Transforming growth factor beta regulates the expression of the M2 muscarinic receptor in atrial myocytes via an effect on RhoA and p190RhoGAP.

Transforming growth factor beta (TGFbeta) signaling is involved in the development and regulation of multiple organ systems and cellular signaling pathways. We recently demonstrated that TGFbeta regulates the response of atrial myocytes to parasympathetic stimulation. Here, TGFbeta(1) is shown to inhibit expression of the M(2) muscarinic receptor (M(2)), which plays a critical role in the parasympathetic response of the heart. This effect is mimicked by overexpression of a dominant negative mutant of RhoA and by the RhoA kinase inhibitor Y27632, whereas adenoviral expression of a dominant activating-RhoA reverses TGFbeta inhibition of M(2) expression. TGFbeta(1) also mediates a decrease in GTP-bound RhoA and a reciprocal increase in the expression of the RhoA GTPase-activating protein, p190RhoGAP, whereas total RhoA is unchanged. Inhibition of M(2) promoter activity by TGFbeta(1) is mimicked by overexpression of p190RhoGAP, whereas a dominant negative mutant of p190RhoGAP reverses this effect of TGFbeta(1). In contrast to atrial myocytes, in mink lung epithelial cells, in which TGFbeta signaling through activation of RhoA has been previously identified, TGFbeta(1) stimulated an increase in GTP-bound RhoA in association with a reciprocal decrease in the expression of p190RhoGAP. Both effects demonstrated a similar dose dependence on TGFbeta(1). Thus TGFbeta regulation of M(2) muscarinic receptor expression is dependent on RhoA, and TGFbeta regulation of p190RhoGAP expression may be a cell type-specific mechanism for TGFbeta signaling through RhoA.

TGFbeta regulates the expression of G alpha(i2) via an effect on the localization of ras.

The negative chronotropic response of the heart to parasympathetic stimulation is mediated via the interaction of M(2) muscarinic receptors, Galpha(i2) and the G-protein coupled inward rectifying K(+) channel, GIRK1. Here TGFbeta(1) is shown to decrease the expression of Galpha(i2) in cultured chick atrial cells in parallel with attenuation of the negative chronotropic response to parasympathetic stimulation. The response to the acetylcholine analogue, carbamylcholine, decreased from a 95+/-2% (+/-SEM, n=8) inhibition of beat rate in control cells to 18+/-2% (+/-SEM,n =8) in TGFbeta(1) treated cells. Data support the conclusion that TGFbeta regulation of Galpha(i2) expression was mediated via an effect on Ras. TGFbeta(1) inhibited Galpha(i2) promoter activity by 56+/-6% (+/-SEM, n=4) compared to control. A dominant activating Ras mutant reversed the effect of TGFbeta on Galpha(i2) expression and stimulated Galpha(i2) promoter activity 1.7 fold above control. A dominant negative Ras mutant mimicked the effect of TGFbeta(1) on Galpha(i2) promoter activity. TGFbeta had no effect on the ratio of GDP/GTP bound Ras, but markedly decreased the level of membrane associated Ras and increased the level of cytoplasmic Ras compared to control. Furthermore, farnesol, a precursor to farnesylpyrophosphate, the substrate for the farnesylation of Ras, not only reversed TGFbeta(1) inhibition of Ras localization to the membrane, but also reversed TGFbeta(1) inhibition of Galpha(i2)promoter activity. FTI-277, a specific inhibitor of the farnesylation of Ras, mimicked the effect of TGFbeta(1) on Ras localization and Galpha(i2) promoter activity. These data suggest a novel relationship between TGFbeta signaling, regulation of Ras function and the autonomic response of the heart.