Ephrin-A5 Is Required for Optimal Fertility and a Complete Ovulatory Response to Gonadotropins in the Female Mouse.

Follicle growth and ovulation involve the coordinated expression of many genes, driven by FSH and LH. Reports indicate that Eph receptors and ephrins are expressed in the ovary, suggesting roles in follicle growth and/or ovulation. We previously reported FSH-induced expression of ephrin-A5 (EFNA5) and 4 of its cognate Eph receptors in mouse granulosa cells. We now report that female mice lacking EFNA5 are subfertile, exhibit a compromised response to LH, and display abnormal ovarian histology after superovulation. Efna5(-/-) females litters were 40% smaller than controls, although no difference in litter frequency was detected. The ovarian response to superovulation was also compromised in Efna5(-/-) females, with 37% fewer oocytes ovulated than controls. These results corresponded with a reduction in ovarian mRNA levels of several LH-responsive genes, including Pgr, Ptgs2, Tnfaip6, Ereg, Btc, and Adamts4, suggesting that Efna5(-/-) ovaries exhibit a partially attenuated response to LH. Histopathological analysis indicated that superovulated Efna5(-/-) females exhibited numerous ovarian defects, including intraovarian release of cumulus oocyte complexes, increased incidence of oocytes trapped within luteinized follicles, granulosa cell and follicular fluid emboli, fibrin thrombi, and interstitial hemorrhage. In addition, adult Efna5(-/-) ovaries exhibited a 4-fold increase in multioocyte follicles compared with controls, although no difference was detected in 3-week-old mice, suggesting the possibility of follicle merging. Our observations indicate that loss of EFNA5 in female mice results in subfertility and imply that Eph-ephrin signaling may also play a previously unidentified role in the regulation of fertility in women.

The ephrin signaling pathway regulates morphology and adhesion of mouse granulosa cells in vitro.

Follicle-stimulating hormone (FSH)-mediated changes in granulosa cell adhesion and morphology are essential for preovulatory follicle development, given the dramatic changes in follicle size and granulosa cell number that occur during this transition. Members of the Eph-ephrin family of cell-positioning and adhesion molecules, a family that consists of ephrin ligands and their Ephrin (Eph) receptors, regulate cell location, adhesion, and migration during embryonic development and tumor growth. However, very little is known about ephrin signaling during folliculogenesis. We have found that FSH increases the expression of several members of the Eph-ephrin family and that this signaling regulates granulosa cell morphology and adhesion. FSH induced increased mRNA levels of the ephrin ligand, ephrin-A5 (Efna5), and its receptors, Eph receptors A3, A5, and A8 (Epha3, Epha5, and Epha8, respectively), in granulosa cells. Immunofluorescence studies indicated that EFNA5 and EPHA5 are located in the membrane of granulosa cells of developing mouse follicles. Eph-ephrin signaling directly affected granulosa cell morphology and adhesion. Recombinant EFNA5 reduced cell spreading and increased cell rounding in mouse primary granulosa cells and in a rat granulosa cell line, whereas EPHA5 reduced granulosa cell adhesion in both model systems. Both FSH and forskolin also increased Efna5 and Epha5 mRNA levels in rat and human granulosa cell lines, indicating that FSH regulates these genes via the cAMP-dependent protein kinase A pathway and that this regulation is conserved across different species. The present study identifies Eph-ephrin signaling as a novel FSH-mediated pathway regulating granulosa cell morphology and adhesion.

Minireview: Estrogen receptor-beta: mechanistic insights from recent studies.

The discovery of estrogen receptor-beta (ERbeta) in 1996 stimulated great interest in the physiological roles and molecular mechanisms of ERbeta action. We now know that ERbeta plays a major role in mediating estrogen action in several tissues and organ systems, including the ovary, cardiovascular system, brain, and the immune system, and that ERbeta and ERalpha generally play distinct physiological roles in the body. Although significant progress has been made toward understanding the molecular mechanisms of ERbeta action, particularly in vitro, there remains a large gap in our understanding of the mechanisms by which ERbeta elicits its biological functions in a true physiological context.