Developmental stage of the oocyte during antral follicle growth and cumulus investment determines in vitro embryo development of sow oocytes

The aim of the study was to determine the contribution of cumulus cells on the developmental competence of porcine oocytes during follicle growth. Oocytes from large (5-8mm) and small (2-3mm) follicles were cultured with or without follicle stimulating hormone (FSH), subsequently examined for nuclear stage and spindle morphology, or fertilized and cultured for embryo development, or analyzed for glutathione content. Additionally, the significance of cumulus investment, corona radiata cells, cumulus cell number and origin of cumulus cells for oocyte maturation were investigated. Small follicle oocytes cultured without FSH exhibited the highest incidence of spindle aberrations. Oocytes cultured without FSH exhibited reduced sperm penetration and blastocyst rates, and a higher proportion monospermic oocytes developed to the blastocyst stage when derived from large follicles. The glutathione content in oocytes increased during follicle growth and oocyte maturation, but no direct correlation between oocyte glutathione content and oocyte developmental capacity was observed. Oocytes with a bigger cumulus investment exhibited better embryo development. Oocytes with a single corona radiata cell layer (CROs) exhibited similar progression through meiosis to oocytes with more cumulus cell layers, but showed reduced embryo development. More blastocysts were observed when CROs were cultured with disconnected cumulus cells during IVM, but no blastocyst increase was observed when CROs were cocultured with a higher number of cumulus cells or with cumulus cells from large follicles. We conclude that increased developmental capacity of oocytes during follicle growth is intrinsic and whether cumulus cells originate from large or small follicles, their contribution to oocyte maturation remains unchanged. Further, cumulus investment can be used as a variable to predict oocyte developmental capacity.     

In vitro parthenogenetic development of mouse oocytes following reciprocal transfer of the chromosome spindle between in vivo-matured oocytes and in vitro-matured oocytes

Mouse follicles grown in vitro from preantral to mature stages yield oocytes that can be fertilized in vitro, but embryonic development is poor. To investigate whether this poor development is due to a nuclear or a cytoplasmatic factor, we designed an experiment in which the MII chromosome spindle was exchanged between in vitro-matured oocytes and in vivo-matured oocytes by electrofusion. Subsequent embryo development was evaluated by blastocyst formation rate and blastocyst cell number after parthenogenetic activation. Electrofusion was successful in 62-78% of the oocytes. Transfer of the spindle apparatus from in vitro-matured oocytes to the in vivo MII cytoplasmic environment resulted in a high rate of blastocyst development, whereas in the reverse situation (transfer of the nucleus from in vivo-matured oocytes into in vitro-matured MII cytoplasm) poor quality embryos and a low rate of blastocyst formation was observed. These results indicate that the low developmental competence of in vitro-matured oocytes from mouse preantral follicles after activation is caused by the cytoplasmic component rather than the nuclear component.     

The developmental competence of mammalian oocytes: a convenient but biologically fuzzy concept

Oocyte developmental competence is often used to qualify in vitro procedures for embryo production. It supposedly accounts for the oocyte's ability to develop into a normal, viable and fertile offspring after fertilization, but for practical reasons it often characterizes the ability of such oocytes to develop to the blastocyst stage in vitro. Molecular tools compatible with the analysis of very small amounts of material have resulted in research aimed at designing molecular criteria to define this competence. However we feel that such research strategies easily lead to misunderstanding of the regulative processes that drive embryo development. Artificially induced blastocyst stage is a poor predictor of oocyte developmental competence. However preimplantation stages also appear to be sensitive to environmental conditions that can induce long-lasting detrimental effects. Larger scale analysis now made available by a functional genomics approach provides a more accurate understanding of the complex regulative networks that sustain the molecular mechanisms responsible for normal development. We propose that the concept of developmental competence should be used more cautiously and also should refer more explicitly to the experimental context it intends to enlighten.     

Responses of oocytes and embryos to the culture environment

Embryo development is strongly influenced by events occurring during oocyte maturation. Although many immature oocytes are capable of completing meiosis in vitro, only a small percentage of the original pool of immature oocytes is competent to continue development to the blastocyst stage and subsequently result in a pregnancy. This indicates that maturation of oocytes in vitro may not be occurring in an entirely normal manner. Cytoplasmic changes occurring during maturation, collectively termed cytoplasmic maturation, are essential for embryonic development. The cytoplasm of the oocyte may play a crucial role in assembling the correct metabolic machinery for production of sufficient energy for cellular functions during maturation, cleavage and blastocyst formation. A better understanding of the structural, functional and metabolic characteristics of the oocyte during maturation, and the consequence of changes in these parameters on developmental competence is needed. Understanding the role of cytoplasmic changes during oocyte maturation will help increase the efficiency of in vitro embryo production. Better embryo production strategies will facilitate basic research into the control of early development, improve implementation in endangered species, provide a source of high quality oocytes for nuclear transfer and transgenic technologies and benefit the commercial embryo transfer industry.     

The importance of mitochondrial metabolic activity and mitochondrial DNA replication during oocyte maturation in vitro on oocyte quality and subsequent embryo developmental competence

Mitochondrial metabolic capacity and DNA replication have both been shown to affect oocyte quality, but it is unclear which one is more critical. In this study, immature oocytes were treated with FCCP or ddC to independently inhibit the respective mitochondrial metabolic capacity or DNA replication of oocytes during in vitro maturation. To differentiate their roles, we evaluated various parameters related to oocyte maturation (germinal vesicle break down and nuclear maturation), quality (spindle formation, chromosome alignment, and mitochondrial distribution pattern), fertilization capability, and subsequent embryo developmental competence (blastocyst formation and cell number of blastocyst). Inhibition of mitochondrial metabolic capacity with FCCP resulted in a reduced percent of oocytes with nuclear maturation; normal spindle formation and chromosome alignment; evenly distributed mitochondria; and an ability to form blastocysts. Inhibition of mtDNA replication with ddC has no detectable effect on oocyte maturation and mitochondrial distribution, although high-dose ddC increased the percent of oocytes showing abnormal spindle formation and chromosome alignment. ddC did, however, reduce blastocyst formation significantly. Neither FCCP nor ddC exposure had an effect on the rate of fertilization. These findings suggest that the effects associated with lower mitochondrial DNA copy number do not coincide with the effects seen with reduced mitochondrial metabolic activity in oocytes. Inhibiting mitochondrial metabolic activity during oocyte maturation has a negative impact on oocyte maturation and subsequent embryo developmental competence. A reduction in mitochondrial DNA copy number, on the other hand, mainly affects embryonic development potential, but has little effect on oocyte maturation and in vitro fertilization.     

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.     

Isolation of genes associated with developmental competency of bovine oocytes

Eggs differ widely in their ability to develop into an embryo. To address this characteristic, the concept of developmental competency has been coined, defined as the ability or potential of an oocyte to undergo maturation, fertilization and development to blastocyst stages or live offspring. Developmental competency is acquired progressively during folliculogenesis and is linked to follicular size. In an effort to understand the molecular changes underlying differences in competency we compared oocytes derived from large follicles (>or=5mm) to those from small follicles (相似文献   

Effect of follicular size on meiotic and developmental competence of porcine oocytes

In several species, the developmental competence of the oocyte is acquired progressively during late follicular growth, after the acquisition of the competence to resume and complete meiosis. In the pig, full meiotic competence of the oocyte is reached in ovarian follicles with a diameter of 3 mm or more. However, there is no information about developmental competence acquisition. We analyzed the ability of oocytes from three foll icular size classes to resume and complete meiosis, to be fertilized, and to develop in vitro to the blastocyst stage. A total of 941 follicles were dissected from slaughterhouse gilt ovaries and classified as small (<3 mm, n = 330), medium (3-5 mm, n = 373), or large (>5 mm, n = 238). The cumulus-oocyte complexes recovered from these follicles were submitted to in vitro maturation for 44 h in TCM199 supplemented with 10 ng/ml EGF, 400 ng/ml pFSH and 570 microM cysteamine; in vitro fertilized for 18 h in mTBM with 10(5) frozen-thawed percoll-selected sperms/ml; and developed for 7 days in mSOF. Samples of oocytes or presumptive zygotes were fixed and stained at the end of maturation and fertilization. Groups of oocytes were cultured for 3 h in the presence of 35S-methionine before or after maturation for SDS-PAGE analysis of protein neosynthesis. More oocytes originating from medium and large follicles were competent for maturation than oocytes from small follicles (77 and 86% of metaphase II, respectively, versus 44%, P < 0.05). More oocytes from medium and large follicles werepenetratedby spermatozoa during in vitro fertilization, resulting in significantly more oocytes presenting two or more pronuclei at the end of fertilization (73 and 77% for medium and large follicles, respectively, versus 53% for small follicles, P < 0.05). More oocytes from medium and large follicles developed to the blastocyst stage (14 and 23%, respectively) than those from small follicles (3%, P < 0.05), even if the development rates were corrected by the maturation or fertilization rates. It is concluded that a high proportion of oocytes harvested from follicles of less than 3 mm in the pig are not fully competent for meiosis and are cytoplasmically deficient for development.     

Morphology and developmental competence of bovine oocytes relative to follicular status

In cattle, follicle dimension has been used as the main criterion for selection of oocytes for in vitro embryo production. However, follicles with similar diameters may be in very different physiologic phases. The aim of this study was to investigate whether morphology and developmental competence of cumulus-oocyte complexes (COCs) are related to the phase of development of the follicle, and presence of the corpus luteum (CL) or the dominant follicle in the ovary from which the COCs were collected. Cows (n = 143) were given a luteolytic dose of PGF(2alpha) and 8 days later underwent transvaginal ultrasound guided ablation of follicles > or =4mm to induce emergence of a new follicular wave. Cows (n = 10-20 per replicate) were slaughtered on Day 2, 3, 5 or 7 (Day 0 = follicular wave emergence), equivalent to the growing, early static, late static, and regressing phases of subordinate follicle development. COCs were collected from subordinate follicles > or =3mm, were classified as denuded, degenerated or healthy, and underwent IVM-IVF-IVC. The proportion of oocytes that developed to the blastocyst stage was higher (P<0.05) in those collected on Day 5 after wave emergence (23%) than on Day 2 (12%), 3 (13%) or 7 (16%). Data did not support the hypothesis of a local effect of the CL or dominant follicle. We conclude that a positive relationship exists between early follicular regression and oocyte competence. Moreover, morphologic characteristics of oocyte quality used in this study were not predictive in identifying competent oocytes.     

Live offspring by in vitro fertilization of oocytes from cryopreserved primordial mouse follicles after sequential in vivo transplantation and in vitro maturation

The objectives of the present study were to achieve 1) oocyte maturation, 2) oocyte competence of fertilization, and 3) oocyte competence of embryogenesis with oocytes from primordial follicles obtained from cryopreserved newborn mouse ovaries by using a two-step method. In the first step, frozen-thawed newborn mouse ovaries were transplanted under the kidney capsule of recipients for the initiation of growth from the primordial follicle stage on. In the second step, growing preantral follicles in the ovarian grafts were recovered and cultured. The results demonstrated that primordial follicles were able to be recruited to preantral follicles during the period of transplantation, and preantral follicles could be mechanically isolated from ovarian grafts. Under the present in vitro culture conditions, 85.8% of the isolated follicles (n = 332) from ovarian grafts survived the 12-day in vitro culture process, 84.9% of the recovered oocytes (n = 285) were germinal vesicle breakdown (GVBD)-competent, and 76% of the oocytes that underwent GVBD (n = 242) developed to the metaphase II (MII) stage. In the in vitro fertilization experiments, 75.4% of 142 inseminated MII oocytes underwent fertilization and cleavage to the 2-cell stage. Subsequently, 79.7% of the 2-cell-stage embryos (n = 69) progressed to the late morula-early blastocyst stage. Transfer of late morula-early blastocyst embryos resulted in the production of live offspring. From our experiments, it may be concluded that in vivo maturation by grafting followed by in vitro maturation of frozen-thawed primordial follicles can restore fertility in mice. This model could be useful for a similar application in the human.     

Bovine follicular development and its effect on the in vitro competence of oocytes

The current knowledge is reviewed concerning correlations between follicular development in the cow and the competence of matured oocytes to develop into an embryo following IVF and IVC. At the follicular size of 3 mm, some oocytes become competent and the proportion of competent oocytes does not increase during development up to 7 mm. The proportion of competent oocytes increases greatly in follicles > 8 mm in both untreated and gonadotropin-stimulated cows. The competence of in vitro-matured oocytes from these large follicles is lower than the competence of in vivo-matured oocytes. These observations lead to the following concept. Oocytes have acquired an intrinsic capacity to develop into an embryo after IVM-IVF-IVC at the follicular stage of 3 mm, but require an additional "prematuration" to express this competence. In vivo, this prematuration occurs during preovulatory development before the occurrence of the LH surge. In follicles of 3-7 mm, a low level of atresia appears to improve the in vitro competence of oocytes which may act via a prematuration-like effect. A thorough understanding, however, of the effect of atresia and other factors on the competence of this highly heterogeneous oocyte population is still missing. Two routes to improve the embryo yield in ovum pick-up (OPU) practice are discussed.     

Follicular 17β-estradiol and progesterone concentrations and degree of cumulus cell expansion as predictors of in vivo-matured oocyte developmental competence in superstimulated heifers

The quality of an oocyte is crucial for successful generation of offspring, but few selection parameters have been identified that reliably predict oocyte developmental competence. The objective of the present study was to determine whether the developmental competence of in vivo-matured oocytes derived from superstimulated heifers could be predicted by 17β-estradiol and progesterone concentrations in follicular fluid, degree of cumulus cell expansion, and follicular diameter. Cumulus oocyte complexes were individually collected from follicles ≥8 mm 22 hours after an induced LH peak and individually fertilized and cultured in vitro. Only oocytes that originated from follicles with 17β-estradiol ≤0.25 μM and progesterone ≥0.26 μM developed into blastocysts. When a combination of these cutoff values was evaluated as a predictor of oocyte competence, the sensitivity, specificity, positive predictive value, and negative predictive value were 100%, 75%, 49%, and 100%, respectively. Hormone concentrations in follicular fluid were also associated with the degree of cumulus cell expansion and only cumulus oocyte complexes with full expansion developed into blastocysts; sensitivity, specificity, positive predictive value, and negative predictive value were 100%, 71%, 45%, and 100%, respectively, when full expansion was used as the predictive criterion for blastocyst production. Follicular diameter was not a good predictor of oocyte competence. In conclusion, concentrations of 17β-estradiol and progesterone in the preovulatory follicle and the degree of cumulus cell expansion are predictors of blastocyst production in superstimulated heifers and can be used as selection markers for oocyte developmental competency.     

Consequences of bovine oocyte maturation, fertilization or early embryo development in vitro versus in vivo: implications for blastocyst yield and blastocyst quality.

The aim of this study is to examine the effect of bovine oocyte maturation, fertilization or culture in vivo or in vitro on the proportion of oocytes reaching the blastocyst stage, and on blastocyst quality as measured by survival following vitrification. In Experiment 1, 4 groups of oocytes were used: (1) immature oocytes from 2-6 mm follicles; (2) immature oocytes from > 6 mm follicles; (3) immature oocytes recovered in vivo just before the LH surge; and (4) in vivo matured oocytes. Significantly more blastocysts developed from oocytes matured in vivo than those recovered just before the LH surge or than oocytes from 2-6 mm follicles. Results from > 6 mm follicles were intermediate. All blastocysts had low survival following vitrification. In Experiment 2, in vivo matured oocytes were either (1) fertilized in vitro or (2) fertilized in vivo by artificial insemination and the resulting presumptive zygotes recovered on day 1. Both groups were then cultured in vitro. In vivo fertilized oocytes had a significantly higher blastocyst yield than those fertilized in vitro. Blastocyst quality was similar between the groups. Both groups had low survival following vitrification. In Experiment 3a, presumptive zygotes produced by in vitro maturation (IVM)/fertilization (IVF) were cultured either in vitro in synthetic oviduct fluid, or in vivo in the ewe oviduct. In Experiment 3b, in vivo matured/in vivo fertilized zygotes were either surgically recovered on day 1 and cultured in vitro in synthetic oviduct fluid, or were nonsurgically recovered on day 7. There was no difference in blastocyst yields between groups of zygotes originating from the same source (in vivo or in vitro fertilization) irrespective of whether culture took place in vivo or in vitro. However, there was a dramatic effect on blastocyst quality with those blastocysts produced following in vivo culture surviving vitrification at significantly higher rates than their in vitro cultured counterparts. Collectively, these results indicate that the intrinsic quality of the oocyte is the main factor affecting blastocyst yields, while the conditions of embryo culture have a crucial role in determining blastocyst quality.     

Noninvasive bovine oocyte quality assessment: possibilities of a single oocyte culture

Although bovine embryos are routinely produced in vitro for several decades, there still exists a critical need for techniques to accurately predict the oocyte's developmental competence in a noninvasive way, before the in vitro embryo production procedure. In this review, several noninvasive methods to evaluate oocyte quality are discussed, such as morphological assessment of the cumulus oocyte complex and the use of brilliant cresyl blue. Because an individual oocyte and embryo culture method can possibly generate additional insights into the factors that determine oocyte quality, the second part of this review summarizes the state of the art of bovine single oocyte culture. The optimization of individual in vitro embryo production can obviously accelerate the quest for better noninvasive oocyte quality markers, because more information about the oocyte's requirements and intrinsic quality will be revealed. Although each step of in vitro culture has to be re-examined in light of the hampered production of single embryos, the reward at the end will be substantial. Individual scored oocytes will be traceable along the in vitro embryo production procedure and the final blastocyst outcome can be linked to the original oocyte quality and follicular environment without the bias caused by simultaneously developing embryos.     

Control of oocyte maturation in cows--biological factors

Since bovine in vitro fertilization became possible in the early 80s, a lot of effort has been done to clarify the mechanisms of what seems more and more one of the crucial steps in this procedure, being oocyte maturation. Undoubtedly, many biological factors act together to prepare the immature oocyte for a successful development to a competent embryo after fertilization. Defects in oocyte maturation can possibly be caused by an inadequate nuclear or cytoplasmic maturation or even by a failure of both. There is a general agreement upon the fact that the origin of the oocyte can play an important role. Oocytes derived from very small follicles show a lower rate of maturation and lower blastocyst development with currently used maturation protocols. Parthenogenetic activation of small size follicle derived oocytes suggests that their poor development was not caused by fertilization problems but more likely by intrinsic oocyte factors. Similar developmental rates achieved through nuclear transfer and parthenogenetic activation suggests that the nucleus of the incompetent oocyte may not be the sole reason for a poor development. Another important factor appears to be the donor animal age. The younger the donor animal, the more impaired is its oocyte's developmental competence in most of the embryo IVP systems. Treatment with exogeneous gonadotropins can be beneficial in young donors on the oocyte cleavage rates but does not always increase the final blastocyst outcome. This review briefly documents some of the biological factors and their possible effects on the developmental capacities of the bovine oocyte in vitro.     

Effect of BMP15 and/or AMH during in vitro maturation of oocytes from involuntarily culled dairy cows

The high metabolic activity to which the dairy cattle are exposed to maintain milk production altered steroid metabolism that affects reproductive physiology and reduce oocyte competence. Our aims were (a) to characterize the competence of immature oocytes collected from dairy cattle based on the expression of genes in cumulus cells (CCs) and (b) to improve oocyte competence to support preimplantation embryo development by the supplementation of maturation medium with bone morphogenetic protein 15 (BMP15) and/or anti‐mullerian hormone (AMH). Oocyte donors were identified at the moment of ovary collection and grouped by involuntarily culled dairy cows (Holstein breed) or beef cattle. The embryo development speed to blastocyst of the cull dairy cattle versus beef cattle (control group) was lower. Besides, <10% of oocytes (with CC biopsies) derived from dairy cattle were able to develop to the blastocyst stage. In addition, a higher level of expression and a positive correlation were observed in the expression of most of the genes evaluated (LUM, KRT18, KRT8, CLIC3, BMPR1B, and SLC38A3) in the cumulus–oocyte complexes that produced blastocysts versus those which did not develop correctly (arrested development). Further, use of BMP15 in the maturation of oocytes from dairy cattle seems to increase competence, modulating the expression of OCT4, SOX2, CDX2, GATA6, and TP1 in resulting blastocysts.     

Increased beta-oxidation and improved oocyte developmental competence in response to l-carnitine during ovarian in vitro follicle development in mice

Oocyte developmental competence is acquired throughout folliculogenesis and is associated with appropriate differentiation and responsiveness to the luteinizing hormone (LH) surge. The recent development of a novel system for culturing ovarian follicles in a three-dimensional alginate matrix shows promise in phenocopying in vivo folliculogenesis. However, oocytes from follicles grown in vitro have a reduced capacity to complete nuclear maturation and be fertilized compared to oocytes matured in vivo. Oocyte metabolism is closely linked with oocyte quality, and we have recently shown that beta-oxidation of lipids is essential for oocyte developmental competence. Thus we investigated whether upregulation of beta-oxidation by treatment with the fatty acid transport cofactor l-carnitine could improve folliculogenesis and developmental competence of mouse follicles following three-dimensional culture. Ovarian hormones (androstenedione, estradiol, and progesterone) and the induction of cumulus matrix proteins (hyaluronan and ADAMTS1) were similar to in vivo follicles, indicating that appropriate differentiation of follicular cells occurs in cultured follicles after an LH/human chorionic gonadotropin (hCG) stimulus. l-carnitine did not alter survival, growth, or differentiation of follicles. However, l-carnitine supplementation significantly increased beta-oxidation, and markedly improved both fertilization rate and blastocyst development. Together, these results show that appropriate responsiveness of the follicle to the LH/hCG surge occurs following three-dimensional follicle culture but limitations on key metabolic requirements remain. l-carnitine supplementation during in vitro follicle culture increased lipid metabolism and improved oocyte developmental competence.     

A revised protocol for in vitro development of mouse oocytes from primordial follicles dramatically improves their developmental competence

The objective of this study was to improve the conditions for oocyte development in vitro beginning with the primordial follicles of newborn mice. Previous studies showed that oocytes competent of meiotic maturation, fertilization, and preimplantation could develop in vitro from primordial follicles. However, the success rates were low and only one live offspring was produced (0.5% of embryos transferred). A revised protocol was compared with the original protocol using oocyte maturation and preimplantation development as end points. The percentage of oocytes maturing to metaphase II and developing to the blastocyst stage was significantly improved using the revised protocol. In addition, we compared the production of offspring from two-cell stage embryos derived from in vitro-grown and in vivo-grown oocytes. Of 1160 transferred two-cell stage embryos derived from in vitro-grown oocytes, 66 (5.7%) developed to term and 7 pups (10.6%) died at birth. The remaining 59 pups (27 females, 32 males) survived to adulthood. By comparison, of 437 transferred two-cell stage embryos derived from in vivo-grown oocytes, 76 (17.4%) developed to term and 4 (5.3%) died at birth. The remaining 72 pups (35 females, 37 males) survived to adulthood. These studies provide proof of the principle that fully competent mammalian oocytes can develop in vitro from primordial follicles and present a significant advance in oocyte culture technology.     

Investigations of oocyte in vitro maturation within a mouse model

This study attempted to develop a 'less meiotically competent' murine model for oocyte in vitro maturation (IVM), which could more readily be extrapolated to human clinical assisted reproduction. Oocyte meiotic competence was drastically reduced upon shortening the standard duration of in vivo gonadotrophin stimulation from 48 h to 24 h, and by selecting only naked or partially naked germinal vesicle oocytes, instead of fully cumulus enclosed oocyte complexes. With such a less meiotically competent model, only porcine granulosa coculture significantly enhanced the oocyte maturation rate in vitro, whereas no significant enhancement was observed with macaque and murine granulosa coculture. Increased serum concentrations and the supplementation of gonadotrophins, follicular fluid and extracellular matrix gel within the culture medium did not enhance IVM under either cell-free or coculture conditions. Culture medium conditioned by porcine granulosa also enhanced the maturation rate, and this beneficial effect was not diminished upon freeze-thawing. Enhanced IVM in the presence of porcine granulosa coculture did not, however, translate into improved developmental competence, as assessed by in vitro fertilization and embryo culture to the blastocyst stage.