Novel insight into the control of litter size in pigs, using placental efficiency as a selection tool.

Chinese Meishan pigs produce three to five more pigs per litter than less-prolific U.S. or European pig breeds as a result of a markedly decreased placental size and an increased pig weight: placental weight ratio (placental efficiency). We hypothesized that as a result of their intense selection for prolificacy, the Chinese had indirectly selected for a smaller, more efficient placenta in the Meishan breed. The goals of this study were to determine whether 1) significant variation in placental size and efficiency existed within our population of purebred Yorkshire pigs and 2) selection of pigs (boars and gilts) based on clear differences in placental size and efficiency would affect litter size. There was significant (approximately threefold) variation in placental efficiency in our herd of Yorkshire pigs, and marked (approximately twofold) variation existed within individual litters. We then selected pigs (boars and gilts) that had either a higher (A Group) or lower (B Group) than average placental efficiency. Although the birth weights of selected A Group pigs were similar to those of the B Group pigs, they had markedly smaller placentae. Males from each group (A or B) were bred to the females of the same group, and farrowing data were collected from parities 1 and 2. In both parities, A Group females farrowed more live pigs per litter than did B Group females (12.5 +/- .7 vs 9.6 +/- .5, P < .05). Although A Group pigs were on average approximately 20% lighter than B group pigs (1.2 +/- .1 vs 1.5 +/- .1 kg, P < .05), their placentae were approximately 40% lighter (250 +/- 10 vs 347 +/- 15 g, P < .01), resulting in a marked increase in placental efficiency. The results of this study suggest that selection on placental size and efficiency may provide a valuable tool for optimizing litter size in commercially important pig breeds.

[1]  M. E. Wilson,et al.  The impact of either a Meishan or Yorkshire uterus on Meishan or Yorkshire fetal and placental development to days 70, 90, and 110 of gestation. , 1998, Journal of animal science.

[2]  M. Wilson,et al.  Development of Meishan and Yorkshire littermate conceptuses in either a Meishan or Yorkshire uterine environment to day 90 of gestation and to term. , 1998, Biology of reproduction.

[3]  M. Wilson,et al.  Differences in trophectoderm mitotic rate and P450 17alpha-hydroxylase expression between late preimplantation Meishan and Yorkshire conceptuses. , 1997, Biology of reproduction.

[4]  S. Ford,et al.  A comparison of the number of inner cell mass and trophectoderm cells of preimplantation Meishan and Yorkshire pig embryos at similar developmental stages. , 1996, Journal of Reproduction and Fertility.

[5]  R. Christenson Ovulation rate and embryonic survival in Chinese Meishan and white crossbred pigs. , 1993, Journal of animal science.

[6]  R. Johnson,et al.  Direct responses to selection for increased litter size, decreased age at puberty, or random selection following selection for ovulation rate in swine. , 1991, Journal of animal science.

[7]  W. F. Pope,et al.  Causes and consequences of early embryonic diversity in pigs. , 2020, Journal of reproduction and fertility. Supplement.

[8]  R. Blair,et al.  Embryonic steroids and the establishment of pregnancy in pigs. , 2020, Journal of reproduction and fertility. Supplement.

[9]  M. Rothschild,et al.  Changes in morphology, cell number, cell size and cellular estrogen content of individual littermate pig conceptuses on days 9 to 13 of gestation. , 1990, Journal of animal science.

[10]  C. Haley,et al.  Embryo survival and conceptus growth after reciprocal embryo transfer between Chinese Meishan and Landrace x Large White gilts. , 1990, Journal of reproduction and fertility.

[11]  R. Johnson,et al.  INDEX SELECTION FOR COMPONENTS OF LITTER SIZE IN SWINE: RESPONSE TO FIVE GENERATIONS OF SELECTION , 1989 .

[12]  F. Bazer,et al.  Sexual maturation and morphological development of the reproductive tract in large white and prolific Chinese Meishan pigs. , 1988, Journal of reproduction and fertility.

[13]  R. Johnson,et al.  Effect of unilateral hysterectomy and ovariectomy on puberty, uterine size and embryo development in swine. , 1987, Journal of Animal Science.

[14]  R. Christenson,et al.  Justification of unilateral hysterectomy-ovariectomy as a model to evaluate uterine capacity in swine. , 1987, Journal of animal science.

[15]  R. Roberts,et al.  Establishment of pregnancy in the pig: II. Cellular remodeling of the porcine blastocyst during elongation on day 12 of pregnancy. , 1982, Biology of reproduction.

[16]  R. Roberts,et al.  Establishment of pregnancy in the pig: I. Interrelationships between preimplantation development of the pig blastocyst and uterine endometrial secretions. , 1982, Biology of reproduction.

[17]  R. Roberts,et al.  Establishment of pregnancy in the pig: III. Endometrial secretory response to estradiol valerate administered on day 11 of the estrous cycle. , 1982, Biology of reproduction.

[18]  S. Ford,et al.  Uterine blood flow and uterine arterial, venous and luminal concentrations of oestrogens on days 11, 13 and 15 after oestrus in pregnant and non-pregnant sows. , 1982, Journal of reproduction and fertility.

[19]  F. Sinowatz,et al.  The placenta of the pig. I. Finestructural changes of the placental barrier during pregnancy. , 1980, Anatomy and embryology.

[20]  L. Anderson Growth, protein content and distribution of early pig embryos , 1978, The Anatomical record.

[21]  J. S. Perry,et al.  Steroid Hormone Production by Pig Blastocysts , 1973, Nature.

[22]  B. N. Day,et al.  Effect of number of embryos on embryonic survival in recipient gilts. , 1972, Journal of animal science.

[23]  L. C. Ulberg,et al.  Stage of gestation when uterine capacity limits embryo survival in gilts. , 1972, Journal of animal science.

[24]  P. Dziuk Effect of number of embryos and uterine space on embryo survival in the pig. , 1968, Journal of animal science.

[25]  Otto Grosser HUMAN AND COMPARATIVE PLACENTATION INCLUDING THE EARLY STAGES OF HUMAN DEVELOPMENT , 1933 .