Repeated endoscopic ovum pick-up in sheep

Endoscopy is an effective and minimally invasive technique which offers the possibility of repeated ovum pick-up (OPU). In this study 4 different treatment programs (Groups A, B, C and D) for repeated endoscopic OPU in sheep were investigated. The number of follicles and oocytes, quality of cumulus-oocyte-complexes (COCs), and detectable effects on fertility of the donor ewes were compared. Each group consisted of 5 East Friesian Milksheep. In Group A, follicles were punctured twice a week, in Group B once a week, and in Group C once a week followed by administration of 1500 IU PMSG 48 h prior to OPU. In Group D follicles were punctured and the sheep stimulated with 1500 IU PMSG 48 h prior to OPU once every 2 weeks. The PMSG-stimulated sheep received anti-PMSG immediately after OPU. Over a period of 10 weeks 216 OPU-sessions were performed. A total of 1978 follicles was punctured, and 1098 oocytes were recovered, for a collection rate of 55.5%. In the Groups A, B, C and D an average of 6.8, 8.6, 12.2 and 14.9 follicles per animal and session was aspirated, and an average of 3.8, 4.9, 7.0 and 7.6 COCs per animal per session was recovered, respectively. No significant differences between groups were observed in the collection rates (51.1 to 57.1%) or in the quality of the COCs, and 65 to 70% of the COCs were suitable for in vitro production of ovine embryos. Seven sheep developed small adhesions between the ovary and infundibulum. After the study 15 ewes became pregnant following natural mating with the same fertile ram (5 from Group A, 1 from Group B, 4 from Group C and 5 from Group D). In conclusion, OPU once a week in PMSG/anti-PMSG treated ewes was found to be the most effective treatment program for oocyte collection.     

Effects of ovarian stimulation, with and without human chorionic gonadotrophin, on oocyte meiotic and developmental competence in the marmoset monkey (Callithrix jacchus)

A reliable ovarian stimulation protocol for marmosets is needed to enhance their use as a model for studying human and non-human primate oocyte biology. In this species, a standard dose of hCG did not effectively induce oocyte maturation in vivo. The objectives of this study were to characterize ovarian response to an FSH priming regimen in marmosets, given without or with a high dose of hCG, and to determine the meiotic and developmental competence of the oocytes isolated. Ovaries were removed from synchronized marmosets treated with FSH alone (50 IU/d for 6 d) or the same FSH treatment combined with a single injection of hCG (500 IU). Cumulus-oocyte complexes (COCs) were isolated from large (>1.5mm) and small (0.7-1.5mm) antral follicles. In vivo-matured oocytes were subsequently activated parthenogenetically or fertilized in vitro. Immature oocytes were subjected to in vitro maturation and then activated parthenogenetically. Treatment with FSH and hCG combined increased the number of expanded COCs from large antral follicles compared with FSH alone (23.5 +/- 9.3 versus 6.4 +/- 2.7, mean +/- S.E.M.). Approximately 90% of oocytes surrounded by expanded cumulus cells at the time of isolation were meiotically mature. A blastocyst formation rate of 47% was achieved following fertilization of in vivo-matured oocytes, whereas parthenogenetic activation failed to induce development to the blastocyst stage. The capacity of oocytes to complete meiosis in vitro and cleave was positively correlated with follicle diameter. A dramatic effect of follicle size on spindle formation was observed in oocytes that failed to complete meiosis in vitro. Using the combined FSH and hCG regimen described in this study, large numbers of in vivo matured marmoset oocytes could be reliably collected in a single cycle, making the marmoset a valuable model for studying oocyte maturation in human and non-human primates.     

Long term effect of Ovum Pick-up in buffalo species

The aim of this study was to evaluate the effect of an Ovum Pick-up (OPU) treatment carried out for 9 months in buffalo (Bubalus bubalis) species. Eight pluriparous non-lactating buffalo cows underwent OPU for 9 months. Recovered cumulus enclosed oocytes (COCs) were classified and COCs suitable for in vitro embryo production (IVEP) were in vitro matured (IVM), fertilized (IVF) and cultured (IVC) to the blastocyst (Bl) stage. Animals were monitored for a total period of 270 days, but at the summer solstice, follicular turnover decreased and at the 68-day of the trial, we decided to increase the OPU sampling interval from 3-4 to 7 days. It was therefore possible to distinguish two phases: a first phase (18 sessions), during which OPU was carried out twice weekly and a second phase (16 sessions) during which OPU sessions were performed weekly. This reduction did not modify the percentage of good quality COCs, while the incidence of grade D COCs decreased (P<0.01). Furthermore, embryo production was higher in the second phase, either if embryos were calculated on the total recovered COCs (8.3% vs. 21.4%; P<0.01) and on grade A+B COCs (13.0% vs. 32.1%; P<0.01), that supposedly should have given similar blastocyst yield. During the total period of the trial it was possible to distinguish a first period of 6 months (34 sessions) characterized by blastocyst production (0.36 blastocyst/buffalo/session), followed by an unproductive period of 3 months (12 sessions), during which embryos were not produced. During the first 6 months a higher (P<0.01) number of follicles (5.06 vs. 3.71), small follicles (3.38 vs. 2.07), total COCs (2.58 vs. 1.56) and good quality (A+B) COCs (1.51 vs. 0.94) per subject/session were recorded compared to the last 3 months. No Blastocyst were produced during the second period, even if the percentage of grade A+B COCs was similar to that recorded during the first period. In conclusion, buffalo cows submitted to repeated OPU sampling for a 9-month period, showed a decline of follicle recruitment and oocyte collection after the first two months of samplings. After 6-month of samplings, in spite of the quality grade of the collected oocytes, we found a drop in their developmental competence.     

Effect of recombinant bovine somatotropin (bST) on follicular population and on in vitro buffalo embryo production

The objective of this study was to evaluate the effect of bovine somatotropin (bST) on ovarian follicular population in buffalo heifers and its influence on oocyte quality, recovery rates and in vitro embryo production. We tested the hypothesis that bST treatment in buffalo females submitted to an ovum pick-up (OPU) program would improve the number of follicles recruited, oocyte quality and in vitro embryo production. A total of 10 heifers were assigned into two treatment groups: group bST (n=5; receiving 500 mg of bST in regular intervals) and control group (n=5; without additional treatment). Both groups were subjected to OPU sessions twice a week (every 3 or 4 days), for a total of 10 sessions per female, although due to procedural problems, only the first five OPU sessions produced embryos. The number of follicles and the diameters were recorded at all OPU sessions. The harvested oocytes were counted and classified according to their quality as either A, B, C, D or E, with A and B considered good quality. Cleavage and blastocyst production rates were evaluated 2 and 7 days after in vitro fertilization, respectively. The bST treatment increased the total number of antral follicles (>3mm in diameter; 12.2 compared with 8.7; p<0.05) and of small antral follicles (<5mm; 9.1 compared with 6.5; p<0.05) per OPU session. The bST also tended to increase the number of oocytes recovered per session (5.2 compared with 4.1; p=0.07), and enhanced the percentage of good quality oocytes (48.8% compared with 40.6%; p=0.07). bST showed no effect on cleavage and blastocyst production rates (p>0.05). The significant effects of performing repeated OPU sessions were decreasing the follicular population (p<0.001) as well as the number of follicles aspirated (p<0.001), and oocytes recovered (p<0.02). In conclusion, bST treatment improves the follicular population, demonstrating its possible application in buffalo donors submitted to OPU programs.     

Bovine and buffalo in vitro embryo production using oocytes derived from abattoir ovaries or collected by transvaginal follicle aspiration

This study was undertaken in order to evaluate the effect of oocyte source (live animals and abattoir ovaries) on subsequent embryo development in buffalo (Bubalus bubalis). Cow ovaries were also collected as oocyte donors for in vitro embryo production (IVEP).Three hundred thirty-eight oocytes were recovered by ovum pick up (OPU, Group A) from 8 pluriparous buffalo cows, while 1127 and 1457 oocytes were aspirated, respectively, from buffalo (Group B) and bovine (Group C) slaughterhouse ovaries. Cumulus enclosed oocytes (COCs) suitable for IVEP were in vitro matured (IVM), fertilized (IVF) and cultured (IVC) to the tight morula (Tm) and blastocyst (Bl) stage.Within buffalo species Group A had a higher Bl yield (29.7 % versus 19.9%; P<0.05) and a lower proportion of embryos arrested at Tm stage (11.1% versus 22.3%; P<0.05) than Group B.Within slaughterhouse groups cattle oocytes had a higher cleavage rate (83.9% versus 64.8%; P<0.05) and yielded 49.2% more blastocysts than buffalo. However, when data are related to the total number of cleaved oocytes, only 13.7% more blastocysts were produced in cattle than in buffalo.In conclusion, in buffalo species the source of oocytes significantly affected post-fertilization embryo development, as demonstrated by the higher Bl yields derived from OPU-derived oocytes.A higher overall IVEP efficiency, mainly related to the higher cleavage rate, was recorded in cattle compared with buffalo when ovaries from an abattoir were used as oocyte donors.     

Mitochondrial aggregation patterns and activity in porcine oocytes and apoptosis in surrounding cumulus cells depends on the stage of pre-ovulatory maturation

In this study, we evaluated the distribution and oxidative activity of mitochondria in ex vivo pre-ovulatory porcine oocytes using the fluorescence probe MitoTracker CMTM Ros Orange. Cumulus-oocyte complexes (COCs) were classified according to cumulus morphology and time from hCG administration. The meiotic configuration of the oocytes and the degree of apoptosis in the surrounding cumulus cells were also evaluated. Estrus was synchronized in 45 crossbred Landrace gilts by feeding altrenogest for 15 days and administering 1000 IU PMSG on Day 16. The LH peak was simulated by treatment with 500 IU hCG, given 80 h after PMSG. Endoscopic oocyte recovery was carried out 2 h before or 10, 22, or 34 h after hCG administration. Altogether 454 COCs were aspirated from follicles with a diameter of more than 5 mm. Cumulus morphology in the majority of COCs recovered 2 h before and 10 h after hCG was compact (60.4 and 52.7%, respectively; P<0.05). At 22 h after hCG, COC morphology changed significantly from 10 h dramatically: 74% of COCs had an expanded cumulus (P<0.01). At 34 h after hCG, 100% of recovered COCs had an expanded cumulus. The percentage of oocytes with a mature meiotic configuration differed among COC morphologies and increased as the interval after hCG administration increased (P<0.05). The type of mitochondrial distribution in the oocytes (n=336) changed from homogeneous to heterogeneous as the interval after hCG administration increased (P<0.01) and was associated with the cumulus morphology. Representative mitochondrial distributions were found as follows: -2 h: fine homogeneous in compact and dispersed COCs; 10 h: granulated homogeneous in compact and dispersed COCs; 22 h: granulated homogeneous in expanded COCs; and 34 h: granulated heterogeneous and clustered heterogeneous in expanded COCs (P<0.01). The oxidative activity of mitochondria measured by fluorescence intensity (Em: 570 nm) per oocyte after Mitotracker CMTM Ros Orange labeling increased in the oocyte as the post-hCG interval increased (P<0.01) and depended on the type of mitochondrial distribution. Lowest oxidative activity of mitochondria was found in oocytes with fine homogeneous distribution (253.1+/-9.4 microA). The oxidative activity increased (334.4+/-10.3 microA) in oocytes with granulated homogeneous distribution of mitochondria, and reached highest level in oocytes with granulated heterogeneous (400.9+/-13.0 microA) and clustered heterogeneous distributions (492.8+/-13.9 microA) (P<0.01). Mitochondrial activity in oocytes coincided with apoptosis in surrounding cumulus cells which increased in a time-dependent manner during pre-ovulatory maturation in vivo (P<0.01). These results indicate that there is a relationship between meiotic progression, cumulus expansion and mitochondrial redistribution and their oxidative activity during final pre-ovulatory maturation in pig oocytes. It appears that increased levels of mitochondrial activities in oocytes are correlated to increased levels of apoptosis in surrounding cumulus cells, in which mitochondria may play a role.     

Influence of FSH and hCG on the resumption of meiosis of bovine oocytes surrounded by cumulus cells connected to membrana granulosa

Cumulus oocyte complexes (COCs) and cumulus oocyte complexes connected to a piece of the membrane granulosa (COCGs) were isolated from bovine antral follicles with a diameter of 2 to 8 mm. After culture of COCGs without gonadotrophic hormones for 22 hr approximately 50% of the oocytes were still in the germinal vesicle (GV) stage Histology of the COCGs showed that the pieces of the membrana granulosa were free of thecal cells and parts of the basal membrane. This indicates that the membrana granulosa solely inhibits the progression of meiosis. To investigate the effect of gonadotropins on the resumption of meiosis of oocytes from small and medium sized antral follicles, COCs and COCGs were cultured with or without rec-hFSH or hCG. Addition of 0.05 IU rec-hFSH to the culture medium of COCGs resulted in germinal vesicle breakdown in 97.8% of the oocytes compared to 46% in the control group, and an increase of the diameter of the COCs (479 μm vs. 240 μm in the control group). Addition of 0.05 IU hCG to the culture medium had no effect on nuclear maturation (47.2% GV vs. 48.5% GV in the control group nor on cumulus expansion (246 μm vs. 240 μm in the control group). RT-PCR on cDNA of the follicular wall, cumulus cells, granulosa cells, COCs, and oocytes revealed that mRNA for FSH receptor was present in all cell types except oocytes. mRNA of the LH receptor was detected exclusively in thecal cells. Nucleotide sequence analysis and alignment of the cloned PCR products showed the presence of two isoforms of the FSH receptor mRNA and two isoforms of the LH receptor mRNA. It is concluded that, in vitro, resumption of meiosis of oocytes, originating from small and medium sized antral follicles and meiotically arrested by the membrana granulosa, is triggered by FSH and not by LH. This is supported by the fact that receptors for FSH, but not for LH, are transcribed in the cumulus and granulosa cells of these follicles. © 1996 Wiley-Liss, Inc.     

Repeated oocyte pick up in prepubertal swamp buffalo (Bubalus bubalis) calves after FSH superstimulation

The objective in this study was to investigate the effect of repeated oocyte collection by transvaginal, ultrasound-guidance, oocyte pick-up (OPU) in nine, prepubertal (8-12 months), swamp buffaloes. Animals were treated with FSH for 3 days and received GnRH on the third day, 24 h before OPU. This session was repeated on five occasions at 2 weekly intervals. Over the five sessions of hormone treatment followed by OPU, 39/42 (92.9%) animals responded and had 6.6+/-3.6 follicles with a follicular diameter of 5.0+/-2.0 mm. The oocyte recovery rate was 5.4+/-3.7 and averaged 82.8% oocytes, except for session 4, when oocyte recovery was around 75.0%. Most oocytes were denuded (39.5%), whilst 28.8% had a substantial cumulus mass. There were no differences in the ovarian responses and the recovery rates between the collections. It was concluded that five repeat cycles of FSH and OPU did not influence the follicular response to superstimulation or the number of oocytes recovered from prepubertal, buffalo calves.     

Morphology of porcine cumulus-oocyte-complexes depends on the stage of preovulatory maturation

The aim of this investigation was to determine the relationship between the morphology of the cumulus-oocyte-complexes (COCs) and the meiotic configuration of oocytes as an LH peak mimicked by hCG. Estrus was synchronized in a total of 29 crossbred Landrace gilts by feeding Regumate for 15 d and administering 1000 IU PMSG. The LH peak was simulated by treatment with 500 IU hCG at 80 h after PMSG. Endoscopic oocyte recovery was carried out 2 h before and 10, 22 and 34 h after hCG. Only macroscopically healthy follicles with a diameter of more than 5 mm were punctured. Altogether, 410 follicles from 57 ovaries were punctured and 251 COCs were aspirated. Oocyte recovery rate increased from 48.5% (P < 0.01) of the early, not yet preovulatory follicles (2 h before hCG) to 80.8% of late preovulatory follicles (34 h after hCG). Cumulus morphology in COCs recovered 2 h before and 10 h after hCG was heterogeneous, with most (72.9 to 57.4%; P < 0.01) showing a compact or slightly expanded cumulus. Starting at about 22 h after hCG, COC morphology changed dramatically (86.7% of COCs with expanded cumulus; P < 0.01), and 34 h after hCG, 98.3% of the COCs had only an expanded cumulus. The percentage of oocytes with a mature meiotic configuration increased (11.2; 7.1; 41.4 and 70.2%, respectively, n = 238 oocytes; P < 0.01) as the interval post hCG increased (-2, 10, 22, 34 h, respectively). Meiotic configuration was related to COC morphology: compact COCs--88.9% diplotene, expanded COCs--53.8% metaphase II (M-II), and denuded oocytes--69.2% degenerated chromatin. These results indicate that there is a relationship between oocyte recovery rate, COC morphology, and meiotic configuration and preovulatory follicle maturation after the application of hCG.     

Ovarian activity in progesterone treated mares following administration of pregnant mare serum gonadotropin

Twelve non-pregnant, non-lactating mares were randomly assigned to four treatment groups using a 2x2 factorial arrangement with three replicates per group. Mares were administered PGF(2alpha) (10 mg, IM) on days -14 and 0, followed by HCG (3000 IU, IM) on day 5. The following treatments were administered: Group A received PMSG on days 2 (4000 IU, IM) and 5 (1000 IU, IV); Group B received PMSG (4000 IU, IM) on day 2; Group C received PMSG (1000 IU, IV) on day; Group D received no PMSG. Mares received progesterone (25 mg, IM) on days 1 through 4. Reproductive tracts were recovered at necropsy on day 16 (10 days post-ovulation). Ovaries were weighed, CL number and weight determined, follicles counted and measured, and volume of follicular fluid quantified. Mean ovarian weight (g) and number of CL per mare, respectively were: Group A, 100.0+/-15.6, 1.7+/-.7; Group B, 128.6+/-40.4, 1.3+/-.7; Group C, 92.4+/-21.0, 2.0+/-.0; Group D, 93.3+/-12.3; .3+/-.3. Mean number of follicles >10 mm and total volume (ml) of follicular fluid per mare, respectively, were: Group A, 9.4+/-2.0, 21.8+/-10.9; Group B, 1.3+/-.3, 32.2+/-28.9; Group C, 4.3+/-1.8, 5.4+/-2.3; Group D, 6.0+/-4.5, 24.0+/-10.3. There was no difference (P>.05) in mean ovarian weight, CL number, CL weight, follicular fluid volume, number of follicles, or size of follicles between treatment groups. These results show no significant effect on ovarian activity in progesterone treated mares following administration of exogenous PMSG.     

Ovarian responses and oocyte recovery in prepubertal swamp buffalo (Bubalus bubalis) calves after FSH or PMSG treatment

Stimulation of follicular growth was examined using two different gonadotropin treatments in 10 prepubertal swamp buffalo calves (8 to 12 mo old). Each calf received an ear implant consisting of 3 mg norgestromet and 5 mg estradiol valerate during hormonal treatment. Five calves were additionally administered FSH (24 mg, im) and, 2 mo later, PMSG (3,000 IU). The remaining 5 calves were first treated with PMSG followed by FSH. Ovarian responses to treatments were examined by laparotomy, 72 h after ear implant removal, and by the number of follicles (diameter > or = 0.8 cm) and corpora hemorrhagica present. Ovaries had more significant response to FSH than PMSG treatment (13.9+/-8.6 vs 5.9+/-3.3 follicles; P<0.01). Although the recovery rate tended to be lower for FSH treated (64%) than PMSG-treated (82%) animals, more oocytes/animal were harvested in the PMSG treatment (8.3+/-5.0 vs 4.6+/-3.2, respectively). The immature oocytes (n = 38) were cultured for 24 to 25 h in maturation medium (TCM-199 NaHCO3+10% fetal calf serum [FCS] in 5%CO2 in air at 39 degrees C). Oocyte maturation was assessed after fixation and staining with aceto orcein. The in vitro maturation rate was 52.6% (20/38). This study shows the possibility of harvesting oocytes from prepubertal swamp buffalo calves and maturing the oocyte in vitro.     

Different intervals of ovum pick-up affect the competence of oocytes to support the preimplantation development of cloned bovine embryos

The objective of this study was to determine the effect of different frequencies of transvaginal ovum pick-up (OPU) on the quantity of recovered cumulus oocyte complexes (COCs) and subsequently the competence of matured oocytes to support the preimplantation development of cloned bovine embryos. The COCs were aspirated from the ovaries of 6 Chinese Holstein cows by transvaginal follicle aspiration twice a week (every 3 or 4 days) (Group I), every 5 days (Group II), once a week (every 7 days) (Group III), every 10 days (Group IV), and once every 2 weeks (every 14 days) (Group V). The developmental stages of the follicles were confirmed by the diameter of the dominant follicle (DF) and harvested COCs, and the dynamics of the follicular wave were clarified. In addition, extrusions of the first polar body (PB I) from the oocytes were observed at different time intervals after the initiation of in vitro maturation (IVM) to identify the appropriate culture time window for somatic cell nuclear transfer. Matured oocytes were used to produce cloned bovine embryos that were subsequently cultured in the goat oviduct. After 7 days, the embryos were flushed out, and the developmental rates of the blastocysts were compared among the five groups. The results showed that the aspirations of all follicles >or=3 mm in diameter (D1) induced and synchronized the dynamics of the follicular wave, and the subordinate follicles became atretic after 4 days (D5). Another follicular wave started between D7 and D10, and atresia in the subordinate follicles in the second follicular wave began on D14. The timing of meiotic progression (from the initiation of IVM to the extrusion of PB I) in the oocytes obtained by OPU was later than that of the oocytes obtained from the abattoir. Between 20 and 24 hr after the initiation of IVM, 20% of the oocytes extruded their PB I. Further, 80% (520/650) of the harvested COCs were arrested at metaphase II (MII) by 22 hr of the initiation of IVM and were used as cytoplast donors. The rates of development of the reconstituted embryos to the blastocyst stage were 23.1% (Group I), 15.0% (Group II), 10.9% (Group III), 4.9% (Group IV), and 29.0% (Group V). The results indicate that the developmental potential of follicles from the same living donors were different when different intervals of OPU were adopted and early atretic follicles from the second follicular wave had higher competence to support the early development of cloned bovine embryos.     

Chemical activation of buffalo (Bubalus bubalis) oocytes by different methods: effects of aging on post-parthenogenetic development

The possibility of artificially inducing activation of MII buffalo oocytes may allow us to evaluate indirectly the quality of oocytes after in vitro maturation. The aim of this work was to compare buffalo embryo development after IVF and after chemical activation by two different agents. A further goal was to evaluate the effects of aging of oocytes on post-parthenogenetic and post-fertilization development. In Experiment 1 cumulus-oocyte complexes (COCs) were recovered from abattoir-derived ovaries and matured in vitro. After IVM the COCs were either fertilized in vitro (positive control) or activated with ethanol and ionomycin, both followed by immediate exposure to 6-diethylaminopurine (6-DMAP) for 4 h. In vitro culture (IVC) was carried out up to the blastocyst stage. In Experiment 2 COCs were matured in vitro for 18, 21, 24, 27 and 30 h before activation was triggered with ethanol, followed by 6-DMAP. In Experiment 3 COCs were fertilized in vitro at 18, 21, 24, 27 and 30 h post-maturation. Ethanol activation gave better results than the IVF control group, with higher cleavage rate (71.4 +/- 7.8 versus 55.8 +/- 5.8, respectively; P < 0.05) and a higher proportion of oocytes developing into morulae-blastocysts (32.6 +/- 6.5 versus 22.9 +/- 7.5, respectively; P < 0.05). Within the activation groups, ethanol supported the highest development in terms of cleavage (71.4 +/- 7.8 versus 59.4 +/- 10.7; P < 0.05) and morulae-blastocysts rate (32.6 +/- 6.5 versus 25.7 +/- 8.3; n.s.). It was also demonstrated that aging negatively affects post-parthenogenetic and post-fertilization development.     

In vitro embryo production in buffalo (Bubalus bubalis) using sexed sperm and oocytes from ovum pick up

The objective was to explore the use of sexed sperm and OPU-derived oocytes in an IVP system to produce sex-preselected bubaline embryos. Oocytes were recovered from 20 fertile Murrah and Nili-Ravi buffalo cows by repeated (twice weekly) ultrasound-guided transvaginal ovum pick up (OPU), or by aspiration of abbatoir-derived bubaline ovaries, and subjected to IVF, using frozen-thawed sexed or unsexed bubaline semen. On average, 4.6 oocytes were retrieved per buffalo per session (70.9% were Grades A or B). Following IVF with sexed sperm, oocytes derived from OPU had similar developmental competence as those from abattoir-derived ovaries, in terms of cleavage rate (57.6 vs. 50.4%, P=0.357) and blastocyst development rate (16.0 vs. 23.9%, P=0.237). Furthermore, using frozen-thawed sexed versus unsexed semen did not affect rates of cleavage (50.5 vs. 50.9%, P=0.978) or blastocyst development (15.3 vs. 19.1%, P=0.291) after IVF using OPU-derived oocytes. Of the embryos produced in an OPU-IVP system, 9 of 34 sexed fresh embryos (26.5%) and 5 of 43 sexed frozen embryos (11.6%) transferred to recipients established pregnancies, whereas 7 of 26 unsexed fresh embryos (26.9%) and 6 out of 39 unsexed frozen embryos (15.4%) transferred to recipients established pregnancies. Eleven sex-preselected buffalo calves (10 females and one male) and 10 sexed buffalo calves (six females and four males) were born following embryo transfer. In the present study, OPU, sperm sexing technology, IVP, and embryo transfer, were used to produce sex-preselected buffalo calves. This study provided proof of concept for further research and wider field application of these technologies in buffalo.     

Hormonal dynamics and follicular turnover in prepuberal Mediterranean Italian buffaloes (Bubalus bubalis)

The aim of this study was the investigation of hormonal and ovarian follicular dynamics in prepuberal buffaloes (Bubalus bubalis) bred in Italy. Eleven 5-9-month old buffalo calves ranging in weight from 122 to 270kg, maintained under controlled nutritional and environmental conditions, underwent 50 days of ultrasonographic ovarian follicular monitoring in the months of October-December. Blood sampling for E(2) and FSH determination and ultrasonographic monitoring using a 7.5MHz linear probe and an ALOKA SSD-500 monitor were performed daily. No differences in any of the parameters under study were highlighted when calves were divided into two weight categories (<200 and >200kg) and thus data were pooled. In this study, values are reported as mean+/-S.D. A range of two-six regular follicular waves was reported among calves with an average of 4+/-1.1. Overall interval (days) between wave emergence was 9.9+/-2.8 and largest diameters (mm) of dominant and first subordinate follicles were 8.4+/-1.2 and 4.8+/-0.6, respectively (P<0.05). With the exception of one calf, some minor follicular waves (short waves or SWs; 1.6+/-1), lasting <10 days (6.1+/-1.2) were reported. They were monitored contemporaneously on the ovary contralateral (n=7) or ipsilateral (n=3) to the main follicular wave. Growth rate (mm per day) of dominant follicles (DF) was significantly faster than for corresponding subordinate follicles (SF) and follicles of SWs (1.08+/-0.2 versus 0.79+/-0.1 and 0.83+/-0.1, respectively, P<0.05). The static phase (days) lasted longer in DF compared to SF and SW (5.4+/-1.8 versus 2.4+/-1.2 and 2.6+/-1, respectively, P<0.05). The regressing phase (mm per day) was similar among DF, SF and SW (0.86+/-0.2, 0.94+/-0.2 and 0.84+/-0.1, respectively, P=0.09). Episodic spikes of E(2) and FSH were reported, corresponding to wave development throughout the course of investigation. In conclusion, the majority of buffalo calves displayed a typical pattern of regular follicular development in conjunction with a dynamic trend of ovarian and hypophyseal hormones. Some minor follicle turnover was reported with parallel main follicular waves.     

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.     

FSH different regimes affect the developmental capacity and cryotolerance of embryos derived from oocytes collected by ovum pick-up in donor sheep

The objective of the present study was to compare the developmental capacity of sheep oocytes obtained by OPU after two different ovarian stimulations, and cryotolerance to vitrification procedures of in vitro derived embryos after in vitro maturation, fertilisation and culture of these oocytes. Sheep were divided into three groups: (A) no treatment (control); (B) constant doses of FSH (FSH-c); (C) decreasing doses of FSH (FSH-d). Ovine groups FSH-c and FSH-d were synchronised by the insertion of intravaginal sponges left in situ for 7 days; FSH (total dose: 96IU) was administered in four doses given every 12h starting on Day 5. Twelve hours after the last FSH administration oocytes were collected by OPU technique. The control group showed a significantly lower number ( P<0.05 ) of follicles (166) than FSH-c (294) and FSH-d (317) groups, while the number of follicles >5mm was significantly higher ( P<0.01 ) in FSH-d group, showing that this protocol stimulates the growth of a different follicle population compared to FSH-c group. The control group showed a higher number of <2mm follicles ( P<0.01 ). We did not find any difference in oocyte quality between the three groups and therefore the percentage of discarded oocytes was similar. No significant differences were found between control, FSH-c and FSH-d groups in terms of maturation (90.9, 85.7 and 87.7%, respectively) and fertilisation rates (75.2, 80.9 and 83.7%, respectively) while a significantly higher ( P<0.01 ) blastocyst rate was observed in the FSH-c group than in the FSH-d and control groups (20.4% versus 11.8 and 13.7%, respectively). After vitrification, warming and 72 h in vitro culture, the hatching rate was significantly higher ( P<0.01 ) in the control (87.5%) and FSH-c (90.5%) groups than in the FSH-d group (66.7%). Control and FSH-c groups showed a significantly higher ( P<0.001 ) number of total cells than FSH-d group ( 217.6+/-26.5 and 203.0+/-33.2 versus 147.5+/-20.2 ), while no differences were observed in ICM cell rates in the control ( 35.6+/-3.8 ), FSH-c ( 37.1+/-4.6 ) and FSH-d ( 36.6+/-6.7 ) groups. These results indicate that donor sheep stimulated with FSH-c produced better quality oocytes and blastocysts showing better cryotolerance than ewes given the decreasing doses treatment.     

Characteristics of bovine estrous cycles during repeated transvaginal, ultrasound-guided puncturing of follicles for ovum pick-up

Repeated transvaginal ultrasound guided puncturing of visible follicles was performed for ovum pick-up (OPU) during Periods A and B, each of which lasted 3 mo. During Period A, 10 cows (A) were used in the study. Period B commenced 1 mo after Period A and two groups of animals were used. The first group (B1) consisted of 9 of 10 cows from Group A. The second experimental group of animals in Period B consisted of 11 cows (B2) which had not been submitted to previous puncture. During the study, all visible follicles larger than 3 mm were punctured and aspirated three times, on Day 3 or 4, Day 9 or 10 and Day 15 or 16 of the estrous cycle. The mean estrous cycle length (+/- SEM) after repeated follicle puncture did not differ among the three groups and was 22.3 +/- 0.4, 22.5 +/- 0.4 and 22.1 +/- 0.3 d for groups A, B1 and B2, respectively. The mean total number (+/- SEM) of punctured follicles per estrous cycle in Group A (13.1 +/- 0.5) was significantly larger than in Groups B1 (11.2 +/- 0.4) and B2 (11.6 +/- 0.4). The largest number of follicles punctured for ovum pick-up in all three groups was always on Day 3 or 4 of the estrous cycle: 4.9 +/- 0.3 follicles; the mean (+/- SEM) number of punctured follicles on Day 9 or 10 and Day 15 or 16 was significantly (P<0.05) lower: 3.4 +/- 0.2 and 3.9 +/- 0.2, respectively. In Period A, primarily 3- to 5-mm follicles were punctured per estrous cycle, while 6- to 10-mm follicles were predominantly punctured in Period B (P<0.05). Recovery rate of oocytes on Day 3 or 4, Day 9 or 10 and Day 15 or 16 were 53, 50 and 52%, respectively. Most oocytes (P<0.05) were aspirated from follicles smaller than 10 mm.