L.A. Guilbault

IN VITRO PRODUCTION OF BOVINE EMBRYOS : DEVELOPMENTAL COMPETENCE IS ACQUIRED BEFORE MATURATION

Few studies have examined the importance of the time during which oocytes are left in the ovaries following animal slaughter. The objective of this study was to determine the optimal time for retrieving oocytes after slaughter and to ascertain if superovulating cows in association with this optimal time could increase the developmental competence of bovine oocytes. In Experiment 1, oocytes were left in the postmortem ovaries for 2,3,4,5,6 or 7 h and were then transported to the laboratory at approximately 30 degrees C. Recovered oocytes were processed in vitro using standard techniques. In Experiment 2, cyclic heifers (n = 18) were superovulated between Days 8 and 12 of the estrous cycle with 8 constant doses (4 mg each, twice daily) or 8 decreasing doses (2 injections of 4,3,2 and 1 mg every 12 h) of FSH-P +/- 1 mg prostaglandin 24 or 48 h before slaughter. Oocytes were left in the ovaries for 4 h and were classified according to the state of their cumulus and cytoplasm. The results indicated that oocytes aspirated from ovaries collected 4 h after slaughter produced significantly more > or =64-cell embryos after 7 d of in vitro development than those collected 2, 6 or 7 h postslaughter. Oocytes (87%) from superovulated animals had numerous layers of cumulus cells and originated from medium (2.7 to 8 mm) and large (> or =8 mm) follicles. Significantly more oocytes developed from large follicles than from medium follicles. Although individual culture of the oocytes negatively affected the percentage of embryos produced, group culture of oocytes from animals that were superovulated and left in the postmortem ovaries for 4 h resulted in exceptionally high rates of embryos after 5 d of IVD. On average, 60 to 80% of 16-cell embryos were produced, indicating that under the proper conditions, developmental competence is acquired before in vitro maturation.

Superovulation can reduce the developmental competence of bovine embryos

This study was done to determine if different superovulatory regimens could have an effect on the percentage of embryos produced using IVM/IVF/IVC. Cyclic heifers (n = 22) were superovulated between Days 8 and 12 of the estrous cycle with 4, 6 or 8 constant doses of FSH-P (4 mg each, twice daily) +/- the addition of 1 mg prostaglandin 24 h before slaughter. Ovaries from these superovulated cows and from untreated cows were collected and the follicles dissected. Oocytes were classified according to the appearance of their cumulus and cytoplasm. Individual culture as well as group culture were performed but an individual culture reduced the percentage of oocytes developing into embryos for both untreated and superovulated animals. The results indicated that despite the superovulation regimen the developmental competence of the oocytes collected was lower (0 to 15% embryos) than that of oocytes from untreated animals (20 to 34% embryos). Small follicles ( < or = 2.7 mm) yielded mostly oocytes with an incomplete or partially expanded cumulus investment that never developed into an embryo. Differences in the morphology of the oocytes from medium (2.7 to 8 mm) and large ( > or = 8 mm) follicles were apparent, but equal developmental rates were obtained between all classes of oocytes (12 and 8% embryos, respectively). Follicular atresia was reduced significantly after superovulation (81% nonatretic follicles in treated vs 42% nonatretic follicles in untreated animals); however oocytes from atretic and slightly atretic follicles developed similarly to those from nonatretic follicles. These results suggest that although superovulation increases follicular size and decreases atresia, these conditions are not sufficient to confer developmental competence on the oocytes.

Synchronization of estrus and fertility in beef cattle with two injections of buserelin and prostaglandin.

Postpartum beef cows and heifers in Group 1 received 8 mug of buserelin on Day 0 (the beginning of the experiment) and 500 microg of cloprostenol (PGF) on Day 6 (GnRH I, n=54). In Group 2 (GnRH II, n=54), the females were injected with buserelin on Day 0 (8 microg) and Day 3 (4 microg), and PGF on Day 6 and Day 9 for females not detected in estrus previously. Animals were bred by AI 12 hours after the onset of estrus. Blood samples were collected on Day -11 and Day 0 to assess cyclicity and on Day 3 and Days 6 to 12 to examine luteal activity. Progesterone levels did not differ between the 2 groups between Days 0 to 9. In both groups, the proportion of spontaneous estruses from Days 0 to 6 was reduced. Precision of estrus was higher (P<0.005) in the GnRH II group than in the GnRH I group of cows that were detected in estrus between Days 6 and 9. The synchronization rate, interval to estrus, pregnancy and conception rates were similar in GnRH I and GnRH II groups. The conception rate and interval to estrus were similar in cyclic and acyclic cows. Increasing the number of buserelin injections enhanced the precision of estrus, but not the conception rate, without any detrimental effect on luteal activity and induced more estruses in postpartum acyclic beef cattle.

The time interval between FSH-P administration and slaughter can influence the developmental competence of beef heifer oocytes.

Superovulation alone may not be enough to result in developmentally competent oocytes. The objective of this study was to determine if a time interval between FSH administration and slaughter and between slaughter and oocyte recovery could increase the percentage of embryos. Beef heifers (n = 20) were superovulated with 1 bolus injection of 25 mg, im FSH-P diluted in saline and then slaughtered at 24, 48 or 72 h after FSH injection and the ovaries transported to the laboratory at 30 degrees C. For 6 of the heifers that received FSH-P and were then culled at 48 h post treatment, oocytes were recovered 1 to 2 h post slaughter from the first ovary and 4 to 5 h from the second ovary. Ovaries from untreated cows were collected and served as controls. The results indicated that FSH-P and culling at 48 h produced 35% >/= 32-cell embryos, significantly more than FSH-P and culling at 24 and 72 h (19 and 14%, respectively; P < 0.05). Furthermore, FSH-P and culling at 48 h produced 25% >/= 64-cell embryos, significantly more than FSH-P and culling at 24 and 72 h and the nontreatment control group (5, 7 and 15%, respectively; P < 0.05). The FSH-P group culled at 48 h produced more >/= 32-cell embryos, with an average of 84 +/- 5 cells/embryo, than the treated groups culled at 24 and 72 h and the untreated group (52 +/- 6, 60 +/- 5 and 63 +/- 3, respectively; P < 0.01). Finally, oocytes left in the postmortem ovaries for 4 to 5 h resulted in higher rates (51% and 41%) of >/= 32- and >/= 64-cell embryos, respectively, compared with that of the untreated control animals (29 and 18%; P < 0.05), but these rates were not different from oocytes left in ovaries for 1 to 2 h (33 and 24%). It is concluded that culling at 48 h after FSH treatment, as well as the conditioning effect on oocytes in warm postmortem ovaries for 4 to 5 h, increases the number of competent oocytes.

Ultrasonographic determination of ovarian follicular. Development in superovulated heifers pretreated with FSH-P at the beginning of the estrous cycle

On Day 3 of the estrous cycle (estrus = Day 0), dairy heifers were given either 10 mg i.m. FSH-P (FSH-P primed; n = 9) or a saline vehicle (saline primed; n = 9). On Day 10, all heifers were superovulated with FSH-P (total = 27.7 mg i.m.) in declining doses over 5 d. Heifers were inseminated artificially at estrus. From Day 2 until estrus, the number and size of follicles >2 mm were monitored daily by ultrasonography. The mean (+/- SEM) number of corpora lutea (CL) (6.2 +/- 1.5 vs 10.7 +/- 0.9; P<0.05) and the mean number of recovered embryos and unfertilized ova (3.6 +/- 1.7 vs 8.4 +/- 2.2; P<0.05) were lower in FSH-P-primed than in saline-primed heifers. Prior to initiation of superovulation, follicles >10 mm appeared on Days 6 to 7 in saline-primed heifers but only on Days 8 to 10 in FSH-P-primed heifers (P<0.05). Also, until Day 10, the mean number of follicles 4 to 6 mm and 7 to 10 mm was higher (P<0.05) in FSH-P-primed than in saline-primed heifers. After initiation of the superovulatory treatment (Day 10 to estrus), saline-primed heifers had a greater and faster increase in the mean number of follicles >10 mm (P<0.02) than FSH-P-primed heifers did. Depletion in the number of follicles 2 to 3 mm (P<0.001) between Day 10 and estrus and in the number of follicles 4 to 6 mm (P<0.05) between Day 12 and estrus occurred in both groups of heifers. Decreased superovulatory response and embryo recovery in FSH-P-primed heifers may have been due to the presence of large follicles (>10 mm) prior to the initiation of the superovulatory treatment which reduced the ability of small follicles to grow into larger size classes during superovulatory treatment.

Alteration of follicular dynamics and superovulatory responses by gonadotropin releasing hormone and follicular puncture in cattle: A field trial

A field experiment was conducted to determine the influence of follicular alteration on superovulatory responses. Ultrasonography was performed once daily over 4 d prior to gonadotropin treatment (Day 0), on the day of estrus during superstimulation, and on the day of embryo collection to monitor follicular development. Animals were superstimulated between Days 8 and 12 of the estrous cycle. Follicular status was altered 2 d prior to initiation of superstimulation (Day 0) with GnRH (Cystorelin, 200 micrograms i.m.) administered with (GnRH-puncture group, n = 31) or without (GnRH-no puncture group, n = 52) concomitant removal of the largest follicle by follicular aspiration. Responses were compared with those of an untreated control group superovulated 8 to 12 d after estrus (n = 102). The proportion of animals with a high number (> or = 2) of large follicles (> = 7 mm) on Day 0 was lower (P < 0.001) in the 2 GnRH-treated groups than in the control group, while the increase in the number of medium size follicles (4 to 6 mm) on Day 0 was greater (P < 0.02) in the GnRH-puncture group. During superstimulation, the proportion of superovulatory cycles with a high follicular (> or = 10 follicles) response was similar in the control and GnRH-no puncture groups. Within the GnRH-treated animals, follicular and ovulatory responses were greater in the GnRH-puncture than in the GnRH-no puncture group (P < 0.001 to P < 0.02). Despite these changes in follicular and ovulatory responses, however, the mean number of embryos produced did not differ (P < 0.1) among treatments (4.3 +/- 0.4, 3.7 +/- 0.7, and 5.4 +/- 0.8 in control, GnRH-no puncture, and GnRH-puncture groups, respectively). This was due primarily to an increase in the mean numbers of unfertilized ova (P < 0.005) and in degenerated embryos (P < 0.06) in the GnRH-puncture group. Results indicate that the beneficial effects of treatment with GnRH and follicular puncture 2 d prior to superstimulation on follicular and ovulatory responses were limited by an increase in the number of unfertilized ova and degenerated embryos.

Origin of the follicular fluid added to the media during bovine IVM influences embryonic development

Abstract The objectives of this study were to evaluate the developmental competence of bovine oocytes matured in the presence of selected follicular fluids (bFF) harvested a) from large follicles of FSH-treated cows on the fourth day of FSH treatment; b) from dominant follicles during the growing or c) the regressing phase; and d) from a pool of small follicles ( 16-cell (P 32-cell stage (P 16-, > 32-, > 64- or > 128-cell stage was similar for those matured in bFF and BES. The proportion of ova reaching the > 16-cell stage was higher (P 16- (P 32-cell stage (P

Effects of superovulation on endogenous LH secretion in cattle, and consequences for embryo production

Stimulation of follicular growth during superovulation is achieved by the injection of FSH or compounds with high FSH-bioactivities. However, some LH-activity is required for follicle maturation. It is of relevance to evaluate, therefore, the effect of superovulatory treatments on endogenous LH secretion. Luteinizing hormone is secreted in discrete pulses, and the pattern of pulsatile LH secretion during superovulation is reviewed. Four of five published studies have shown that LH pulse frequency is significantly reduced by injection of eCG or FSH preparations. This suppression appears within 8 h of treatment Effects of superovulation on LH pulse amplitude are less consistent. The reasons for the decrease in pulse frequency have been investigated, and although the answer is not definitive, it would seem that increased follicular estradiol, acting perhaps in synergism with progesterone, may play a role. Changes in plasma progesterone concentrations are not related to changes in LH pulse frequency. What is the significance of decreased LH pulse frequency? We attempted to investigate this by inducing LH pulses during superovulation, but the result was a major reduction in ovulation rate. More research is required to determine if modification of endogenous LH secretion can improve superovulatory responses.

CHANGES IN MORPHOLOGICAL APPEARANCE AND FUNCTIONAL CAPACITY OF RECRUITED FOLLICLES IN COWS TREATED WITH FSH IN THE PRESENCE OR ABSENCE OF A DOMINANT FOLLICLE

This study was designed to determine the effect of the presence of a dominant follicle at the beginning of FSH stimulation on the morphological appearance and functional capacity of recruited follicles during FSH stimulation in cattle. Synchronized nonlactating dairy cows were assigned to 1 of 2 groups and treated with FSH in the presence (n = 5) or absence (n = 6) of a dominant follicle between Days 7 and 12 of the estrous cycle (Day 0 = estrus) to stimulate follicular growth. Dominant follicles were identified by daily ultrasonographic observations, beginning on Day 3 of the estrous cycle. Dominant follicle had an ultrasonographic diameter > or = 10 mm and were in a growing phase, or maintaining a constant diameter (> or = 10 mm) for less than 4 d. Ovaries were collected at slaughter on the morning of the third day following initiation of the FSH stimulation. All follicles > 2 mm were dissected, classified according to diameter (Class 1: 2 to 4.4 mm; Class 2: 4.5 to 7.9 mm; Class 3: > 8 mm), and incubated individually for 90 min in medium M-199 (37 degrees C, 5% CO2). Following incubation, integrity of each follicle was evaluated histologically to assess the level of atresia and biochemically to determine the in vitro release of estradiol (E2) and androstenedione in culture media. On Day 3 of the FSH treatment, mean number of follicles in each class was similar (P > 0.1) between the 2 groups. The percentage of atretic follicles in Classes 1 and 3 on Day 3 of the FSH stimulation did not differ (P > 0.1) between the 2 groups. However, the percentage of atretic follicles in Class 2 was higher (P < 0.005) in cows treated with FSH in presence than in absence of a dominant follicle (60.8 vs 38.2%). The release of E2 in culture media by small Class 1 atretic or healthy follicles, by Class 2 atretic and by Class 3 healthy follicles was not affected (P > 0.1) by the ovarian status. However (P < 0.001), the release of E2 in culture media of Class 2 healthy and Class 3 atretic follicles was less for follicles harvested from cows bearing than from those not bearing a dominant follicle. Within each follicular class, concentrations of androstenedione in the culture media did not differ between the 2 groups (P > 0.1). These results suggest that the presence of a dominant follicle at the beginning of FSH stimulation alters the population of follicles recruited FSH stimulation. This may be associated with the reported decrease of the superovulatory response in cows superovulated in presence of a dominant follicle.

Ovarian superstimulation after follicular wave synchronization with GnRH at two different stages of the estrous cycle in cattle.

The objective of this study was to evaluate superovulatory programs based on synchronization of follicular waves with GnRH at 2 different stages of the estrous cycle. Sixteen Holstein cows were randomly assigned to 1 of 3 groups and administered GnRH (Cystorelin, 4 ml i.m.) between Days 4 and 7 (Groups 1 and 3) or between Days 15 and 18 (Group 2) of the estrous cycle (estrus = Day 0). Four days after GnRH treatment, > or = 7-mm follicles were punctured in Groups 1 (n = 6) and 2 (n = 6) or were left intact in Group 3 (n = 4). All cows were superstimulated 2 d later (i.e., from Days 6 to 10 after GnRH treatment) with a total of 400 mg NIH-FSH (Folltropin-V) given twice daily in decreasing doses. The GnRH treatment caused a rapid disappearance of large follicles (P < 0.005), rapid decrease in estradiol concentrations (P < 0.003), and increase in the number of recruitable follicles (4 to 6 mm; P < 0.04), indicative of the emergence of a new follicular wave within 3 to 4 d of treatment. Between 4 and 6 d after GnRH treatment, the mean number of 4- to 6-mm follicles decreased (4.7 +/- 1.8 to 1.5 +/- 3.3) in the nonpunctured group but increased (3.9 +/- 1.0 to 7.3 +/- 1.9) in the punctured group of cows (P < 0.05). In response to FSH treatment, the increase in the number of > or = 7-mm follicles was delayed by approximately 2 d in the nonpunctured group (P < 0.006). Moreover, the mean number of > or = 7-mm follicles at estrus was higher (16.9 +/- 1.7 vs 11.5 +/- 3.0; P < 0.1) in the punctured than the nonpunctured group. The increase in progesterone concentration after estrus was delayed in the nonpunctured group (P < 0.1) compared with the punctured follicles. Mean numbers of CL as well as freezable (Grade 1 and 2) and transferable (Grade 1, 2 and 3) embryos were similar (P > 0.1) in punctured and nonpunctured groups. Spontaneous estrus did not occur prior to cloprostenol-induced luteolysis in any group, and stage of the estrous cycle during which GnRH was given did not affect (P > 0.1) hormonal and follicular responses in the punctured groups. In conclusion, GnRH given at different stages of the estrous cycle promotes the emergence of a follicular wave at a predictable time. Puncture of the newly formed dominant follicle increases the number of recruitable follicles (4 to 6 mm) 2 d later and, in response to superstimulation with FSH, causes a greater number and faster entry of recruitable follicles into larger classes (> or = 7 mm) and a faster postovulatory increase in progesterone concentrations.