Effect of gonadotropin-releasing hormone on estrus, ovulation, and ovum cleavage rates of dairy cows.

In a 2 x 2 factorial experiment, 110 Holstein cows (55 first-breeding and 55 repeat-breeding), free of genital abnormalities, were injected i.m. at the time of insemination with either saline solution or 100 micrograms of GnRH. Blood samples were drawn from the tail vein or artery of 22 cows (10 first- and 12 repeat-breeding) immediately before GnRH injection and again 1 and 2 h later to determine whether the GnRH induced the release of LH. The GnRH caused LH release in 18 of 22 cows, with a greater (P < .05) mean concentration of LH than that in saline-treated cows at 1 h (2.3 vs 7.0 ng/mL) and 2 h (2.5 vs 6.0 ng/mL) after injection. Length of estrus and time of ovulation were calculated from estrus checks and ovarian palpations per rectum at 8-h intervals. The GnRH injections produced no change in duration of estrus (19.2 h) or time of ovulation postestrus (9.5 h). The cows were slaughtered 41 to 90 (mean = 60) h after ovulation to determine the ovum cleavage rate and the number of accessory sperm in the zona pellucida. The GnRH treatment increased the incidence of twin ovulations but did not increase the number of accessory sperm or improve the proportion of ova that cleaved in either first-service or repeat-breeding cows.

Investigation of means to improve rates of fertilization in in vitro matured/in vitro fertilized bovine oocytes.

Experiments were conducted with 5,979 oocytes to determine whether detaching some of the cumulus cells from oocytes either before or after maturation would improve the fertilization rate and proportion of oocytes that developed to expanded blastocysts. Oocytes were aspirated from ovaries of slaughtered cows and matured, fertilized and cultured in vitro. Pipetting immature oocytes before maturation to detach some of the cumulus, with all cumulus cells left in the maturation wells, significantly increased fertilization rates, especially of oocytes that initially had a full cumulus investment. In further experiments, pipetting oocytes either before or after maturation to detach most of the cumulus, or treating with hyaluronidase after maturation to disperse the cumulus, significantly increased fertilization rates and proportions of oocytes developing to expanded blastocysts.

Making transgenic livestock: genetic engineering on a large scale.

The feasibility of introducing foreign genes into the genomes of cattle, goats, pigs, and sheep has only recently been demonstrated. Studies have thus far focused on improving growth efficiency or directing expression of pharmaceutical proteins to the mammary glands of these species. The general strategy for producing transgenic livestock and mice is similar. In addition to the obvious difference in scale between mice and livestock experiments, there are noteworthy obstacles that significantly reduce the efficiency of producing transgenic livestock. Low embryo viability, low transgene integration rates, and high animal costs contribute to project costs that can easily exceed hundreds of thousands of dollars. A better understanding of the mechanisms that govern transgene integration should lead to improved efficiencies. But, the full potential of the transgenic livestock system will not be fully realized until: 1) gene constructs can be designed that function in a reproducible, predictable manner; and 2) the genetic control of physiological processes are more clearly elucidated. Newly emerging approaches may resolve at least some of these issues within the next decade.

Sex preselection in rabbits: live births from X and Y sperm separated by DNA and cell sorting.

Intact, viable X and Y chromosome-bearing sperm populations of the rabbit were separated according to DNA content with a flow cytometer/cell sorter. Reanalysis for DNA of an aliquot from each sorted population showed purities of 86% for X-bearing sperm and 81% for Y-bearing sperm populations. Sorted sperm were surgically inseminated into the uterus of rabbits. From does inseminated with sorted X-bearing sperm, 94% of the offspring born were females. From does inseminated with sorted Y-bearing sperm from the same ejaculates, 81% of the offspring were males. The probability of the phenotypic sex ratios differing from 50:50 were p less than 0.0003 for X-sorted sperm and p less than 0.004 for Y-sorted sperm. Thus, the phenotypic sex ratio at birth was accurately predicted from the flow-cytometrically measured proportion of X- and Y-bearing sperm used for insemination.

Survival of DNA-injected cow embryos temporarily cultured in rabbit oviducts.

Holstein or Angus cows were superovulated, inseminated with fresh bull semen, and necropsied about 12 h after estimated time of ovulation. Ova were centrifuged at 15,600 G for 3 to 8 min to reveal pronuclei. In Experiment 1, pronuclear bovine embryos were transferred to ligated or unligated oviducts of 1-d pseudopregnant rabbits for 7 d; 30 of 32 embryos were recovered from ligated oviducts but only 2 of 26 from oviducts and uterine horns of unligated oviducts. In Experiment 2, a Rous sarcoma virus-chloramphenicol acetyl transferase fusion gene was injected into one pronucleus of about half of 404 fertilized bovine ova, using a micromanipulator and interference contrast optics. Injected and noninjected embryos were then transferred to opposite ligated rabbit oviducts. Embryos were recovered after 7, 8 or 9 d. Of 120 centrifuged but uninjected embryos recovered from rabbit oviducts, 66 (55%) were in the morula to hatching blastocyst stage of development. Of 105 embryos centrifuged and injected with foreign DNA, 55 (52%) were in the morula to hatching blastocyst stage. In Experiment 3, centrifuged bovine embryos, noninjected or DNA-injected, were cultured in rabbit oviducts for 7 d then transferred nonsurgically to the uterus of recipient cows. Embryos were also flushed from superovulated cows 8 d after estrus and transferred directly to recipient cows. After 7 d, the uterus of recipient cows was flushed nonsurgically to recover embryos. The proportion of transferred embryos recovered with normally elongated trophoblastic membranes and the proportion of recipient cows with developing embryos were 14 of 25 DNA-injected embryos, 5 of 8 cows; 6 of 15 centrifuged but noninjected embryos, 4 of 6 cows; and 11 of 29 embryos transferred directly, 5 of 8 cows. Results indicate that bovine embryos can be cultured in rabbit oviducts and survive after transfer to cow uteri and that injection of foreign DNA may not increase embryonic loss within the first 2 wk after injection.

Development of centrifuged cow zygotes cultured in rabbit oviducts.

Zygotes from superovulated cows were centrifuged and pronuclei were detected by differential interference-contrast microscopy in 73% of 106 zygotes. Zygotes were then transferred to ligated oviducts of follicular-phase, 1-day pseudopregnant or 7-day pseudopregnant rabbits and recovered 5 days later. Their development did not differ from that of uncentrifuged zygotes transferred to the opposite oviduct: 41% of the embryos recovered from rabbit oviducts contained 17-32 nuclei and an additional 5% contained greater than 32 nuclei. In another experiment, 399 ova from unmated cows were transferred to rabbit oviducts to determine whether centrifugation induced parthenogenetic development. After 7 days, 257 ova were recovered; 16% of the recovered ova had developed parthenogenetically and contained 2-30 nuclei. Neither centrifugation of the ova nor reproductive status of the rabbits influenced the proportion of parthenogenotes found. Parthenogenetic development was also observed in 14 of 71 ova (20%) recovered on Day 7 from uninseminated superovulated cows. In an attempt to increase the probability of detecting treatment differences, centrifuged and control cow zygotes were incubated for 7 (rather than 5) days in opposite oviducts of fourteen 1-day pseudopregnant rabbits. Development was unaffected by centrifugation: 61% of the zygotes recovered had developed beyond the 16-cell stage, with 23, 24 and 15% containing 17-32, 33-64, and greater than 64 nuclei, respectively. Taking into account the percentage of zygotes in which pronuclei can be seen, the recovery rate from rabbit oviducts, and the proportion of embryos that develop to the morula stage or beyond, 26% of the original group of zygotes would be candidates for transfer into recipient cows.

Fertilization rates in superovulating cows after deposition of semen on the infundibulum, near the uterotubal junction or after insemination with high numbers of sperm.

Three experiments were conducted with 105 superovulating Holstein dairy cows in attempts to improve the fertilization rate. Cows were superovulated with follicle-stimulating hormone (FSH) and time of estrus was regulated with prostaglandin F(2)alpha (PGF(2)alpha). Semen was deposited on each infundibulum through a laparoscope inserted through the flank (Experiment 1) or near the uterotubal junctions through flexible tubing passed through the cervix and uterine horns (Experiment 2). In the third experiment, high numbers of sperm in fresh semen were deposited in the uterus. Cows were necropsied and ova were recovered and examined about 3.5 d after the beginning of estrus. Deposition of 0.5 ml of frozen-thawed semen on each infundibulum (Experiment 1) reduced both ovum recovery and fertilization. In ten cows inseminated on the infundibulum, ova representing 43% of ovulation points were recovered and 9% of these recovered ova were fertilized. In ten control cows, ova representing 80% of ovulation points were recovered and 62% of them were fertilized. In a 2 x 2 experiment with 36 superovulating cows (Experiment 2), 1 ml of diluted fresh or frozen semen was deposited either near the uterotubal junction or in the uterine body. The overall fertilization rate was 61%, with no significant effect of site of semen deposition or type of semen used. In Experiment 3, 2 or 3 ml of neat semen (average of 4.4 billion sperm) was deposited in the uterus of 12 cows; 183 of 197 intact ova (93%) were fertilized. In 56 control cows inseminated with 0.5 to 1.5 ml of frozen diluted semen (average of 70 million sperm), 502 of 947 intact ova were fertilized (53%, P<0.001). Insemination with high numbers of fresh sperm overcame problems of sperm loss or sperm transport and improved the fertilization rate.

Inhibition of sperm transport and fertilization in superovulating ewes.

In Experiment 1, all ewes were treated with follicle stimulating hormone (FSH-P) to induce superovulation. Ewes came into natural estrus or were treated with prostaglandin F(2)alpha (PGF(2)alpha) or 6-methyl-17-acetoxyprogesterone (MAP) to regulate the time of estrus. The ewes were mated during estrus and necropsied 3 h after mating. Regulation of estrus with either compound reduced the number of sperm recovered from the cervix, uterus, and oviducts and increased the proportions of sperm recovered from the cervix and uterine body that were immotile, dead, or had disrupted membranes. In Experiment 2, all ewes were in natural estrus. They either ovulated naturally or were superovulated, and ewes in each group were necropsied at 3 or 23 h after mating. Superovulation reduced the number of sperm in oviducts, uterus, and anterior segments of the cervix at both time intervals and increased the proportions of sperm that were immotile, dead, or had disrupted membranes. In Experiment 3, of 3x2 design, ewes were in either natural estrus or estrus regulated with PGF(2)alpha or with MAP; they ovulated naturally or were superovulated. Ewes were necropsied 3 d after mating and ova were examined. Both regulation of estrus and superovulation reduced the proportion of ova that were fertilized and reduced the number of accessory sperm attached to fertilized ova.

Transport and fate of spermatozoa after insemination of cattle.

Sperm capable of fertilizing ova reach the isthmus of cows about 8 h after mating and remain in the caudal 2 cm of the isthmus until ovulation. Then small numbers of sperm move to the site of fertilization at the junction of the isthmus and ampulla. Within a few hours after deposition of semen in the uterine body, most sperm have drained to the exterior in cervical mucus. By 12 to 24 h after insemination, only a few percent of the sperm remain in the reproductive tract, and most of these are in the vagina. Contractions of the reproductive tract appear to be the primary mechanism of sperm transport. Flagellation of sperm is probably required for sperm to enter the folds of the cervix, and flagellation may be helpful or essential for sperm to pass through the uterotubal junction, move from the isthmus to the ampulla, and penetrate ova. High proportions of sperm undergo the acrosome reaction only in the ampulla on the side of ovulation and only after ovulation. The fertilization rate in cattle can be improved by use of semen from high fertility bulls and perhaps by timing insemination with semen from lower fertility bulls after the end of estrus.

Effect of unilateral cornual insemination upon fertilization rate in superovulating and single-ovulating cattle.

In Exp. 1, 21 first-service cattle and seven repeat-breeder cattle, averaging 4.7 infertile services, were brought into estrus and superovulated by treatment with follicle-stimulating hormone and prostaglandin F2 alpha. At insemination, semen was deposited in the greater curvature of one uterine horn, about midway between the utero-cervical junction and the utero-tubal junction. Cattle were necropsied 2 to 7 d after estrus and ova were recovered and examined. The fertilization rate for first-service cows was 74% of 362 intact ova and for repeat-breeders, 43% of 128 intact ova (P less than .001). Fertilization rate in first-service cows was 81% on the side of semen deposition and 68% on the opposite side (P less than .01); the rates in repeat-breeders were 54% and 32% (P less than .025). Differences between sides were due mostly to four cows that averaged 93% fertilization on the side of semen deposition and 19% on the opposite side. The proportion of fertilized ova with accessory sperm (17%) did not differ between sides of the reproductive tract. In Exp. 2, 60 first-service and 32 repeat-breeder cows in natural estrus had semen deposited in the uterine body or in the greater curvature of one uterine horn, either on the side of impending ovulation or on the opposite side. At necropsy, 55 ova were recovered from first-service cows, of which 42 (76%) were intact and 13 (24%) were ruptured or fragmented. Of the 42 intact ova, 41 (98%) were cleaved. From the 32 repeat-breeders, 30 ova were recovered, of which 26 (87%) were intact and 4 (13%) were ruptured; 23 of the 26 intact ova (88%) were cleaved. Site of semen deposition had no significant effect on either fertilization rate or number of accessory sperm in either type of cow. First-service cows averaged more accessory sperm (40) than did repeat-breeders (19, P less than .01). Overall results indicated that sperm deposited deep in one uterine horn fertilized ova nearly as frequently in the opposite oviduct as in the adjacent oviduct except in 14% of superovulating cattle.

Comparative fertility of normal and repeat-breeding cows as embryo recipients.

Morphologically normal embryos were transferred surgically into uteri of normal and repeat-breeder cows at seven days post-estrus to compare embryo survival rates in the two kinds of cows. All cows were less than ten years of age and had no abnormal genital discharges, cystic ovarian follicles, or anatomical abnormalities of the reproductive tract. Normal cows had not been inseminated after last calving. Repeat-breeders had at least four infertile services within the past six months (average of 6.2 services after calving). To test fertility of repeat-breeders at synchronized estrus, 22 anatomically-normal repeat-breeders were treated by intramuscular (i.m.) injection with prostaglandin F(2)alpha (PGF(2)alpha) on day 11 of an estrous cycle (estrus = day 0) and inseminated at induced estrus; 11 cows (50%) had a normal fetus at necropsy on day 60. Twenty-three repeat-breeders and 23 normal cows were assigned as embryo recipients and treated i.m. with PGF(2)alpha to synchronize estrus. All embryo donors were normal cows. Donors were treated with FSH and PGF(2)alpha and inseminated at estrus. On day 7 after estrus, embryos were recovered nonsurgically from donors and one embryo was transferred through a flank incision to the anterior end of the uterine horn adjacent to the corpus luteum of each recipient. Recipients that did not return to estrus were necropsied at day 60. Of 28 normal and 23 repeat-breeder recipients, 23 normal cows (82%) and 16 repeat breeders (70%) were pregnant at day 60 (P=0.235). Thus, at seven days post-estrus, the maternal environment of most of these repeat-breeders was satisfactory for maintaining pregnancy.

Effect of prostaglandin F2 alpha, phenylephrine and ergonovine on uterine contractions in the ewe.

Two experiments were conducted to determine the effect of prostaglandin F2 alpha (PGF2 alpha), phenylephrine and ergonovine on uterine contractions. In the first experiment, ewes were bilaterally ovariectomized, and a strain gauge force transducer was sutured to the serosa of one uterine horn. Each ewe was treated sc with 2 micrograms of estradiol-17 beta daily to prevent regression of the uterus. Beginning at least 5 d after ovariectomy, four dose levels of PGF2 alpha, phenylephrine and methoxamine were given by im injection and ergonovine was given by im or iv injection. Phenylephrine, methoxamine and ergonovine are alpha-adrenoceptor agonists. Uterine activity was recorded by physiograph for 30 min before and 90 min after treatment. Tracing were analyzed for 20-min periods before treatment and 4 to 24 min and 50 to 70 min after treatment. In Exp. 2, transducers were attached to uteri of intact ewes at d 10 to 12 of an estrous cycle. During subsequent estrus, one or two dose levels of PGF2 alpha, phenylephrine and ergonovine were given by im injection and uterine activity recorded. In Exp. 1, PGF2 alpha and phenylephrine increased (P less than .05 or .01) the number of amplitude of contractions at both 4 to 24 and 50 to 70 min. Ergonovine given im increased the number of contractions. In intact estrous ewes, PGF2 alpha increased the number and amplitude of contractions at 4 to 24 min, phenylephrine increased the number and amplitude at both 4 to 24 and 50 to 70 min, and ergonovine increased the number slightly but significantly at 4 to 24 min.(ABSTRACT TRUNCATED AT 250 WORDS)

Improvement by ergonovine of sperm transport, fertilization and pregnancy rates in ewes in natural or prostaglandin-induced estrus.

Eight experiments were conducted with 451 ewes to test effects of ergonovine, prostaglandin F2 alpha (PGF2 alpha) and phenylephrine on sperm transport and fertility. In most experiments, ewes were mated at estrus and necropsied 2 or 3 h later. Sperm were flushed from the oviducts, uterus and anterior, middle and posterior thirds of the cervix and counted. Various doses of PGF2 alpha or phenylephrine given im at mating caused no significant increase in sperm numbers in any segment of the tract 2 h later. Three different dose levels of ergonovine were given im to ewes in natural estrus 1 h after mating and ewes were necropsied 3 h after mating. Doses of .2 and 1.0 mg were ineffective, but .5 mg increased sperm numbers about 10-fold in the oviducts and uterus. When given im at the time of artificial insemination, .6 mg of ergonovine increased the fertilization rate at 3 d from 5/25 in control ewes to 12/25 (P less than .05). In three experiments with ewes in PGF2 alpha-induced estrus, .6 mg of ergonovine increased sperm numbers in the cervix and uterus at 3 h after mating and in the uterus and oviducts at 23 h, near ovulation. Other ewes were artificially inseminated in the external cervical os and one-half of the ewes were given .6 mg of ergonovine im; ewes not returning to estrus were laparotomized at 22 to 26 d and embryos removed. After insemination during natural estrus with .2 ml of semen, pregnancy rates were 14/25 for control ewes and 15/25 for ergonovine-treated ewes; after insemination during natural estrus with .1 ml of semen, 6/35 and 18/35 (P less than .005); after insemination during PGF2 alpha-induced estrus with .2 ml of semen, 7/60 and 12/60. Fertilization and pregnancy rates combined were 32/145 (22%) for all control ewes and 57/145 (39%) for ergonovine-treated ewes (P less than .005).

Estrus-related odors in body fluids of dairy cows.

Six experiments were to test for estrus-associated odors in 1) swabs of the vulva and vestibule, 2) fluids from deep in the vagina, 3) naturally voided urine, 4) urine obtained from the bladder by catheter, 5) milk, and 6) blood plasma. Tests were with dogs trained to identify vaginal fluids from estrous cows. In the tests, dogs were walked along lines of seven sample bottles consisting of samples from two estrous cows, two luteal-phase cows, one vaginal swab from estrous cows used as a standard, and two blank sample bottles. Correct responses to fluids from estrous cows averaged 97, 86, 96, 97, 99, and 94% for the six fluids listed. Incorrect responses to fluids from luteal-phase cows were 2, 1, 1, 1, 1, and 8%. Responses to blank samples were usually zero. Results indicate that odors associated with estrus are spread throughout the cow's body fluid.

Estrus-related odors in milk detected by trained dogs.

Dogs trained to identify vaginal mucus samples and other fluids from estrous cows were used for further studies of estrus-related odors in milk. In the first experiment, milk was collected from 10 cows during estrus and luteal phase of the estrous cycle and tested in trials of 9 samples each; 1 or 2 of the samples were from estrous cows. Dogs responded to milk from estrous cows in 76% of the exposures to such samples with significant differences among cows and significant improvement by the dogs during the experiment. Responses to milk from luteal-phase cows, averaged 6%. In a second experiment, milk was frozen and thawed four times without decreasing the frequency of response to samples from estrous cows. In the third and fourth experiments, milk was collected from four cows on several days of the estrous cycle. After the dogs were trained to respond to milk from pre-estrous cows (1 or 2 days before estrus), they responded to 64% of these samples; after the dogs were retrained to not respond to milk from pre-estrous cows, they responded 21% of the time to milk obtained 1 to 3 days before estrus. In these two experiments, responses to milk from estrous cows averaged 83% and to milk from luteal-phase cows, 8%. Trained dogs can distinguish milk of pre-estrous cows from milk of either estrous or luteal-phase cows.

Sperm survival and transport in the female reproductive tract.

Fertilization failure, mostly due to absence of sperm in the oviducts, is a major cause of reproductive inefficiency of farm animals. Sperm may be transported to the oviducts of cattle and sheep within a few minutes after mating or insemination, but these sperm probably fertilize few ova. Slower transport, with establishment of sperm populations in each segment of the reproductive tract, requires a few to several hours. In swine, sperm capable of fertilizing ova reach the oviducts in less than 1 h. Smooth muscle contractions of the reproductive tract, ciliary beats, fluid currents, and flagellar activity of sperm are primary mechanisms of sperm transport. Sperm become hyperactive in the oviducts in association with capacitation. Most sperm in an inseminate drain from the female reproductive tract within a few minutes or hours after insemination; remaining sperm are removed from the tract by slower drainage or phagocytosis. Sperm survival and transport in estrous ewes is reduced drastically by pastures with high estrogen content and by regulating estrus with progestogen or prostaglandin F2 alpha. The cervix is the initial site of inhibition of sperm transport in ewes, and endocrine imbalances probably are the basis of inhibition. Sperm transport problems generally are associated with immobilization and death of sperm in the uterus and anterior segments of the cervix within 2 h after mating. After gilts are inseminated with frozen-thawed semen, relatively few sperm are retained in the reproductive tract, apparently accounting for lowered fertilization rates. Sperm transport has been improved by adding to semen or administering to females such compounds as prostaglandin F2 alpha, oxytocin, estradiol, phenylephrine, or ergonovine. Estradiol, prostaglandin F2 alpha, phenylephrine, and ergonovine administered to rabbits at insemination each increased fertilization rates.

Increased numbers of sperm in the oviducts and improved fertilization rates in rabbits after administration of phenylephrine or ergonovine near the time of insemination.

Phenylephrine, an alpha-adrenoceptor agonist, was administered im to does near the time of mating or insemination. The treatment increased sperm numbers in the oviducts by about 50-fold and in the uterus by about 10-fold at 2 or 2.5 h after insemination. Methoxamine, another alpha-adrenoceptor agonist that was given im, did not increase sperm numbers, although both phenylephrine' and methoxamine significantly increased the number and amplitude of uterine contractions when contractions were measured by strain gauge force transducers attached to the uterus of conscious does. Ergonovine, an ergot derivative given im, increased sperm numbers more than 10-fold in the oviducts and five to 10-fold in the uterus at 2 or 2.5 h after insemination. Ergonovine increased the frequency and amplitude of uterine contractions when given iv but not when given im. In tests with a range of doses of phenylephrine and ergonovine, 5 mg of phenylephrine and .6 mg of ergonovine appeared to be near optimal for maximizing the number of sperm in the uterus and oviducts at 2.5 h after insemination. Phenoxybenzamine, an alpha-adrenoceptor blocking agent, prevented the phenylephrine-induced increases in both uterine contractions and sperm numbers in the oviducts and uterus. Phenoxybenzamine also prevented the effect of ergonovine on sperm numbers. In does inseminated with low numbers of sperm (92,000; an inseminate selected to result in a low fertilization rate in control does), the administration of phenylephrine or ergonovine significantly increased ovum fertilization rates (16% for control does, 52 and 63%, respectively, for phenylephrine- and ergonovine-treated does).

Effect of acetylcholine, prostaglandin F2 alpha and estradiol on number of sperm in the reproductive tract of inseminated rabbits.

Acetylcholine, injected im into does immediately after natural mating, significantly increased the number of sperm recovered 1 h later from the vagina and cervices but not from the oviducts. Acetylcholine caused immediate increases in the frequency and amplitude of uterine contractions as measured by strain-gauge force transducers attached to the serosa and recorded by physiograph; contraction patterns returned to the preinjection pattern within 30 min. Administration of prostaglandin F2 alpha (.75 mg) at the time of insemination increased sperm numbers significantly at 2.5 h in the oviducts, uterus and cervices; .15 or 3.75 mg caused relatively little increase in sperm numbers. Prostaglandin F2 alpha increased the number and strength of uterine contractions for more than 30 min. Estradiol injected 1 h before artificial insemination increased the number of sperm recovered from the oviducts, uterus, cervices and vagina at 2.5 h after insemination. Estradiol caused little if any detectable increase in the frequency or strength of uterine contractions during the period of increased retention and transport of sperm. When does were inseminated with low numbers of sperm (86,000), prostaglandin F2 alpha and phenylephrine, used for comparison, each increased the ovum fertilization rate (22% for control does; 76 and 73%, respectively, for prostaglandin F2 alpha- or phenylephrine-treated does).