Inhibition of LH-induced and spontaneous meiotic maturation in mouse oocytes by N alpha-tosyl-L-lysine chloromethylketone

The effect of N alpha-tosyl-L-lysine chloromethylketone (TLCK), an inhibitor of trypsin-type proteases, on luteinizing hormone (LH)-induced and spontaneous meiotic maturation and follicular production of cAMP in mice was determined. When follicle-enclosed mouse oocytes were incubated with LH (1 micron/ml), they underwent the breakdown of the germinal vesicle (GVBD). TLCK (0.02-0.5 mM) inhibited LH-induced GVBD in folliculated oocytes. The concentration (0.5 mM) of TLCK that inhibited LH-induced GVBD did not significantly suppress LH-induced cAMP production by follicle cells. The effect of TLCK on spontaneous maturation in cumulus cell-enclosed and denuded oocytes was also determined. TLCK strongly inhibited spontaneous maturation in denuded oocytes only if it was added to the incubation medium for 1-3 h before oocytes were liberated from the follicular tissue. The inhibition of oocyte maturation by TLCK was significantly greater in cumulus cell-enclosed oocytes than in denuded oocytes, either with or without preincubation with TLCK. These results suggest that trypsin-type protease in oocytes participates in the process of meiotic maturation in mouse oocytes.     

Direct effects of leptin on mouse reproductive function: regulation of follicular, oocyte, and embryo development

Because body condition can affect reproduction, research has focused on the role of leptin, a body condition signal, in regulation of reproductive function. Objectives of this study were to determine if leptin supplementation directly affects 1) ovarian follicle growth and function, 2) oocyte maturation, or 3) preimplantation embryo development. Follicles cultured in the presence of recombinant mouse leptin resulted in a significant decrease in rate of follicle, but not oocyte, growth in a dose-dependent manner, with higher doses of leptin inhibiting growth. Leptin was also found to significantly increase stimulated progesterone, estradiol, and testosterone production/secretion by cultured follicles in a dose-dependent manner, with higher concentrations of leptin significantly increasing steroidogenesis. Culture of fully grown cumulus-enclosed germinal vesicle-intact (GV) mouse oocytes in the presence of increasing concentrations of leptin (0, 12.5, 25, 50, 100 ng/ml) had no effect on germinal vesicle breakdown (GVBD) or development to metaphase II (MII). Similarly, fully grown denuded oocytes showed no difference in GVBD at any concentration of leptin. However, maturation of denuded oocytes with 100 ng/ml leptin resulted in significantly reduced development to MII compared with oocytes matured with 0 or 12.5 ng/ml leptin. Culture of one-cell mouse embryos in increasing concentrations of leptin had no effect on cleavage or blastomere degeneration at 24 h of culture. Exposure of embryos for the first 96 h of development to increasing concentrations of leptin did not significantly affect total or expanded blastocyst development or hatching of blastocysts from zona pellucida. These results indicate leptin directly enhances insulin and gonadotropin-stimulated ovarian steroidogenesis, compromises denuded oocyte maturation, yet has no direct effect on preimplantation embryo development.     

Biochemical studies of mammalian oogenesis: Metabolic cooperativity between granulosa cells and growing mouse oocytes

Freeze fracture and lanthanum tracer experiments have shown that gap junctions exist throughout folliculogenesis between granulosa cells and growing mouse oocytes (Anderson and Albertini, J. Cell Biol.71, 680–686, 1976). The following lines of experimentation in the present study suggest that metabolic cooperativity exists between granulosa cells and their enclosed oocytes, i.e., gap junctions are functional, and that in most cases examined, greater than 85% of the metabolites present in follicle-enclosed oocytes were originally taken up by the granulosa cells and transferred to the oocyte via gap junctions: (1) When incubated with various radiolabeled compounds, follicle-enclosed oocytes contained more intracellular radioactivity than did oocytes with no attached granulosa cells (denuded oocytes); (2) for two radiolabeled ribonucleosides examined, the distribution of phosphorylated metabolites in follicle-enclosed oocytes resembled that of granulosa cells and differed significantly from that in denuded oocytes; (3) pulse-chase experiments with radiolabeled ribonucleosides revealed that during the chase period more radioactivity became associated with the follicle-enclosed oocyte; (4) treatments known to disrupt gap junctions in other cell types were effective in reversibly uncoupling metabolic cooperativity between granulosa cells and oocytes; and (5) a series of control experiments using (a) medium conditioned by granulosa cells and (b) cocultures of denuded oocytes and granulosa cells in which physical contact between the two cell types was not permitted demonstrated that contact between follicle cells and oocytes was necessary for observing metabolic cooperativity. Metabolic cooperativity was also found between follicle cells and oocytes in the two culture systems which support growth of mouse oocytes in vitro. The fact that oocytes do not grow well, if at all, in the absence of follicle cells and the large contribution of nutrients apparently furnished to the oocyte by the granulosa cells is consistent with the concept that gap junction mediated metabolic cooperativity between follicle cells and their enclosed oocytes is vital for mammalian oocyte growth.     

Estradiol synergism and inhibition of insulin-induced meiotic maturation in Rana pipiens oocytes in vitro

Estradiol 17-β (E2) was found to either inhibit or synergize Na-insulin (Ins)-induced meiotic maturation of Rana oocytes. Inhibition of Ins activity occurred in the presence of the follicular investments of the oocyte; synergism with Ins occurred in oocytes denuded of the follicle wall. Similarly, co-incubation of E2 with frog pituitary homogenate (FPH) or pregnenolone (Pe) significantly decreased meiotic reinitiation as determined by germinal vesicle dissolution (GVD) in follicle-enclosed oocytes. By contrast, E2 had no consistently significant effect on progesterone (P)-induced meiosis in follicle-enclosed oocytes. Furthermore, E2 had no significant effect, either inhibitory or synergistic, on Pe- or P-induced GVD of denuded oocytes. Thus, of the meiotogens tested (Ins, P, Pe, FPH), all but P were consistently inhibited by E2 in the presence of the follicle wall. Na-insulin was the only meiotogen tested (Ins, P, Pe) which was potentiated by E2 in denuded oocytes, However, when E2 and Ins were spatially separated on the surface of individual intact follicles, the result was synergism of Ins-induced GVD rather than inhibition. These results suggest that Ins acts to induce GVD in the denuded oocyte through a mechanism distinct from that used by P (ie, Ins mechanism allows E2 synergism while the P mechanism does not). The E2 inhibitory effect on Ins-induced GVD appears to be dependent upon simultaneous exposure of follicle wall tissue to mixtures of E2 and Ins. The synergistic effect of E2 on Ins-induced GVD is dependent upon the simultaneous exposure of the oocyte surface to Ins and E2, either as a homogenous mixture in the case of denuded oocytes or as single substances at independent sites, for follicle-enclosed oocytes.     

Effects of gonadotropins on oocyte maturation and progesterone production by porcine ovarian follicles cultured in vitro

Effects of gonadotropins on the maturation of isolated oocytes and production of progesterone by porcine ovarian follicles from gonadotropin treated gilts have been studied in vitro. The addition of gonadotropins (2 I. U./ml, PMSG, HGC or 2 mg/ml FSH) to the culture medium resulted in increasing the number (84 - 90 %) of isolated oocytes which reached metaphase II. Expansion of the whole cumulus mass was observed only in media containing PMSG, whereas FSH or HCG alone did not cause these marked changes in the cumulus cells. Denudation of the eggs prior to culture gave no significant differences in the maturation rates between oocytes cultured in media with or without gonadotropins. In vitro maturation of follicle-enclosed oocytes took place only in HCG treated animals. Removing the ovary at 15 or 60 minutes after intravenous HCG administration induced oocyte maturation only in 22% and 17% respectively. A sharp increase in the number of oocytes which resume meiosis during follicle culture was observed 4 hours after HCG injection (84 %) and all of the oocytes of the gilts ovariectomized at 8 hours after HCG injection matured during the culture period. The progesterone production of isolated follicles from control gilts (only PMSG injected) increased slowly during a 96-hour culture period (from 48 to 240 ng progesterone/follicle), whereas the secretion of progesterone was drastically increased after a 15 minute interval between HCG injection and ovariectomy (from 42 to 950 ng progesterone/follicle). Follicles removed 24 hours after HCG injection showed a further increase in steroid production (2000 ng progesterone/follicle) and consistently secreted large amounts of progesterone during the culture period.     

Protein kinase C mediates gonadotropin-releasing hormone agonist-induced meiotic maturation of follicle-enclosed rabbit oocytes.

The present study was undertaken to determine the effects of a protein kinase C inhibitor, staurosporine, on gonadotropin-releasing hormone agonist (GnRHa)-induced oocyte maturation and follicular prostaglandin (PG) production, and the response to direct activators of protein kinase C using rabbit mature follicle culture. Treatment of mature follicles with GnRHa (buserelin and leuprolide acetate) neither stimulated nor inhibited cAMP accumulation in both the follicle and oocyte. Exposure to staurosporine at 10(-6) M 60 or 15 min before GnRHa (buserelin) administration reduced significantly the meiotic maturation of follicle-enclosed oocytes induced by GnRHa at 10(-7) M. However, staurosporine addition coincident with the agonist or thereafter did not inhibit meiotic maturation. Staurosporine suppressed GnRHa-induced meiotic maturation in a dose-dependent manner, whereas hCG-stimulated oocyte maturation was not inhibited. Similarly, staurosporine administered 60 min before exposure to GnRHa suppressed GnRHa-stimulated PG production by mature follicles. The active phorbol esters, 10(-6) M 12-0-tetra-decanoyl phorbol 13-acetate (TPA) and 10(-6) M 4 beta-phorbol 12,13-didecanoate (4 beta-PDD) stimulated meiotic maturation whereas the biological inactive isomer, 4 alpha-PDD, did not. The kinetics of germinal versicle breakdown of follicle-enclosed oocytes in the presence of active phorbol esters paralleled that of GnRHa-treated oocytes. Furthermore, the concomitant addition of staurosporine at 10(-6) M to the culture medium inhibited significantly (p less than 0.05) TPA-induced meiotic maturation. These data demonstrate that GnRHa stimulated both the meiotic maturation of follicle-enclosed oocytes and follicular PG formation via a mechanism other than the cAMP-mediated process.(ABSTRACT TRUNCATED AT 250 WORDS)     

Role of G protein-coupled estrogen receptor 1, GPER, in inhibition of oocyte maturation by endogenous estrogens in zebrafish

Estrogen inhibition of oocyte maturation (OM) and the role of GPER (formerly known as GPR30) were investigated in zebrafish. Estradiol-17β (E2) and G-1, a GPER-selective agonist, bound to zebrafish oocyte membranes suggesting the presence of GPER which was confirmed by immunocytochemistry using a specific GPER antibody. Incubation of follicle-enclosed oocytes with an aromatase inhibitor, ATD, and enzymatic and manual removal of the ovarian follicle cell layers significantly increased spontaneous OM which was partially reversed by co-treatment with either 100 nM E2 or G-1. Incubation of denuded oocytes with the GPER antibody blocked the inhibitory effects of estrogens on OM, whereas microinjection of estrogen receptor alpha (ERα) antisense oligonucleotides into the oocytes was ineffective. The results suggest that endogenous estrogens produced by the follicle cells inhibit or delay spontaneous maturation of zebrafish oocytes and that this estrogen action is mediated through GPER. Treatment with E2 and G-1 also attenuated the stimulatory effect of the teleost maturation-inducing steroid, 17,20β-dihyroxy-4-pregnen-3-one (DHP), on OM. Moreover, E2 and G-1 down-regulated the expression of membrane progestin receptor alpha (mPRα), the intermediary in DHP induction of OM. Conversely DHP treatment caused a > 50% decline in GPER mRNA levels. The results suggest that estrogens and GPER are critical components of the endocrine system controlling the onset of OM in zebrafish. A model is proposed for the dual control of the onset of oocyte maturation in teleosts by estrogens and progestins acting through GPER and mPRα, respectively, at different stages of oocyte development.     

Induction and Inhibition of Meiotic Maturation in Follicle-enclosed Mouse Oocytes by Forskolin

A continuous exposure of follicle-enclosed mouse oocytes to ovine luteinizing hormone (LH, 10 μg/ml) in vitro resulted in a 3-fold elevation of CAMP levels in the follicle cells, but not the oocytes, with subsequent oocyte maturation. When follicle-enclosed oocytes were exposed to forskolin (0.01–10 μM) for 2 hr and then incubated in forskolin-free medium (transient exposure group), oocytes underwent germinal vesicle breakdown in a dose-dependent manner. In contrast, a continuous exposure of the follicles to forskolin (10 μM) for up to 10 hr failed to induce resumption of meiosis. Follicle cell cAMP levels increased within 2 hr after the initial exposure to forskolin, and thereafter decreased rapidly regardless of whether forskolin treatment was transient or continuous. A similar transient increase in oocyte cAMP levels was observed after transient or continuous treatment with forskolin. It was evident, however, that at any time examined oocyte cAMP levels were consistently higher in the continuous exposure group than in the transient exposure group. Furthermore, a continuous exposure to forskolin also blocked LH-induced meiotic maturation. These findings suggest that elevated levels of cAMP in the oocyte block meiotic maturation in mouse oocytes. The present results further suggest that an increase in follicle cell cAMP levels is essential to the LH-induced meiotic maturation.     

Steroidogenesis in Fundulus heteroclitus. IV. Dichotomous effects of a phorbol ester on ovarian steroid production and oocyte maturation.

The possible role of protein kinase C (PKC) activation in mediating the stimulatory actions of a Fundulus pituitary extract (FPE) on ovarian steroidogenesis and oocyte maturation was investigated. The phorbol ester, phorbol 12-myristate 13-acetate (PMA), alone slightly increased basal 17 alpha-hydroxy,20 beta-dihydroprogesterone (DHP) and 17 beta-estradiol (E2) synthesis and significantly stimulated germinal vesicle breakdown (GVBD). Addition of FPE promoted synthesis of DHP, testosterone (T), and E2, and initiated GVBD. Phorbol ester inhibited FPE-induced steroidogenesis but increased the number of oocytes that underwent GVBD. Phorbol ester also markedly impeded induction of steroidogenesis by dibutyryl cAMP and differentially affected the conversion of 25-hydroxycholesterol, pregnenolone, or progesterone to DHP, T, and E2: DHP production was not affected; T production diminished; and E2 synthesis increased (T aromatization also increased). These results suggest an inhibitory role for the PKC pathway on FPE-induced ovarian steroid production, with PMA appearing to affect various steroidogenic steps. The stimulatory action of PMA on oocyte maturation seems to be independent of follicular steroid production since aminoglutethimide, an inhibitor of steroidogenesis, did not block PMA-induced GVBD. Moreover, PMA had a marked stimulatory effect on GVBD in denuded oocytes. Thus, in contrast to the inhibitory role found for the PKC pathway on ovarian follicular steroidogenesis, activation of PKC in the oocyte may serve as a signal-transducing mechanism leading to GVBD.     

Evidence for a role of Na+,K(+)-ATPase in the hydration of Atlantic croaker and spotted seatrout oocytes during final maturation.

During final maturation the oocytes of many marine teleosts swell four to five times their original size due to uptake of water. The involvement of active inorganic ion transport and Na+,K(+)-ATPase in oocyte hydration in Atlantic croaker (Micropogonias undulatus) and spotted seatrout (Cynoscion nebulosus), marine teleosts which spawn pelagic eggs, was investigated by examining changes in the inorganic ion content of ovarian follicles containing mainly oocytes, by performing in vitro incubations of the follicles with ion channel blockers, and by assaying membrane preparations of ovaries containing hydrating and non-hydrating oocytes for Na+,K(+)-ATPase activity and content. There were marked increases in the contents of K+, Mg++, and Ca++, but not Na+, in oocytes of M. undulatus and C. nebulosus during hydration. Incubation of follicle-enclosed oocytes in K(+)-free medium or with ouabain or amiloride, inhibitors of Na+,K(+)-ATPase and Na+ channels, respectively, blocked gonadotropin-induced oocyte hydration in M. undulatus. In addition, Na+,K(+)-ATPase activity increased threefold and the concentration of the enzyme increased 50% in ovarian tissue during oocyte hydration. These results strongly suggest a major role for active ion regulation by a ouabain-sensitive Na+,K(+)-ATPase system in oocyte hydration in two species of sciaenid fishes.     

Activin A stimulates meiotic maturation of the rat oocyte in vitro

The effect of activin A on meiotic maturation was analyzed in oocytes from immature rats treated with PMSG. Activin A, which was purified as the erythroid differentiation factor, accelerated the maturation of not only follicle-enclosed oocytes and oocyte-cumulus complexes, but also denuded oocytes, as measured by an increase in the percentage of oocytes with germinal vesicle breakdown (GVBD). Oocyte maturation was not accelerated by activin A in the presence of the inhibitor of GVBD such as cyclic-AMP. These results showed activin A is a potent in vitro stimulator of oocyte maturation.     

Regulation of murine oocyte meiosis: evidence for a gonadotropin- induced, cAMP-dependent reduction in a maturation inhibitor

We have developed an assay that can detect relative changes in the amount of a non-cAMP inhibitor of maturation present in cumulus cells (Eppig et al., 1983, Dev. Biol., 100:39-49). Using this assay in which accelerated maturation of a group of treated cumulus cell-oocyte complexes relative to untreated complexes indicates a decrease in the amount of inhibitor, results of the experiments described here suggest a possible relationship between elevation of cAMP levels and subsequent decreased amounts of a non-cAMP inhibitor. Mouse oocytes obtained from cumulus cell-oocyte complexes treated with luteinizing hormone (LH) resumed meiosis prior to oocytes obtained from untreated complexes; the degree of acceleration of maturation was dependent on LH concentration. A similar result was obtained with follicle-stimulating hormone (FSH). Correlated with LH- or FSH-acceleration of maturation was an LH- or FSH-induced elevation of cumulus cell cAMP levels. Inhibiting LH-induced elevation of cumulus cell cAMP levels inhibited LH-induced acceleration of maturation. An initial incubation of complexes in medium containing dibutyryl cAMP (dbcAMP) also promoted acceleration of maturation. In contrast, maturation of denuded oocytes was not altered by treatment with either LH, FSH, or dbcAMP. Complexes initially incubated in dbcAMP-containing medium still demonstrated acceleration of maturation after a subsequent 2 h incubation in dbcAMP-free medium. Relative to untreated complexes, none of these treatments disrupted intercellular communication between cumulus cells and the oocyte. Elevating follicle cAMP levels with cholera toxin induced maturation of follicle-enclosed oocytes when cumulus cell-oocyte coupling was still fully maintained. These results are interpreted to indicate that gonadotropin-mediated acceleration of maturation is via a cAMP-dependent reduction in the level of a maturation inhibitor present in granulosa/cumulus cells.     

Pituitary adenylate cyclase-activating polypeptide (PACAP) and its receptors in the zebrafish ovary: evidence for potentially dual roles of PACAP in controlling final oocyte maturation

Pituitary adenylate cyclase-activating polypeptide (PACAP) is a neuropeptide originally purified from ovine hypothalamus for its potent activity to stimulate cAMP production. However, its presence and action have also been demonstrated in various peripheral tissues including the ovary. In the zebrafish, two forms of PACAP (PACAP(38)-1, adcyap1a; and PACAP(38)-2, adcyap1b) and three PACAP receptors (PAC(1)-R, adcyap1r1; VPAC(1)-R, vipr1; and VPAC(2)-R, vipr2) were all expressed in the ovary. Interestingly, although both follicle cells and oocytes express adcyap1b, the expression of adcyap1a was restricted to the oocytes only. Among the three receptors, adcyap1r1 and vipr2 were expressed in the oocytes, whereas the expression of vipr1 was exclusively located in the follicle cells. Temporal expression analysis of PACAP ligands and receptors during folliculogenesis suggested that PACAP might play differential roles in regulating follicle growth and maturation through different receptors. The two receptors that are expressed in the oocyte (adcyap1r1 and vipr2) showed a significant increase in expression at the transition from the primary growth (PG) stage to previtellogenic (PV) stage and their levels maintained high during follicle growth. However, when the follicle development approached full-grown (FG) stage, these two receptors both decreased significantly in expression. In contrast, vipr1, the receptor expressed in the follicle cells, showed little change in expression at the PG-PV transition and afterwards during follicle growth; however, its expression surged dramatically at the FG stage prior to oocyte maturation. Based on these results, we hypothesized that PACAP might play dual roles in regulating follicle growth and maturation through different receptors located in different compartments. PACAP may stimulate oocyte growth but block its maturation in early follicles by acting directly on the oocyte via PAC1-R and VPAC2-R, whose expression is dominant in growth phase; however, PACAP may promote oocyte maturation in the maturation phase via VPAC1-R on the follicle cells, whose expression surges in FG follicles prior to maturation and is consistently high in the follicles undergoing final maturation. This hypothesis was further supported by the observation that PACAP promoted maturation of follicle-enclosed oocytes but suppressed spontaneous maturation of denuded oocytes in vitro. This study provides strong evidence for a PACAP-mediated signaling network in the zebrafish ovarian follicle, which may play roles in orchestrating follicle growth and maturation via different types of receptors located in different compartments of the follicle.     

Mouse oocyte development in vitro with various culture systems

These experiments were designed to determine whether or not hormones are required for the growth of mouse oocytes and to assess the possible role of companion granulosa cells in oocyte growth. To approach these problems, four systems for the culture of oocytes, either alone or in association with granulosa cells, were utilized: (1) isolated oocyte culture, (2) isolated oocyte-ovarian cell coculture, (3) isolated follicle culture, and (4) ovarian organ culture. Oocytes from 8-day-old B6D2F₁ mice failed to grow in isolated oocyte culture. Addition of follicle-stimulating hormone (FSH), 17β-estradiol (E₂), or serum to the medium failed to prevent oocyte degeneration or to promote oocyte growth. On the other hand, oocytes in isolated follicle culture or in organ culture grew significantly in defined medium. The results showed that oocytes grown in isolated follicle culture under defined conditions and in the absence of gonadotropins resemble oocytes grown in vivo in terms of their ultrastructural characteristics, with the exception of enlarged mitochondria. In addition, these oocytes were shown to exhibit some normal functional characteristics in terms of their increased levels of CO₂ evolution from exogenous pyruvate, and the ability of the fully grown oocytes to initiate meiotic maturation when freed from granulosa cells. It was concluded that gonadotropins are not necessary for oocyte growth and that gonadotropins are not required to potentiate the spontaneous meiotic maturation of oocytes which occurs after their isolation from granulosa cells. The results indicated that association of granulosa cells and oocytes was necessary for oocyte growth. However, isolated oocytes in coculture with ovarian cells failed to grow. Addition of FSH or E₂ to the cocultures failed to promote oocyte growth or delay oocyte degeneration. It was concluded that, under the culture conditions used, granulosa cells must be in contact with the oocyte, perhaps by means of specialized cell junctions, for oocyte growth to occur.     

Spontaneous oocyte maturation in Rana pipiens: Estrogen and follicle wall involvement

Immature (germinal vesicle stage) Rana pipiens oocytes typically remain arrested in prophase I of meiosis even after extended periods of in-vitro culture, if not stimulated with hormones. We have, however, sporadically observed “spontaneous” occurrences of oocyte maturation in vitro without the addition of hormones. This study documents some of our observations on this phenomenon and presents experimental results concerning the effects and possible involvement of estrogen and follicle wall components in regulating spontaneous oocyte maturation. Estrogen was found to inhibit spontaneous oocyte maturation (GVBD) in a dose-dependent fashion. Follicles in which spontaneous maturation was inhibited by estrogen retained their responsiveness (GVBD) to both frog pituitary homogenate (FPH) and progesterone stimulation. Inhibitory effects of estrogen on spontaneous maturation, however, were not reversed following incubation of washed follicles in plain culture medium without added hormones. Possible involvement of progesterone synthesis in spontaneous oocyte maturation was ascertained by simultaneously monitoring endogenous progesterone synthesis and the occurrence of spontaneous GVBD over the course of the maturation process. In spontaneous maturing follicle there was a gradual increase in basal levels of progesterone synthesis that preceded GVBD. Significantly, addition of estrogen abolished both the spontaneous progesterone production and spontaneous oocyte maturation. When FPH was added to follicles exhibiting spontaneous oocyte maturation, progesterone production was augmented and the time course of oocyte maturation was greatly accelerated. Involvement of ovarian components in the maturation process was investigated by selective removal of various follicle layers by microdissection. Removal of follicle epithelium and theca layer (defolliculation) markedly decreased spontaneous and FPH-induced maturation, whereas removal of the entire follicle wall (denudation) completely blocked it. Our results suggest that both spontaneous and FPH-induced maturation involve an estrogen sensitive process in the follicle wall. Thus, somatic follicle cells appear to serve as a common mediator for both types of maturation, which are linked by some intrafollicular mechanism involving steroidogenesis. Hence, estrogen may play an important role as an endogenous intrafollicular regulator of oocyte meiotic maturation.     

The role of follicle cells in Rana pipiens oocyte maturation induced by delta 5-pregnenolone.

Previous studies have indicated that pituitary-initiated oocyte maturation in the amphibian is mediated by steroidogenesis in the somatic portion of the follicle. This study compares the ability of (1) oocytes surrounded by a single layer of follicle cells, (2) denuded oocytes, and (3) isolated follicle cells to metabolize Δ⁵-pregnenolone, the common precursor of the steroids. Use of radiolabeled compounds demonstrates that the conversion of Δ⁵-pregnenolone to progesterone is confined to the follicle cells, while further reduction of progesterone takes place in the oocyte. The follicle cells also convert Δ⁵-pregnenolone to a form more potent in inducing meiotic maturation. Thus, the behavior of follicle cells in isolation is consistent with the suggested site of pituitary action leading to meiotic maturation as proposed by an earlier theory.