Decreased type VI adenylyl cyclase mRNA concentration and Mg(2+)-dependent adenylyl cyclase activities and unchanged type V adenylyl cyclase mRNA concentration and Mn(2+)-dependent adenylyl cyclase activities in the left ventricle of rats with myocardial infarction and longstanding heart failure.

OBJECTIVE: To address the effect of longstanding left ventricular (LV) hypertrophy and failure on LV adenylyl cyclase (AC) gene expression, mRNA concentrations of the main cardiac AC isoforms were measured in the non-infarcted area of LV from rats with myocardial infarction (MI), without (H) or with (F) LV failure, and in control (C) rats. Basal, GTP- and forskolin-stimulated Mg(2+)- and Mn(2+)-dependent AC activities were also measured in F and C rats. METHODS: Two- and six months after MI, steady-state AC mRNA concentrations were assessed by Northern blot analysis and RNase protection assay with isoform-specific cDNA and cRNA probes, respectively. AC activities were assessed on LV microsomal fractions using standard procedures. RESULTS: Types V and VI, and types IV and VII were the major and minor AC mRNA isoforms in both the LVs of F and C rats. Two months after MI, no difference in LV type V or VI mRNA to glyceraldehyde-3-phosphate dehydrogenase (GAPDH) mRNA ratios was observed in rats with H or F compared to C. Six months after MI, no difference in LV type V mRNA concentration was observed between the three rat groups, whether this level was normalized to GAPDH, poly-(A+) or 18S RNAs. In contrast, a 35% decrease in the type VI mRNA to poly-(A+) RNA ratio and a 29% decrease in the type VI mRNA to 18S RNA ratio was observed only in rats with F compared to C (p < 0.05 vs. C for the two comparisons). Two- and six months after MI, basal and forskolin-stimulated Mg(2+)-dependent AC activities were decreased by 30-35% in F rats compared to C (p < 0.05), whereas Mn(2+)-dependent activities were unchanged. CONCLUSION: Longstanding LV hypertrophy and failure resulting from MI in rats is not associated with altered expression of the most abundant, type V, AC mRNA isoform, whereas that of type VI is decreased. The lack of change in Mn(2+)-dependent AC activities in the LV of F rats suggests that this decrease has no functional consequence on overall AC activity and that decreased Mg(2+)-dependent activities are related to alterations occurring upstream.

[Beta adrenergic signal transduction and heart adenyl cyclase]. / Transduction du signal beta-adrénergique et adénylate cyclases cardiaques.

Transduction of the beta-adrenergic signal plays an important role in the regulation of cardiac contractility. It is mediated by three sarcolemmal proteins: the beta-adrenergic receptor, G proteins and adenylyl cyclase which is the catalytic unit of the system which generates cAMP, the second messenger of the system. Each protein comprises a number of isoforms which yields a wide range of potential regulations, many of which are not yet elucidated. Among the three proteins, the adenylyl cyclase is the one which has been less studied. However, the recent cloning of many of its isoforms allows now investigations of their expression in many tissues and cell types. We have shown in rats that among the five isoforms detected in the myocardium, type V and VI adenylyl cyclase mRNAs are the most abundant ones. Type V and VI adenylyl cyclase mRNA abundance is similar in late fetal hearts. Type V mRNA accumulates in the heart during postnatal development whereas type VI mRNA concentration remains unchanged. Consequently, type V mRNA becomes highly predominant compared to type VI mRNA in the adult rat ventricle (type V/type VI adenylyl cyclase mRNAs approximately 10). Whatever the developmental stage, cardiac adenylyl cyclase activity is inhibited by submicromolar calcium concentrations. In adult ventricles, adenylyl cyclase activity in the presence of 1 mM ATP is at least three times higher than that observed in fetal and new born rat hearts. Since this increase parallels the accumulation of type V adenylyl cyclase mRNA, one can hypothesize that the former is due to the latter. In contrast, our preliminary results seem to indicate that during heart failure in rats, decreased adenylyl cyclase activity is not associated with decreased cardiac concentrations of type V and VI adenylyl cyclase mRNAs. Isoform specific antibodies are now required to understand the reasons for such discrepancy.

Type V, but not type VI, adenylyl cyclase mRNA accumulates in the rat heart during ontogenic development. Correlation with increased global adenylyl cyclase activity.

Type V and VI adenylyl cyclase mRNAs are the two main cyclase isoforms expressed in the mammalian heart. A recent report has shown that their expression is differentially regulated during ontogenic development, but the accumulation of the two mRNA species and their concentration ratio have not been determined. We thus determined the accumulation and the relative amounts of type V and VI adenylyl cyclase mRNA in fetal, neonatal and adult rat hearts, using a sensitive ribonuclease protection assay. In 18-day-old fetuses, the two adenylyl cyclase mRNA isoforms were weakly expressed in approximately equal amounts (type V mRNA/type VI mRNA = 0.93 +/- 0.09). Further development was characterized by a sharp increase in type V adenylyl cyclase mRNA (x 1.9 in neonates v fetuses, P < 0.01; x 2.4 and x 4.5 in adults v neonates and fetuses, respectively, P < 0.01 for both comparisons) and a slight, non-significant fall in type VI mRNA (P = 0.16). As a result, the type V mRNA/type VI mRNA ratio was 2.86 +/- 0.57 and 9.09 +/- 1.21 in neonatal hearts and adult ventricles, respectively (P < 0.01 v ratio in fetal hearts for both comparisons; P < 0.01 for ratio in adult ventricles v ratio in neonatal hearts), and the overall amount of the two mRNA isoforms was 2.3 times greater in adult than in fetal hearts (P < 0.01). This increase was paralleled by an increase in basal and isoproterenol- and forskolin-stimulated adenylyl cyclase activities in adult hearts compared to fetal and neonatal hearts (P < 0.01 for the three comparisons). Our results demonstrate that type V adenylyl cyclase mRNA accumulates in the rat heart after birth to become the highly predominant isoform in the adult heart. They further suggest that the increase in cardiac adenylyl cyclase activity observed during rat development is due to this accumulation.

Molecular cloning and developmental expression of human cardiac troponin T.

We have isolated a full-size cDNA coding for cardiac troponin T (cTnT) from a human adult heart library, using a slow skeletal TnT probe. This cDNA detected a 1.2 kb mRNA in fetal and post-natal human heart, the amount of which increased during ontogenic development. Interestingly, a similar transcript was coexpressed in fetal skeletal muscle, together with the 0.9 kb slow skeletal muscle mRNA, and its expression was down-regulated during further development.