The equine oocyte: Factors affecting meiotic and developmental competence

There is currently much interest in assisted reproduction techniques in the horse, however, many aspects of oocyte maturation, fertilization, and embryo development in the horse differ from those in other species. Because of the close attachment of the equine oocyte to the follicle wall, scraping of the follicle is the most effective method for oocyte recovery. A notable feature of equine oocytes is that those with expanded cumuli (Ex oocytes), which originate from atretic follicles, have higher meiotic competence (ability to mature to metaphase II in vitro) than do oocytes with compact cumuli (Cp oocytes). Cp oocytes originate in viable follicles but are largely juvenile. Recovery and culture of equine oocytes immediately after slaughter yields a higher maturation rate than that obtained from oocytes after ovary storage; this is related to damage to chromatin in Cp oocytes during storage. In contrast, developmental competence (rate of blastocyst development in vitro) is higher in oocytes recovered from the ovary after a delay. The optimum duration of maturation varies based on cumulus morphology and time of recovery from the ovary, but there is no difference in developmental competence between Ex and Cp oocytes. Because standard in vitro fertilization is not repeatable in the horse, oocyte transfer (surgical transfer of oocytes to the oviducts of inseminated mares) has been developed to allow fertilization of isolated oocytes. Fertilization in vitro may be achieved using intracytoplasmic sperm injection; culture of injected oocytes in a medium with high glucose can yield over 30% blastocyst development. Mol. Reprod. Dev. 77: 651–661, 2010. © 2010 Wiley‐Liss, Inc.     

Meiotic competence in horse oocytes: interactions among chromatin configuration, follicle size, cumulus morphology, and season

Horse oocytes were collected from an abattoir over a 15-mo period. After classification of follicle size and cumulus morphology, oocytes were either fixed immediately (0 h) or matured in vitro (24 h). There was no effect of season on the number of antral follicles present on the ovaries, or on oocyte maturation rate for any class of oocyte. The proportion of oocytes having condensed chromatin at 0 h increased with increasing follicle size. The oocyte maturation rate also increased with follicle size, and for follicles 相似文献   

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.     

Influence of oocyte collection technique on initial chromatin configuration, meiotic competence, and male pronucleus formation after intracytoplasmic sperm injection (ICSI) of equine oocytes

There is a great variability in the success of horse oocyte maturation and fertilization among laboratories. This study was conducted to determine if the meiotic and developmental competence of horse oocytes could be dependent on the method of oocyte collection, i.e., aspiration of follicular fluid with a vacuum apparatus, or opening follicles and scraping the granulosa layer. Horse oocytes were recovered from abattoir ovaries by aspiration or scraping and classified as having compact (Cp), expanded (Ex), or partial (P) cumuli. In Experiment 1 (Part A in May and Part B in October), oocytes were fixed immediately after collection to assess whether the collection method influenced the initial chromatin configuration of oocytes. In Experiment 2, in vitro maturation rates of oocytes recovered by aspiration or scraping were compared. In Experiment 3, oocytes were matured in vitro and submitted to intracytoplasmic sperm injection (ICSI). Initial chromatin configuration differed according to collection method in that there was a significantly higher prevalence of diffuse chromatin within the germinal vesicle in oocytes recovered by scraping than in oocytes recovered by aspiration (29/87, 33% and 28/166, 17%, respectively; P < 0.01). Maturation of oocytes to metaphase II did not significantly differ between scraped and aspirated oocytes (56/101, 55.4 % vs. 65/106, 61.4%, respectively). The overall pronucleus formation rate after ICSI of oocytes recovered by scraping was not significantly different than that of oocytes recovered by aspiration (50/99, 52.6% vs. 50/85, 68.5 %, respectively); however, the rate of abnormal fertilization was significantly higher for oocytes collected by aspiration (14/73, 19% vs. 6/94, 6%, respectively; P <0.05). These results demonstrate that the collection method affects the population of recovered oocytes and may contribute to differences in results observed among laboratories working with horse oocytes.     

Effect of ovary holding temperature and time on equine granulosa cell apoptosis, oocyte chromatin configuration and cumulus morphology

The effects of ovary holding time and temperature on granulosa cell apoptosis, oocyte chromatin configuration and cumulus morphology were investigated through a series of experiments. Three experiments were performed to determine the effect of ovary holding time and temperature on granulosa cell apoptosis. Ovaries were held (1) at 20, 30 or 35-37 degrees C for up to 2h, (2) at 30 degrees C for 0-1, 1-2, 2-3, 3-4, 4-6 or 6-10h, and (3) granulosa cells were held for 0, 1, 2, 3, 5, 12 or 24h in M199 with Hank's salts at room temperature (suboptimal incubation). Granulosa cell DNA was analysed by ethidium bromide staining or 3'-end labelling. Two experiments were performed to determine the effect of ovary holding time and temperature on oocyte chromatin configuration. Ovaries were held (1) at 20, 30 or 35-37 degrees C for up to 3h and (2) at 20-37 degrees C for 0-1, 1-2, 2-3, 3-4, 4-6, 6-8 or 8-12h. The oocytes were stained with Hoechst stain 33258 and the chromatin configuration was evaluated. Two experiments were performed to determine the effect of ovary holding time and temperature on cumulus oophorus morphology. Ovaries were held at (1) 20-30 or 35-37 degrees C for up to 2h and (2) for 0-2, 2-4, 4-6, and 6-10h at 35-37 degrees C. The cumulus oocyte complex (COC) were retrieved and the cumulus morphology was evaluated. There was no difference in proportion of follicles with non-apoptotic granulosa cells in the two groups below body temperature (20 and 30 degrees C), but more follicles had apoptotic granulosa cells when the ovaries were held at 35-37 degrees C (P < 0.001). Holding ovaries at 30 degrees C for more than 3h increased the proportion of follicles with apoptotic granulosa cells (P < 0.01). When follicles with non-apoptotic granulosa cells were incubated at room temperature, there was no granulosa cell apoptosis in any of the follicles within the first 3h, but at 5h apoptosis was present in the granulosa cells of 22% of the follicles, and 78% of the follicles contained apoptotic granulosa cells at 24h (P < 0.001). The temperature at which the ovaries were held did not influence oocyte chromatin, although there was a tendency towards more condensed chromatin configurations in the groups below body temperature. More denuded and expanded COCs were present in the lower temperature group (P < 0.001). Oocyte chromatin configuration changed after 6h of holding (P < 0.001), and numbers of compact COCs decreased after 2h (P < 0.05). The present studies suggest that equine follicles should be held for no more than 3h at 20-30 degrees C if granulosa cell apoptosis is to be avoided. To avoid changes in cumulus oophorus morphology, ovaries should be held at 35-37 degrees C and for less than 2h before processing, and to avoid oocyte chromatin configuration changes, ovaries should be stored for less than 6h. When ovaries are to be used in oocyte maturation studies, and assuming that (1) CC is the chromatin configuration of choice for oocyte maturation, (2) that presence of granulosa cell apoptosis promotes maturation of the oocyte and (3) that expanded cumulus oocytes are preferable, the present data suggests that ovaries should be stored for 4-6h before oocyte retrieval.     

Meiotic competence of prepubertal goat oocytes

The object of this work was to evaluate in vitro maturation of follicular oocytes from the ovaries of prepubertal goats obtained from the slaughterhouse. To obtain the oocytes, follicles were dissected and classified according to their diameters. In the first experiment, oocytes were matured in vitro with granulosa cells. No significant differences were detected in the percentages of maturation between adult and prepubertal goat oocytes recovered from follicles of 2.5 to 6.0 mm in diameter (81.82 vs 72.47%, respectively). The percentage of maturation increased to 88.0% in prepubertal goat oocytes from 3.0 to 6.0-mm follicles. In the second experiment, the percentage of maturation of prepubertal goat oocytes was greater after 27 than after 24 h. In the third experiment, the maturational capacity of prepubertal goat oocytes according to follicular diameter was evaluated. The percentages of maturation after 27 h of culture with no granulosa cells were 24.14, 56.60 and 74.78%, respectively, for follicles 1.0 to 1.9 mm, 2.0 to 2.9 mm, and 3.0 to 6.0 mm in diameter. As the follicular diameter increased, growth of the oocyte as well as a greater number of oocytes with more cumulus cell layers were observed. A correlation between the diamter of the oocyte and its competence to complete in vitro maturation was also observed. Oocytes with more cumulus cell layers showed only a slight superiority in their capacity for maturation in large-size follicles (3.0 to 6.0 mm), but the difference was not significant. In conclusion, oocytes from prepubertal goats complete their growth and reach meiotic competence in follicles larger than 3.0 mm. With these oocytes it is possible to obtain in vitro maturation results similar to those from adult goats.     

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.     

Chemical signals that regulate mammalian oocyte maturation

The nature and functions of the chemical signals involved in the acquisition of competence to resume meiosis, and the maintenance of meiotic arrest in antral follicles are the subjects of this paper. Evidence indicating that gonadotropins are not required for the development of competence to undergo spontaneous maturation is discussed. However, gonadotropins may promote optimal conditions for oocyte development via an estrogen-dependent action on follicular cells. Evidence for the participation of cyclic AMP (cAMP), steroids and a putative maturation-inhibiting factor in the maintenance of meiotic arrest in mammalian oocytes is discussed. Cyclic AMP seems to play a critical role in the maintenance of meiotic arrest by actions in both granulosa/cumulus cells and oocytes. However, cAMP does not appear to equilibrate between cumulus cells and oocytes. In the granulosa/cumulus cells, cAMP may promote the generation/activation of a maturation-inhibiting factor which is transferred to the oocyte. Oocyte cAMP appears to be produced in the oocyte itself. The putative maturation-inhibiting factor may be maintained in an active form by a cAMP-dependent process in the oocyte. Alternatively, the putative maturation-inhibiting factor may play a role in maintaining oocyte cAMP levels. Some steroid hormones act synergistically with a cAMP-dependent process in the oocyte to maintain meiotic arrest. However, the physiological significance of this observation remains in question.     

In vitro and in vivo studies reveal that hamster oocyte meiotic arrest is maintained only transiently by follicular fluid, but persistently by membrana/cumulus granulosa cell contact

Studies were carried out with the golden Syrian hamster to investigate the capacity of follicular fluid to maintain oocyte meiotic arrest and to determine the importance of cumulus-membrana granulosa cell contact in the regulation of meiotic status. The follicular fluid studies were conducted by cytological assessment of meiotic stage up to 6 hr after transferring cumulus-free oocytes into antra of explanted "host" follicles in vitro or into follicles of anesthetized animals prior to the gonadotropin surge at proestrus in vivo. The cumulus-membrana granulosa contact studies were undertaken with explanted follicles in which the oocyte-cumulus complex was dislodged from the underlying membrana granulosa, released into the antrum, and subsequently allowed to reestablish contact during 6 hr of incubation within the follicle. The extent of recontact of the dislodged complex with the underlying membrana granulosa was assessed visually at the end of incubation and was classified as close, moderate, or none. These various degrees of contact typically involved the following number of cumulus cells, as determined by serial sectioning of a representative sample of follicles after dislodgement and subsequent incubation: close, 32.7 +/- 1.78; moderate, 9.0 +/- 2.1; and no contact, 0. After 6 hr of incubation either in vitro or in vivo, few transferred oocytes remained at the germinal vesicle (GV) stage (18.8 +/- 8.7 and 17.3 +/- 4.0% GV, respectively). However, time course experiments revealed that meiotic resumption was significantly delayed in transferred oocytes compared with either liberated oocytes, spontaneously maturing oocytes, or follicle-enclosed oocytes induced to mature by luteinizing hormone in vitro (after 4 hr, transferred, 31.3 +/- 6.0% GV; liberated, 0% GV; follicle-enclosed, 0% GV; after 6 hr, 0% transferred oocytes exhibited a GV). In the dislodgement studies, after 6 hr of incubation, 26% of complexes reestablished close contact with the underlying membrana granulosa, 67% showed moderate contact, while 7% revealed no contact. There was a significant increase in the percentage GV stage oocytes as the extent of recontact increased (no contact, 21.9 +/- 3.6% GV; moderate contact, 56.6 +/- 6.8% GV; close contact, 87.5 +/- 14.4% GV). These data argue in favor of a stringent control of hamster oocyte meiotic status by the follicle cell/oocyte syncytium and against the possibility that follicular fluid is independently responsible for maintaining meiotic arrest.(ABSTRACT TRUNCATED AT 400 WORDS)     

Intracytoplasmic sperm injection (ICSI) versus conventional IVF on abattoir-derived and in vitro-matured equine oocytes

Conventional IVF as well as several assisted microfertilization techniques have shown limited success in the horse. After recent positive results achieved with intracytoplasmic injection of a single spermatozoon (ICSI) in human IVF, we chose to try the method in the horse. We compared conventional IVF to ICSI by fertilization rates of oocytes with compact and expanded cumuli and by developmental potential of the resulting embryos. Cumulus-oocyte complexes (COCs) were obtained by aspirating the follicular fluid from the ovaries of slaughtered mares. Complexes showing complete cumulus investment, either compact or expanded, were randomly assigned to IVF or ICSI trials and separately cultured for IVM. Frozen-thawed stallion spermatozoa were prepared for IVF with a swim-up procedure conducted in Talp-Hepes with heparin or for ICSI in Earle's balanced salt solution (EBSS) supplemented with human serum albumin (HSA). Oocytes for IVF were partially decumulated by pipetting, whereas those for ICSI were totally denuded with 80 UI/ml hyaluronidase. Oocytes were fixed, stained and examined for signs of fertilization the day after IVF or ICSI. The percentage of normally fertilized oocytes showing 2 pronuclei or cleavage was significantly higher with ICSI than IVF (29.8%, 17/57 vs 8.7%, 9/103 ; P < 0.01). Significantly higher fertilization rates were observed in oocytes retrieved with an expanded cumulus when submitted to ICSI procedure as compared with IVF (52.2%, 12/23 vs 17.1%, 6 35 ; P < 0.01), whereas in oocytes recovered with a compact cumulus, fertilization rates were low (14.7%, 5/34 with ICSI and 4.4%, 3 68 with IVF; NS). Embryonal development did not occur after culture following IVF, as indicated by absence of cleavage in any of the 93 inseminated oocytes. Following ICSI, 7 of 55 injected oocytes cleaved, 5 of which had shown expanded cumuli; of the 5, 2 were at the 16-cell stage and one each at the 8-, 3- and 2-cell stage, respectively. The other 2 fertilized oocytes, originating from compact cumuli, reached 4- and 8- cell stages, respectively. These results indicate that ICSI can be applied successfully to in-vitro matured equine oocytes to increase the fertilization rates. In addition, it seems that in vitro cytoplasmic maturation of oocytes issuing from a compact cumulus may not be complete enough to lead to a successful fertilization and that ICSI may be a tool to evaluate ooplasmic maturation.     

Apoptosis within bovine follicular cells and its effect on oocyte development during in vitro maturation

Developmental competence of oocytes is compromised if they originate from atretic follicles. Apoptosis is the underlying process of atresia. Apoptotic changes in follicular cells are thought to influence the outcome of IVF. The aim of this study was to investigate apoptosis in different compartments of single bovine follicles (follicular wall, granulosa and cumulus cells (CC)) in relation to COC morphology, and to determine whether the addition, in vitro, of exogenous follicular cells from atretic follicles to maturing cumulus oocyte complexes (COCs) influenced the development of oocytes.Antral follicles were dissected from bovine ovaries and opened to obtain COCs and free floating granulosa cells (GC). The COCs were classified according to morphology. Apoptosis was determined in cumulus and granulosa cells and in homogenates of the remaining follicular wall.For every morphological class of COCs, a large variability of apoptotic expression was found in all follicle compartments. Follicular wall apoptosis was not correlated to COC morphology or to the percentage of apoptotic granulosa or cumulus cells. In grade 1 (best morphology) COCs, the degree of apoptosis in granulosa cells was comparable to cumulus cell apoptosis (P<0.01). The overall expression of apoptosis in granulosa cells of follicles containing grade 3 COCs (median+/-median absolute deviation: 37.8+/-13.8%) was significantly higher (P<0.05) than in follicles with grade 1 (22.7+/-10.4%) or grade 2 COCs (20.0+/-17.0%). About 48.3% of grade 3 COCs possessed strongly apoptotic cumulus cells compared to 27.8 and 28.2% of grade 1 or grade 2 COCs, respectively. Nonapoptotic cumulus complexes were observed in grades 1 and 2 COCs only.Adding exogenous follicular cells from atretic follicles to bovine COCs (grades 1 and 2) during in vitro maturation (IVM) had no impact on fertilization, blastocyst formation or hatching after IVF. This is of particular practical relevance to embryo production after ovum pick up (OPU), as during this process, good quality COCs are cultured together with simultaneously collected slightly atretic COCs.     

Effect of specific phosphodiesterase isoenzyme inhibitors during in vitro maturation of bovine oocytes on meiotic and developmental capacity

Compared with oocytes matured in vivo, in vitro-matured oocytes are compromised in their capacity to support early embryo development. Delaying spontaneous in vitro meiotic maturation using specific phosphodiesterase (PDE) isoenzyme inhibitors may permit more complete oocyte cytoplasmic maturation, possibly by prolonging cumulus cell (CC)-oocyte gap junctional communication during meiotic resumption. This study aimed to investigate the effect of the isoenzyme 3- (oocyte) and isoenzyme 4- (granulosa cell) specific PDE inhibitors on the kinetics of in vitro maturation and on subsequent oocyte developmental competence. Cumulus-oocyte complexes from antral bovine follicles were isolated and cultured in the presence of the specific PDE inhibitors milrinone (type 3) or rolipram (type 4) (100 microM). In the presence of FSH, both PDE inhibitors only slightly extended CC-oocyte gap junctional communication over the first 9 h, but they completely blocked meiotic resumption during this period (P < 0.001). The indefinite inhibitory effect of milrinone on meiotic resumption (30% at germinal vesicle stage after 48 h) was overridden by 24 h when treated with FSH, but not with hCG, suggesting a form of induced meiotic resumption. Oocytes treated with FSH with or without either PDE inhibitor were inseminated at either 24, 26, or 28 h. Treated with either the type 3 or type 4 PDE inhibitor significantly (P < 0.05) increased embryo development to the blastocyst stage by 33%-39% (to an average of 52% blastocysts) compared with control oocytes (38%) after insemination at 28 h, and significantly (P < 0.05) increased blastocyst cell numbers when inseminated at 24 h. These results suggest that delayed spontaneous meiotic maturation, coupled with extended gap junctional communication between the CCs and the oocyte has a positive effect on oocyte cytoplasmic maturation, thereby improving oocyte developmental potential.     

Oocyte nucleus controls progression through meiotic maturation

We analyzed progression through the meiotic maturation in oocytes manipulated to replace the prophase oocyte nucleus with the nucleus from a cumulus cell, a pachytene spermatocyte or the pronucleus from a fertilized egg. Removal of the oocyte nucleus led to a significant reduction in histone H1 kinase activity. Replacement of the oocyte nucleus by a pronucleus followed by culture resulted in premature pseudomeiotic division and occasional abnormal cytokinesis; however, histone H1 kinase activity was rescued, microtubules formed a bipolar spindle, and chromosomes were condensed. In addition to the anomalies observed after pronuclear transfer, those after transfer of the nucleus from a cumulus cell or spermatocyte included a dramatically impaired ability to form the bipolar spindle or to condense chromosomes, and histone H1 kinase activity was not rescued. Expression of a cyclin B-YFP in enucleated oocytes receiving the cumulus cell nucleus rescued histone H1 kinase activity, but spindle formation and chromosome condensation remained impaired, indicating a pleiotropic effect of oocyte nucleus removal. However, when the cumulus cell nucleus was first transformed into pronuclei (transfer into a metaphase II oocyte followed by activation), such pronuclei supported maturation after transfer into the oocyte in a manner similar to that of normal pronuclei. These results show that the oocyte nucleus contains specific components required for the control of progression through the meiotic maturation and that some of these components are also present in pronuclei.     

Oocyte regulation of anti-Müllerian hormone expression in granulosa cells during ovarian follicle development in mice

In the ovarian follicle, anti-Müllerian hormone (Amh) mRNA is expressed in granulosa cells from primary to preovulatory stages but becomes restricted to cumulus cells following antrum formation. Anti-Müllerian hormone regulates follicle development by attenuating the effects of follicle stimulating hormone on follicle growth and inhibiting primordial follicle recruitment. To examine the role of the oocyte in regulating granulosa cell Amh expression in the mouse, isolated oocytes and granulosa cells were co-cultured and Amh mRNA levels were analysed by real-time RT-PCR. Expression in freshly isolated granulosa cells increased with preantral follicle development but was low in the cumulus and virtually absent in the mural granulosa cells of preovulatory follicles. When preantral granulosa cells were co-cultured with oocytes from early preantral, late preantral or preovulatory follicles, and when oocytes from preovulatory follicles were co-cultured with cumulus granulosa cells, Amh expression was increased at least 2-fold compared with granulosa cells cultured alone. With oocytes from preantral but not preovulatory follicles, this was a short-range effect only observed with granulosa cells in close apposition to oocytes. We conclude that stage-specific oocyte regulation of Amh expression may play a role in intra- and inter-follicular coordination of follicle development.     

The relationship of follicle atresia to follicle size, oocyte recovery rate on aspiration, and oocyte morphology in the mare

Oocytes were collected by aspiration of follicles from horse ovaries obtained at surgery or post-mortem. The oocytes were classified according to morphology of the ooplasm and cumulus. The size of the corresponding follicles was measured, and sections of the follicles were fixed and examined histologically to determine the stage of viability or atresia. In Part 1, 11 pairs of ovaries were examined and all follicles were sectioned; in Part 2, 9 pairs of ovaries were examined and only those follicles from which oocytes were recovered were sectioned. The number of follicles examined per pair of ovaries in Part 1 (average +/- SD) was 12.9 +/- 4.1. The proportion of follicles that were viable increased with increasing follicular size (P < 0.01); the percentage of viable follicles was 21, 42 and 83% for follicles < 10 mm, 10 to 19 mm, and >/= 20 mm in diameter, respectively. The overall oocyte recovery rate on aspiration of follicles was 46%. There was no significant difference in the oocyte recovery rate between viable and atretic follicles. A significantly higher proportion of oocytes recovered from viable follicles had granular ooplasm (64 vs 39%; (P < 0.05); whereas significantly more oocytes from atretic follicles had a misshapen or dense ooplasm (23 vs 6%; P < 0.05), or an expanded or pyknotic cumulus (24 vs 6%; P < 0.05). The most common cumulus morphology (63% of oocytes from viable follicles and 48% of oocytes from atretic follicles) was presence of only the corona radiata. Only 11% of oocytes from viable follicles and 9% of oocytes from atretic follicles had a complete cumulus present.     

Effect of follicular cells,IGF-I and tyrosine kinase blockers on oocyte maturation

The aim of this study was to test the following hypotheses: (i) that oocyte maturation is controlled by surrounding follicular cells; (ii) that a meiosis-regulating factor of follicular origin is not species-specific; (iii) that one of the follicular regulators of oocyte maturation is IGF-I; and, (iv) that Cumulus oophorus and tyrosine kinase-dependent intracellular mechanisms do not mediate IGF-I action on oocytes. It was found that co-culture of cumulus-enclosed bovine oocytes with isolated bovine ovarian follicles or with isolated porcine ovarian follicles significantly increased the proportion of matured oocytes (at metaphase II of meiosis) after culture. Porcine oocytes without cumulus investments had lower maturation rates than cumulus-enclosed oocytes. Co-culture with isolated porcine ovarian follicles resulted in stimulation of maturation of both cumulus-free and cumulus-enclosed porcine oocytes. These observations suggest that follicular cells (whole follicles or Cumulus oophorus) support bovine and porcine oocyte maturation, and that follicular maturation-promoting factor is not species-specific. The release of significant amounts of IGF-I by cultured bovine and porcine isolated follicles and granulosa cells was demonstrated. Addition of IGF-I to culture medium at 10 or 100 (but not 1000) ng/ml stimulated meiotic maturation of both cumulus-enclosed and cumulus-free porcine oocytes. Neither of the tyrosine kinase blockers, genistein or lavendustin (100 ng/ml medium), changed the stimulating effect of IGF-I on porcine oocytes. The present data suggest that at least one of the follicular stimulators of oocyte nuclear maturation is IGF-I, and that its effect is probably not mediated by cumulus investment or by tyrosine kinase-dependent intracellular mechanisms.     

Comparison of protein synthesis patterns in mouse cumulus cells and mural granulosa cells: effects of follicle-stimulating hormone and insulin on granulosa cell differentiation in vitro.

Successful development of mammalian oocytes requires correct interactions between developing oocytes and associated granulosa cells. Development of oocyte-granulosa cell complexes from preantral follicles in vitro does not produce oocytes competent to develop to blastocysts at the same frequency as for oocytes that develop in vivo. Addition of either FSH or insulin to cultures of oocyte-granulosa cell complexes does not improve the frequency of blastocyst development, and the combination of both insulin and FSH is deleterious. Here, high-resolution 2-dimensional PAGE (2D-PAGE) and computerized gel image analysis were used to compare patterns of protein synthesis in cumulus cells and mural granulosa cells of small antral follicles, and then to assess effects of FSH and insulin on the differentiation of oocyte-associated granulosa cells (OAGCs) in vitro. Culture of OAGCs without FSH or insulin resulted in failure to synthesize many proteins at rates characteristic of cumulus cells. Either hormone used alone caused many cumulus cell proteins that were decreased in control cultures to be synthesized at nearly normal cumulus cell rates, and also caused the synthesis of other proteins to be increased or decreased. The two hormones added together produced the greatest change in protein synthetic pattern, including overexpression or underexpression of many proteins not affected by either hormone alone. Addition of these hormones to culture media thus appeared insufficient to elicit a normal cumulus cell phenotype in OAGCs and could lead to complex changes in protein synthesis that may be deleterious to oocyte development. The high-resolution 2D-PAGE approach described here should be a valuable tool in studies on oocyte and granulosa cell development in vitro, since phenotype can be evaluated globally through the display of over 1000 newly synthesized proteins rather than relying upon the expression of just a few genes.     

In vitro development of sheep preantral follicles

Preantral ovarian follicles isolated from prepubertal sheep ovaries were individually cultured for 6 days in the presence of increasing doses of FSH (ranging from 0.01 to 1 microg/ml) and under two different oxygen concentrations, 20% and 5% O2. Follicle development was evaluated on the basis of antral cavity formation as well as the presence of healthy cumulus oocyte complexes. Follicle growth was enhanced by FSH addition to culture medium, while the use of a low oxygen concentration slightly stimulated this process. However, when follicles were cultured in the presence of high doses of FSH (1 microgram/ml) and under low oxygen concentration, a high proportion of them showed the presence of an antral cavity and of a healthy cumulus-oocyte complex. In addition, under this specific culture condition sheep preantral follicles released higher levels of estradiol as compared to those secreted at lower FSH concentrations or under 20% O2. When the meiotic competence of oocytes derived from follicles cultured at 1 microgram/ml FSH was assessed, no significant difference was recorded between the two oxygen groups. These results show that the culture conditions here identified are beneficial to in vitro growth and differentiation of sheep preantral follicles.     

Developmental competence of bovine oocytes is not related to apoptosis incidence in oocytes, cumulus cells and blastocysts

The number of follicles undergoing atresia in an ovary is very high, and isolation of cumulus-oocyte complexes (COCs) from such atretic follicles may impair subsequent embryo development in vitro. Our aim was to study if stringent selection by morphological assessment of COCs can improve embryo development, and to evaluate whether oocyte diameter is related with apoptotic ratio in oocytes and blastocysts. COCs from slaughtered cattle were recovered by follicle aspiration and classified depending on oocyte diameter: (A) <110 microm; (B) 110-120 microm; (C) >120 microm. COCs were matured, fertilized and cultured in vitro. Early and late stages of apoptosis were detected by Annexin-V and TUNEL staining, respectively, in denuded oocytes, COCs and blastocysts. Immature oocytes from Group A showed higher apoptotic ratio assessed by TUNEL assay, and the COCs corresponding to this group also showed a higher proportion of apoptotic cumulus cells. After maturation, no differences were present in the incidence of apoptosis among oocytes from different groups, but COCs corresponding to the largest diameter showed less apoptotic cumulus cells. In addition, the percentage of apoptotic oocytes decreased during in vitro maturation in all groups. Apoptotic cell ratio (ACR) in blastocysts was not related to oocyte diameter. In conclusion, oocyte selection and oocyte morphological evaluation prior to maturation was not sufficient to select non-atretic oocytes. When oocyte diameter was used as an additional selection the embryonic developmental potential increased together with oocyte diameter, but this improvement was not related to a lower incidence of apoptosis in the largest oocytes.