Alex Tsafriri

GREATER THAN 99% of ovarian follicles undergo a degenerative process called atresia during reproductive life. Extending earlier morphological analysis, recent studies have demonstrated that apoptotic cell death is the molecular mechanism underlying follicle atresia. The use of DNA 3′-end-labeling methods allows quantitation and identification of internucleosomal degradation of DNA after gel fractionation as well as in situ analysis of specific cell types undergoing DNA fragmentation in histological sections. Using rats as the experimental model, gonadotropins, epidermal growth factor (EGF)/transforming growth factor-α (TGFα), basic fibroblast growth factor (bFGF), insulin-like growth factor-I (IGF-I), and estrogens have been identified as follicle survival factors capable of suppressing apoptotic DNA fragmentation, whereas androgens, interleukin-6 (IL-6), and GnRH are potential atretogenic factors. This review summarizes the historical background of studies on follicle atresia and selection as well as recent advances in the intraovarian hormonal mechanisms that control follicle apoptosis. It is suggested that during the penultimate stage of follicle development, exposure to a survival factor (probably FSH) is responsible for follicle selection.

It is generally accepted that cyclic nucleotides are key signaling molecules in the control of oocyte meiotic resumption. Given the role of phosphodiesterases (PDEs) in cyclic nucleotide degradation, this study was undertaken to investigate the properties and regulation of PDEs expressed in rat oocytes. Cilostamide-sensitive PDE3 was the major activity detected in denuded oocytes, whereas no PDE3 activity could be detected in cumulus cells. Moreover, comparable levels of PDE3 activity were measured in cumulus-oocyte complexes (COCs) and in denuded oocytes. The oocyte PDE was recovered in the soluble fraction of the homogenate and immunoprecipitated with a specific PDE3A antibody. A significant and transient increase (P < 0.05) in PDE3 activity was measured in the oocytes after 30 min of culture (70 min after isolation) compared with immediately after collection (10 min after isolation). Conversely, no changes in activity were observed when denuded oocytes or cumulus cells were incubated for up to 130 min. Evaluation of oocyte maturation indicated that only 10% of oocytes had resumed meiosis at the peak of the PDE3 activity. A significant increase (P < 0.05) in PDE3 activity was measured in COCs when follicle-enclosed oocytes were cultured in the presence of hCG. Again, this increase preceded oocyte maturation. In conclusion, these data demonstrate that PDE3A is the major PDE form expressed in mammalian oocytes. PDE3A activity increases prior to resumption of meiosis in both spontaneous and gonadotropin-stimulated maturation. These findings strongly support the hypothesis that an increase in oocyte PDE3A activity is one of the intraoocyte mechanisms controlling resumption of meiosis in rat oocytes, at least in vitro.

Indirect evidence has suggested a role for plasminogen activator (PA) in ovulation. Our recent studies demonstrated that 1) tissue-type PA (tPA) is the predominant PA produced by preovulatory rat follicles in response to gonadotropins or GnRH; and 2) several inhibitors of the serine proteases, to which PA and plasmin belong, block ovulation. Here, the role of tPA and plasmin in ovulation was examined directly by the use of specific antibodies to tPA and alpha 2-antiplasmin (alpha 2AP). Immature female rats at 25-26 days of age were treated (sc) with 15 IU PMSG to induce multiple preovulatory follicles. Fifty-four hours later, tPA antibodies and alpha 2AP were injected into one of the ovarian bursae to check their ability to block ovulation, which was initiated with an ovulatory dose (4 IU) of hCG. The data are expressed as percent inhibition of ovulation in the treated vs. the untreated ovaries. A significant decrease in the ovulation rate was obtained by administration of 500 micrograms antibodies to tPA (39.6%) or 1-50 micrograms alpha 2AP (36-44%), whereas minimal inhibition (12%) was found at lower doses of anti-tPA (10 micrograms) or alpha 2AP (0.1 micrograms). Furthermore, nonimmune immunoglobulin G (500 micrograms) and heat-inactivated alpha 2AP were not effective. Anti-tPA and alpha 2AP suppressed ovulation only when injected at the time of hCG administration; later injections (4-h delay) were ineffective, suggesting that PA and plasmin are involved in the early follicular responses to the ovulatory stimulus. Histological observation of the ovaries did not reveal any pathological changes associated with the anti-tPA and alpha 2AP treatment. Suppression of ovulation, as evidenced by decreased number of tubal ova, was frequently accompanied with intraovarian release of the eggs into the follicular thecal compartment. Thus, these results provide direct evidence for an essential role of tPA and plasmin in ovulation.