Myosin heavy chain gene expression in neonatal rat heart cells: effects of [Ca2+]i and contractile activity.

Abstract

To determine if mechanical signals or alterations in intracellular Ca2+ concentration ([Ca2+]i) affect myosin heavy chain (MHC) gene expression in spontaneously beating, neonatal rat ventricular myocytes, contractile activity was inhibited with verapamil, KCl, or 2,3-butanedione monoxime (BDM), and their acute and chronic effects on myocyte shortening, [Ca2+]i, and MHC gene expression were examined. Despite their differing effects on [Ca2+]i, verapamil, KCl, and BDM all inhibited contractile activity and markedly downregulated beta-MHC mRNA levels to 24 +/- 5, 21 +/- 7, and 6 +/- 2% of contracting cells, respectively. In contrast, these inhibitors of contraction upregulated alpha-MHC mRNA levels to 163 +/- 19, 156 +/- 7, and 198 +/- 20% of contracting cells, respectively. Transient transfection with a rat beta-MHC promoter-luciferase expression plasmid demonstrated that all inhibitors of contraction significantly decreased beta-MHC promoter activity. Paradoxically, contractile arrest also inhibited alpha-MHC promoter activity, suggesting that increased alpha-MHC mRNA levels resulted from posttranscriptional mechanisms. Actinomycin D mRNA stability assays indicated that alpha-MHC mRNA half-life was prolonged in noncontracting cells (33 h) compared with contracting myocytes (14 h). Contraction-dependent alterations in MHC gene expression were not dependent on release of angiotensin II or other growth factors into the culture medium. Thus intrinsic mechanical signals rather than alterations in [Ca2+]i regulate alpha-MHC and beta-MHC gene expression by both transcriptional and posttranscriptional mechanisms.