The use of embryo transfer to produce pregnancies in repeat-breeding dairy cattle

Repeat breeding is an important factor affecting economic success in dairy management. The objective of this study was to investigate the effectiveness of transfer of frozen-thawed IVF embryos in establishing pregnancy in repeat-breeding Holstein cattle. Cumulus oocyte complexes were collected by aspiration of 2-5 mm follicles from ovaries obtained at two local abattoirs. After IVF, days 7 and 8 blastocysts were frozen either in 1.5M ethylene glycol with 0.1M sucrose, or in 1.4M glycerol with 0.1M sucrose. Holstein recipients (122 heifers and 410 cows) included those that had not conceived after 3-21 inseminations. Embryos frozen in ethylene glycol were transferred directly, and embryos frozen in glycerol were transferred after dilution of the cryoprotectant in sucrose into recipients 7 or 8 days after estrus (without-AI group), or following AI (with-AI group). Pregnancy rates were compared by the Chi-square test. Significantly higher pregnancy rates were achieved by embryo transfer following AI (with-AI group) than by embryo transfer alone (without-AI group) in both heifers (49.2 and 29.5%, respectively) and cows (41.5 and 20.4%, respectively; P<0.05). Pregnancy rates were not significantly different between heifers and cows. However, pregnancy rate decreased as the number of inseminations prior to embryo transfer increased in the with-AI group, but not in the without-AI group. Therefore, transfer of frozen-thawed IVF embryos during the same cycle in which AI was done improved pregnancy rates in repeat-breeding Holstein heifers and cows, and suggested that embryo transfer is an alternative in the treatment of repeat breeding.     

Non-surgical embryo transfer in cattle

Embryos collected surgically from donors superovulated with PMSG and synchronized with either prostaglandin F(2)alpha or progestagen impregnated sponges were transferred non-surgically to prostaglandin or progestagen synchronized recipients. One embryo was transferred to the uterine horn ipsilateral to the corpus luteum either through a flexible catheter introduced through a steel tube and passed to the uterine tip, or through a Cassou inseminating gun passed approximately 6 cm into the horn. Of 16 recipients receiving 5 or 6 day old embryos through the catheter (1976), 6 (38%) were palpated pregnant at 42 days and 4 (25%) subsequently calved. Of 16 recipients receiving 7 or 8 day old embryos through the straw and 16 through the catheter (1977), 10 (63%) and 3 (19%), respectively, were palpated pregnant (P<0.05) and 8 (50%) and 3 (19%), respectively, had normal embryos at slaughter 4 to 29 days after palpation (P reverse similar0.10 ). Forty 7 to 9 day old embryos were transferred through the straw in 1978. Eighteen (45%) of the recipients were palpated pregnant and 16 (40%) had normal embryos at slaughter 98 to 168 days after palpation. The success of the transfers in 1978 was affected by embryo quality [good vs poor embryos; 64% vs 22% recipients pregnant (P<0.01) and 59% vs 17% embryos surviving to slaughter (P<0.05)]. Also, in 1978, pregnancy rate was affected by the time taken to transfer the embryo with the highest rate achieved with the fastest transfers (P<0.10, b = -0.47). Injection of Indomethacin near the time of transfer, synchronization between donor and recipient onset of estrus and embryo age did not affect pregnancy rates. The pregnancy rate achieved after the transfer of good quality embryos by the straw technique was equal to that expected from surgical techniques.     

Plasma progesterone profiles and factors affecting embryo-fetal mortality following embryo transfer in dairy cattle

The relationship between plasma progesterone (P4) levels and embryo survival, and the value of P4 profiles for the selection of cattle embryo transfer recipients is still a matter of controversy. This study reports a comparison between lactating cows and heifers (n = 407) from a single dairy herd, after transfer of either fresh or frozen-thawed good quality embryos, of their ability to sustain embryo-fetal development to term. Plasma P4 concentrations on the day of estrus (Day 0 = D0), Day 4, Day 7 and on Day 21 were measured and related to embryo survival. Plasma P4 levels on Days 0, 4 and 7 were similar in recipients later found pregnant or open. Plasma P4 levels on Day 7 were significantly higher (P < 0.01) in heifers than in cows, but they were similar in pregnant and nonpregnant heifers and in pregnant and nonpregnant cows. Pregnancy rates for fresh and frozen-thawed embryos were higher in heifers than in cows, but the differences did not reach significance. However, the overall late embryonic mortality was significantly higher (P < 0.01) and the calving rate for frozen-thawed embryos was significantly lower (P < 0.05) in cows than in heifers. As expected, plasma P4 on Day 21 was significantly higher (P < 0.001) in pregnant than in nonpregnant recipients, but there was no difference between pregnant cows and pregnant heifers. Plasma P4 levels on Day 7 of recipients presumed pregnant on Day 21 and later found pregnant or nonpregnant were similar, but plasma P4 levels on Day 21 were significantly higher (P < 0.001) in pregnant than in nonpregnant recipients. The results of this study suggest that plasma P4 levels until the day of transfer, except for the rejection of recipients with abnormal luteal function, are of limited practical use for embryo transfer recipient selection. However, in lactating cows low plasma P4 values on Day 7 might negatively affect embryo survival, while in heifers this effect is not noticeable. Lactating cows are more prone to embryo loss than heifers, especially in the case of frozen-thawed embryos; this is associated with a lower competence of the corpus luteum at Day 7.     

The use of embryo transfer in the field for increased calf crops in beef and dairy cattle

Non-surgical transfer of one embryo to 63 previously synchronized inseminated recipients was performed on farms to induce twinning in beef and dairy cattle. All the transfers were done by technicians of A.I. centers. After calving, a twinning rate of 44.4% was achieved with no differences between beef Charolais heifers (45.4%), lactating Normande cows (42.8%) and dairy Friesian cows (45.4%). Compared with controls, the calving crop after a three-breeding-cycle period was significantly higher with recipients: 1.16 calf per treated recipient vs. 0.83 calf per control animal. It would seem that the possibility of obtaining about one-third more calves with embryo transfer could be of economical interest to increase meat production from cattle herds.     

Non-surgical embryo transfer in cattle embryo-recipient interactions

Results from 2286 non-surgical embryo transfers were analyzed to find relationships between embryo factors and recipient factors that affect pregnancy. Pregnancy rates from morulae (44%) and advanced morulae (53%) were reduced (P < .05) when compared to early blastocysts (65%), blastocysts (65%), blastocysts (66%) and advanced blastocysts (64%). Pregnancy rates from good quality Grade 1 embryos (64%) were higher (P < .05) than from Grade 2 (45%) or Grade 3 (33%) embryos. Pregnancy rates related to synchronization of estrus between donor and recipients are: -36 hrs. (before donor) (59%), -24 hrs. (61%), -12 hrs. (68%), 0 hr. (59%), +12 hrs. (61%), +24 hrs. (58%) and +36 hrs. (41%). Differences in pregnancy rate were significant for -12 hrs. (P < .01) and +36 hrs. (P < .01) recipients. Overall pregnancy rates in recipients on day 5 (48%), 5 1/2 (50%) and 6 (53%) were reduced (P < .02) when compared to day 6 1/2 (62%), 7 (63%), and 7 1/2 (66%) and 8 (62%). Pregnancy rates within each embryo stage of development were not related to synchronization with the donor cow (-36 hrs. to +36 hrs.) or the day of the recipient cycle (day 5 to 8).     

Influence of summer heat stress on pregnancy rates of lactating dairy cattle following embryo transfer or artificial insemination

Lactating Holstein cows were used to determine if pregnancy rate from embryo transfer (n = 113) differed from contemporary control cows (n = 524) that were artificially inseminated (AI). Holstein heifers (n = 55) were superovulated with FSH-P (32 mg total) and inseminated artificially during estrus and subsequently managed under shade structures. On Day 7 post estrus, embryos were recovered, and primarily excellent to good quality embryos (90.3%) were transferred to estrus-synchronized lactating cows. Cows were managed under conditions of exposure to summer heat stress. Pregnancy status was determined by milk progesterone concentrations at Day 21 and palpation per rectum at 45 to 60 d post estrus. Pregnancy rates of cows presented for AI (Day 21, 18.0%; Days 45 to 60, 13.5%) were typical for lactating cows inseminated during periods of summer heat stress in Florida. Pregnancy rates of embryo recipient cows were higher (P<0.001) than those of control cows (Day 21, 47.6%; Days 45 to 60, 29.2%). Summer heat stress had no adverse effect on heifer superovulatory response, but it increased (P<0.05) the incidence of retarded embryos (相似文献   

Superovulation and embryo transfer in Bos indicus cattle

Compared to Bos taurus breeds, Bos indicus breeds of cattle present several differences in reproductive physiology. Follicular diameter at deviation and at the time of ovulatory capability are smaller in B. indicus breeds. Furthermore, B. indicus breeds have a greater sensitivity to gonadotropins, a shorter duration of estrus, and more often express estrus during the night. These differences must be considered when setting up embryo transfer programs for B. indicus cattle. In recent studies, we evaluated follicular dynamics and superovulatory responses in B. indicus donors with the objective of implementing fixed-time AI protocols in superstimulated donors. Protocols using estradiol and progesterone/progestrogen releasing devices to control follicular wave emergence were as efficacious as in B. taurus cattle, allowing the initiation of superstimulatory treatments (with lower dosages of FSH than in B. taurus donors) at a self-appointed time. Furthermore, results presented herein indicate that delaying the removal of progesterone/progestogen-releasing devices, combined with the administration of GnRH or pLH 12 h after the last FSH injection, results in synchronous ovulations, permitting the application of fixed-time AI of donors without the necessity of estrus detection and without compromising the results.     

Effect of time of artificial insemination on embryo sex ratio in dairy cattle

The objective of the present study was to examine whether different intervals between insemination and ovulation have an influence on the sex of seven-day-old embryos in dairy cattle. Cows were inseminated once with semen of one of two bulls of proven fertility between 36 h before ovulation and 12 h after ovulation. Time of ovulation was assessed by ultrasound at 4-h intervals. In total, 64 embryos were determined to be male or female. Of these 64 embryos, 51.6% were female. The sex ratio in the various insemination-ovulation intervals (early: between 36 and 20 h before ovulation; intermediate: between 20 and 8 h before ovulation; late: between 8 h before and 12 h after ovulation) did not significantly differ from the expected 1:1 sex ratio (50, 50 and 55% females, respectively). Bull (Bull A and B) and Parity (primiparous and multiparous) had no influence on the expected 1:1 sex ratio either. The number of cell cycles was similar for male and female (P = 0.23) embryos when quality of the embryo (P < 0.0001) was included in the model. The results of this study indicate that, in cattle, the interval between insemination and ovulation does not influence the sex ratio of seven-day-old embryos.     

Effects of insemination-ovulation interval on fertilization rates and embryo characteristics in dairy cattle

The objective of this study was to examine effects of the interval between insemination and ovulation on fertilization and embryo characteristics (quality scored as good, fair, poor and degenerate; morphology; number of cell cycles and accessory sperm number) in dairy cattle. Time of ovulation was assessed by ultrasonography (every 4h). Cows were artificially inseminated once between 36h before ovulation and 12h after ovulation. In total 122 oocytes/embryos were recovered 7d after ovulation. Insemination-ovulation interval (12h-intervals) affected fertilization and the percentages of good embryos. Fertilization rates were higher when AI was performed between 36-24 and 24-12h before ovulation (85% and 82%) compared to AI after ovulation (56%). AI between 24 and 12h before ovulation resulted in higher percentages of good embryos (68%) compared to AI after ovulation (6%). Insemination-ovulation interval had no effect on number of accessory sperm cells and number of cell cycles when corrected for embryo quality. This study showed that the insemination-ovulation interval with a high probability of fertilization is quite long (from 36 to 12h before ovulation). However, the insemination-ovulation interval in which this fertilized oocyte has a high probability of developing into a good embryo is shorter (24-12h before ovulation).     

Statistical models predicting embryo survival to term in cattle after embryo transfer

Embryo survival to term in recipient cattle is highly variable. We examined calving data in the published literature to determine whether a model of binomial independence or a model which includes an embryo (e) and recipient term (r), adequately explain observed embryo survival rates following attempts to induce twin calving using transfer of two embryos. To achieve this we examined 32 published papers which provided us with 47 sets of data concerning 4560 recipients with either 0, 1 or 2 calves born. In each set of data, the observed embryo survival rate to term (p) (number of calves born/number of embryos) was calculated and the expected number of recipients with either 0, 1 or 2 calves born was determined, assuming a binomial distribution. Parameters for the second model were estimated using maximum-likelihood procedures. The model of embryo independence was rejected in 85% of the sets of data, suggesting that factors other than the embryo are important sources of variation in embryo survival or loss. The proposed e and r model of embryo survival adequately describes the published data in recipients receiving either single or twin embryos. In general, only 50-70% of embryos and recipients are sufficiently competent to result in a calving. Variation among laboratories producing either in vitro or in vivo derived embryos was due to variation in recipient and not embryo competence. It is argued that e rather than observed embryo survival rate, and r rather than observed pregnancy rate, should be used to compare differences among embryo treatments and groups of recipients, respectively. Acceptance of this proposition should permit faster progress in identifying the biology of superior embryos and recipients, which is a prerequisite to improving embryo survival rate in cattle. Collectively, the published data are not consistent with a model of embryo independence, and that a model of embryo survival to term which recognises recipient as well as embryo contributions to embryo survival may be more appropriate in cattle.     

Freemartins in beef cattle twins induced by embryo transfer

The incidence of freemartinism in heterosexual twins (male-female) resulting from embryo transfer was studied by determining sex chromosome chimerism in lymphocytes and masculinization of female reproductive tracts at slaughter. In one group of calves, ten of 11 heifers born co-twin to full sib, paternal half sib, or unrelated bull calves exhibited sex chromosome chimerism, a proportion in close agreement with that observed in naturally occurring twins. The ten calves with sex chromosome chimerism also had masculinized tracts whereas the other had an apparently normal female tract. Bull calves had a percentage of XY cells similar to their female co-twins, except for the twin set from which the “normal” female was obtained. The bull calf from this set had 5.6% XX cells although no XY cells were observed in the heifer in 66 metaphase spreads. No association was observed between the degree of sex chromosome chimerism and abnormalities of the female tract. Reproductive tracts from all female-female twin sets were normal. In another group of calves, all 20 heifers from heterosexual twin sets had masculinized reproductive tracts. It is concluded that the induction of twins by embryo transfer results in normal expression of freemartinism even though calves may be unrelated and are known to develop in separate uterine horns.     

Superovulation and embryo transfer in Holstein cattle using sexed sperm

The use of sexed bull sperm in multiple ovulation and embryo transfer (MOET) programs for Holsteins was evaluated for (1) heifers housed at a commercial embryo transfer (ET) facility (Experiments 1 and 2), and (2) heifers and cows on dairy farms (Experiment 3). In Experiment 1, superstimulated heifers were inseminated with 5 × 10⁶ sexed (X-sorted; n = 5) or unsexed (n = 5) frozen-thawed sperm from one bull at 12 and 24 h after estrus detection. No difference was observed in the rates of transferable embryos (53.4% vs 68.1%), degenerate embryos (24.8% vs 26.6%) and unfertilized ova (21.8% vs 5.3%) between sexed and unsexed sperm, respectively, except for the percent of female transferable embryos diagnosed by embryo sexing (100% vs 49.3%, P < 0.0001). In Experiment 2, donors were inseminated twice with 5 × 10⁶ sexed unfrozen sperm (n = 10) or sexed frozen-thawed sperm (n = 9). Embryo production rates for both treatments were similar to that observed on a commercial ET facility using unsexed sperm. Pregnancy rates for frozen-thawed embryos were similar for sexed and unsexed sperm (70.4% vs 72.4%, respectively). In Experiment 3, 99 flushes were conducted using sexed frozen-thawed sperm from nine bulls but an overall statistical analysis was not completed because the use of bulls was not balanced. However, for one bull with balanced usage, the rate of transferable embryos was higher in heifers than in cows (P < 0.05) inseminated twice with 5 × 10⁶ sperm/dose (10 × 10⁶ total). We concluded that the use of sexed frozen-thawed sperm (≥90% X-sperm biased and 10 × 10⁶ total sperm) may be economically viable for commercial MOET programs in Holstein heifers.