells (GCs), we established stable FOXL2-knockdown GCs and then analyzed using transcriptome sequencing. It is observed that knockdown the FOXL2 affects the biological processes of cell proliferation, DNA replication, apoptosis and cell cycle. In which, the FOXL2 knockdown promoted cell proliferation and DNA replication, decreased cell apoptosis, and promoted mitosis. In addition, by comparing the transcriptome by FOXL2 knockdown, we found a serious of DEGs and their related pathways. These results indicated that, through mediating these genes and pathways, the FOXL2 might induce the cell proliferation, cycle, and DNA replication, and play a key role during ovarian development and maintenance.

Project description:Gonadectomy (GDX) induces sex steroid-producing adrenocortical tumors in certain mouse strains and in the domestic ferret. Complementary approaches, including DNA methylation mapping and microarray expression profiling, were used to identify novel genetic and epigenetic markers of GDX-induced adrenocortical neoplasia in female DBA/2J mice. Markers were validated by quantitative RT-PCR, laser capture microdissection, in situ hybridization, and immunohistochemistry. Two genes with hypomethylated promoters, Igfbp6 and Foxs1, were upregulated in post-GDX adrenocortical neoplasms. The neoplastic cells also exhibited hypomethylation of the fetal adrenal enhancer of Sf1, an epigenetic signature that typifies descendants of fetal adrenal rather than gonadal cells. Expression profiling demonstrated upregulation of gonadal-like genes, including Spinlw1, Insl3, and Foxl2, in GDX-induced adrenocortical tumors of the mouse. One of these markers, FOXL2, was detected in adrenocortical tumor specimens from gonadectomized ferrets. These new markers may prove useful for studies of steroidogenic cell development and for diagnostic testing.

Project description:Development of the adrenal cortex, a vital endocrine organ, originates in the adrenogonadal primordium, a common progenitor for both the adrenocortical and gonadal lineages in rodents. In contrast, we find that in humans and cynomolgus monkeys, the adrenocortical lineage originates in a temporally and spatially distinct fashion from the gonadal lineage, arising earlier and more anteriorly within the coelomic epithelium. The adrenal primordium arises from adrenogenic coelomic epithelium via an epithelial-to-mesenchymal-like transition, which then progresses into the steroidogenic fetal zone via both direct and indirect routes. Notably, we find that adrenocortical and gonadal lineages exhibit distinct HOX codes, suggesting distinct anterior-posterior regionalization. Together, our assessment of the early divergence of these lineages provides a molecular framework for understanding human adrenal and gonadal disorders.

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:The nuclear receptor subfamily 5 group A member 1 (NR5A1), encoding steroidogenic factor 1 (SF-1), has been identified as a critical factor in gonadal development in animal studies. A previous study of ours suggested that upregulation of NR5A1 during early gonadal differentiation in male (46,XY) human pluripotent stem cells steers the cells into a more mature gonadal cell type. However, the detailed role of NR5A1 in female gonadal differentiation has yet to be determined. In this study, by combining the processes of gonadal differentiation and conditional gene activation, we show that NR5A1 induction predominantly upregulates the female gonadal marker inhibin subunit α (INHA) and steroidogenic markers steroidogenic acute regulatory protein (STAR), cytochrome P450 family 11 subfamily A member 1 (CYP11A1), cytochrome P450 family 17 subfamily A member 1 (CYP17A1), hydroxy-delta-5-steroid dehydrogenase (HSD3B2) and hydroxysteroid 17-beta dehydrogenase 1 (HSD17B1). In contrast, NR5A1 induction did not seem to affect the bipotential gonadal markers gata binding protein 4 (GATA4) and Wilms tumour suppressor 1 (WT1) nor the female gonadal markers r-spondin 1 (RSPO1) and wnt family member 4 (WNT4). Differentially expressed genes were highly associated with adrenal and ovarian steroidogenesis pathways. Moreover, time-series analysis revealed different dynamic changes between male and female -induced samples, where continuously upregulated genes in female gonadal differentiation were mostly associated with adrenal steroidogenesis. Thus, in contrast to male gonadal differentiation, NR5A1 is necessary but not sufficient to steer human embryonic stem cell (hESC)-derived bipotential gonadal-like cells towards a more mature somatic, female cell fate. Instead, it seems to direct bipotential gonadal-like cells more towards a steroidogenic-like cell population. The information obtained in this study helps in elucidating the role of NR5A1 in gonadal differentiation of a female stem cell line.

Project description:Despite their distinct biology, granulosa cell tumours (GCTs) are treated the same as other ovarian tumours. Intriguingly, a recurring somatic mutation in the transcription factor Forkhead Box L2 (FOXL2) 402C>G has been found in nearly all GCTs examined. This investigation aims to identify the pathogenicity of mutant FOXL2 by studying its altered transcriptional targets. The expression of mutant FOXL2 was reduced in the GCT cell line KGN, and wildtype and mutant FOXL2 were overexpressed in the GCT cell line COV434. Comparisons were made between the transcriptomes of control cells and cells altered by FOXL2 knockdown and overexpression, to detect potential transcriptional targets of mutant FOXL2. Comparisons were made between the transcriptomes of control cells and cells altered by FOXL2 knockdown and overexpression, to detect potential transcriptional targets of mutant FOXL2.