Association of luteinizing hormone receptor gene expression with cell cycle progression in granulosa cells.

During hormonally induced ovarian follicle growth, granulosa cell proliferation increases and returns to baseline prior to the administration of an ovulatory stimulus. Several key genes appear to follow a similar pattern, including the luteinizing hormone receptor (LHCGR), suggesting an association between cell cycle progression and gene expression. The expression of LHCGR mRNA in granulosa cells isolated from immature rats and treated in culture with FSH increased in a time-dependent manner, whereas administration of the cell cycle inhibitor mimosine completely suppressed expression. Although forskolin was able to induce luteinization in cells treated with mimosine, human chorionic gonadotropin had no effect, indicating the functional loss of LHCGR. The effects of mimosine on cell cycle progression and LHCGR mRNA expression were reversible within 24 h of mimosine removal. Cell cycle inhibition did not alter the stability of LHCGR mRNA, indicating that the primary effect was at the transcriptional level. To determine whether the relationship between LHCGR expression and cell cycle were relevant in vivo, immature rats were given a bolus of PMSG, followed by a second injection of either saline or PMSG 24 h later to augment levels of proliferation. The expression of LHCGR mRNA was elevated in the ovaries of animals receiving a supplement of PMSG. Mimosine also blocked cell cycle progression and LHCGR mRNA expression in macaque granulosa cells isolated following controlled ovarian stimulation cycles and in two different mouse Leydig tumor lines. These data collectively indicate that LHCGR mRNA is expressed as a function of the passage of cells across the G1-S phase boundary.

Granulosa cell expression of G1/S phase cyclins and cyclin-dependent kinases in PMSG-induced follicle growth.

Follicular development involves a complex orchestration of granulosa cell proliferation and differentiation. It is becoming increasingly apparent that the rate of granulosa cell proliferation declines as follicles reach the large antral status, prior to an ovulatory gonadotropin stimulus, although a precise time course and mechanism for this decline has not been described. The goal of the present study was to characterize granulosa cell proliferation following the onset of antral follicle growth in PMSG-primed immature rats, with emphasis on G1/S phase cyclins and cyclin-dependent kinases. Flow cytometric analysis demonstrated that the percentage of granulosa cells in S phase peaked 24-30 h post-PMSG and declined to control levels 48 h after PMSG administration. Expression of both Cyclin D2 and Cdk 4 was highest 12h post-PMSG and decreased to control levels by 48 h. In addition, Cdk 2 protein increased transiently 12-24h after PMSG. Cyclin E expression increased significantly by 12h but remained elevated through 48 h, and multiple isoforms of Cyclin E were observed with increased proliferation. Both Cdk 4 and Cdk 2 activity parallel protein expression, although, changes in Cdk 2 were more marked. Levels of mRNA for the cell cycle inhibitors p21CIP1 and p27KIP1 increased significantly by 48 h post-PMSG. These results demonstrate that PMSG-stimulated movement of granulosa cells across the G1/S boundary during follicle growth is transient. In addition, the control of granulosa cell proliferation may reside through the regulation of both Cdk 2 and Cdk 4.

Proliferation of rat granulosa cells during the periovulatory interval.

Granulosa cell proliferation during luteinization and terminal differentiation has historically been assumed to decline rapidly after an ovulatory stimulus. In contrast, terminal differentiation in other cell types has recently been associated with a transient increase in proliferation, suggesting that this may occur in the ovarian follicle. The goal of the current study was to test the hypothesis that an ovulatory stimulus to rats results in additional granulosa cell proliferation before cell cycle arrest. Immature rats were given a single injection of pregnant mare serum gonadotropin (PMSG) followed by human chorionic gonadotropin (hCG) to initiate periovulatory events. The proportion of granulosa cells in S phase did not change until 12 h after hCG, although the majority of the post-hCG proliferation was localized to cumulus granulosa cells for up to 10 h after hCG. The expression of cyclin D2 mRNA did not decline until 12 h after hCG, although both cyclin-dependent kinase (Cdk)4 and Cdk6 mRNA increased at 6 h. Protein levels of cyclin D2 and Cdk4 did not change as a result of hCG, whereas cyclin E increased 6 h after hCG. Kinase activity of Cdk2 dropped markedly by 4 h after hCG, but a slight increase in activity was evident 6-8 h after hCG. These data suggest that cumulus granulosa cells continue to proliferate for up to 10 h after an ovulatory stimulus, possibly via cyclin E/Cdk2. It is concluded that proliferation is maintained in granulosa cells in the proximity of the oocyte during luteinization of the rat follicle.