Uptake and effects of ovarian steroids in the early pig embryo: In vitro and in vivo studies

Abstract

The role of ovarian steroids in the preimplantation pig embryo was studied in vivo and in vitro. Twenty gilts were treated three times daily on days 1 to 4 after insemination with either 25, 100, 250, or 1000 mg progesterone in oil, and 17 gilts were injected with corresponding amounts of sesame oil (controls). All gilts were slaughtered 5 days after insemination and the embryos were recovered. Oviduct and plasma progesterone content were significantly (P<0.001) higher in gilts treated with 750 mg of exogenous progesterone per day. After 750 mg progesterone, oviduct progesterone content was twice as high as control levels, while after 3000 mg progesterone per day the levels in oviduct and uterus exceeded those of controls by five and seven times, respectively. In gilts treated with 750 mg progesterone per day, plasma progesterone levels were 177.4 ± 22.1 ng/ml ( x ± SD ) on day 3 and 186.4 ± 69.2 ng/ml on day 5 and resembled values found in superovulated pigs with more than 40 ovulations. Excessive plasma progesterone values of 1014.6 ± 840.4 ng/ml on day 3 and 473.2 ± 197.2 ng/ml on day 5 were found after treatment with 3000 mg of progesterone per day. Treatment with up to 750 mg of exogenous progesterone per day, did not affect embryonic development, but 3000 mg per day resulted in a significantly (P<0.001) higher percentage of retarded and degenerate embryos compared to controls (71.8% versus 3.2%). In addition, the amount and specificity of uptake of 3H-labelled progesterone and estradiol-17 beta by pig blastocysts recovered from superovulated gilts were investigated after 6 hrs in vitro culture. The uptake of 3H-progesterone was 131.9 ± 56.9 counts per million (cpm) per 10 blastocysts, corresponding to 1.1 fmoles progesterone. The uptake was non-specific for it was only slightly reduced in the presence of a 100-fold excess of unlabelled progesterone (20.1%) or estradiol-17 beta (27.0%). The uptake of 3H-estradiol-17 beta was 133.9 ± 74.12 cpm per 10 blastocysts, corresponding to 1.3 fmoles estradiol-17 beta. The uptake was significantly (P<0.01) reduced by 67.7% in the presence of a 100-fold excess of unlabelled estradiol-17 beta. Apparent specific binding was 0.87 fmoles estradiol-17 beta per 10 blastocysts or 72.5 fmoles estradiol-17 beta per mg protein. The uptake was only slightly reduced in the presence of a 100-fold excess of unlabelled progesterone (23.3%). This significant inhibition could be determined after 2 hrs in vitro culture. There was no competitive inhibition after 20 min. of culture. Uptake by unfertilized ova and degenerate embryos recovered on day 5 was significantly smaller (51.8 ± 10.3 cpm per 10 eggs; P<0.001) than by blastocysts recovered on the same day. No competitive inhibition could then be determined. In vivo, preimplantation pig embryos seem to be rather insensitive to high progesterone levels. Excessive amounts of progesterone probably can be metabolized to a great extent. Progesterone seems to be taken up rather non-specifically by the pig embryo. The uptake and binding of estradiol-17 beta seems to be more specific. Studies are in progress to investigate the physiological role of estradiol-17 beta uptake in early embryonic development.