Amplification of angiotensin II signaling in cardiac myocytes by adenovirus-mediated overexpression of the AT1 receptor.

Low levels of AT1 receptor can make studying the growth-related signal transduction events mediated by this angiotensin II receptor in cardiac myocytes technically difficult. The purpose of the present study was to establish whether an adenovirus expression system could be used to increase the number of plasma membrane AT1 receptors in neonatal rat ventricular myocytes, thereby amplifying the signaling pathways activated by this receptor. Cardiac myocytes infected with adenovirus expressing the AT1 receptor exhibited increased ligand binding. The overexpressed receptor appeared to function like the endogenous receptor, in regard to agonist-induced internalization, as well as coupling to MAPK activation and protein tyrosine phosphorylation events. In addition, adenovirus-mediated overexpression of the AT1 receptor resulted in the amplification of angiotensin II intracellular signaling. In conclusion, adenovirus-mediated overexpression of angiotensin II receptors appears to be a useful strategy for studying the signal transduction events activated by this hormone in cardiac myocytes and for unraveling the molecular means by which this receptor type couples to a hypertrophic pattern of growth and gene expression.

Acceleration of growth of cultured cardiomyocytes and translocation of protein kinase C.

Phorbol 12-myristate 13-acetate (PMA), norepinephrine (NE), and contraction stimulate cardiomyocyte growth (increased protein content). Differences exist in the time course and extent of protein and RNA accumulation. Cells plated at 4 x 10(6) cells/60-mm dish and arrested with 50 mM KCl demonstrated no significant growth. Treatment with PMA stimulated growth to a maximum of 17% at 48 h. In contrast, maximal stimulation of growth was 36% at 48 h and 31% at 72 h for contracting and NE-treated cells, respectively. Maximal stimulation of the capacity for protein synthesis (RNA content) was 32% for PMA-treated cells at 24 h compared with 59% and 77% for NE-treated and contracting cells, respectively, at 72 h. In support of a primary role for altered capacity in the regulation of protein synthesis, there was a significant correlation (r = 0.84) between RNA and protein contents that was independent of the stimulus used. Angiotensin II increased RNA content by 28% at 48 h but had no effect on growth up to 72 h. Growth stimulation and increased nuclear protein kinase C (PKC) activity were induced by contraction, NE, and PMA treatment and were inhibited by staurosporine (a PKC inhibitor), suggestive of a central role for PKC.

Contractile activity and passive stretch regulate tubulin mRNA and protein content in cardiac myocytes.

Accumulation of tubulin protein and an increased array of microtubules have been associated with contractile dysfunction in cardiac myocytes after pressure overload in vivo. Experiments were performed to assess the ability of mechanical stimuli experienced by ventricular cardiac myocytes during the progression of hypertrophic and dilated pathology to increase beta-tubulin production in cultured neonatal rat cardiac myocytes. Results indicate that both contractile activity and load due to passive stretch increase beta-tubulin protein content in neonatal rat cardiac myocytes through accumulation of beta-tubulin mRNA, which occurs without increased beta-tubulin gene transcription. Western blot analysis demonstrated that contraction resulted in the accumulation of beta-tubulin in neonatal rat cardiac myocytes above increases observed in the content of total cellular protein. Northern blot analysis indicated that beta-tubulin mRNA content increased in response to both stretch and contraction. alpha-Adrenergic agonists that lead to pathophysiological growth in cardiac myocytes also stimulated an increase in beta-tubulin mRNA content. Treatment of contracting neonatal cardiac myocytes with angiotensin II (ANG II) further increased beta-tubulin mRNA content, whereas ANG II treatment in arrested neonatal cardiac myocytes failed to increase beta-tubulin mRNA. Nuclear run-on experiments indicate that contraction stimulates beta-tubulin mRNA accumulation without an increase in beta-tubulin gene transcription. These results imply that tubulin production in cultured cardiac myocytes can be regulated directly by mechanical forces. In mechanically challenged hearts, the accumulation of beta-tubulin and the development of contractile dysfunction may be directly related to the mechanical forces imposed on the myocardium during the onset and progression of cardiovascular disease.

Phorbol ester stimulation of protein kinase C activity and ribosomal DNA transcription. Role in hypertrophic growth of cultured cardiomyocytes.

The mechanism by which phorbol esters induce hypertrophic growth of cardiomyocytes was investigated. Control and 4 alpha-phorbol 12,13-didecanoate-treated myocytes demonstrated a slow rate of growth as measured by the protein/DNA ratio and cell area. In contrast, treatment with phorbol 12-myristate 13-acetate (PMA) stimulated protein accumulation by 34%, while cell area was increased by 68% over control myocytes after 72 h. RNA content in PMA-treated myocytes was 33% higher than in control cells and 4 alpha-phorbol 12,13-didecanoate-treated cells after 72 h. Membrane-associated protein kinase C activity was transiently increased after PMA treatment but returned to normal by 48 h. Cytosolic protein kinase C activity was not significantly altered by PMA. Membrane-associated and cytosolic protein kinase C activities were not altered by 4 alpha-phorbol 12,13-didecanoate. Protein kinase C activity, RNA polymerase I activity, and the transcriptional rate of ribosomal DNA (rDNA) were increased in nuclei isolated from PMA-treated cells. However, consistent with a high rate of processing of pre-ribosomal RNA (pre-rRNA), the pool size of pre-rRNA relative to the 28 S rRNA was unaltered by PMA treatment. These data demonstrated that PMA-induced hypertrophic growth of cardiomyocytes was due to an increase in the capacity for protein synthesis (rRNA), and suggest that this results from protein kinase C mediated increase in the rate of transcription of rDNA.

Transcriptional regulation of ribosomal RNA synthesis during growth of cardiac myocytes in culture.

The mechanism(s) by which rRNA accumulates during the growth of cardiac myocytes was investigated. The rates of rDNA transcription were measured in contracting myocytes and compared with nonbeating myocytes depolarized with 50 mM KCl. After 3 days of contraction the absolute rate of rDNA transcription was accelerated by 2-fold as measured by incorporation of [3H]UTP into the external transcribed spacer of preribosomal RNA. Corresponding increases in transcription were observed in isolated nuclei of contracting myocytes as measured by either hybridization of run-on transcripts of preribosomal RNA or activity of RNA polymerase I. The extent to which transcription was stimulated in contracting myocytes accounted for the previously observed acceleration of rRNA synthesis rates. The steady-state levels of preribosomal RNA relative to rRNA were unchanged in contracting myocytes, but the total amount of preribosomal RNA was 1.3-fold greater as a result of increased rRNA content. The increase of preribosomal RNA in proportion to rRNA in contracting myocytes demonstrated that the rate of preribosomal RNA processing was unchanged and that rRNA synthesis is regulated by an accelerated rate of rDNA transcription.

Desmin gene expression in cardiac myocytes is responsive to contractile activity and stretch.

Experiments were performed to assess the ability of mechanical stimuli, experienced by ventricular cardiac myocytes during the progression of hypertrophic and dilated pathology, to increase the expression of desmin in cultured neonatal rat cardiac myocytes. Results indicate that both contractile activity and load due to passive stretch increase desmin content in neonatal rat cardiac myocytes through increased desmin gene transcription. Western blot analysis demonstrated that contraction induced a selective increase in desmin protein content in neonatal rat cardiac myocytes above increases observed in the content of total cellular protein. Northern blot analysis indicated that desmin mRNA content increased in response to contraction as well as to alpha-adrenergic stimulation. Desmin mRNA content also increased in cultured neonatal myocytes in response to stretch. Angiotensin II (ANG II) treatment of contracting neonatal cardiac myocytes further increased desmin mRNA content, whereas similar treatment in arrested neonatal cardiac myocytes further increased desmin mRNA content, whereas similar treatment in arrested neonatal cardiac myocytes failed to increase desmin mRNA. This contraction-dependent responsiveness to ANG II is not a function of increases in the density or relative subtype composition of ANG II receptors. Treatment of contracting neonatal rat cardiac myocytes with actinomycin D prevented increases in desmin mRNA content, suggesting regulation of transcription of the desmin gene by contraction. Nuclear run-on experiments indicate that contraction. Nuclear run-on experiments indicate that contraction increases transcription of the desmin gene in cardiac myocytes. These results are consistent with the modulation of desmin gene expression secondarily to changes in the mechanical environment that occur in cardiac tissue undergoing dilation or hypertrophy.