Transgenic replacement of type V adenylyl cyclase identifies a critical mechanism of beta-adrenergic receptor dysfunction in the G alpha q overexpressing mouse.

Chronic activation of Gq coupled receptors, or overexpression of G alpha q, in cardiomyocytes results in hypertrophy, enhanced expression of fetal genes, decreased basal and beta-adrenergic receptor (beta AR) stimulated adenylyl cyclase (AC) activities, and depressed cardiac contractility in vivo. Among several abnormalities of the beta AR-Gs-AC pathway that occur in G alpha q overexpressing transgenic mice, we have investigated whether the observed approximately 45% decrease in type V AC expression and function compared to non-transgenic (NTG) is the basis of the above phenotype. Transgenic mice were generated that overexpressed by approximately 50% the rat type V AC in the heart using the alpha-myosin heavy chain promoter. These mice were mated with the G alpha q transgenics resulting in animals (ACV/G alpha q) that had restored levels of forskolin stimulated AC activities in cardiac membranes. In addition, basal cardiac AC activities were normalized in the ACV/G alpha q mice (NTG=23+/-4.4, G alpha q=14+/-3.6, ACV/G alpha q=29+/-5.3 pmol/min/mg) as were maximal isoproterenol stimulated activities (59+/-8.9, 34+/-4.6, 52+/-6.7 pmol/min/mg respectively). Cardiac contractility was also improved by ACV replacement, with increased fractional shortening (51+/-2%, 36+/-6%, 46+/-3% respectively). In contrast, hypertrophy and expression of hypertrophy associated fetal genes were not affected. Thus the observed decrease in type V AC that accompanies the development of the cardiac phenotype in the G alpha q model is the dominant mechanism of dysfunctional beta AR signalling and contractility. In contrast, the decrease in type V AC or beta AR signalling to cAMP is not the basis of the hypertrophic response.