W. Hazeleger

Weight distribution within litters at the early foetal stage and at birth in relation to embryonic mortality in the pig

Abstract This study investigated whether the within-litter weight distribution at birth is already established by the end of the embryonic stage of pregnancy (Day 35) and whether it is related to embryonic mortality rate. All data were obtained from Dutch Landrace gilts which had been inseminated with semen of Dutch Landrace boars. A total of 373 foetal litters (Day 27–Day 110) and 826 litters at term were classified into one of five litter types on the basis of the within-litter weight distribution. Independent of stage of pregnancy, within-litter weights were normally distributed in approximately 67% of all litters. The within-litter weight distribution at birth was already established by the end of the embryonic stage. Embryonic mortality rate was lower in litters with two discrete subpopulations than in litters with a normal distribution, except for litters with giants (growth-enhanced foetuses). The latter had the highest average embryonic mortality rate. The type of within-litter weight distribution might be a consequence of the very early existence of variation in embryonic development and the functioning of an intrauterine mechanism of selective mortality to reduce developmental variation before implantation.

RECENT DEVELOPMENTS IN PIG EMBRYO TRANSFER

Porcine embryo transfer has been performed for approximately 50 years, and surgical methods have proven to be reliable for collection and transfer of embryos. However, surgical collection and transfer have the disadvantage of being less useful on the farm. Recently, new procedures for both collection and transfer of embryos have been developed to improve usefulness. The surgical procedure has been refined to a minimally invasive procedure, using endoscopy for collection and transfer of embryos. A nonsurgical procedure for embryo collection has also been devised, but is limited to use in sows with surgically shunted (shortened) uterine horns. Nonsurgical embryo transfer procedures have been developed recently and have proven to be successful. The nonsurgical procedures are preferable to surgical procedures from an animal welfare point of view and because these procedures can be performed on farms without the need for special facilities.

Periovulatory hormone profiles and components of litter size in gilts with different estrogen receptor (ESR) genotypes.

Estrus, endocrine changes during the periovulatory period, and components of litter size at Day 35/36 of pregnancy were studied in gilts with estrogen receptor genotype AA (AA gilts) or BB (BB gilts), in which the B allele is associated with a larger litter size. Neither estrus length nor estrous cycle length was affected by estrogen receptor genotype. No differences in periovulatory plasma LH, estrogen or progesterone profiles between the AA and BB gilts were detected. Furthermore, temporal aspects of these profiles were not different for both genotypes. Although the B allele is associated with a larger litter size, no differences in number of corpora lutea or number and percentage of vital Day 35/36 embryos were found in this study. This indicates that the difference in litter size is not due to differences in oocyte maturation, fertilization, implantation or embryonic survival, but is likely caused by a difference in fetal survival. Thus, uterine capacity might be different for both genotypes. The available uterine space per embryo seems to be the same for both genotypes, as is endometrial folding of uterine surface area. However, a difference in placental size was found. Embryos of BB gilts had significantly longer placentae than embryos of AA gilts. These results suggest a higher chance for placental insufficiency in AA gilts, leading to the expected higher fetal mortality compared with the BB gilts. The difference in placental size might have been related to a difference in the timing of embryonic mortality.

Development, DNA fragmentation and cell death in porcine embryos after 24 h storage under different conditions.

For practical applications of porcine embryo transfer (ET) it is important to develop feasible embryo storage conditions. The aim of the present study was to evaluate the effect of short-term storage (24 h) on the quality of in vivo produced porcine embryos. Three temperatures 18, 25 and 38 degrees C and three different media: Dulbeccos phosphate buffered saline (DPBS), TCM199 and Emcare, were tested for two different embryo ages: D4 embryos (collected 144 h after hCG treatment) and D5 embryos (collected 168 h after hCG). After slaughter of the donor gilts, embryos were collected and transported at 25 degrees C to the lab where morulas and blastocyst were selected (D4 n = 222; D5 n = 167) and randomly used as controls or distributed over the treatment groups. Developmental stage and embryo diameter were assessed by normal light microscopy, while total number of cells and incidence of apoptosis were assessed using a fluorescent embryo quality staining technique that combines three different dyes: Ethidium Homodimer (EthD-1), TUNEL and Hoechst 33342. Following 24 h storage, D5 embryos had higher rates of hatching (24%) and degeneration (9%) compared to D4 embryos (10 and 4%, respectively; P < 0.05). Embryos stored at 38 degrees C had higher rates of hatching (37%) compared to those ones stored at 25 degrees C (13%) or 18 degrees C (0%; P < 0.01). More embryos hatched when stored in medium Dulbeccos phosphate buffered saline (DPBS) or in TCM199 compared to those stored in Emcare (P < 0.05). A higher percentage of embryos stored at 18 degrees C degenerated compared to those stored at 25 or 38 degrees C (P < 0.01). No significant increase in apoptosis was observed after storage compared to the rates of apoptosis at 0 h (controls) or between the different storage groups. Based on the results we conclude that D4 porcine embryos produced in vivo, selected under normal light microscopy and stored at 25 degrees C in a serum free medium for 24 h will have a suitable developmental stage for ET and a high embryo quality.

State of the art in pig embryo transfer

Embryo transfer in pigs has required surgical procedures in both donors and recipients. Over the last decade, procedures have been developed for transferring embryos by endoscopic or nonsurgical (transcervical) procedures. The feasibility of these procedures for practical application and the latest results of these new approaches are compared here. Factors affecting the current results and obstacles to be overcome in the near future are also discussed. Finally, some relevant embryo collection procedures and applications are briefly summarized.

Effect of excessive, hormonally induced intrauterine crowding in the gilt on fetal development on day 40 of pregnancy

Selection for litter size may result in an increase in uterine crowding due to a faster increase in ovulation rate than in litter size. Increased ovulation rate does not result in a proportionally increased number of piglets born alive. In this study, the effect of ovulation rate on vitality characteristics of fetal-placental units at d 40 of pregnancy was investigated. For this, 43 Large White gilts were treated with hormones to induce superovulation. Average ovulation rate was 45.16 +/- 13.22; average number of vital fetuses at d 40 of pregnancy was 17.09 +/- 3.61 that weighed 11.26 +/- 1.99 g; their placenta weighed 31.88 +/- 14.79 g; and they occupied 11.69 +/- 4.90 cm of the uterus. Loss in oocytes (i.e., that did not result in a vital fetus at d 40) increased with increasing ovulation rate and occurred before (early mortality; P = 0.0003) and after implantation (late mortality, i.e., traces visible at d 40; P < 0.0001). With respect to the vital fetuses, increased ovulation rate resulted in decreased fetal (P = 0.0008) and placental weight (P = 0.0008) and decreased length of the area in the uterus that was occupied by the placenta (P = 0.0011). Strong correlations existed between placental and fetal weight [0.68; 95% confidence interval (CI) = 0.64 to 0.72], and placental weight and length (0.78; 95% CI = 0.74 to 0.82). Fetal-placental characteristics were weakly correlated to distance to the implantation sites of neighboring fetuses, a measure of crowdedness [-0.002 (95% CI = -0.042 to 0.038) with fetal weight to 0.16 (95% CI = 0.12 to 0.20) with placental length]. Increased ovulation rates, but more specifically increased late mortality rates, have negative effects on the remaining vital fetuses with respect to the fetal (P = 0.0085) and placental weight (P < 0.0001) and length of the implantation site (P = 0.0016). The most extreme effect was on placental weight, in which a uterus with <10 cases of late mortality was on average 25% greater than placental weight in a uterus with >18 cases of late mortality (P < 0.0001). Furthermore, increased ovulation rates resulted in decreased within litter variation for fetal (P = 0.0018) and placental weight (P = 0.0084). At increased ovulation rates, the number of live fetuses remained similar, but placental development is impaired and the growth of the fetus is retarded compared with reduced ovulation rate, with effects likely lasting into adult life.

A method for transcervical embryo collection in the pig.

Five cyclic primiparous sows were used to test a surgical procedure for in vivo transcervical collection of pig embryos. The procedure consisted of shortening the uterine horns. After surgery, all sows returned to estrus and embryos were recovered following artificial insemination. Transcervical uterine flushing was carried out in four sows. On average 3.6 +/- 1.5 (mean +/- SD) embryos were recovered from the five sows. The results indicate that it is possible to recover embryos transcervically from sows with a resectioned uterus.

Embryonic survival in the pig after insemination with antigen-enriched semen.

Ninety-two first-litter Dutch Landrace sows were inseminated at their first oestrus after weaning with diluted semen containing 2.3 x 10(9) motile sperm cells. Immediately before insemination of 46 randomly chosen sows, 2 x 10(8) fresh bovine leucocytes were added to the semen. All sows were slaughtered on Day 8, 9, or 10 after insemination. In the control group and leucocyte-treated group respectively, 41 and 39 sows were pregnant at slaughter. The average number of corpora lutea (+/- SEM) in pregnant animals was 15.72 +/- 0.60 and 15.22 +/- 0.61, respectively. The average number of embryos was 10.66 +/- 0.79 and 10.36 +/- 0.80, respectively. The addition of bovine leucocytes to semen had neither influence on the pregnancy rate, nor on the number of embryos during early pregnancy.