GATA4 and GATA6 Knockdown During Luteinization Inhibits Progesterone Production and Gonadotropin Responsiveness in the Corpus Luteum of Female Mice.

The surge of luteinizing hormone triggers the genomic reprogramming, cell differentiation, and tissue remodeling of the ovulated follicle, leading to the formation of the corpus luteum. During this process, called luteinization, follicular granulosa cells begin expressing a new set of genes that allow the resulting luteal cells to survive in a vastly different hormonal environment and to produce the extremely high amounts of progesterone (P4) needed to sustain pregnancy. To better understand the molecular mechanisms involved in the regulation of luteal P4 production in vivo, the transcription factors GATA4 and GATA6 were knocked down in the corpus luteum by crossing mice carrying Gata4 and Gata6 floxed genes with mice carrying Cre recombinase fused to the progesterone receptor. This receptor is expressed exclusively in granulosa cells after the luteinizing hormone surge, leading to recombination of floxed genes during follicle luteinization. The findings demonstrated that GATA4 and GATA6 are essential for female fertility, whereas targeting either factor alone causes subfertility. When compared to control mice, serum P4 levels and luteal expression of key steroidogenic genes were significantly lower in conditional knockdown mice. The results also showed that GATA4 and GATA6 are required for the expression of the receptors for prolactin and luteinizing hormone, the main luteotropic hormones in mice. The findings demonstrate that GATA4 and GATA6 are crucial regulators of luteal steroidogenesis and are required for the normal response of luteal cells to luteotropins.

FSH Regulates IGF-2 Expression in Human Granulosa Cells in an AKT-Dependent Manner.

CONTEXT: IGF-2 is highly expressed in the granulosa cells of human dominant ovarian follicles; however, little is known about the regulation of the IGF-2 gene or the interaction of IGF-2 and FSH during follicle development. OBJECTIVE: To examine the mechanisms involved in the regulation of the IGF-2 gene by FSH and the interplay between FSH and IGF-2 during granulosa cell differentiation. Design, Setting, Patients, and Interventions: Cumulus granulosa cells were separated from cumulus-oocyte complexes isolated from the follicular aspirates of in vitro fertilization patients and cultured for in vitro studies. MAIN OUTCOME: Protein and mRNA levels of IGF-2 and CYP19A1 (aromatase) were quantified using Western blot and quantitative real-time PCR. IGF-2 promoter-specific activation was determined by the amplification of alternative exons by PCR. Cell proliferation was assessed after treatment with FSH and/or IGF-2. RESULTS: FSH significantly enhanced IGF-2 expression after 8 hours of treatment and at low doses (1 ng/mL). Reciprocally, IGF-2 synergized with FSH to increase cell proliferation and the expression of CYP19A1. When IGF-2 activity was blocked, FSH was no longer able to stimulate CYP19A1 expression. Determination of IGF-2 promoter usage in human cumulus cells showed that the IGF-2 gene is driven by promoters P3 and P4. However, FSH exclusively increased P3 promoter-derived transcripts. Moreover, the FSH-induced stimulation of P3-driven IGF-2 transcripts was blocked by cotreatment with inhibitors of AKT or IGF-1 receptor (IGF-1R). The inhibitory effect of the IGF-1R inhibitor on FSH-induced IGF-2 mRNA accumulation was reversed by overexpression of a constitutively active AKT construct. CONCLUSIONS: FSH is a potent enhancer of IGF-2 expression in human granulosa cells. In return, IGF-2 activation of the IGF-1R and AKT is required for FSH to stimulate CYP19A1 expression and proliferation of granulosa cells. These findings suggest a positive loop interaction between FSH and IGF-2 that is critical for human granulosa cell proliferation and differentiation.

IGF1R signaling is necessary for FSH-induced activation of AKT and differentiation of human Cumulus granulosa cells.

CONTEXT: FSH is routinely administered to in vitro fertilization patients to induce follicle maturation. During this process, granulosa cells differentiate and acquire specific functional characteristics that are required to coordinate ovulation and oocyte maturation. OBJECTIVE: The objective of the study was to gain insight into the molecular mechanisms regulating human granulosa cell differentiation. Design, Setting, Patients, and Interventions: Cumulus and mural granulosa cells were isolated from the follicular aspirates of in vitro fertilization patients and analyzed immediately or cultured in serum-free media in the presence of FSH, IGFs, or an inhibitor of type I IGF receptor (IGF1R) activity. MAIN OUTCOME: We quantified the mRNA and protein levels of steroidogenic enzymes, components of the IGF system, and gonadotropin receptors; measured 17ß-estradiol levels; and examined the activation of intracellular signaling pathways to assess the granulosa cell differentiation as well as the FSH and IGF actions in both cumulus and mural cells. RESULTS: In freshly isolated cells, LH receptor (Lhr) and steroidogenic acute regulator (Star) were expressed at lower levels in cumulus than mural cells, whereas FSH receptor (Fshr) and anti-Müllerian hormone (Amh) were expressed at higher levels in cumulus than mural cells. In vitro, the expression of Igf2, the differentiation markers Lhr, Star, and Cyp19a1 (aromatase) as well as 17ß-estradiol production remained low in untreated cumulus cells but increased significantly after FSH treatment. Strikingly, this stimulatory effect of FSH was abolished by the inhibition of IGF1R activity. FSH-induced activation of v-akt murine thymoma viral oncogene homolog 3 (AKT) required IGF1R activity, and overexpression of constitutively active AKT rescued the induction of differentiation markers and 17ß-estradiol production by FSH in the presence of the IGF1R inhibitor. CONCLUSIONS: The cumulus cell response to FSH resembles the differentiation of preantral to preovulatory granulosa cells. This differentiation program requires IGF1R activity and subsequent AKT activation.