Regulation of myometrial Gi2, Gi3, and Gq expression during pregnancy. Effects of progesterone and estradiol.

The possibility that progesterone or estradiol may regulate expression of G protein in the rat myometrium during the course of pregnancy has been investigated using 1) immunoblot analysis of Gi2 alpha, Gi3 alpha, and Gq alpha subunits and 2) hybridization blot analysis of subunit mRNA. Eighteen hours after administration, estradiol had significantly increased the levels of both Gi2 alpha subunit and Gi2 alpha mRNA (by 40% and 32%, respectively). In control pregnant rats, we observed similar changes at the end of pregnancy, when myometrial concentrations of estradiol had increased, i.e., a 41% increase in immunoreactive Gi2 alpha subunit that correlated with a parallel 45% increase in mRNA levels. In contrast, levels of immunoreactive Gi3 alpha subunit and mRNA, which decreased with advancing gestation, were not influenced by estradiol or progesterone administration. Progesterone administration resulted 30 h later in a significantly decreased level of Gq alpha immunoreactivity (32%) and Gq alpha mRNA (30%). In control rats, Gq alpha protein and mRNA were also significantly lower at midpregnancy under progesterone dominance vs. term. At this stage, a twofold increase in Gq alpha subunit correlated with a 40% increase in mRNA levels. These results demonstrate that myometrial Gi2 alpha and Gq alpha subunits are physiological targets for estradiol and progesterone, respectively, in vivo. Alterations of these G protein levels are discussed in relation to their mediating effects on adenylyl cyclase activity or the phospholipase C pathway during the course of pregnancy.

Pregnancy-related modifications of rat myometrial Gs proteins: ADP ribosylation, immunoreactivity and gene expression studies.

Previous studies from our laboratory have suggested that post-receptor events at the level of beta-adrenergic receptor-adenylate cyclase interaction could be altered in myometrium by steroid hormones or pregnancy. In this study, we have addressed this question by performing a direct evaluation of rat myometrial Gs proteins at various stages of pregnancy or 24 h after administration of progesterone. In the 50,000 g myometrial plasma membrane fraction, in the presence of 32P-labelled NAD, cholera toxin ribosylated three predominant proteins with apparent molecular masses of 42, 47 and 55 kDa. Western blot analysis using the RM/1 antibody recognized the 42 and 47 kDa cholera toxin ADP-ribosylated bands but not the 55 kDa band. Thus, the 42 and 47 kDa immunoreactive bands were interpreted as being the small (Gs alpha-S) and large (Gs alpha-L) forms of Gs respectively. With a more purified myometrial plasma membrane fraction (105,000 g) an additional minor band of 44 kDa could be observed with both techniques. Treatment of late pregnant rats with 5 mg progesterone resulted in a significant increase in both Gs alpha subunits: +25% and +30% after ADP-ribosylation, +50% and +60% after Western blot analysis for Gs alpha-L and Gs alpha-S respectively. Pretreatment with the antiprogestin RU 486 completely suppressed the effect of progesterone, suggesting that the expression of Gs alpha subunits may be under the control of progesterone. However, changes in the myometrial content of Gs in progesterone-treated rats were not associated with concomitant variations in the steady-state levels of mRNA as demonstrated by Northern blot analysis. These data suggest a post-translational regulation of Gs expression by progesterone. Amounts of ADP-ribosylated Gs showed characteristic changes during the course of pregnancy with a fourfold or threefold increase (P < 0.05) on day 15 versus day 12 or delivery respectively. During pregnancy, or after progesterone administration, myometrial alterations of Gs strongly correlated (r = 0.913, P < 0.01) with the cholera toxin-stimulated adenylate cyclase activity. These findings provide evidence that changes in myometrial amounts of functional Gs i) are controlled by the hormonal status of pregnancy and progesterone and ii) play an important role in the transduction pattern of adenylate cyclase activity during the course of pregnancy.