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Vertebrate reproductive science and technology
RESEARCH ARTICLE

73 INTRAUTERINE GROWTH RESTRICTION AFTER BETWEEN-BREED EMBRYO TRANSFER IS ASSOCIATED WITH STRONG ALTERATIONS IN PLACENTAL STRUCTURE AND FUNCTION IN HORSES

P. Peugnet A B , S. Valentino A B , A. Tarrade A B , L. Wimel C , F. Reigner D , D. Serteyn E and P. Chavatte-Palmer A B
+ Author Affiliations
- Author Affiliations

A INRA, UMR1198 Biologie du Développement et Reproduction, Jouy en Josas, France;

B ENVA, Biologie du Développement et Reproduction, Maisons-Alfort, France;

C IFCE, Station Expérimentale, Chamberet, France;

D INRA, UE1297, UEPAO, Nouzilly, France;

E Clinique équine, Faculté de Médecine Vétérinaire, CORD, Université de Liège, Liège, Belgium

Reproduction, Fertility and Development 26(1) 150-151 https://doi.org/10.1071/RDv26n1Ab73
Published: 5 December 2013

Abstract

In equids, placentation is diffuse and the nutrient supply to the fetus is determined by uterine size, which is correlated with maternal size. The size of the mare affects fetal development as shown by embryo transfer (ET) between Ponies and Thoroughbreds. In turn, insulin sensitivity in the newborn foal and subsequent postnatal growth rate are affected. We enhanced or restricted fetal growth through ET using Pony (P), Saddlebred (S), and Draft (D) horses and investigated placental morphology, structure, and function at term. Control pregnancies of P-P (n = 21), S-S (n = 28), and D-D (n = 8) were obtained by AI. Enhanced and restricted pregnancies were obtained by transferring P (P-D, n = 6) and S embryos (S-D, n = 8) into D mares or S embryos into P mares (S-P, n = 6), respectively. Placental weight and surface were recorded at delivery. Samples were collected for stereology and RT-qPCR analysis of expression of genes involved in placental growth, vascularization, and nutrient transport. Housekeeping genes were RPL32, SCAMP3, and B2M. Data were analysed by Kruskal-Wallis followed by Dunn's post hoc test. Placental weight and surface were increased in S-S and in D-D compared with P-P, whereas S-S and D-D were not different. No histological changes were observed among controls, but most genes had their expression decreased in P-P compared with S-S and D-D. The P-D foals had a 57% increased birthweight with heavier and larger placentas than P-P foals. The S-D foals were similar to both S-S and D-D in terms of birthweight and placental weight and surface. No major modifications in placental histology or transcript levels were observed in both enhanced groups. In contrast, S-P foals had a 37% decreased birthweight with lighter and smaller placentas compared with S-S and S-D foals. There was no gross histological difference between S-P and S-S but the microcotyledonary surface density was higher in S-P compared with S-D. Moreover, the expression of IGF2, IGF2R, SLC2A1, and eNOS was decreased in S-P compared with S-S. There was no difference in gene expression between S-P and P-P. In conclusion, intrauterine growth restriction led to marked changes in placental morphology, histology, and gene expression. The increased microcotyledonary surface density suggests a lengthening of villi, which could increase feto-maternal contact surface as a compensatory mechanism for the restricted uterine capacity. Surprisingly, placental adaptation to the restricted intrauterine environment in S-P induced gene profiles resembling that of control P, whereas no difference was observed in enhanced pregnancies.