Effect of empty uterine space on birth intervals and fetal and placental development in pigs

A substantial loss of embryos occurs between Days 30 and 40 of pregnancy in the pig under crowded intrauterine conditions, but it is not clear whether this loss affects the growth of adjacent conceptuses. Birth intervals are known to increase with decreasing litter size, but the factors responsible are unknown. Two possibilities are that increased birth weight associated with reduced litter size and the empty uterine space and resulting constricted uterine regions that occur in pigs with small litters may impair piglet delivery. To address these, pregnant gilts were laparotomized on Day 35 of pregnancy and one or two fetuses were manually crushed through the uterine wall on the ovarian or cervical end of each uterine horn to create an empty uterine space behind or in front of the litter of piglets, respectively, in relation to the route of delivery from the uterus. A subset of gilts was slaughtered at 105 days of gestation to confirm that the empty uterine spaces were successfully created and to determine their effects on placental and fetal weights of adjacent conceptuses. At slaughter, the lengths of all externally visible empty constricted regions of the uterus were measured. The uterine horns were opened and the lengths of each placenta were measured from the umbilicus toward the ovary and toward the cervix to assess whether placentas developed symmetrically, and then each fetus and placenta was weighed. Fetal crushing successfully created constricted empty uterine regions on the ovarian and cervical ends of the uterine horns. Ovarian-side placental lengths were greater than cervical-side for conceptuses adjacent to fetuses crushed on the ovarian end of the horn. Cervical-side placental lengths were greater than ovarian-side for conceptuses adjacent to fetuses crushed on the cervical end. Both placental and fetal weights were greater (10% and 6%, respectively, P<0.05) for conceptuses adjacent to crushed fetuses compared to nonadjacent conceptuses. Remaining gilts were farrowed to determine the effect of litter size, average birth weights, and treatment on birth intervals of piglets, which were monitored using 24-h video surveillance. The negative association between number of piglets born alive and average birth interval was confirmed and was not explained by litter size-induced reduction in litter average birth weights. Birth intervals and stillbirth rate did not differ between cervically- and ovarian-treated gilts. These results indicate that conceptus loss on Day 35 of gestation can benefit the growth of adjacent placentas and fetuses, but the benefit is small. Increased average birth weight and the presence of empty uterine space that occurs when litter size is reduced does not fully explain the effect of litter size on birth intervals.     

Ovulation and early embryogenesis in swine

Thirty gilts were used to examine if the sequence in which oocytes were released at ovulation contributed to differences in embryonic development and uterine secretions by Day 12 (Day 0 = onset of estrus). Oocytes of follicles destined to ovulate last were recovered 42 h after injecting proestrous gilts with hCG, incubated with a fluorescent stain, and returned to the donor's oviduct. These later-maturing oocytes subsequently became the lesser-developed (p less than 0.01) embryos on Day 4. In a second experiment, lesser- vs. more-developed Day 4 embryos from additional gilts were transferred to ligated uterine horns of nonpregnant gilts. Subsequently, the lesser-developed Day 4 embryos became the smaller (p less than 0.01) blastocysts within a litter on Day 12. Uterine flushings associated with lesser-developed embryos on Day 12 contained less estradiol (p less than 0.01), less total protein (p less than 0.10), and less acid phosphatase activity (p less than 0.05), but total content of calcium was not different compared to flushings that contained more-developed embryos. Analysis of uterine flushings with two-dimensional PAGE procedures indicated advanced uteroferrin-associated glycoprotein secretion from the horn that contained more-developed embryos. Results of these experiments suggested that oocytes of later-ovulating follicles were progenitors of smaller embryos, which probably stimulated uterine secretion later than more advanced littermates on Day 12.     

Relationship of length of uterus in prepubertal pigs and number of corpora lutea and fetuses at 30 days of gestation

Relationships of the length of the uterus at one reproductive stage to the length at other stages and the effect on potential litter size were determined. In Experiment 1, the length of the uterus was measured in situ at 20, 60, or 100 days of age at laparotomy with 20 gilts in each of the three age groups. Forty days after the initial measurement, the uterus was again measured in situ, gilts were ovariectomized and hysterectomized, and associations among uterine measurements at the two different stages were determined. Correlations between uterine length in situ and between uterine length and weight 40 days later were all greater than 0.75 (P < 0.001). The length of one uterine horn increased from 13.9 cm at 20 days of age to 36.7 cm at 140 days of age (P < 0.01). In Experiment 2, 66 gilts were unilaterally hysterectomized and ovariectomized (UHOX) at 150 days of age and the ovary was weighed. Length of the one horn was measured in 36 gilts. At 10 days after first estrus, the length of the remaining uterine horn was measured at laparotomy and corpora lutea were counted in 53 gilts. In 15 of the 53 gilts the remaining uterine horn was removed to obtain uterine weights. At the second or third estrus, 38 gilts were mated and at Day 30 of gestation, 31 gilts were pregnant. The gilts were killed, and the length of the uterus measured and corpora lutea (CL) and fetuses were counted. The length of one uterine horn at 150 days of age was 70 cm with a range of 47–110 cm. At 10 days after first estrus, length had increased to a mean of 141 cm with a range of 86–194 cm and at 30 days of gestation the mean was 244 cm with a range of 186–311 cm. There were 12.2 CL at first estrus, which was not different from 12.4 CL at the second or third estrus. The mean number of fetuses in one horn at 30 days of gestation was 9.5 with 77% prenatal survival. Length of uterine horn at 150 days of age was correlated with uterine horn length (r = 0.56, P < 0.001) at 10 days after first estrus and number of live fetuses (r=0.39, P<0.05) at 30 days of gestation. At Day 10 after first estrus, uterine length was not correlated with the number of CL, whereas at Day 30 of gestation, the number of CL and uterine length were correlated with the number of live fetuses in those gilts with below the mean number of live fetuses, but not in those gilts with above the mean of live fetuses. The number of live fetuses (r=0.66, P < 0.001) and fetal survival (r=0.63; P < 0.001) were correlated with uterine horn length in pregnant UHOX gilts. Length of the prepubertal uterus gives an indication of postpubertal length and the potential litter size in pigs.     

Intrauterine migration of the porcine embryo: influence of estradiol-17 beta and histamine

The role of estradiol-17 beta (E2) in migration of the porcine embryo was examined (Experiment 1) by observing the distribution of Silastic (polydimethyl siloxane, Medical Adhesive Silicone Type A, Dow Corning) beads impregnated with cholesterol or E2 (n=5 gilts per treatment) after 5 days in utero (Day 12 of the estrous cycle, Day 0=1st day of estrus). Beads impregnated with E2 migrated farther (P less than 0.05) than those impregnated with cholesterol. Twenty additional gilts and sows were used to determine if histamine was involved with intrauterine migration (Experiment 2). On Day 6 of gestation the tip of each uterine horn was exposed and the subserosa of each of 5 gilts was injected with either vehicle, 8 mg of cromolyn sodium (an inhibitor of histamine release) or 8 mg of cromolyn sodium plus 1 mg of histamine. Four days later (Day 10), the excised uterus was examined for migration of embryos. An additional group of 5 gilts received 8 mg of cromolyn sodium on Days 6 and 10 and were examined on Day 12. Results from the second experiment demonstrated that cromolyn sodium treatment alone restricted (P less than 0.05) Day 10 embryos to the tip of the uterine horn but by Day 12 embryos had overcome this restriction. Injection of histamine overcame the inhibitory effects of cromolyn sodium and restored migration of Day 10 embryos. These experiments suggest that both E2 and histamine are involved in intrauterine migration of the porcine embryo. The extent to which these hormones might be interrelated during migration is not fully understood at this time.     

Factors affecting pregnancy rates and early embryonic death after equine embryo transfer

In the present study, 638 embryo transfers conducted over 3 yr were retrospectively examined to determine which factors (recipient, embryo and transfer) significantly influenced pregnancy and embryo loss rates and to determine how rates could be improved. On Day 7 or 8 after ovulation, embryos (fresh or cooled/transported) were transferred by surgical or nonsurgical techniques into recipients ovulating from 5 to 9 d before transfer. At 12 and 50 d of gestation (Day 0 = day of ovulation), pregnancy rates were 65.7% (419 of 638) and 55.5% (354 of 638). Pregnancy rates on Day 50 were significantly higher for recipients that had excellent to good uterine tone or were graded as "acceptable" during a pretransfer examination, usually performed 5 d after ovulation, versus recipients that had fair to poor uterine tone or were graded "marginally acceptable." Embryonic factors that significantly affected pregnancy rates were morphology grade, diameter and stage of development. The incidence of early embryonic death was 15.5% (65 of 419) from Days 12 to 50. Embryo loss rates were significantly higher in recipients used 7 or 9 d vs 5 or 6 d after ovulation. Embryos with minor morphological changes (Grade 2) resulted in more (P<0.05) embryo death than embryos with no morphological abnormalities (Grade 1). Between Days 12 and 50, the highest incidence of embryo death occurred during the interval from Days 17 to 25 of gestation. Embryonic vesicles that were imaged with ultrasound during the first pregnancy exam (5 d after transfer) resulted in significantly fewer embryonic deaths than vesicles not imaged until subsequent exams. In the present study, embryo morphology was predictive of the potential for an embryo to result in a viable pregnancy. Delayed development of the embryo upon collection from the donor or delayed development of the embryonic vesicle within the recipient's uterus was associated with a higher incidence of pregnancy failure. Recipient selection (age, day after ovulation, quality on Day 5) significantly affected pregnancy and embryo loss rates.     

Sex ratio bias in postpartum-conceived Norway rat litters is produced by embryonic loss in midpregnancy

In rats, dams that conceive in their postpartum oestrus and then lose their firstborn litter bias the sex ratio of the litter toward females in utero. The present study identifies the source of litter sex ratio bias in these postpartum pregnant non-lactating dams. The female bias arises first through the postconception loss of embryos, and second, the loss occurs in midpregnancy between the attachment of the blastocyst to the uterine wall on day 5 and full metrial gland development on day 14. Some pregnancies were restricted to one uterine horn to see if this loss (and thus the opportunity for litter sex ratio biasing) was influenced by local factors operating within the uterine horn. Embryonic loss was more closely associated with the number of embryos implanting in a single horn than with the number implanting in the litter, demonstrating that local crowding within a horn is sufficient for the preferential loss of male embryos. This loss did not cause an obvious decrease in the size of the live-born litter because only those horns with a surfeit of embryos lost them. This process was the same in the right and left horns; both carried and lost the same numbers of embryos. A dam that conceives in her postpartum oestrus and then loses her suckling litter forgoes the implantation delay and uterine healing caused by lactation. Male embryos are less successful at implanting in a uterus only recently vacated by a previous litter.     

Embryonic mortality and the uterine environment in first-service lactating dairy cows

Embryos were collected non-surgically from the tip of one uterine horn of 23 lactating dairy cows on Day 7 of pregnancy. Embryos were classified on the basis of morphological criteria as normal (n = 12) or abnormal (n = 13). Abnormal embryos were further classified as cleavage stage (n = 9) or morula/blastocyst (n = 4). Cows producing an abnormal embryo did not differ in days post partum at oestrus, age or parity from cows producing a normal embryo. Cows with an abnormal morula/blastocyst also did not differ with respect to days post partum at oestrus from cows with abnormal cleavage-stage embryos but cows with an abnormal morula/blastocyst were significantly older and of greater parity than cows with an abnormal cleavage-stage embryo. Hepes-saline-PVP solution (30 ml) was initially infused into the uterine tip, mixed and then withdrawn with a syringe. Analysis of this fluid revealed that the concentrations of glucose, total protein, calcium, magnesium and potassium were significantly higher in the flushings from the uterus of cows with abnormal embryos than from cows with normal embryos and zinc and phosphorus tended to be higher in the uterine flushings of cows with abnormal embryos. Phosphorus, total protein, calcium and magnesium tended to be higher in the flushings from cows with abnormal morulae/blastocysts than from cows with abnormal cleavage-stage embryos. Plasma progesterone did not differ between cows with normal or abnormal embryos or in cows with abnormal morulae/blastocysts or abnormal cleavage-stage embryos. Most embryonic mortality therefore occurred before Day 5 (during cleavage) in these cows.(ABSTRACT TRUNCATED AT 250 WORDS)     

Autotransfer of Day 4 embryos from oviduct to oviduct versus oviduct to uterus in the mare

Embryo autotransfer is defined as the collection of an embryo from and the transfer of this embryo into the same animal. The objectives of this study were to: 1) test the hypothesis that oviduct transport of the equine embryo from the oviduct into the uterus is not dependent on a unilateral embryo-corpus luteum interaction, 2) develop an embryo autotransfer technique for the mare and 3) compare the success rates of Day 4 embryos surgically autotransferred from the oviduct ipsilateral to ovulation to either the oviduct (n=10 mares) or the uterine horn (n=10 mares) contralateral to ovulation. Seventy percent (7 10 ) of the Day 4 embryos which were autotransferred to the oviduct contralateral to ovulation were transported through the oviduct and subsequently developed into embryonic vesicles detectable by ultrasonography between 10 and 21 days postovulation. This finding supported the hypothesis that oviductal embryo transport is not dependent upon the ipsilateral corpus luteum. Overall, sixty percent (12 20 ) of the autotransfers were successful. The success rate of uterine-transferred embryos was not significantly less (P>0.3) than that of oviductal-transferred embryos (5 10 vs 7 10 , respectively). Therefore, the Day 4 equine embryos were apparently mature enough to survive in the mare's uterus.     

Characterization of intrauterine mobility of the early equine conceptus

Intrauterine mobility patterns of the embryonic vesicle were characterized on Days 9 to 17 after ovulation in pony mares using real-time ultrasonography (n=5 or 7 mares per day). The location of the vesicle was determined by dividing the uterus into right horn, left horn, and body. Each uterine horn was further divided into three approximately equal portions (cranial third, middle third, caudal third), yielding seven segments (body plus three portions of each horn). Location of the vesicle within the uterus was recorded every five minutes for two consecutive hours (25 location determinations per trial). The number of times the vesicle was found in the uterine body versus one of the uterine horns was greater for the body on Day 9 (15.2 vs 9.8; not significant) and Day 10 (17.3 vs 7.7 P<0.05) and greater (P<0.05) for the horns on Days 12 (7.3 vs 17.7) through 17 (0.0 vs 25.0). Averaged over all days, when the vesicle was in one of the uterine horns it was present 56% of the time in the caudal third, 30% of the time in the middle third, and 14% of the time in the cranial third. Mobility was determined by the number of times the vesicle changed locations during successive examinations. On Day 9, the mean number of location changes per trial was minimal (horn to horn, 0.2; body to horn or vice versa, 1.8; between two segments, 4.2). The extent of mobility increased on Day 10 and reached an apparent plateau from Day 11 to Day 14. The mean number of location changes per trial during the plateau was as follows: horn to horn, 1.6; body to horn or vice versa, 5.6; between two segments, 10.7. Fixation (cessation of mobility) occurred in one of the horns in 5 7 mares on Day 15 and in 7 7 mares by Day 16. Mobility was present on the earliest day the embryonic vesicle was detected (Day 9), but Days 11 to 14 were characterized as the days of maximum mobility.     

Survival of equine embryos transferred to normal and subfertile mares

To test the hypothesis that an abnormal uterine environment was a cause of early embryonic loss in subfertile mares, morphologically normal embryos were transferred to normal mares (n = 20) and subfertile mares (n = 20), and embryo survival rates were compared. Embryos were recovered nonsurgically at Days 7 to 8 postovulation and transferred surgically to normal and subfertile mares that had ovulated on the same day or within 2 d after a donor. Survival of transferred embryos was monitored by ultrasonography of the recipient mare's uterus from Day 9 through Day 28 postovulation. There were no significant differences (P > 0.5) in the embryo survival rates at Day 12 (11 20 vs 9 20 ) or Day 28 (10 20 vs 8 20 ) for normal or subfertile mares, respectively. The uterine environment of subfertile mares was apparently adequate to support the development of transferred embryos from Days 7 or 8 through Day 28 postovulation.     

Morphometry of implantation in sheep. I. Trophoblast attachment, modification of the uterine lining, conceptus size and embryo location

The degree of trophoblastic attachment, modification of the uterine lining epithelium during implantation, possible differences in size of the conceptus, and preferential zones of nidation were evaluated. Eight ewes at 14 (n=3), 17 (n=2), 20 (n=1), and 24 (n=2) d of gestation were used, and 6 to 8 equidistant samples of either uterine o uterine plus embryonic membranes tissues were taken from each uterine horn for histomorphometric analysis. Trophoblastic attachment varied from 1.5 to 100% at 14 and 24 d of gestation, respectively. Modification of the uterine lining epithelium ranged from 0% at 14 d to 90% at 24 d. The conceptuses occupied a variable area of the uterine cavity; 15.1% at 14 d, 100% at 17 d, 70.6% at 20 d and 100% at 24 d of gestation. All the embryos were located caudal to the center of the uterine horn. Attachment of the trophoblast and modification of the uterine lining epithelium occurred in the area surrounding the embryos. Implantation was a gradual and long-lasting process which commenced near the embryo and extended peripherally. Morphological variations need to be considered when evaluating embryonic viability.     

A Globosus amorphus from an in vitro fertilized embryo transferred to a Japanese black cow

A Globosus amorphus along with a living calf was encountered following the transfer of blastocysts obtained by in vitro fertilization of in vitro-matured follicular oocytes in Japanese black cattle. Two embryos obtained 9 days after in vitro fertilization developed into either a hatched blastocyst with distinct inner cell mass or an expanded blastocyst with indistinct inner cell mass. The embryos were loaded into a 0.25-ml plastic straw and were nonsurgically transferred to the uterus of a heifer on Day 8 (Day 0 = estrus). On Day 75, a twin pregnancy was ultrasonically diagnosed in the right uterine horn, in which a live fetus with distinct limbs and a concomitant ovoid mass were detected. On Day 287, the dam developed parturient paralysis with dropsy of the fetal membranes. By palpation per rectum an ovoid mass was detected in the body of the uterus [corpus uteri] and a larger live fetus was in the uterine horn. A cesarean section was performed to extract a live fetus and a Globosus amorphus. The live fetus was female with the 60, XX female complements.     

Endoscopic embryo collection and embryo transfer into the oviduct and the uterus of pigs

We describe the first complete embryo transfer program, including flushing of embryos from the oviducts via the uterine horns, transfer of embryos into the Fallopian tubes or the uterine horns and recording of the number of piglets born live. The described procedure is minimally invasive and allows the use of pigs simultaneously for embryo collection and production of normal pregnancies. A 30 degrees forward oblique endoscope provided optimal visualization of the reproductive organs and free access to the organs for embryo flushing and transfer. In contrast to surgical and nonsurgical methods, endoscopy allows to pre-examine the genital tract for reproductive abnormalities and successful ovulation. A total of 95 prepuberal gilts or cyclic sows were used in this trial. Embryos or oocytes were collected from hormonally treated pigs via endoscopy(n = 17) on Day 3 and via laparotomy or post mortem after slaughter (control group, n = 38) on Day 3 and 6 after insemination. One (unilateral collection, n = 7) or both oviducts (bilateral collection, n = 10) were flushed endoscopically. We recovered 114 (average 16/pig) and 279 (average 28/pig) oocytes or embryos with fertilization rates of 89% and 72%, respectively. In the control group 834 oocytes or embryos were collected at Day 3 and 6 after insemination (fertilization rate 64%, total 534 embryos, 33 at 2-, 367 at 4-, 2 at 8-cell stage, 24 morulae and 108 blastocysts). Of 836 embryos recovered by endoscopy, surgery or slaughter 528 Day 3 embryos at 2- to 4-cell stage were transferred into (one) oviducts (n = 27 pigs, about 20/pig) resulting in 9 pregnant pigs diagnosed at Day 28 by sonography. Of the 9, 8 carried a total of 49 piglets to term. A total of 195 Day 6 embryos were transferred into uterine horns (n = 12 pigs, about 16/pig), resulting in 5 pregnant pigs carrying a total of 38 offspring to term. The use of endoscopy in assisted reproduction of pigs has the advantages of allowing easy access to the ovary, oviduct and uterus, clear view of the organ manipulation without exposure and exteriorization of viscera during surgery.     

Uterine transport of prostaglandin E(2)-releasing simulated embryonic vesicles in mares

Transrectal ultrasonography was used to test the hypothesis that prostaglandin E(2) (PGE(2)) would increase the uterine transport of simulated embryonic vesicles in mares. Uterine transport of PGE(2)-releasing (PGE) vesicles, vehicle-releasing (sham) vesicles, and equine embryos was contrasted on Day 12 or Day 13 post ovulation. In Experiment 1, there was no difference (P>0.10) in transport of PGE vesicles, sham vesicles, Day-12 embryos, and Day-12 embryos after cervical manipulation (n = 3 per group). In Experiments 2 and 3, respectively, transport of PGE and sham vesicles was contrasted with transport of Day-13 embryos after the vesicles (1 vesicle per mare) were placed into the uterine lumen with the embryo, (n = 7 per group). In Experiment 2, PGE vesicles were transported less often (P<0.05) from horn to body and from segment to segment than Day-13 embryos before vesicle insertion. In Experiment 3, sham vesicles were transported less often from horn to body (P<0.10) and from segment to segment (P<0.01) than Day-13 embryos before vesicle insertion. However, there was no difference (P>0.10) in the transport of PGE vesicles and embryos (Experiment 2) or sham vesicles and embryos (Experiment 3) together in the uterine lumen. In Experiment 4, transport of PGE and sham vesicles was contrasted by placing them together into the uterine lumen of nonpregnant mares on Day 13 (n = 7). There was no difference (P>0.10) in the transport of PGE and sham vesicles together in the uterine lumen. These results do not support the hypothesis that PGE(2) increases uterine transport of simulated embryonic vesicles. In addition, these results do not support the hypothesis that equine embryos stimulate uterine transport.     

Uterine asynchrony: a cause of embryonic loss

During early gestation, hormonal events associated with corpora lutea formation and embryonic synthesis of proteins, prostaglandins, and steroids result in synthesis and release of endometrial secretory products into the uterine lumen. The embryo, inherently and in response to secretory products of the uterus, develops and grows. However, considerable embryonic mortality occurs when uterine secretions become altered in such a manner that they are asynchronous to the developing embryo. Factors that advance or retard development of the uterus and embryo have been utilized to document utero-embryonic asynchrony, and it has been observed that the uterus will not "wait" for embryos to become synchronous. However, the reverse is possible: embryonic development can be accelerated or decelerated. Furthermore within the uterus, localized areas might also exist that favor development of some embryos at the expense of others. This review will consider causes of utero-embryonic asynchrony and offer models of embryonic loss associated with an asynchronous environment in cattle, sheep, and swine.     

Changes in the uterine metabolome of the cow during the first 7 days after estrus

The uterine microenvironment during the first 7 days after ovulation accommodates and facilitates sperm transit to the oviduct and constitutes the sole source of nutrients required for the development of preimplantation embryos. Knowledge of the composition of uterine fluid is largely incomplete. Using untargeted mass spectrometry, we characterized the uterine metabolome during the first 7 days of the estrous cycle. Bovine uteri were collected on Days 0 (N = 4), 3 ( N = 4), 5 ( N = 3), and 7 ( N = 4) relative to ovulation and flushed with Dulbecco’s phosphate‐buffered saline. A total of 1,993 molecular features were detected of which 184 peaks with putative identification represent 147 unique metabolites, including amino acids, benzoic acids, lipid molecules, carbohydrates, purines, pyrimidines, vitamins, and other intermediate and secondary metabolites. Results revealed changes in the uterine metabolome as the cow transitions from ovulation to Day 7 of the estrous cycle. The majority of metabolites that changed with day reached maximum intensity on either Day 5 or 7 relative to ovulation. Moreover, several metabolites found in the uterine fluid have signaling capabilities and some have been shown to affect preimplantation embryonic development. In conclusion, the metabolome of the bovine uterus changes during early stages of the estrous cycle and is likely to participate in the regulation of preimplantation embryonic development. Data reported here will serve as the basis for future studies aiming to evaluate maternal regulation of preimplantation embryonic development and optimal conditions for the culture of embryos.     

Identification of single-nucleotide polymorphism in the progesterone receptor gene and its association with reproductive traits in rabbits

A total of 598 F₂ does from a cross between the high and low lines selected divergently for uterine capacity during 10 generations were used in a candidate gene analysis. The presence of major genes affecting the number of implanted embryos and uterine capacity has been suggested in lines divergently selected for uterine capacity. Uterine capacity is a main component of litter size. The progesterone receptor gene was tested as a candidate gene to determine whether polymorphisms explain differences in litter size and its components. Fragments of the promoter region and exons 1–8 were amplified and sequenced. One SNP was found in the promoter region, 2464G>A, three SNPs in the 5′-UTR exon 1, and a silence SNP in exon 7. The first four SNPs were segregated in two haplotypes. The allele G found in the promoter region was found in 75% of the high-line parental animals and in 29% of the low-line parental animals. The GG genotype had 0.5 kits and 0.5 implanted embryos more than the AA genotype. At 48 hr of gestation, the difference in early embryo survival and embryonic stage of development was small. However, at 72 hr of gestation, the GG genotype had 0.36 embryos more than the AA genotype and also had a more advanced embryonic stage of development, showing a lower percentage of compacted morulae and a higher percentage of blastocysts. The difference in litter size between the GG and GA genotypes was similar to the difference found between homozygote genotypes; however, differences in implanted embryos, early embryo survival, and embryo development were not detected between the GG and GA genotypes.     

A timetable of embryonic development, and ovarian and uterine changes during pregnancy, in the stripe-faced dunnart, Sminthopsis macroura (Marsupialia: Dasyuridae)

Aged stages (63) were available for establishment of a timetable of embryonic development of the stripe-faced dunnart. On Day 0 oocytes reaching maturity were found in the ovary. Within +/- 24 h of time 0 (time of minimum morning weight) polymorphonuclear leucocytes appeared and spermatozoa were last detected in the urine of 70% of females. Embryos were collected at intervals during pregnancy by hemihysterectomy and the embryos in the contralateral uterus either were examined at a later stage of pregnancy or allowed to develop to term. Cleavage to the unilaminar blastocyst stage with around 32 cells took 3 days with a cleavage arrest of 24 h at the 4-cell stage. Expansion of the unilaminar blastocyst occurred over the next 3 days. Primitive endoderm cells appeared on Day 6, fully bilaminar blastocysts by the end of Day 7 and trilaminar blastocysts on Day 8. Shell loss and implantation of 13-15-somite stage embryos occurred on Day 8 and organogenesis over the next 2-3 days. The gestation period was 9.5-12.0 days with most births occurring between 10.5 and 11.0 days. Major steps in embryonic development were correlated with stages in the development of the corpora lutea, which were maximal in size, and possibly in secretory activity, when the embryos were at the bilaminar blastocyst stage. Regression commenced when the embryos were at the primitive streak stage. At the time the corpora lutea were maximal the uterine epithelium reached its greatest height and the endometrium was thick and folded. Later in pregnancy villous-like projections of the epithelium formed, and the luminal epithelial cells became rounded. Two cell populations, a tier of 8 smaller cells above the yolk mass and a tier of 8 larger cells around the sides of the yolk mass appeared at the 16-cell stage. From the 16-cell stage to the blastocyst stage, with 150-200 cells, two cell populations distinguished by size, cell cycle time, cytoplasmic appearance and position relative to the yolk mass were present. The two populations were indistinguishable in blastocysts with greater than 200 and less than 2000 cells. They reappeared in blastocysts with greater than 2000 cells, as the darker cells of the embryoblast, and as the paler cells of the trophoblast. The darker cells lay in the yolky hemisphere and the paler cells in the non-yolky hemisphere.     

Hastened transport of equine embryos through the oviduct of the mare

The purposes of this experiment were 1) to test the hypothesis that placing rabbit embryos into the mare's uterus would hasten oviduct transport and 2) to determine if placing fluid into the uterus of bred mares on Day 4 and/or Day 5 would subsequently disrupt the mare's pregnancy. The hypothesis that placing rabbit embryos into the mare's uterus would hasten oviduct transport was not supported, since the uterine recovery rate of equine embryos on Day 5 was not significantly higher (P>0.05) for mares receiving rabbit embryos on Day 4 than for mares receiving no uterine infusion on Day 4 (1 10 vs 0 10 , respectively). However, placing fluid into the mare's uterus on Day 4 was apparently responsible for hastened oviduct transport, since mares with media infused into the uterus on Day 4 had a significantly higher (P<0.05) recovery rate of equine embryos on Day 5 than did mares receiving either rabbit embryos or no uterine infusion on Day 4 post ovulation (5 10 vs 1 10 or 0 10 , respectively). The Day-14 pregnancy rate was significantly higher (P<0.05) for mares receiving no uterine infusion on Day 4 or Day 5 than for mares receiving uterine infusion on Day 5 or uterine infusion on both Days 4 and 5 (9 10 vs 4 10 , 2 10 and 0 10 , respectively).     

Reproduction,placentation, and embryonic development of the Atlantic sharpnose shark,Rhizoprionodon terraenovae

The Atlantic sharpnose shark Rhizoprionodon terraenovae (Richardson) is a small carcharhinid that is a common year-round resident along the southeast coast of the United States. It is viviparous and its embryos develop an epithelio-vitelline placenta. Females enter shallow water to give birth in late May and early June. Mating occurs shortly after parturition, and four to seven eggs are ovulated. Fertilized eggs attain the blastoderm stage in early June to early July. Separate compartments for each egg are formed in the uterus when the embryos reach 3–30 mm. Embryos depend on yolk for the first 8 weeks of development. When embryos reach 72 mm their yolk supply is nearly depleted and they shift to matrotrophic nutrition. When the embryos reach 40–55 mm, placental development begins with the vascularization of the yolk sac where it contacts the uterine wall. Implantation occurs at an age of 8–10 weeks by which time the embryos reach 70–85 mm. The expanding yolk sac engulfs the maternal placental villi, and its surface interdigitates with the villi to form the placenta. The rest of the lumenal surface of the uterus is covered by non-placental villi that appear shortly after implantation. Histotrophe production by the non-placental villi begins just after their formation. The placenta grows continuously during gestation. The egg envelope is present throughout gestation, separating maternal and fetal tissues. Embryos develop numerous appendiculae on the umbilical cord. Young sharks are born at 290–320 mm after a gestation period of 11 to 12 months. © 1993 Wiley-Liss, Inc.