In vitro and in vivo developmental competence of dromedary (Camelus dromedarius) oocytes following in vitro fertilization or parthenogenetic activation.

Parthenogenetic activation of the oocyte represents an important step in the somatic cloning. The aim of the present study was to evaluate the effectiveness (in term of in vitro development) of different methods of parthenogenetic activation of dromedary oocytes. Selected cumulus-oocytes-complexes (n=1264) collected by follicular aspiration from ovaries obtained postmortem were matured in vitro (IVM) for 30 h then divided randomly into seven groups and submitted to artificial activation. Two groups were preactivated with 25 microM of calcium ionophore (CaI) for 20 min then incubated for 4h with either 2mM 6-dimethylaminopurine (6-DMAP) (group 1, n=202) or with 10 microg/mL cycloheximide (CHX) (group 2, n=194). Group 3 (n=172) and group 4 (n=184), oocytes were pretreated with 5 microM ionomycin (Iono) for 5 min then incubated with either 2mM 6-DMAP or 10 microg/mL cycloheximide for 4h, respectively. Group 5 (n=161) and group 6 (n=155) oocytes were preactivated with electrical stimulation (ES) then activated with either 2mM 6-DMAP or 10 microg/mL cycloheximide for 4h, respectively. Group 7 (n=196) oocytes were submitted to in vitro fertilization (IVF) and served as a control. All groups containing oocytes were cultured in vitro following activation or IVF, at 38.5 degrees C under 5% CO(2) in air with >95% humidity. The in vitro development rates of dromedary oocytes exposed to 6-DMAP after CaI (61%), ES (74%) and the IVF group (71%) were similar and significantly greater (P<0.05) than other treatments (10% for group 2, 47% for group 3, 27% for group 4 and 41% for group 6). The blastocyst developmental rate was better (P<0.05) in parthenotes following activation with Iono/6-DMAP (21%) compared to activation with Iono/CHX (12%). However, all were less than that achieved in the IVF group (35%). We conclude that parthenogenetic activation of camel oocytes with 6-DMAP is more effective than activation with CHX for all pre-treatments tested (CaI, Iono or ES). The viability of activated (n=15) or IVF (n=10) hatched-dromedary embryos was examined by transfer to synchronized recipients. An embryonic vesicle was seen by ultrasonography at 15 days post transfer in four females (CaI/6-DMAP: 1/5; 20%, IVF: 3/10; 30%). The only pseudopregnancy obtained with an activated embryo resorbed at 25 days. One of the females receiving the IVF produced embryos aborted at 2 months and the other two females carried to term and gave birth to healthy calves (one female and one male). This study shows that artificial activation of dromedary oocytes with CaI/6-DMAP or ES/6-DMAP is more effective than other treatments in terms of in vitro embryo development. This provides efficient activation conditions which may lead to the development of the somatic cell nuclear transfer procedure in dromedary.

Preliminary assessment of somatic cell nuclear transfer in the dromedary (Camelus dromedarius).

Somatic cloning may enable the maintenance/expansion of the population of camels with the highest potential for milk production or the best racing performances. However, there have been no reports of embryonic or somatic nuclear transfer in camels. The aim of this study was to produce dromedary embryos by nuclear transfer using in vitro matured oocytes and two somatic cells from two sources (adult fibroblasts or granulosa cells). A total of 58 adult females were superstimulated by a single dose of eCG (3500 IU). Ten days later, their ovaries were collected postmortem. Cumulus-oocytes-complexes (COCs) were aspirated from stimulated follicles and were matured in vitro for 30 h. Fibroblasts (from live adult male) and granulosa cells (from slaughtered adult females) were used as donor karyoplasts and injected into mature enucleated dromedary oocytes. The cleavage rate was significantly higher (P<0.05) for embryos reconstructed with fibroblasts (59%) versus those with granulosa cells (45%). However, there was no difference between the two groups in the proportion of cloned embryos reaching the blastocyst stage (fibroblasts: 14% vs. granulosa cells: 15%) or those that hatched (fibroblasts: 10% vs. granulosa cells: 12%). The viability of reconstructed dromedary embryos from the two sources of donor cells (fibroblasts; n=5 vs. granulosa cells; n=7) was examined by transferring them to synchronized recipients. Two females (fibroblasts: 1/5; 20%, granulosa cells: 1/7; 14%) were confirmed pregnant by ultrasonography at 15 and 25 days following transfer. Later, the pregnancies were followed by pregnancy empirical-symptoms. These two pregnancies were lost between 25 and 60 days following transfer, respectively. In conclusion, the present study shows for the first time that the development of dromedary NT embryos derived from either adult fibroblasts or granulosa cells can occur in vitro and the transfer of these cloned embryos to recipients can result in pregnancies.

Quality and developmental ability of dromedary (Camelus dromedarius) embryos obtained by IVM/IVF, in vivo matured/IVF or in vivo matured/fertilized oocytes.

The effect of source of cumulus-oocytes-complexes (COCs), maturation and fertilization conditions on developmental competence of dromedary embryos was examined. Thirty-six adult females were superovulated with equine Chorionic Gonadotropin (eCG) injection (3500 IU, IM) and divided in three groups of 12 females each. Group 1 provided 138 COC's collected from follicles >or= 5 mm 10 days after stimulation prior hCG treatment and matured in vitro for 30 h. Group 2 provided 120 in vivo matured oocytes which were aspirated from their follicles 20 h after hCG (3000 IU, IV) given on day 10 follow eCG injection. Group 3 provided 65 in vivo matured/fertilized oocytes. Females in Group 3 received hCG on day 10 following eCG treatment and then were mated 24 h later. Fertilized oocytes were collected from the oviducts of females 48-h post-mating. Quality of the oocytes was assessed after in vitro maturation (IVM), in vitro fertilization (IVF) and in vitro culture (IVC) of COCs. All cultures were performed in three replicates (n = 3) at 38.5 degrees C, under 5% CO(2) and high humidity (>95%). Only COCs with cumulus and homogenous (dark) cytoplasm were used. Nuclear maturation rate for Groups 1 and 2 was determined by epifluorescence microscopy in a sample of COCs (n = 30) denuded, fixed and stained with Hoechst 33342. To study the viability of obtained embryos, hatched blastocysts from each group were transferred to recipients followed by pregnancy diagnosis using ultrasonography at 15, 60 and 90 days. The percentage of COCs reaching metaphase II (MII) after 30 h of maturation was slightly but not significantly higher for in vivo matured oocytes (28/30; 93%) than those in vitro matured (25/30; 84%). The total rate of cleavage (2 cells to blastocyst stage) was not different for the three groups. However, significantly (p < 0.05) more blastocyst and hatched blastocysts were obtained from in vivo matured and in vivo fertilized oocytes (Group 3; 52% and 73%) than from in vitro fertilized oocytes whether they were matured in vitro (Group 1; 35% and 32%) or in vivo (Group 2; 32% and 45%). Pregnancy rates were not significantly different amongst all groups for the three first months following embryo transfer. All pregnancies were lost after day 90 follow transfer except for in vivo matured and in vivo matured/fertilized groups. Only in vivo matured/in vitro fertilized and in vivo matured/fertilized produced embryos continued normal development until term and resulted in the birth of normal and healthy live calves. Six claves (29%; 6/21) were born from Group 3 and one (8%; 1/13) calf was born from Group 2. This study shows that the IVC system used is able to support camel embryo development. However, developmental competence and viability of dromedary embryos may be directly related to the intrinsic quality (cytoplasmic maturation) of oocytes.

Current knowledge and future challenges in camelid reproduction.

Reproductive biology research on camelids offers some interesting peculiarities and challenges to scientists and animal production specialists. The objective of this paper is to review camelid reproduction, advances in reproductive physiology and reproductive biotechnologies in camelids and discuss some areas for further research. In the female, the focus has been on understanding follicular dynamics. This has allowed development of synchronization and superovulation strategies to support embryo transfer technologies which are now commonly used in camels. Some advances have been achieved in preservation of embryos by vitrification. Fertilization, early embryo development and embryo signaling for maternal recognition of pregnancy are still not fully understood. New information on the interaction of the developing embryo and the endometrium may shed some light on this signaling as well as the mechanism of prevention of luteolysis. The presence of a seminal ovulation-inducing factor (OIF) was confirmed in llamas and alpacas. Chronology of oocytes maturation has been described. In vitro production of embryos has been achieved resulting in successful pregnancies and births in the dromedary. These techniques offer a new tool for the production and study of interspecies/cross-species embryos and their effect on pregnancy. Male reproductive function remains poorly studied. Semen preservation and artificial insemination still present many challenges and are not used in production at the moment. The involvement of climatic and nutritional conditions as well as the role of leptin in the regulation of reproductive function need to be evaluated.

Effect of follicular size on in vitro developmental competence of oocytes and viability of embryos after transfer in the dromedary (Camelus dromedarius).

The aim of this work was to determine the effect of follicle size on camel oocyte quality as measured by developmental competence in vitro and in vivo. Ovaries from a local slaughterhouse were dissected to obtain two classes of follicle size: small (3-6 mm) and large (>6 mm) follicles. Quality of the oocytes was assessed after in vitro maturation (IVM), in vitro fertilization (IVF) and in vitro culture (IVC) of cumulus oocyte complexes (COCs). All cultures were done in four replicates at 38.5 degrees C, under 5% CO(2) and high humidity (>95%). Only COCs with cumulus and homogenous (dark) cytoplasm were used. The COCs were matured for 28 h in TCM-199 medium supplemented with 10% heat-treated fetal calf serum (FCS), 10 ng/mL EGF, and 250 microM cysteamine. Nuclear maturation rate for each class of follicle size was determined by contrast phase microscopy in a sample of COCs (n=30) denuded, fixed and stained with aceto-orcein. In vitro fertilization was performed using fresh semen (0.5 x 10(6)spermatozoa/mL in modified TALP-solution). Fertilized oocytes were cultured in mKSOMaa, under 5% O(2) and 90% N(2). The percentage of COCs reaching metaphase II (MII) after 28 h of maturation was 87% (26/30) and 73% (22/30) for oocytes originating from large and small follicles, respectively (P>0.1). The rate of total cleavage (two cells to blastocyst stage) was greater (P<0.05) for oocytes originating from large follicles (72%; 116/162) than for those derived from small follicles (59%; 140/237). The percentage of fertilized oocytes reaching the blastocyst stage was 35% (57/162) and 20% (48/237) for oocytes collected from large and small follicles, respectively (P<0.05). The viability of in vitro-produced hatched blastocyst from the two groups (15 from 3 to 6mm follicle size and 22 from follicles >6 mm) was assessed by transfer to synchronized recipients. None of the hatched blastocysts from small follicles resulted in a pregnancy whereas 68% (15/22) of the transferred hatched embryos from large follicles developed into a 25-day pregnancy. Of the resulting 15 pregnancies, 53% (n=8) aborted (five between 2 and 4 months and three between 5 and 7 months of pregnancy). The remaining seven pregnant females gave birth to normal healthy offsprings (four females and three males). The present study shows that dromedary oocytes developmental competence is acquired late during the final phase of follicular development and this developmental ability translates into greater pregnancy rates after transfer of in vitro produced hatched blastocysts.

In Vitro and in vivo developmental competence of dromedary (Camelus dromedarius) embryos produced in vitro using two culture systems (mKSOMaa and oviductal cells).

Development competence and pregnancy rate of in vitro-produced (IVP) dromedary embryos were studied in two culture systems: (i) semi-defined modified medium (mKSOMaa) and (ii) co-culture using camel epithelial oviducal cells. Five hundred and three cumulus-oocytes complexes (COCs) were selected, allowed to mature, fertilized and cultured in vitro (38.5 degrees C; 5% CO2, maximum humidity > 95%, with concentration of oxygen of 5% for semi-defined medium and 20% for co-culture cells). Maturation was accomplished by incubation in TCM-199 medium supplemented with 10% heat-treated foetal calf serum (FCS), 10 ng/ml epidermal growth factor, 1 microg/ml follicle-stimulating hormone, 1 microg/ml oestradiol and 500 microM cysteamine for 30 h. In vitro fertilization (IVF) was performed using fresh semen (0.5 x 10(6) spermatozoa/ml in modified TALP solution). Fertilized COCs were denuded by vortexing, then cultured in either mKSOMaa (10% heat-treated FCS was added 24 h post-IVF), under 5% O2 and 90% N2 (group 1; n = 249) or with dromedary epithelial oviducal cell monolayers in TCM-199 with 10% heat-treated FCS under 20% O2 (group 2; n = 254). The rate of cleavage was significant higher (p < 0.05) for group 1 (63%, 156/249) than for group 2 (51%, 130/254). No significant difference was found between the two groups in the rate of development to blastocyst (21% vs 16.5%) and their hatchability (21% vs 14%). Pregnancy rates were similar for the first 60 days. However, all pregnancies were lost after 60 days with the exception of two of six (33%) from recipients of hatched blastocysts from group 1. We conclude that both systems support in vitro production of dromedary embryos by in vitro maturation (IVM)/IVF of oocytes. However, embryos obtained by culture in the semi-defined medium (mKSOMaa) appear to have a better in vivo development ability.

Update on reproductive biotechnologies in small ruminants and camelids.

Recent advances in reproductive biotechnologies in small ruminants include improvement of methods for in vitro production of embryos and attempts at spermatogonial stem cell transplantation. In vitro production of embryos by IVM/IVF, intra-cytoplasmic sperm injection (ICSI), or nuclear transfer (NT) has been made possible by improvements in oocyte collection and maturation techniques, and early embryo culture systems. However, in vitro embryo production still is not very efficient due to several limiting factors affecting the outcome of each step of the process. This paper discusses factors affecting in vitro embryo production in small ruminants and camelids, as well as preliminary results with the technique of spermatogonial stem cell transplantation.

Effect of GnRH antagonist-induced prolonged follicular phase on follicular atresia and oocyte developmental competence in vitro in superovulated heifers.

A GnRH antagonist (Antarelix) was used to suppress endogenous pulsatile secretion of LH and delay the preovulatory LH surge in superovulated heifers to study the effect of a prolonged follicular phase on both follicle and oocyte quality. Oestrous cycles were synchronized in 12 heifers with progestagen (norgestomet) implants for 10 days. On day 4 (day 0 = day of oestrus), heifers were stimulated with 24 mg pFSH for 4 days and luteolysis was induced at day 6 with PGF2 alpha (2 ml Estrumate). Animals in the control group (n = 4) were killed 24 h after the last FSH injection. At this time, heifers in group A36h (n = 4) and group A60h (n = 4) were treated with 1.6 mg of Antarelix every 12 h for 36 and 60 h, respectively, and then killed. After dissection of ovarian follicles, oocytes were collected for individual in vitro maturation, fertilization and culture; follicular fluid was collected for determination of steroid concentrations, and granulosa cells were smeared, fixed and stained for evaluation of pycnosis rates. Granulosa cell smears showed that 90% of follicles were healthy in the control group. In contrast, 36 and 58% of the follicles in group A36h showed signs of early or advanced atresia, respectively, while 90% of the follicles in group A60h showed signs of late atresia. Intrafollicular concentrations of oestradiol decreased (P < 0.0001) from healthy follicles (799.14 +/- 40.65 ng ml-1) to late atretic follicles (3.96 +/- 0.59 ng ml-1). Progesterone concentrations were higher (P < 0.0001) in healthy follicles compared with atretic follicles, irrespective of degree of atresia. Oestradiol:progesterone ratios decreased (P < 0.0001) from healthy (4.58 +/- 0.25) to late atretic follicles (0.07 +/- 0.009). The intrafollicular concentrations of oestradiol and progesterone were significantly higher (P < 0.0001) in the control than in the treated groups. The oestradiol:progesterone ratio was higher (P < 0.0001) in the control (4.55 +/- 0.25) than in the A36h (0.40 +/- 0.05) and A60h (0.07 +/- 0.009) groups. Unexpectedly, the cleavage rate of fertilized oocytes, blastocyst rate and number of cells per blastocyst were not significantly different among control (85%, 41% and 95 +/- 8), A36h (86%, 56% and 93 +/- 5) and A60h (88%, 58% and 79 +/- 4) groups. In addition, there were no significant differences in the blastocyst rates from oocytes derived from healthy (45%), early atretic (54%), advanced atretic (57%) and late atretic follicles (53%). In conclusion, the maintenance of the preovulatory follicles in superovulated heifers with a GnRH antagonist induced more atresia and a decrease in oestradiol and progesterone concentrations. However, the developmental potential in vitro to day 8 of the oocytes recovered from these atretic follicles was not affected.

Effect of time interval from insemination to first cleavage on the developmental characteristics, sex ratio and pregnancy rate after transfer of bovine embryos.

In vitro produced bovine zygotes show substantial variation in the time required to complete the first cell cycle and in their in vitro development potential. A number of reports have highlighted the fact that the fastest developing embryos in vitro are most likely to be comparable with their in vivo counterparts. At 24 h after IVF, presumptive zygotes were cultured in droplets of synthetic oviduct fluid medium. Droplets were examined at regular intervals and all cleaved embryos at each time point were transferred into new droplets and cultured separately for the duration of the experiment. All uncleaved zygotes were returned to the incubator and re-examined at the successive time points until 48 h after insemination, at which time the remaining uncleaved oocytes were retained as a group. A representative number of day 7 blastocysts from zygotes that had cleaved by 30 or 36 h were transferred to synchronized recipients and pregnancy was diagnosed by ultrasonography at day 35. Glucose and glutamine metabolism was examined in zygotes and blastocysts and compared retrospectively with time of first cleavage. A representative number of blastocysts from each of the cleavage groups was sexed using PCR. Data were analysed by chi-squared and regression analysis. Development to the blastocyst stage decreased as the time from insemination to first cleavage increased (r = 0.97, P < 0.03). There was no difference in blastocyst hatching, number of blastocyst cells or pregnancy rate between the 30 and 36 h groups. The overall sex ratio was 62% males (n = 258, P < 0.0001) and was not different in the 30 and 36 h groups (61%, n = 155 versus 63%, n = 95, respectively). These results indicate that although time of first cleavage has a major influence on the probability of an embryo developing to the blastocyst stage, once that stage is attained, subsequent developmental characteristics are unrelated to the time of first cleavage.

Effect of follicle size and of the FecB Booroola gene on oocyte function in sheep.

Booroola ewes have a major gene that affects ovulation rate. Gene expression has consequences on ovarian somatic cells but it is unknown whether it also affects germ cells in the adult ovary. Hence, the present study examined (1) whether oocyte growth was similar in FecBFecB and Fec+ Fec+ oocytes during preantral and antral follicular growth, (2) whether the patterns of proteins neosynthesized by oocytes of these two genotypes were identical, (3) whether the ability of the oocytes to resume meiosis was unaffected by genotype and (4) whether, after IVF, oocytes from both genotypes could develop to the blastocyst stage at similar rates. Histological examination of the respective sizes of the oocyte and of the follicle demonstrated that oocytes were larger in FecBFecB versus Fec+ Fec+ preantral follicles. Resolution of the proteins neosynthesized by FecBFecB and Fec+ Fec+ oocytes by one-dimensional PAGE and image analysis demonstrated that quantitative (but not qualitative) differences could be observed between genotypes for bands at 74, 59, 35 and 25 kDa. In addition, a genotype by oocyte size interaction was detected for two additional bands at 45 and 43 kDa. After 24 h of culture in vitro in TCM-199 plus 100 ng ml-1 FSH plus 10% sheep follicular fluid, oocytes from FecBFec+ follicles gained the ability to resume meiosis at a smaller size and a higher proportion of them reached metaphase II irrespective of the size class studied compared with Fec+ Fec+ follicles. In addition, the developmental rate of eggs after IVF was also affected by follicle size and genotype, since FecBFec+ oocytes originating from 1.0-3.5 mm follicles had a greater ability (P < 0.05) to develop to the blastocyst stage than Fec+ Fec+ oocytes. It is concluded that the FecB gene, in addition to its effects on granulosa cell maturation, also affects oocyte development and function. Whether these alterations are related requires further investigation.

Effect of protein synthesis inhibition before or during in vitro maturation on subsequent development of bovine oocytes.

The overall objective of this study was to assess the effect of maintaining meiotic arrest in bovine oocytes in vitro on developmental competence. In Experiment 1 the effect of inhibition of meiotic resumption using cycloheximide (CX), on subsequent was examined. Immature cumulus oocyte complexes (COCs, n = 804) were cultured in the absence (24 h) or presence of CX for 6, 12, 18 or 24 h. The control was inseminated 24 h later, while CX-treated oocytes were cultured for a further 24 h before insemination. In Experiment 2 the effect of exposing the oocyte (n = 1239) during meiotic arrest to putative stimulatory substances (pFSH and FCS) was examined. In Experiment 3, to study the importance of protein synthesis during maturation, synthesis was blocked for a 6-h period at various times (6, 12, 18 h) after start of culture (n = 1117). In Experiment 1, there was no difference in cleavage rate between treatments. However, the percentage of 5 to 8 cell embryos at 72 h post insemination was significantly lower after CX treatment (64 vs 42 to 51%; P < 0.05). This was reflected in a lower rate of blastocysts at Day 6 (9 to 15 vs 31%, P < 0.002). While the blastocyst rate at Day 8 was lower in CX-treated oocytes, the effect was only significant when CX was present for longer than 12 h. A marked decrease in development was noted following inhibition for 18 h or more compared with the control (17 to 19 vs 40%; P < 0.0002). In Experiment 2, addition of either FSH or FCS to oocytes in the presence of CX had no effect on any of the parameters studied, even though there was a positive effect in control oocytes. In Experiment 3, treatment with CX after the oocytes had matured for varying periods resulted in decreased blastocyst rates at Days 6 and 8 of culture. The most significant drop in development occurred when oocytes were cultured for 12 h before exposure to CX (15 vs 40%; P < 0.0001). In conclusion, CX-blocked oocytes retained their developmental competence, although final blastocyst yields were reduced.

The characterization of bovine embryos obtained from prepubertal calf oocytes and their viability after non surgical embryo transfer.

We have previously shown that the addition of epidermal growth factor (EGF) during in vitro maturation was capable of stimulating the cytoplasmic maturation of cow and calf oocytes. The aim of the present study was to compare calf and cow blastocysts produced in the presence of EGF in terms of total cell number and cell distribution between trophectoderm (TE) and inner cell mass (ICM), pattern of protein synthesis, and ability to establish pregnancy after embryo transfer to recipients. For all experiment, embryos at Day 7 were obtained from IVM/IVF/IVC oocytes. No significant differences were noted in total cell number (cow = 138 +/- 46 vs calf = 142 +/- 59; mean +/- SD) or ICM and TE cell number between calf (ICM = 35 +/- 19, TE = 107 +/- 52) and cow (ICM = 38 +/- 21, TE = 99 +/- 32) blastocysts, nor in the ICM/total cell number ratio (cow = 0.27 +/- 11, calf = 0.25 +/- 12). No differences were noted in the constitutive and the neosynthetic protein profiles between cow and calf embryos obtained in vitro. The results of embryo transfer, showed that there was higher pregnancy loss following transfer of calf compared with cow embryos. After Day 35, the rate of pregnancy decreases, with only 22% of calf embryos maintaining pregnancy until calving compared with 39% for cow embryos. In conclusion, it would seem that embryos originating from calf oocytes are less capable of establishing pregnancies than embryos obtained from adult oocytes, although this difference was not significant. This low viability cannot be explained by differences in cell number or by the protein profiles identified between these 2 groups of embryos.

Kinetics of nuclear maturation and protein profiles of oocytes from prepubertal and adult cattle during in vitro maturation.

The aim of this present study was to compare the kinetics of nuclear maturation between calf and cow oocytes in order to determine if there are differences between the 2 groups which could explain their disparate developmental capacity. The constitutive and neosynthetic protein patterns of cow and calf oocytes and of their corresponding cumulus cells were also compared during in vitro maturation. A total of 397 calf oocytes and 406 cow oocytes was matured in M199 + 10 ng/mL EGF. The first group of oocytes (n = 30) was immediately fixed and stained after removal from the follicle, and represent 0 h. The remaining oocytes were removed from the maturation medium at 4, 8, 12, 16, 20 and 24 h respectively. Half were denuded, fixed and stained for nuclear status; while the remainder were radiolabeled with methionine-(35S). Immediately after isolation, all the oocytes were at the GV stage. By 8 h, GVBD had occurred in most oocytes (calf: 97%; cow: 100%) and some had reached pro-metaphase I (calf: 49%; cow: 51%). By 12 h, most of the oocytes were at metaphase I (calf: 84%; cow: 94%). By 16 h, 54% of calf oocytes had reached telophase I or beyond compared with 71% of cow oocytes. This difference between the 2 groups became significant by 20 h, with 89% of cow oocytes (P < 0.05) at metaphase II and 71% of calf oocytes. By 24 h of culture, GVBD had occurred in all cases. Most oocytes completed meiosis I and were arrested at metaphase II with the first polar body extruded (calf: 72%; cow: 86%). No differences were noted in the constitutive and the neosynthetic protein profiles of cumulus cells in relation to the age of animal. Changes in neosynthetic protein patterns were observed both in cow and calf cumulus during IVM, and several proteins showed stage-specific synthesis. For the constitutive protein patterns of cow and calf oocytes, there were quantitative (38 and 40 kD) and qualitative (4, 10, 16, 17, 24, 25 and 26 kD) differences between the 2 groups. Only a few differences were observed in neosynthetic proteins between cow and calf oocytes, but there were changes in relation to nuclear status both in cow and calf oocytes. In conclusion, the difference in developmental capacity between cow and calf oocytes may be explained by a difference in the kinetics of nuclear maturation, which was significant at 20 h of culture (with 89% of cow oocytes at metaphase II and 71% of calf oocytes). At the biochemical level, our results indicate that nuclear progression during in vitro maturation of bovine oocytes is linked to changes in protein synthesis by the oocyte itself, while cumulus protein synthesis may either stimulate or modulate the process of oocyte maturation.

Bovine blastocyst production in vitro after inhibition of oocyte meiotic resumption for 24 h.

The aims of the present study were to assess the effect of various substances on meiotic resumption and subsequent development to the blastocyst stage of bovine oocytes. Immature cumulus-oocyte complexes were cultured for 24 h in (a) Medium 199 (M199) alone, or M199 supplemented with (b) 10% fetal calf serum (FCS), (c) 1 micrograms cycloheximide ml-1, (d) 2 mmol 6-dimethylaminopurine (6-DMAP) l-1, or (e) 0.1 mmol vanadate l-1. After 24 h, groups (a) and (b) were inseminated with frozen-thawed spermatozoa and subsequently cultured, while groups (c-e) were washed and cultured for a second 24 h in M199 + FCS, after which they were inseminated and cultured. At all time points a representative sample of oocytes were fixed and stained with orcein to observe the nuclear status, while others were labelled with [35S]methionine to study protein biosynthesis. Incubation with 6-DMAP, cycloheximide or vanadate completely blocked germinal vesicle breakdown with most oocytes remaining at the germinal vesicle stage after 24 h culture (89%, 100% and 85%, respectively). This inhibitory effect was fully reversible in the case of 6-DMAP and cycloheximide; after a second period of incubation, germinal vesicle breakdown occurred in almost all cases (99% and 100%, respectively), and most reached metaphase II (85% and 83%, respectively). In contrast, inhibition with vanadate was only reversible in 56% of oocytes, with only 6% reaching metaphase II. Cleavage rates at 72 h after insemination and blastocyst yields on day 8 of culture were, respectively: (i) M199, 72% and 34%; (ii) M199 + FCS, 80% and 45%; (iii) M199 + cycloheximide, 81% and 19%; (iv) M199 + 6-DMAP, 77% and 14%. 6-DMAP did not modify methionine incorporation. However, cycloheximide completely blocked protein synthesis when present during the period of labelling. Addition of epidermal growth factor to cycloheximide-inhibited oocytes was without effect. In contrast, epidermal growth factor overcame the effect of 6-DMAP in about 50% of oocytes, resulting in lower developmental rates after IVF. These results give an indication of the feasibility of in vitro meiotic inhibition as a tool in the study of the mechanisms involved in acquisition of competence.

Characterization of calf follicular fluid and its ability to support cytoplasmic maturation of cow and calf oocytes.

The aims of the present study were to characterize the follicular fluid from prepubertal calf follicles of known size and quality and to study the ability of follicular fluid to support cytoplasmic maturation of calf and cow oocytes. Follicular fluid was obtained from 67 calf follicles classified according to size (S: small < 6 mm, M: medium 6-8 mm and L: large > 8 mm in diameter) and quality (HY: healthy, EA: early atretic and A: atretic). Quality was first determined by mitosis:pycnosis ratios in granulosa cell smears and confirmed by insulin-like growth factor binding protein (IGFBP) patterns. There was approximately 90% agreement between the two methods of follicle classification and on this basis the calf follicular fluid was pooled into nine groups. The accuracy of this pooling was confirmed by evaluation of oestradiol concentrations in the nine pools of follicular fluid using radio-immunoassay. Increases in follicle size were characterized by a decreased intensity of bands for IGFBP-2, IGFBP-5 and IGFBP-4, an increase in the proportion of healthy follicles and a decrease in the proportion of follicles in the early stages of atresia. This finding is in agreement with previously published results in cows. All classes of calf follicular fluid contained lower concentrations of oestradiol than previously reported for corresponding classes of cow follicular fluid. Cow oocytes were matured in M199 alone, or supplemented with 10% fetal calf serum (FCS), or 10% calf follicular fluid from one of three pools (LHY, LEA, LA), fertilized, and cultured for 8 days in synthetic oviduct fluid. Addition of FCS or calf follicular fluid to cow oocytes during in vitro maturation increased the yield of blastocysts on day 8 over the control (23%, 21/91), FCS (39%, 37/96, P < 0.05), LA (41% 21/52, P < 0.05), LEA (32%, 28/88), LHY (36%, 32/88), although not significantly in all cases. The rate of hatching of blastocysts was also improved: control (38%, 8/21), FCS (54%, 20/37), LA (62%, 13/21), LEA (75%, 21/28, P < 0.02), LHY (59% 19/32). In contrast, the addition of either FCS, calf follicular fluid or cow follicular fluid did not improve development of calf oocytes compared with the unsupplemented control. In conclusion, it is probable that serum and follicular fluid contain factors that stimulate the acquisition by oocytes, during maturation, of developmental competence and to which prepubertal oocytes are unable to respond. Specific receptors for these factors may develop only around puberty.

In vitro production of bovine embryos using individual oocytes.

The development of a bovine in vitro embryo production system where individual oocytes could be followed through to the morula or blastocyst stage would be of interest to several fields of study and would allow us to characterise developmentally competent oocytes and their corresponding follicular environment. Several studies have, however, reported significantly reduced embryo development when oocytes or embryos were cultured individually compared to in groups. The aim of this study was to establish such an embryo production system, with embryo development rates similar to that observed under control (grouped) conditions. This study showed that conservation of the oocyte/embryo medium densities generally employed for grouped culture does not facilitate embryo development if oocytes/embryos are cultured individually. However, individual oocytes could effectively undergo IVM/IVF/IVC to the expanded blastocyst stage with some small modifications to the standard protocol. Individual IVF was effective if carried out in either 100 microliters of medium in wells or in 50 microliters droplets. Individual IVC, if carried out in 10 or 20 microliters droplets of SOF with FCS added at either 0 or 24 hr, was effective in terms of blastocyst yields but 20 microliters droplets did yield significantly fewer hatched blastocysts compared to grouped controls (p < 0.05). An entirely individual embryo production system was effective when it included individual IVM in 10 microliters droplets of M199 + 10 ng/ml EGF resulting in day 8 blastocyst yields not significantly different from controls (38% vs. 35% respectively). The use of 10% FCS during individual IVM appeared, at least under our experimental conditions, to be detrimental to subsequent development. The uses of an individual system for embryo production are many and varied. The results of this study show clearly that a large proportion of bovine oocytes can develop to the blastocyst stage when matured, fertilized, and cultured individually. This opens the way for studies regarding the quality of specific oocytes in such a way as will greatly improve our understanding of the events of late folliculogenesis.

Prepubertal bovine oocyte: a negative model for studying oocyte developmental competence.

To identify potential markers of maturation quality, differences in developmental capacity between cow and calf oocytes were compared in parallel with their constitutive and neosynthetic protein profiles before and after in vitro maturation (IVM). A comparison was also made between the protein profiles of follicular fluid (FF) from calf and cow ovaries. The effect of epidermal growth factor (EGF) during IVM on the subsequent development of prepubertal calf oocytes was examined. The effect of the presence of fetal calf serum (FCS) during development of embryos originating from calf oocytes was also examined. No differences were noted between the constitutive proteins of cow and calf oocytes and only a minor modification was observed before IVM in the pattern of neosynthesized proteins (presence of a band of 37 kD and a slight increase in the intensity of band of 78 kD in cow as compared to calf oocytes). However, the comparison of constitutive protein profiles from calf and cow FF demonstrated quantitative (the bands of 34 and 45 kD were more intense for cow than for calf) differences. EGF receptors (EGF-R) were demonstrated on cumulus-oocytes complexes (COCs) by immunofluorescence. There was no difference in intensity between cow and calf COCs. Furthermore, the addition of EGF during IVM of calf oocytes dramatically stimulated cumulus expansion and significantly increased the cleavage rate at 72 h post-insemination (82% vs 67%), as well as the proportion of embryos at the 5- to 8-cell stage at this time (54% vs 43%). Also, blastocyst yields at day 6 (11% vs 5%) and at day 8 (17% vs 10%) were significantly higher in the presence of EGF P < 0.05). The addition of FCS to synthetic oviduct fluid droplets at day 2 of culture (48 hpi) had no effect on cleavage, blastocyst yield, or blastocyst cell number. In conclusion, differences in developmental ability between calf and cow oocytes would appear to be not solely linked to differences in oocyte protein patterns. It is likely that the FF, which constitutes the microenvironment in which the oocyte develops, plays a major modulating role in determining the fate of the oocyte/follicle.

[In vitro oocyte maturation in domestic ruminants]. / Maturation ovocytaire in vitro chez les ruminants domestiques.

In vitro maturation represents the first step towards the in vitro production of embryos in domestic species. This production is of great interest from both zootechnic and basic points of view. Beyond nuclear aspects of maturation (progression of meiosis to metaphase II) cytoplasmic aspects confer to oocytes their potential to be fertilized and to develop normally. The culture medium used for maturation could influence this competence. Furthermore, the origin of oocytes (physiologic and genetic status of the oocyte donor, characteristics of the follicle) could also be determinant. The improvement of in vitro maturation techniques will certainly require a better understanding of these different aspects. Additionally, the maintenance of the oocytes in meiotic block during a pre-maturation in vitro culture will allow them to complete the storage of molecules necessary for fertilization and development.

Role of epidermal growth factor in bovine oocyte maturation and preimplantation embryo development in vitro.

Epidermal growth factor (EGF) has been shown to have a positive effect during in vitro maturation (IVM) and has been reported in follicular fluid at levels capable of stimulating meiosis in a variety of species. The aim of the present work was to study the effect on subsequent development of EGF present in defined medium during bovine 1) oocyte maturation or 2) embryo culture. The presence of EGF during IVM, irrespective of concentration (1, 10, 100 ng/mg), stimulated cumulus expansion and significantly increased the proportion of oocytes attaining metaphase II, the rate of cleavage, and the proportion of embryos reaching the 5- to 8-cell stage at 72 h postinsemination. Blastocyst rates on Days 7 and 9 were also significantly improved for oocytes matured in the presence of EGF (10% vs. 18-24% on Day 7 and 21% vs. 31-32% on Day 9, for Tissue Culture Medium 199 [M199] and M199 + EGF, respectively). The presence of fetal calf serum (FCS) during IVM resulted in similarly elevated rates of development. There was no cumulative effect when EGF and FCS were present together during IVM. The presence of EGF also altered the pattern of proteins neosynthesized during maturation. The maturation-promoting effect of EGF was evident for denuded oocytes also, suggesting that EGF may act, at least in part, directly on the oocyte. Immunofluorescence studies revealed the EGF receptor on immature cumulus-oocyte complexes. When present during postfertilization culture in defined medium (synthetic oviduct fluid), EGF stimulated development in comparison to that of the control but could not replace serum. The results suggest a physiological role for EGF in the regulation of bovine oocyte maturation and development.