150 ENVIRONMENT OF THE EARLY EMBRYO AND ITS EFFECT ON DEVELOPMENT AND POSTNATAL LIFE
A. Watkins A C , A. Wilkins A , T. Papenbrock A , C. Osmond B , M. Hanson C and T. Fleming AA School Of Biological Sciences, Developmental and Cell Biology Group, University of Southampton, Southampton 5016 7PX, UK
B MRC Environmental Epidemiology Unit, Southampton General Hospital, Southampton 5016 6YD, UK
C Centre for Developmental Origins of Health and Disease, University of Southampton, Southampton 5016 5YA, UK. Email: ajw7@soton.ac.uk
Reproduction, Fertility and Development 17(2) 225-226 https://doi.org/10.1071/RDv17n2Ab150
Submitted: 1 August 2004 Accepted: 1 October 2004 Published: 1 January 2005
Abstract
We have investigated the impact of mouse early embryo in vitro culture environment on (a) short-term blastocyst development and (b) long-term postnatal growth and physiology after embryo transfer. In vitro-developed blastocysts, cultured from the 2-cell stage, had reduced inner cell mass (ICM) and trophectoderm (TE) cell numbers when compared to in vivo-derived blastocysts at 96 h post-hCG (n = 13–39, P < 0.05). Despite the retardation in blastocyst development, the ICM:TE ratio was equivalent in both treatment groups. Using embryo transfer techniques, we compared the postnatal development of embryos cultured in vitro from the 2-cell to the blastocyst stage (termed “in vitro” mice) with offspring generated from blastocysts developed in vivo, but which also underwent embryo transfer (termed “in vivo” mice). These two treatment groups were in turn compared with mice derived from naturally mated mothers, which had their mean litter size at birth adjusted to a size comparable with that of the in vitro and in vivo mice (a mean of 6 animals) and which had not been transferred. All data were analyzed using a multilevel random effects regression model which took into account between-mother and within-mother variation in litter size for parameters measured from individual animals. No significant differences in birth weight were observed between in vitro and in vivo offspring. However, in vitro offspring were significantly lighter than in vivo offspring in a gender-dependent manner at 2 weeks of age (males, P = 0.009) and at 6 and 11 weeks of age (females, P = 0.037 and 0.035, respectively). In addition, at 4 weeks of age, the in vivo males became significantly lighter when compared to the naturally mated males (P = 0.034). At 8 weeks of age, the in vivo females had a significantly elevated systolic blood pressure when compared to the in vitro females (P = 0.003); however, at 21 weeks of age, both in vitro males and females had a significantly elevated blood pressure when compared to in vivo offspring (P < 0.003). At 8, 15, and 21 weeks of age, offspring derived from transferred embryos developed with significantly elevated systolic blood pressure when compared to non-embryo transfer offspring (P < 0.05). No significant differences in serum angiotensin-converting enzyme activity (a potent regulator of systolic blood pressure) was observed between the treatment groups. Significantly altered liver:body weight ratios were observed between the in vitro and in vivo males, and between the in vitro and the naturally mated (6) females (P < 0.038). All of the above data are independent of litter size. These data support the hypothesis that early embryo environment can influence postnatal growth and cardiovascular physiology.
This research was funded by an MRC research grant to TPF, and by a DOHaD studentship.
