Stefan Bagheri-Fam

SOX9 Regulates MicroRNA miR-202-5p/3p Expression During Mouse Testis Differentiation

ABSTRACT MicroRNAs are important regulators of developmental gene expression, but their contribution to fetal gonad development is not well understood. We have identified the evolutionarily conserved gonadal microRNAs miR-202-5p and miR-202-3p as having a potential role in regulating mouse embryonic gonad differentiation. These microRNAs are expressed in a sexually dimorphic pattern as the primordial XY gonad differentiates into a testis, with strong expression in Sertoli cells. In vivo, ectopic expression of pri-miR-202 in XX gonads did not result in molecular changes to the ovarian determination pathway. Expression of the primary transcript of miR-202-5p/3p remained low in XY gonads in a conditional Sox9-null mouse model, suggesting that pri-miR-202 transcription is downstream of SOX9, a transcription factor that is both necessary and sufficient for male sex determination. We identified the pri-miR-202 promoter that is sufficient to drive expression in XY but not XX fetal gonads ex vivo. Mutation of SOX9 and SF1 binding sites reduced ex vivo transactivation of the pri-miR-202 promoter, demonstrating that pri-miR-202 may be a direct transcriptional target of SOX9/SF1 during testis differentiation. Our findings indicate that expression of the conserved gonad microRNA, miR-202-5p/3p, is downstream of the testis-determining factor SOX9, suggesting an early role in testis development.

Antagonistic regulation of Cyp26b1 by transcription factors SOX9/SF1 and FOXL2 during gonadal development in mice

Sex determination in fetal germ cells depends on a balance between exposure to retinoic acid (RA) and the degradation of RA achieved by the testis‐specific expression of the catabolic cytochrome P450 enzyme, CYP26B1. Therefore, identification of factors regulating the expression of the Cyp26b1 gene is an important goal in reproductive biology. We used in situ hybridization to demonstrate that Cyp26b1 and transcription factor genes steroidogenic factor‐1 (Sf1) and Sry‐related HMG box 9 (Sox9) are coexpressed in Sertoli cells, whereas Cyp26b1 and Sf1 are coexpressed in Leydig cells in mouse fetal testes. In the mouse gonadal somatic cell line TM3, transfection of constructs expressing SOX9 and SF1 activated Cyp26b1 expression, independently of the positive regulator RA. In embryonic gonads deficient in SOX9 or SF1, Cyp26b1 expression was decreased relative to wild‐type (WT) controls, as measured by quantitative RT‐PCR (qRT‐PCR). Furthermore, qRT‐PCR showed that Cyp26b1 up‐regulation by SOX9/SF1 was attenuated by the ovarian transcription factor Forkhead box L2 (FOXL2) in TM3 cells, whereas in Foxl2‐null mice, Cyp26b1 expression in XX gonads was increased ~20‐fold relative to WT controls. These data support the hypothesis that SOX9 and SF1 ensure the male fate of germ cells by up‐regulating Cyp26b1 and that FOXL2 acts to antagonize Cyp26b1 expression in ovaries.—Kashimada, K., Svingen, T., Feng, C.‐W., Pelosi, E., Bagheri‐Fam, S., Harley, V. R., Schlessinger, D., Bowles, J., Koopman, P. Antagonistic regulation of Cyp26b1 by transcription factors SOX9/SF1 and FOXL2 during gonadal development in mice. FASEB J. 25, 3561–3569 (2011). www.fasebj.org

Male-Specific Expression of Aldh1a1 in Mouse and Chicken Fetal Testes: Implications for Retinoid Balance in Gonad Development

Balanced production and degradation of retinoids is important in regulating development of several organ systems in the vertebrate embryo. Among these, it is known that retinoic acid (RA), and the retinoid‐catabolyzing enzyme CYP26B1 together regulate the sex‐specific behavior of germ cells in developing mouse gonads. We report here that the gene encoding a cytosolic class‐1 aldehyde dehydrogenase, ALDH1A1, a weak catalyst of RA production, is strongly expressed in a male‐specific manner in somatic cells of the developing mouse testis, beginning shortly after Sry expression is first detectable. This expression pattern is conserved in the developing male gonad of the chicken and is dependent on the testis‐specific transcription factor SOX9. Our data suggest that low levels of RA may be required for early developmental events in the testis, or that Aldh1a1 expression in the fetus may prefigure a later requirement for ALDH1A1 in regulating spermatogenesis postnatally. Developmental Dynamics 238:2073–2080, 2009.

Inhibition of SRY-Calmodulin Complex Formation induces ectopic expression of ovarian cell markers in developing XY gonads

The transcription factor sex-determining region of the Y chromosome (SRY) plays a key role in human sex determination, because mutations in SRY cause disorders of sex development in XY individuals. During gonadal development, Sry in pre-Sertoli cells activates Sox9 gene transcription, committing the fate of the bipotential gonad to become a testis rather than an ovary. The high-mobility group domain of human SRY contains two independent nuclear localization signals, one bound by calmodulin (CaM) and the other by importin-β. Although XY females carry SRY mutations in these nuclear localization signals that affect SRY nuclear import in transfected cells, it is not known whether these transport mechanisms are essential for gonadal development and sex determination. Here, we show that mouse Sry protein binds CaM and that a CaM antagonist reduces CaM binding, nuclear accumulation, and transcriptional activity of Sry in transfected cells. CaM antagonist treatment of cultured, sexually indifferent XY mouse fetal gonads led to reduced expression of the Sry target gene Sox9, defects in testicular cord formation, and ectopic expression of the ovarian markers Rspondin1 and forkhead box L2. These results indicate the importance of CaM for SRY nuclear import, transcriptional activity, testis differentiation, and sex determination.

Protein tyrosine kinase 2 beta (PTK2B), but not focal adhesion kinase (FAK), is expressed in a sexually dimorphic pattern in developing mouse gonads.

Sexual reproduction is essential for the propagation and the maintenance of fitness of our species, and is dependent on the correct development of the bipotential genital ridges into testes and ovaries. Although several transcription factors, secreted signaling molecules, and their receptors have been found to be important for testis determination and early gonad development, comparatively little research has been carried out into intracellular signal transduction pathways activated during these processes. Focal adhesion kinase (FAK) and protein tyrosine kinase 2 beta (PTK2B) form one group of cytosolic tyrosine kinases that are known to be important for processes such as cell proliferation, differentiation, and motility. Here, we describe the temporal and spatial expression patterns of Fak and Ptk2b mRNA and protein during sex determination and early gonadogenesis in mouse embryos. Ptk2b mRNA and PTK2B protein were expressed in testes from 11.5 days post coitum onward, predominantly in developing Sertoli cells, in a SOX9‐dependent manner. Fak mRNA and FAK protein were expressed in gonads of both sexes at all stages examined. Our data suggest cell type‐ and stage‐specific roles for PTK2B during early testis development. Developmental Dynamics 239:2735–2741, 2010.

Dynamic expression patterns of Irx3 and Irx5 during germline nest breakdown and primordial follicle formation promote follicle survival in mouse ovaries

Women and other mammalian females are born with a finite supply of oocytes that determine their reproductive lifespan. During fetal development, individual oocytes are enclosed by a protective layer of granulosa cells to form primordial follicles that will grow, mature, and eventually release the oocyte for potential fertilization. Despite the knowledge that follicles are dysfunctional and will die without granulosa cell-oocyte interactions, the mechanisms by which these cells establish communication is unknown. We previously identified that two members of the Iroquois homeobox transcription factor gene family, Irx3 and Irx5, are expressed within developing ovaries but not testes. Deletion of both factors (Irx3-Irx5EGFP/Irx3-Irx5EGFP) disrupted granulosa cell-oocyte contact during early follicle development leading to oocyte death. Thus, we hypothesized that Irx3 and Irx5 are required to develop cell-cell communication networks to maintain follicle integrity and female fertility. A series of Irx3 and Irx5 mutant mouse models were generated to assess roles for each factor. While both Irx3 and Irx5 single mutant females were subfertile, their breeding outcomes and ovary histology indicated distinct causes. Careful analysis of Irx3- and Irx5-reporter mice linked the cause of this disparity to dynamic spatio-temporal changes in their expression patterns. Both factors marked the progenitor pre-granulosa cell population in fetal ovaries. At the critical phase of germline nest breakdown and primordial follicle formation however, Irx3 and Irx5 transitioned to oocyte- and granulosa cell-specific expression respectively. Further investigation into the cause of follicle death in Irx3-Irx5EGFP/Irx3-Irx5EGFP ovaries uncovered specific defects in both granulosa cells and oocytes. Granulosa cell defects included poor contributions to basement membrane deposition and mis-localization of gap junction proteins. Granulosa cells and oocytes both presented fewer cell projections resulting in compromised cell-cell communication. Altogether, we conclude that Irx3 and Irx5 first work together to define the pregranulosa cell population of germline nests. During primordial follicle formation, they transition to oocyte- and granulosa cell-specific expression patterns where they cooperate in neighboring cells to build the foundation for follicle integrity. This foundation is left as their legacy of the essential oocyte-granulosa cell communication network that ensures and ultimately optimizes the integrity of the ovarian reserve and therefore, the female reproductive lifespan.

Genes and Gene Defects Affecting Gonadal Development and Sex Determination

Abstract Sex in mammals is determined genetically with the acquisition of either the XX (female) or XY (male) chromosomes at the time of fertilization. The chromosomal sex will determine if, during embryogenesis, ovaries or testes form from the bipotential gonadal anlage, the genital ridges. Hormones produced by testes and ovaries will then drive most, if not all, secondary sexual characteristics, resulting in the female or male phenotype. Each of these sequential steps is promoted by specific genes and mutations in these genes can lead to disorders of sex development (DSDs).