Secretion of cumulus expansion-enabling factor (CEEF) in porcine follicles

The objective of this study was to find out whether porcine cumulus and mural granulosa cells can secrete cumulus expansion-enabling factor (CEEF). Culture drops of M-199 medium were conditioned with denuded porcine oocytes (1 oocyte/μl), cumulus cells from oocytectomized complexes (1 OOX/μl), pieces of mural granulosa isolated from preantral to preovulatory follicles (1000 cells/μl), or oviductal cells (1000 cells/μl) for 24 hr. The production of CEEF was assessed by the addition of mouse OOX and follicle-stimulating hormone (FSH) (1 μg/ml) to microdrops of the conditioned medium. After 16–18 hr, expansion of the mouse OOX was scored on a scale of 0 to 4 by morphologic criteria. Mouse OOX did not expand in nonconditioned FSH-supplemented medium. Immature porcine oocytes produced +3 to +4 expansion of the mouse OOX. Granulosa cells isolated from preantral and early antral follicles and cumulus cells isolated from all stages of follicle development constitutively secreted CEEF under in vitro conditions. Mural granulosa cells of small, medium, and preovulatory (PMSG) follicles also secreted CEEF in vitro; however, FSH or leutenizing hormone (LH) stimulation was essential for this secretion. Hormonally induced secretion of CEEF was accompanied by expansion of the mural granulosa itself. Granulosa cells isolated from follicles of gilts 20 hr after PMSG and human chorionic gonadotropin (hCG) administration did not produce CEEF and did not expand in response to FSH and LH in vitro. CEEF activity also was found in the follicular fluid of small antral follicles, was reduced in medium follicles, and was not detectable in PMSG-stimulated follicles. However, CEEF activity was reestablished in the follicular fluid of preovulatory follicles by hCG injection, conceivably due to increased production of CEEF by cumulus cells. We conclude that (1) porcine cumulus and mural granulosa cells are capable of CEEF production in vitro and (2) autocrine secretion of CEEF by cumulus cells is involved in regulation of porcine cumulus expansion both in vitro and in vivo. Mol. Reprod. Dev. 49:141–149, 1998. © 1998 Wiley-Liss, Inc.     

Secretion of paracrine factors enabling expansion of cumulus cells is developmentally regulated in pig oocytes

To demonstrate secretion of cumulus expansion-enabling factor (CEEF) by porcine oocytes, we used an interspecies testing system. Porcine oocytes were used to condition culture medium, and the presence of CEEF was tested using mouse oocytectomized complexes (OOX), which require CEEF for expansion. Follicle-stimulating hormone-stimulated expansion and synthesis of hyaluronic acid (HA) by mouse OOX were assessed after 18 h of culture in media conditioned by porcine oocytes: 1) at different stages of maturation and 2) in which maturation was inhibited with a specific inhibitor of cdk-kinases, butyrolactone I. Fully grown (GV-germinal vesicle), late-diakinesis (LD), metaphase I (MI), and metaphase II (MII) oocytes were prepared by culture of oocyte-cumulus complexes (OCC) for 0, 22, 27, and 42 h, respectively. To block GV breakdown, porcine oocytes were cultured for 27 h in medium supplemented with butyrolactone I (50 microM). Medium conditioned by oocytes in GV, LD, and after butyrolactone I block allowed full expansion of >90% of mouse OOX, whereas oocytes in MI and MII caused disintegration of mouse OOX without cumulus mucification. To measure synthesis of HA by cumulus cells, 25 mouse OOX were cultured in the conditioned media in the presence of 2.5 microCi of D-[6-(3)H]glucosamine hydrochloride. After 18 h, incorporation of the [(3)H]glucosamine into HA was determined either in complexes (retained HA) or in medium plus complexes (total HA). Total HA accumulation by mouse OOX was not different from that of intact OCC. However, oocytes in GV, LD, and after butyrolactone I treatment enabled mouse OOX to retain significantly more HA within the complex than oocytes in MI and MII. The results indicate that secretion of factors that promote the retention of HA within the complex is developmentally regulated during oocyte maturation.     

FSH-induced expansion of the mouse cumulus oophorus in vitro is dependent upon a specific factor(s) secreted by the oocyte

Although it has been shown that granulosa cells regulate the growth and meiotic maturation of mammalian oocytes, there is little evidence of a role for the oocyte in the differentiation or function of granulosa cells. To test the hypothesis that the oocyte participates in the regulation of granulosa cell function, oocytes were removed from isolated oocyte-cumulus cell complexes by a microsurgical procedure and oocytectomized complexes were tested for their ability to undergo expansion in response to follicle-stimulating hormone (FSH). FSH increased the levels of intracellular cAMP, the activity of the hyaluronic acid-synthesizing enzyme system, and induced cumulus expansion in intact complexes. In contrast, FSH did not induce increased hyaluronic acid-synthesizing enzyme activity or cumulus expansion in oocytectomized complexes. Therefore, the participation of the oocyte is necessary for the cumulus cells to synthesize hyaluronic acid and undergo cumulus expansion in vitro in response to stimulation with FSH. FSH induced the elevation of intracellular cAMP to the same extent in both intact and oocytectomized complexes and the cAMP analog 8-bromo cyclic adenosine monophosphate (8Br-cAMP) did not stimulate expansion in oocytectomized complexes. Therefore, the influence of the oocyte on cumulus expansion occurs downstream from the elevation of cAMP levels in the cumulus cells. Epidermal growth factor (EGF), a potent stimulator of cumulus expansion in intact complexes, which probably acts by a mechanism at least initially different from FSH, failed to stimulate cumulus expansion after oocytectomy. Next, oocytectomized complexes were either cocultured with germinal vesicle stage denuded oocytes or cultured in medium conditioned by denuded oocytes. In both cases, FSH or EGF stimulated expansion by oocytectomized complexes. The degree of expansion was directly correlated to the number of oocytes used to condition the medium. Contact between the oocyte and the cumulus cells is not necessary for cumulus expansion. Rather, a factor(s) secreted by the oocyte is necessary for the cumulus cells to undergo expansion in response to either FSH or EGF. FSH did not induce expansion of oocytectomized complexes in media conditioned by various somatic cells such as granulosa cells, fibroblasts, and Sertoli cells; by a mixed population of male germ cells; or by spermatozoa. This suggests that the expansion enabling activity is specific to the oocyte. These results demonstrate that the oocyte participates in the regulation of cumulus cell function.     

Presence of cumulus cells during in vitro fertilization protects the bovine oocyte against oxidative stress and improves first cleavage but does not affect further development

The present study was conducted to evaluate the function of cumulus cells during bovine IVF Oocytes within cumulus-oocyte complexes (COCs) or denuded oocytes (DOs) were inseminated in control medium, or DOs were inseminated in cumulus cell conditioned medium (CCCM). DOs exhibited reduced cleavage and blastocyst formation rates when compared with intact COCs. The reduced blastocyst formation rate of DOs resulted from reduced first cleavage but subsequent embryo development was not changed. Live-dead staining and staining for apoptotic cells revealed no differences in blastocysts from oocytes fertilized as COC or DO. Fertilization of DOs in CCCM partially restored the cleavage rate, suggesting that factors secreted by cumulus cells are important for fertilization but that physical contact between oocytes and cumulus cells is required for optimal fertilization and first cleavage. Exposure of COCs to hydrogen peroxide shortly before fertilization reduced the cleavage rate, but did not lead to enhanced death of cumulus cells or oocyte death. Exposure of DOs to hydrogen peroxide, however, resulted in oocyte death and a complete block of first cleavage, suggesting that cumulus cells protect the oocyte against oxidative stress during fertilization.     

Developmental pattern of the secretion of cumulus expansion-enabling factor by mouse oocytes and the role of oocytes in promoting granulosa cell differentiation

The expansion, or mucification, of the mouse cumulus oophorus in vitro requires the presence of an enabling factor secreted by the oocyte as well as stimulation with follicle-stimulating hormone (FSH). This study focuses on (1) the ability of mouse oocytes to secrete the enabling factor at various times during oocyte growth and maturation, (2) the temporal relationships between the development of the capacity of the oocyte to undergo germinal vesicle breakdown, the ability of the oocyte to secrete cumulus expansion-enabling factor, and the capacity of the cumulus oophorus to undergo expansion, and (3) the role of the oocyte in the differentiation of granulosa cells as functional cumulus cells. Growing, meiotically incompetent oocytes did not produce detectable amounts of cumulus expansion-enabling factor, but fully grown meiosis-arrested oocytes, maturing oocytes, and metaphase II oocytes did. Detectable quantities of enabling factor were produced by zygotes, but not by two-cell stage to morula embryos. The ability of oocytes to secrete cumulus expansion enabling factor and the capacity of cumulus cells to respond to FSH and the enabling factor are temporally correlated with the acquisition of oocyte competence to undergo germinal vesicle breakdown. Mural granulosa cells of antral follicles do not expand in response to FSH even in the presence of cumulus expansion-enabling factor, showing that mural granulosa cells and cumulus cells are functionally distinct cell types. The perioocytic granulosa cells of preantral follicles isolated from 12-day-old mice differentiate into functional cumulus cells during a 7-day period in culture. Oocytectomized granulosa cell complexes grown in medium conditioned by either growing or fully grown oocytes were comparable in size to intact complexes and maintained their 3-dimensional integrity to a greater degree than oocytectomized complexes grown in unconditioned medium. After 7 days, the oocytectomized complexes were stimulated with FSH in the presence of enabling factor, but no expansion was observed whether or not the oocytectomized complexes grew in the presence of oocyte-conditioned medium. These results suggest that a factor(s) secreted by the oocyte affects granulosa cell proliferation and the structural organization of the follicle, but continual close association with the oocyte appears necessary for the differentiation of granulosa cells into functional cumulus cells, insofar as they are capable of undergoing expansion.     

Developmental and hormonal regulation of cumulus expansion and secretion of cumulus expansion-enabling factor (CEEF) in goat follicles

The objective of this article was to study the developmental and hormonal regulation of cumulus expansion and secretion of cumulus expansion-enabling factor (CEEF) in goat follicles. M-199 medium was conditioned for 24 hr with cumulus-denuded oocytes (DOs), oocytectomized complexes (OOXs), or mural granulosa cells (MGCs) from goat follicles of different sizes. Mouse OOXs and eCG were added to culture drops of the conditioned medium and cumulus expansion was scored at 18 hr of culture to assess CEEF production. While mouse OOXs did not expand, goat OOXs underwent full cumulus expansion when cultured in nonconditioned eCG-supplemented M-199 medium. When cultured in nonconditioned medium containing 10% follicular fluid (FF) from goat medium (2-4 mm) and small (0.8-1.5 mm) follicles, 71-83% mouse OOXs expanded; but expansion rates decreased (P < 0.05) at either lower or higher FF concentrations. FF from large (5-6 mm) follicles did not support mouse OOX expansion at any concentrations. While medium conditioned with DOs from follicles of all the three sizes supported expansion of 80-90% mouse OOXs, medium conditioned with mature DOs had no effect. While cumulus cells from follicles of all the three sizes secreted CEEF in the absence of gonadotropins, MGCs from large follicles became gonadotropin dependent for CEEF production. Both FSH and LH stimulated CEEF production by large follicle MGCs, but FSH had a shorter half-life than LH to expand mouse OOXs. Few meiosis-incompetent goat oocytes from small follicles underwent cumulus expansion when cultured in medium conditioned with goat DOs or cocultured with goat COCs from medium follicles. It is concluded that (1) goat cumulus expansion is independent of the oocyte; (2) the limited CEEF activity in FF from large follicles was due mainly to the inability of MGCs in these follicles to secret the factor in absence or short supply of gonadotropins; (3) the cumulus expansion inability of the meiosis incompetent goat oocytes was due to the inability of their cumulus cells to respond to rather than to produce CEEF.     

Localization and synthesis of hyaluronic acid in the cumulus cells and mural granulosa cells of the preovulatory follicle.

Mural and cumulus granulosa cells synthesize hyaluronic acid (HA) and expand in vitro in response to follicle-stimulating hormone and a soluble factor(s) produced by fully grown oocytes. In the present study we examined HA synthesis and extracellular matrix organization by the two cell populations in vivo during the preovulatory period. After injection of human chorionic gonadotropin into pregnant mares' serum gonadotropin-primed animals, a progressive increase in HA synthesis was observed by the cumulus cell-oocyte complex (COC), and by the mural granulosa cells adjacent to the antrum (antral granulosa cells). The outermost layers of mural granulosa cells (peripheral granulosa cells) did not synthesize HA. Net HA synthesis was approximately 4 pg/cell for COCs isolated after full expansion induced either in vivo or in vitro, whereas the total HA content and cell number in the ovulated COC (approximately 11 ng HA and approximately 3000 cells per COC) were about threefold higher than for COCs expanded in vitro (approximately 4 ng HA and approximately 1000 cells per COC). The increased cell content of ovulated COCs appears to be primarily the result of inclusion of proximal mural granulosa cells which synthesize HA in response to the oocyte factor(s) and become incorporated in the expanded COC extracellular matrix mass. Media conditioned by oocytes enclosed in the cumulus cell mass (intact COCs) contained only 10-20% of the HA-stimulatory activity of media conditioned by an equal number of isolated oocytes when tested on mural granulosa cell cultures. Further, HA-stimulatory activity of media conditioned by isolated oocytes was dramatically reduced (approximately 70%) by preincubation for 5 hr with cumulus cells compared to preincubation in the absence of cells. The results suggest that differences in HA synthesis between subregions of membrana granulosa depend on a diffusion gradient of the oocyte factor(s).     

Pig membrana granulosa cells prevent resumption of meiosis in cattle oocytes

Membrana granulosa was isolated from healthy large antral follicles of prepubertal or cyclic gilts stimulated with PMSG or PMSG and hCG. Ultrastructural observations revealed that pieces of pig membrana granulosa were associated with the basement membrane. The cattle cumulus-enclosed oocytes (COC) were placed in the rolled pieces of the pig membrana granulosa (PMG). After 8 and 24 hr of coculture with PMG from prepubertal gilts, only 16% and 21% of oocytes underwent GVBD, respectively. PMG from PMSG-stimulated cyclic gilts blocked the resumption of meiosis in all COC. The inhibitory effect of heterologous granulosa cells was fully reversible. When COC were initially incubated for 2 and 4 hr, subsequent culture in PMG prevented GVBD in 100% and 36% of oocytes, respectively. This suggests that functional contact between COC and PMG was established during the first 2 hr of coculture. To follow metabolic cooperation between PMG and COC, PMG was prelabeled with ³H-uridine and cocultured with COC. Autoradiography on semithin sections revealed the intensive passage of ³H-uridine from PMG into the cumulus layer and an oocyte. COC placed in PMG after GVBD (8 and 12 hr of an initial incubation) did not extrude the first polar body. PMG isolated from cyclic gilts after PMSG and hCG stimulation also inhibited GVBD of COC. Since nearly all COC placed in PMG isolated 10 and 12 hr after hCG remained in the GV stage after 24 hr of coculture, the hCG stimulation did not substantially diminish the meiosis inhibiting activity of PMG. During coculture, cattle cumulus cells were closely associated with the basement membrane, but no gap junctions were formed among heterologous granulosa cells. These results suggest that an inhibitory factor secreted by pig granulosa cells is not species specific and it can act in vitro without the mediation of gap junctions. © 1993 Wiley-Liss, Inc.     

Meiotic state of bovine oocytes is regulated by interactions between cAMP,cumulus, and granulosa

Bovine oocytes are arrested at the prophase of first meiotic cell cycle. Meiosis resumes in oocytes of pre-ovulatory follicles upon LH surge. However, oocytes from secondary follicles spontaneously resume meiosis in the absence of hormones if removed from the follicle and cultured in vitro. The nature of meiotic arrestor in bovine follicles is poorly understood. In this study we investigated the role of cell-cell interactions between granulosa and cumulus cells and the oocyte in mediating maintenance of meiotic arrest by cAMP. We sorted oocytes as granulosa-cumulus oocyte complexes (GCOC) if surrounded with cumulus cells attached to a large granulosa investment or cumulus oocytes complexes (COC) if surrounded with cumulus cells only and investigated the role cAMP in maintenance of meiotic arrest in these oocytes under various conditions. In hormone- and serum-free medium both GCOC and COC enclosed oocytes resumed meiosis. When [cAMP](i) was elevated with addition of invasive adenylate cyclase (iAC) GCOC enclosed oocytes were maintained in the prophase with intact germinal vesicle (GV) while COC enclosed oocytes underwent GV breakdown (GVBD). iAC elevated [cAMP](i) in both types of oocytes to the same level. If oocytes were liberated from the cumulus and granulosa cells, they re-initiated meiosis in serum and hormone free medium, but remained in the GV stage if iAC was added to the medium. Untreated GCOC and COC enclosed oocytes extruded first polar body at the same frequency in hormone-supplemented media. GCOC and COC enclosed oocytes but not denuded oocytes (DO) cultured without somatic cells acquired developmental competence if cultured in hormone-containing medium. It is concluded that maintenance of meiotic arrest is regulated by the interplay of [cAMP](i), and cumulus and granulosa cells.     

Effects of transforming growth factors and activin-A on in vitro porcine oocyte maturation

Growth factors are known to regulate ovarian function. In the present study, effects of these growth factors, TGF-α, TGF-β, and activin-A were tested on spontaneous porcine oocyte maturation. Cumulus-oocyte complexes (COC) were cultured in the presence of TGF-α, TGF-β, and activin-A for 48 hr. Stages of meiotic maturation were assessed by staining with acetic orcein. Among these factors, only TGF-α significantly enhanced the maturation rate, whereas TGF-β suppressed the spontaneous maturation rate. The site of action of TGF-α on COC and the interaction between TGF-α and EGF receptor was also examined. Denuded oocytes, alone or in coculture with cumulus cells, were cultured in the presence of TGF-α for 48 hr. TGF-α did not have any significant effect on denuded oocyte maturation. Heptanol was employed to investigate the role of gap junctions on TGF-α-induced oocyte maturation in COC. Although heptanol did not have any significant effect in the control medium, heptanol reversed the stimulatory effect of TGF-α on porcine oocyte maturation. TGF-α was able to displace ¹²⁵I-EGF binding on COC. In conclusion, TGF-α enhances the spontaneous maturation of porcine oocytes by generating positive signal(s) in cumulus cells that are transferred to the oocyte via gap junctions. TGF-α shares the same receptor with EGF on porcine COC. TGF-β, in contrast, inhibits porcine oocyte maturation. © 1994 Wiley-Liss, Inc.     

Apoptotic index within cumulus cells is a questionable marker of meiotic competence of bovine oocytes matured in vitro

Information gained from most human studies indicate a negative correlation between the apoptotic index (AI) in cumulus cells (CC) and the quality of the corresponding oocytes. However, results obtained in other species are not so consistent. The rate of apoptosis-free COCs (cumulus oocytes complexes) subjected to IVM (in vitro maturation) also varies among studies. The aim of the present study was to investigate whether the AI in cumulus cells of post-IVM COCs is related to the morphology of pre-IVM COCs and to meiotic competence of bovine oocytes. COCs of known morphology (four grade scale) obtained from individual follicles were matured in a well-in-drop system. After IVM, the external layers of CC of each COC were analyzed by TUNEL. In order to determine the meiotic stage, oocytes were stained with DAPI. It was found that 25.6% of bovine COCs contained apoptosis-free cumulus cells. Moreover, the majority of COCs with apoptotic cells were characterized by apoptotic index lower than 15%. The level of apoptosis in CC was related neither to COC morphology nor to the oocyte meiotic stage. It is suggested that the extent of apoptosis in cumulus cells is not a reliable quality marker of the corresponding oocyte after IVM.     

Effect of cumulus cell removal of in vitro matured bovine oocytes prior to in vitro fertilization on subsequent cleavage rate

The aim of this study is to identify the effect of cumulus cells removal prior to the in vitro fertilization of matured bovine oocytes on cleavage rate. Denuded, matured oocytes were fertilized in presence or absence of loose cumulus cells, cumulus cell conditioned IVF medium (CCCM), charcoal-treated CCCM and charcoal-treated CCCM supplemented with progesterone at a final concentration of 150 ng/ml. After 18 h of incubation with sperm, the presumptive embryos were cultured on a BRL monolayer and the percentage of cleaved embryos was evaluated on Day 4. Removal of cumulus cells prior to IVF significantly reduced the cleavage rate (25% for denuded oocytes versus 56% for cumulus-oocyte complexes (COCs)). The addition of loose cumulus cells partially restored the effect of denudation (cleavage rate: 37% for denuded oocytes supplemented with loose cumulus cells versus 27% for denuded oocytes and 58% for COCs). CCCM also had a positive effect on the cleavage rate of oocytes denuded prior to IVF (36% for denuded oocytes fertilized in CCCM versus 14% for denuded oocytes). Treating the CCCM with charcoal resulted in complete loss of its effect on cleavage rate (18% for denuded oocytes fertilized in charcoal-treated CCCM versus 34% for denuded oocytes fertilized in CCCM). The addition of progesterone to charcoal-treated CCCM partially restored the reduction of the cleavage rate caused by charcoal treatment (27% for denuded oocytes fertilized in charcoal-treated CCCM supplemented with progesterone versus 14% for denuded oocytes fertilized in charcoal-treated CCCM and 36% for denuded oocytes fertilized in CCCM). In conclusion, removal of cumulus cells prior to IVF adversely affects the cleavage rate through loss of a factor secreted by these cells. This factor probably is progesterone.     

Effect of follicle cells on the acrosome reaction, fertilization, and developmental competence of bovine oocytes matured in vitro

The role of follicle cells in the acrosome reaction of frozen-thawed bovine spermatozoa, in vitro fertilization, cleavage, and development in vitro was investigated. Cumulus-oocyte complexes were cocultured and matured in vitro with additional granulosa cells for 24 hr. Immediately before in vitro insemination, the oocytes were divided into three types with different follicle cells: denuded and corona- and cumulus-enclosed oocytes. The proportion of live, acrosome-reacted spermatozoa significantly increased at 3 and 6 hr after insemination in all types of oocytes. However, the mean proportion of live, acrosome-reacted spermatozoa that inseminated cumulus-enclosed oocytes at 6 hr after insemination was significantly higher than that of spermatozoa inseminating denuded oocytes (18.3% and 13.3%, respectively). The frequency of in vitro fertilization was significantly higher for cumulus-enclosed oocytes (65.4%) than for denuded and corona-enclosed oocytes (30.8% and 39.4%, respectively). Cumulus-enclosed oocytes when cocultured with oviduct epithelial cells also had significantly higher rates of cleavage (two- to eight-cell, 59.8%; eight-cell, 22.4%) and blastocyst formation (7.7%) than denuded and corona-enclosed oocytes. No eight-cell embryos or more advanced stages of embryonic development were observed in either denuded or corona-enclosed oocytes without the coculture. The present results indicate that cumulus cells at fertilization play an important role in inducing the acrosome reaction and promoting a high fertilization rate, cleavage, and development into blastocysts in vitro.     

Oocyte-secreted factor activation of SMAD 2/3 signaling enables initiation of mouse cumulus cell expansion

Expansion of the mouse cumulus-oocyte complex (COC) is dependent on oocyte-secreted paracrine factors. Transforming growth factor beta (TGFB) superfamily molecules are prime candidates for the cumulus expansion-enabling factors (CEEFs), and we have recently determined that growth differentiation factor 9 (GDF9) alone is not the CEEF. The aim of this study was to examine oocyte paracrine factors and their signaling pathways that regulate mouse cumulus expansion. Using RT-PCR, oocytes were found to express the two activin subunits, Inhba and Inhbb, and activin A and activin B both enabled FSH-induced cumulus expansion of oocytectomized (OOX) complexes. Follistatin, an activin-binding protein, neutralized activin-induced expansion but had no effect on oocyte-induced expansion. The type I receptors for GDF9 and activin are activin receptor-like kinase 5 (ALK5) and ALK4, respectively, both of which activate the same SMAD 2/3 signaling pathway. We examined the requirement for this signaling system using an ALK 4/5/7 inhibitor, SB-431542. SB-431542 completely ablated FSH-stimulated GDF9-, activin A-, activin B-, and oocyte-induced cumulus expansion. Moreover, SB-431542 also antagonized epidermal growth factor-stimulated, oocyte-induced cumulus expansion. Using real-time RT-PCR, SB-431542 also attenuated GDF9-, activin A-, and oocyte-induced OOX expression of hyaluronan synthase 2, tumor necrosis factor alpha-induced protein 6, prostaglandin synthase 2, and pentraxin 3. This study provides evidence that the CEEF is composed of TGFB superfamily molecules that signal through SMAD 2/3 to enable the initiation of mouse cumulus expansion.     

Oocyte-secreted factor(s) determine functional differences between bovine mural granulosa cells and cumulus cells

Cumulus cells and mural granulosa cells (MGC) are phenotypically different and there is now evidence suggesting that the oocyte plays an active role in determining the fate of follicular somatic cells. This study investigates the role of oocyte-secreted factor(s) in the regulation of the growth and differentiation of cumulus and MGC. Bovine cumulus-oocyte complexes (COC) and MGC were cultured with various hormones for 18 h followed by a further 6-h pulse of [(3)H]thymidine as an indicator of follicular cell DNA synthesis. The COC incorporated 11 to 14 times more [(3)H]thymidine than MGC in either the absence or presence of 50 ng/ml insulin-like growth factor (IGF)-I. Purified porcine FSH (450 ng/ml) added together with IGF-I marginally increased (3)H incorporation in MGC relative to IGF-I alone but dramatically decreased incorporation in COC sixfold. Conversely, mean progesterone production in the presence of IGF-I + FSH was 13-fold higher from MGC than from COC, confirming a distinctive phenotype of cumulus cells. However, this phenotype was found to be dependent on the presence of the oocyte, as microsurgical removal of the oocyte (oocytectomy) resulted in an 11-fold decrease in [(3)H]thymidine incorporation in cumulus cells treated with IGF-I, elimination of the inhibitory effect of FSH on IGF-I-stimulated DNA synthesis, and led to a 2-fold increase in progesterone production in medium with IGF-I and FSH. All of these markers were completely restored to COC levels when oocytectomized complexes were cocultured with denuded oocytes (DO) at a concentration of 0.5 oocytes/microl, demonstrating that oocytes secrete a soluble factor(s) that promotes growth and attenuates cumulus cell progesterone secretion. In the presence of IGF-I, [(3)H]thymidine incorporation in MGC increased ninefold above control levels with the addition of DO. The addition of FSH to IGF-I-increased (3)H counts in MGC, however, led to a decrease in counts in MGC + DO as is also observed in COC. Furthermore, progesterone production was halved when DO were added to MGC cultures, most notably in the presence of IGF-I and/or FSH. These results provide further evidence that MGC and cumulus cells have distinctive phenotypes and that the oocyte is responsible for some of the characteristic features of cumulus cells. Bovine oocytes secrete a soluble factor(s) that simultaneously promotes growth and attenuates steroidogenesis in follicular somatic cells.     

Effects of maturational stage, cumulus cells and coincubation of mature and immature cumulus-oocyte complexes on in vitro penetrability of porcine oocytes

The in vitro penetrability of porcine oocytes is conditioned by several factors, some of which remain unclear. Knowledge of the different effects of the cellular components involved in penetrability would no doubt serve to simplify laboratory IVF methods. This study was designed to evaluate the effects of the following factors on penetrability: oocyte maturational stage, the presence of isolated or oocyte-attached cumulus cells, and coincubation of in vitro-matured and immature oocytes. Immature oocytes and oocytes matured in Waymouth medium were obtained from non atretic follicles and fertilized in TCM 199 medium. Sperm-rich fractions were collected by the gloved hand method and semen was used for IVF at a final concentration of 1 x 10(6) cells/mL in all experiments. Under the same conditions of IVF, the penetrability of the immature cumulus-oocyte complexes (COCs) was significantly lower than that of mature COCs, in terms of penetration rate and mean number of sperm per penetrated oocyte. This difference was abolished when the oocytes were denuded, leading to similar penetration rates. Coincubation of mature and immature COCs reduced the penetrability of immature COCs compared with that observed when these were incubated in isolation. However, neither the addition of isolated cumulus cells from decumulated mature oocytes nor the addition of denuded mature oocytes to immature COCs modified the penetration rate. These findings suggest that the presence of surrounding cumulus cells is mainly responsible for the differences observed in penetrability, regardless of the maturational stage of the oocyte. Moreover, when mature and immature COCs are coincubated, penetrability of immature COCs is diminished by the effects of the mature COC and not by the independent actions of the cellular components.     

Responsiveness of bovine cumulus-oocyte-complexes (COC) to porcine and recombinant human FSH,and the effect of COC quality on gonadotropin receptor and Cx43 marker gene mRNAs during maturation in vitro

Substantially less development to the blastocyst stage occurs in vitro than in vivo and this may be due to deficiencies in oocyte competence. Although a large proportion of bovine oocytes undergo spontaneous nuclear maturation, less is known about requirements for proper cytoplasmic maturation. Commonly, supraphysiological concentrations of FSH and LH are added to maturation media to improve cumulus expansion, fertilization and embryonic development. Therefore, various concentrations of porcine FSH (pFSH) and recombinant human FSH (rhFSH) were investigated for their effect on bovine cumulus expansion in vitro. Expression of FSHr, LHr and Cx43 mRNAs was determined in cumulus-oocyte complexes to determine whether they would be useful markers of oocyte competence. In serum-free media, only 1000 ng/ml pFSH induced marked cumulus expansion, but the effect of 100 ng/ml pFSH was amplified in the presence of 10% serum. In contrast, cumulus expansion occurred with 1 ng/ml rhFSH in the absence of serum. FSHr mRNA was highest at 0–6 h of maturation, then abundance decreased. Similarly, Cx43 mRNA expression was highest from 0–6 h but decreased by 24 h of maturation. However, the relative abundance of LHr mRNA did not change from 6–24 h of maturation. Decreased levels of FSHr, LHr and Cx43 mRNAs were detected in COCs of poorer quality. In conclusion, expansion of bovine cumulus occurred at low doses of rhFSH in serum-free media. In summary, FSHr, LHr and Cx43 mRNA abundance reflects COC quality and FSHr and Cx43 mRNA expression changes during in vitro maturation; these genes may be useful markers of oocyte developmental competence.