G beta gamma signaling reduces intracellular cAMP to promote meiotic progression in mouse oocytes.

In nearly every vertebrate species, elevated intracellular cAMP maintains oocytes in prophase I of meiosis. Prior to ovulation, gonadotropins trigger various intra-ovarian processes, including the breakdown of gap junctions, the activation of EGF receptors, and the secretion of steroids. These events in turn decrease intracellular cAMP levels in select oocytes to allow meiotic progression, or maturation, to resume. Studies suggest that cAMP levels are kept elevated in resting oocytes by constitutive G protein signaling, and that the drop in intracellular cAMP that accompanies maturation may be due in part to attenuation of this inhibitory G protein-mediated signaling. Interestingly, one of these G protein regulators of meiotic arrest is the Galpha(s) protein, which stimulates adenylyl cyclase to raise intracellular cAMP in two important animal models of oocyte development: Xenopus leavis frogs and mice. In addition to G(alpha)(s), constitutive Gbetagamma activity similarly stimulates adenylyl cyclase to raise cAMP and prevent maturation in Xenopus oocytes; however, the role of Gbetagamma in regulating meiosis in mouse oocytes has not been examined. Here we show that Gbetagamma does not contribute to the maintenance of murine oocyte meiotic arrest. In fact, contrary to observations in frog oocytes, Gbetagamma signaling in mouse oocytes reduces cAMP and promotes oocyte maturation, suggesting that Gbetagamma might in fact play a positive role in promoting oocyte maturation. These observations emphasize that, while many general concepts and components of meiotic regulation are conserved from frogs to mice, specific differences exist that may lead to important insights regarding ovarian development in vertebrates.

Epidermal growth factor receptor signaling is required for normal ovarian steroidogenesis and oocyte maturation.

The midcycle luteinizing hormone (LH) surge triggers several tightly linked ovarian processes, including steroidogenesis, oocyte maturation, and ovulation. We designed studies to determine whether epidermal growth factor receptor (EGFR)-mediated signaling might serve as a common regulator of these activities. Our results showed that EGF promoted steroidogenesis in two different in vitro models of oocyte-granulosa cell complexes. Inhibition of the EGFR kinase prevented EGF-induced steroidogenesis in these in vitro systems and blocked LH-induced steroidogenesis in intact follicles primed with pregnant mare serum gonadotropin. Similarly, inhibition of the EGFR kinase attenuated LH-induced steroidogenesis in MA-10 Leydig cells. Together, these results indicate that EGFR signaling is critical for normal gonadotropin-induced steroidogenesis in both male and female gonads. Interestingly, inhibition of metalloproteinase-mediated cleavage of membrane-bound EGF moieties abrogated LH-induced steroidogenesis in ovarian follicles but not MA-10 cells, suggesting that LH receptor signaling activates the EGFR by different mechanisms in these two models. Finally, steroids promoted oocyte maturation in several ovarian follicle models, doing so by signaling through classical steroid receptors. We present a model whereby steroid production may serve as one of many integrated signals triggered by EGFR signaling to promote oocyte maturation in gonadotropin-stimulated follicles.

Specific modulation of nongenomic androgen signaling in the ovary.

Maturation, or meiotic progression, of amphibian oocytes is one of the few physiologically relevant steroid-mediated processes that occurs in the complete absence of transcription from beginning to end. As such, frog oocyte maturation has served as a useful model of nongenomic steroid signaling for many years. Earlier work in Xenopus laevis demonstrated that, although several steroids promoted oocyte maturation in vitro, androgens were the most abundant and potent steroids detected in the serum and ovaries of ovulating frogs. Thus, androgens were likely the primary physiologic regulators of Xenopus oocyte maturation, mediating their actions at least in part via classical androgen receptors expressed in oocytes. The importance of androgens for Xenopus oocyte maturation and ovulation has now been confirmed, as inhibition of androgen production in vivo by blocking CYP17 activity reduced hCG-triggered oocyte maturation and delayed ovulation in female frogs. Taking advantage of the absolute transcription-independence of this androgen-mediated response, selective androgen receptor modulators (SARMs) have been characterized that specifically promote genomic versus nongenomic androgen responses. These include androstenediol and estren, which preferentially promote nongenomic signals, as well as R1881 and 19-nortestosterone, which preferentially promote genomic signaling. Interestingly, the SARMs androstenediol and R1881 signal similarly in mouse oocytes, demonstrating the conserved nature of androgen-mediated maturation in vertebrates. These results suggest that SARMs may serve as useful tools for specifically regulating nongenomic androgen signaling both in vitro and in vivo.

Androgens promote maturation and signaling in mouse oocytes independent of transcription: a release of inhibition model for mammalian oocyte meiosis.

Normal fertility in females depends upon precise regulation of oocyte meiosis. Oocytes are arrested in prophase I of meiosis until just before ovulation, when meiosis, or maturation, is triggered to resume. Whereas sex steroids appear to promote maturation in fish and amphibians, the factors regulating mammalian oocyte maturation have remained obscure. We show here that, similar to lower vertebrates, steroids may play a role in promoting the release of meiotic inhibition in mammals. Specifically, testosterone induced maturation of mouse oocytes arrested in meiosis, as well as activation of MAPK and cyclin-dependent kinase 1 signaling. These responses appeared to be transcription independent and might involve signaling through classical androgen receptors expressed in the oocytes. Our results are the first to show that sex steroids can modulate meiosis in mammalian oocytes and suggest a model whereby dominant ovarian follicles in mammals may produce sufficient androgen and/or other steroids to overcome constitutive inhibitory signals and allow oocyte maturation and subsequent ovulation to occur.

Selective modulation of genomic and nongenomic androgen responses by androgen receptor ligands.

Steroids can induce both transcription-dependent (genomic) and independent (nongenomic) signaling. Here, several classical androgen receptor ligands were tested for their ability to modulate genomic and nongenomic responses, focusing on the role of the oocyte-expressed Xenopus classical androgen receptor (XeAR) in mediating these processes. Cellular fractionation and immunohistochemistry revealed that the XeAR was located throughout oocytes, including within the plasma membrane. RNA interference and oocyte maturation studies suggested that androgen-induced maturation was mediated in part by the XeAR in a transcription-independent fashion, perhaps by altering G protein-mediated signaling. While inducing minimal transcription in oocytes, all AR ligands promoted significant XeAR-mediated transcription in CV1 cells. In contrast, only testosterone and androstenedione potently induced oocyte maturation, whereas dihydrotestosterone and R1881 actually inhibited testosterone and human chorionic gonadotropin-induced maturation and signaling. These results suggest that the nature of a steroid-induced signal (genomic vs. nongenomic) may depend on the type of target cell, the receptor location within cells, as well as the ligand itself. The identification of molecules capable of selectively altering genomic vs. nongenomic signaling may be useful in delineating the roles of these pathways in mediating androgen responses and might lead to the development of novel compounds that specifically modulate these signals in vivo.

Rapid activation of glycogen phosphorylase by the endoplasmic reticulum unfolded protein response.

Endoplasmic reticulum (ER) stress is associated with misfolding of ER proteins and triggers the unfolded protein response (UPR). The UPR, in turn, helps restore normal ER function. Since fastidious N-linked glycosylation is critical for folding of most ER proteins, this study examined whether metabolic interconversions of precursors used for glycan assembly were controlled by the UPR. Thus, eight enzymes and factors with key roles in hexose phosphate metabolism were assayed in cytoplasmic extracts from primary dermal fibroblasts treated with UPR inducers. Stimulation of only one activity by the UPR was detected, AMP-independent glycogen phosphorylase (GP). GP activation required only 20 min of ER stress, with concurrent decreases in cellular glycogen and elevations of its metabolites Glc-1-P and Glc-6-P. Addition of phosphatase inhibitors to enzyme extracts from unstressed cells mimicked the effect of ER stress on GP activity, suggesting that phosphorylation of GP or a regulatory factor was involved. These data show that the UPR can modulate hexose metabolism in a manner beneficial for protein glycosylation. Since activation of GP appears to occur by a rapid post-translational process, it may be part of a general strategy of ER damage control, preceding the well-known transcription-dependent processes of the UPR that are manifested hours after the occurrence of ER stress.