Fibroblast growth factors (FGF) are involved in paracrine signaling between cell types in the ovarian follicle. FGF8, for example, is secreted by oocytes and controls cumulus cell metabolism. The closely related FGF18 is also expressed in oocytes in mice. The objective of this study was to assess the potential role of FGF18 in follicle growth in a monovulatory species, the cow. Messenger RNA encoding FGF18 was detected primarily in theca cells, and in contrast to the mouse, FGF18 was not detected in bovine oocytes. Addition of FGF18 protein to granulosa cell cultures inhibited estradiol and progesterone secretion as well as the abundance of mRNA encoding steroidogenic enzymes and the follicle-stimulating hormone receptor. In vivo, onset of atresia of the subordinate follicle was associated with increased thecal FGF18 mRNA levels and FGF18 protein in follicular fluid. In vitro, FGF18 altered cell cycle progression as measured by flow cytometry, resulting in increased numbers of dead cells (sub-G1 peak) and decreased cells in S phase. This was accompanied by decreased levels of mRNA encoding the cell cycle checkpoint regulator GADD45B. Collectively, these data point to a unique role for this FGF in signaling from theca cells to granulosa cells and suggest that FGF18 influences the process of atresia in ovarian follicles.
Whereas the roles of the canonical winglesstype MMTV (mouse mammary tumor virus) integration site family (WNT) signaling pathway in the regulation of ovarian follicle growth and steroidogenesis are now established, noncanonical WNT signaling in the ovary has been largely overlooked. Noncanonical WNTs, including WNT5a and WNT11, are expressed in granulosa cells (GCs) and are differentially regulated throughout follicle development, but their physiologic roles remain unknown. Using conditional gene targeting, we found that GC-specific inactivation of Wnt5a (but not Wnt11) results in the female subfertility associated with increased follicular atresia and decreased rates of ovulation. Microarray analyses have revealed that WNT5a acts to down-regulate the expression of FSH-responsive genes in vitro, and corresponding increases in the expression of these genes have been found in the GCs of conditional knockout mice. Unexpectedly, we found that WNT5a regulates its target genes not by signaling via the WNT/Ca 2+ or planar cell polarity pathways, but rather by inhibiting the canonical pathway, causing both b-catenin (CTNNB1) and cAMP responsive element binding (CREB) protein levels to decrease via a glycogen synthase kinase-3b-dependent mechanism. We further found that WNT5a prevents follicle-stimulating hormone and luteinizing protein from up-regulating the CTNNB1 and CREB proteins and their target genes, indicating that WNT5a functions as a physiologic inhibitor of gonadotropin signaling. Together, these findings identify WNT5a as a key regulator of follicle development and gonadotropin responsiveness.-Abedini, A., Zamberlam, G., Lapointe, E., Tourigny, C., Boyer, A., Paquet, M., Hayashi, K., Honda, H., Kikuchi, A., Price, C., Boerboom, D. WNT5a is required for normal ovarian follicle development and antagonizes gonadotropin responsiveness in granulosa cells by suppressing canonical WNT signaling. FASEB J. 30, 1534-1547 (2016 The pituitary gonadotropins follicle-stimulating hormone (FSH) and luteinizing hormone (LH) represent the major endocrine regulators of ovarian function and are essential for follicle development beyond the secondary stage (1, 2). In addition to the endocrine level of control, follicle development is regulated by several paracrine and autocrine factors produced within the ovary itself. These factors notably include IGF-1, steroid hormones, prostaglandins, epidermal growth factor-like molecules and several TGF-b superfamily members, all of which are indispensable for normal ovarian function and female fertility. The gonadotropins can affect the expression and function of these intraovarian factors; conversely, these factors can modulate follicular responses to the gonadotropins (1-3).Recent studies have established the wingless-type MMTV (mouse mammary tumor virus) integration site (WNT) family of secreted glycoproteins as yet another class of signaling molecules that act to modulate and coordinate follicular responses to the gonadotropins and whose activities are indispensable for ovarian...
Although the various members of the fibroblast growth factor (FGF) family are generally mitotic, one member, FGF18, has been shown to increase the rate of apoptosis of ovarian granulosa cells. In the present study, we first determined whether granulosa cells express FGF18 and we then explored the mechanism through which FGF18 increases apoptosis in vitro. Under culture conditions that favored estradiol secretion and CYP19A1 expression, granulosa FGF18 mRNA levels were barely detectable; however, withdrawing gonadotropic support (follicle-stimulating hormone or insulin-like growth factor 1) reduced levels of CYP19A1 mRNA and increased abundance of mRNA encoding the death ligand FASLG and FGF18. Addition of FGF18, but not FGF2, FGF10, or EGF, increased the proportion of apoptotic cells and frequency of caspase 3 activation, and these effects were abrogated by coculture with estradiol. Addition of FGF18 decreased abundance of mRNA encoding the antiapoptotic proteins GADD45B and MDM2, and increased that encoding the proapoptotic protein BBC3; these effects were reversed by coculture with estradiol. The physiological relevance of FGF18 was determined using an in vivo model: injection of FGF18 directly into growing bovine dominant follicles caused cessation of follicle growth by 24 h after injection. Collectively, these data demonstrate that FGF18 is proapoptotic in vivo and may act through a mechanism involving the BBC3-MDM2 pathway.
Angiotensin II (AGT-2) induces follicular prostaglandin release in a number of species and ovulation in rabbits. Conversely, AGT-2 antagonists block ovulation in cattle. To determine the mechanism of action of AGT-2, we used a bovine granulosa cell model in which luteinizing hormone (LH) increased the expression of genes essential for ovulation in a time- and dose-dependent manner. The addition of AGT-2 to LH-stimulated cells significantly increased abundance of prostaglandin-endoperoxide synthase 2 (PTGS2) mRNA and protein, whereas AGT-2 alone had no effect. Upstream of PTGS2, AGT-2 increased abundance of mRNA encoding the epidermal growth factor-like ligands amphiregulin (AREG) and epiregulin (EREG) at 6 h posttreatment and abundance of a disintegrin and metalloprotease 17 (ADAM17), a sheddase, within 3 h of treatment. Inhibiting sheddase activity abolished the stimulatory effect of AGT-2 on AREG, EREG, and PTGS2 mRNA. The addition of selective AGT-2 antagonists to cells stimulated with LH plus AGT-2 demonstrated that AGT-2 did not act through the type 1 receptor and did not increase mitogen-activated protein kinase 3/1 phosphorylation. Combined with previous data from studies in vitro, we conclude that AGT-2 is an essential cofactor for LH in the early increase of ADAM expression/activity that induces the cascade of events leading to ovulation.
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