Activation of the calcineurin signaling pathway induces atrial hypertrophy during atrial fibrillation.

Atrial tachyarrhythmia (AF) alters intracellular calcium homeostasis and induces cellular hypertrophy of atrial myocytes. The impact of the calcium-dependent calcineurin pathway on the development of AF-induced atrial hypertrophy has not yet been analyzed. In this study, atrial tissue samples from patients with sinus rhythm and chronic persistent atrial fibrillation (CAF) were used to determine changes in expression and activity of calcineurin A (CnA), and its relation to CnA-regulated transcription factors NFATc1-4, and hypertrophic markers ANP, troponin I, and beta-MHC. CnA phosphatase activity and CnAbeta protein contents were significantly upregulated in patients with CAF. Calcineurin activation led to dephosphorylation, redistribution, and subsequent accumulation of NFATc3 in nuclei during CAF, and expression of hypertrophic genes was increased. CAF-dependent changes were reproduced by ex vivo pacing (2-4 Hz) of human atrial tissue slices. FK506 abolished the hypertrophic response induced by electrical-field stimulation. Atrial tachyarrhythmia causes atrial hypertrophy by activation of the CnA signal pathway, which thereby contributes to structural remodeling of human atria.

Cardiac beta-adrenoceptors in chronic uremia: studies in humans and rats.

OBJECTIVES: The purpose of this study was to elucidate whether cardiac beta-adrenergic effects may be blunted in patients on maintenance hemodialysis (HD) and may help to explain autonomic dysfunction. BACKGROUND: Patients on HD often suffer from autonomic dysfunction. METHODS: We investigated the cardiovascular response of five HD patients (age: 46.1+/-7.9 years) and six healthy volunteers (age: 48.2+/-7.5 years) to isoprenaline, pirenzepine and phenylephrine. For analysis of underlying mechanisms of beta-adrenoceptor hyporesponsiveness, six-week-old male Wistar rats were rendered uremic by 5/6-nephrectomy (n = 9; SNX) and were killed for removal of the heart after six to seven weeks. Sham-operated rats (n = 15) served as controls. RESULTS: In the patient study, isoprenaline (3.5, 7, 17, 35 ng/kg/min, i.v.) led to an increase in heart rate, and shortening of the heart rate corrected duration of the electromechanical systole (QS2c), both of which were significantly reduced in HD patients. Baroreflex sensitivity was significantly reduced in HD patients. The response to low parasympathomimetic doses of pirenzepine was unchanged. In the rat study, left ventricular strips were placed in an organ bath, electrically driven and exposed to isoprenaline (10(-11) to 10(-6) mol/liter). While pD2 values were unchanged, maximum effect at the highest concentration was significantly reduced in SNX rats. The response to carbachol was not altered, nor was the M2-cholinoceptor density. There was no difference in beta-adrenoceptor density, or in immunodetectable amount of Gs and Gi protein. Activation of adenylyl cyclase evoked by isoprenaline was significantly reduced in left ventricular membranes of SNX rats, whereas effects of 10 micromol/liter GTP, 10 mmol/liter NaF, 10 micromol/liter forskolin and 10 mmol/liter Mn2+ were not altered. CONCLUSIONS: Cardiac beta-adrenergic responses are blunted in chronic uremia due to reduced isoprenaline-dependent activation of adenylyl cyclase. This might be caused by an "uncoupling" of the receptor or by an inhibition of the receptor by uremic toxins.

Nitric oxide inhibits isoprenaline-induced positive inotropic effects in normal, but not in hypertrophied rat heart.

Evidence has accumulated that, in the rat heart, nitric oxide (NO) inhibits beta-adrenoceptor-mediated positive inotropic effects. The aim of this study was to investigate whether this effect of NO may be altered in cardiac hypertrophy. For this purpose we studied the effects of the NO-donor SNAP (S-nitroso-N-acetyl-D,L-penicillamine) on isoprenaline-induced positive inotropic effects in left ventricular strips from three models of cardiac hypertrophy: a) 12-16 weeks old male spontaneously hypertensive rats (SHR) vs. age-matched normotensive Wistar-Kyoto (WKY) rats, b) six weeks old male Wistar WKY-rats sub-totally nephrectomized (SNX) 7 weeks after SNX vs. sham-operated rats (SOP) and c) four weeks old male Wistar WKY-rats supra-renal aortic-banded (AOB, band diameter 1.0 mm) 8 weeks after AOB vs. SOP. In all three models of cardiac hypertrophy the heart weight/body weight ratio was significantly higher than in their respective controls. On isolated electrically driven ventricular strips isoprenaline (10(-10)-10(-5) M) caused concentration-dependent increases in force of contraction. Maximal increases (Emax) were similar in SHR vs. WKY-rats, but reduced in SNX- (2.9+/-0.29 vs. 5.1+/-0.34 mN, p<0.01) and AOB-rats (2.3+/-0.37 vs. 4.2+/-0.33 mN, p<0.01). In control rats (WKY and the respective SOP) the NO-donor SNAP (10(-5) M) caused a significant rightward-shift of the concentration-response curve for isoprenalinel; this rightward-shift could be inhibited by methylene blue (10(-5) M). In ventricular strips of SHR, SNX- and AOB-rats, however, 10(-5) M SNAP failed to significantly affect isoprenaline-induced positive inotropic effect. We conclude that in cardiac hypertrophy effects of NO are attenuated. Such an impairement of the NO-system could contribute to the development and/or maintenance of cardiac hypertrophy.