Overexpression of the human angiotensin II type 1 receptor in the rat heart augments load induced cardiac hypertrophy.

Angiotensin II is known to stimulate cardiac hypertrophy and contractility. Most angiotensin II effects are mediated via membrane bound AT1 receptors. However, the role of myocardial AT1 receptors in cardiac hypertrophy and contractility is still rarely defined. To address the hypothesis that increased myocardial AT1 receptor density causes cardiac hypertrophy apart from high blood pressure we developed a transgenic rat model which expresses the human AT1 receptor under the control of the alpha-myosin heavy-chain promoter specifically in the myocardium. Expression was identified and quantified by northern blot analysis and radioligand binding assays, demonstrating overexpression of angiotensin II receptors in the transgenic rats up to 46 times the amount seen in nontransgenic rats. Coupling of the human AT1 receptor to rat G proteins and signal transduction cascade was verified by sensitivity to GTP-gamma-S and increased sensitivity of intracellular Ca2+ [Ca2+]i to angiotensin II in fluo-3 loaded transgenic cardiomyocytes. Transgenic rats exhibited normal cardiac growth and function under baseline conditions. Pronounced hypertrophic growth and contractile responses to angiotensin II, however, were noted in transgenic rats challenged by volume and pressure overload. In summary, we generated a new transgenic rat model that exhibits an upregulated myocardial AT1 receptor density and demonstrates augmented cardiac hypertrophy and contractile response to angiotensin II after volume and pressure overload, but not under baseline conditions.

Differential regulation of cardiac ANP and BNP mRNA in different stages of experimental heart failure.

Atrial natriuretic peptide (ANP) and brain natriuretic peptide (BNP) are cardiac hormones that are involved in water and electrolyte homeostasis in heart failure. Although both hormones exert almost identical biological actions, the differential regulation of cardiac ANP and BNP mRNA in compensated and overt heart failure is not known. To study the hypothesis that cardiac BNP is more specifically induced in overt heart failure, a large aortocaval shunt of 30 days duration was produced in rats and compared with compensated heart failure. Compensated heart failure was induced either by a small shunt of 30 days duration or by a large shunt of 3 days duration. Both heart failure models were characterized by increased cardiac weight, which was significantly higher in the large-shunt model, and central venous pressure. Left ventricular end-diastolic pressure was elevated only in the overt heart failure group (control: 5.7 +/- 0. 7; small shunt: 8.6 +/- 0.9; large shunt 3 days: 8.5 +/- 1.7; large shunt 30 days: 15.9 +/- 2.6 mmHg; P < 0.01). ANP and BNP plasma concentrations were elevated in both heart failure models. In compensated heart failure, ANP mRNA expression was induced in both ventricles. In contrast, ventricular BNP mRNA expression was not upregulated in any of the compensated heart failure models, whereas it increased in overt heart failure (left ventricle: 359 +/- 104% of control, P < 0.001; right ventricle: 237 +/- 33%, P < 0.01). A similar pattern of mRNA regulation was observed in the atria. These data indicate that, in contrast to ANP, cardiac BNP mRNA expression might be induced specifically in overt heart failure, pointing toward the possible role of BNP as a marker of the transition from compensated to overt heart failure.

Regulation of cardiac adrenomedullin-mRNA in different stages of experimental heart failure.

Adrenomedullin (AM) is a peptide hormone with vasodilating and natriuretic properties. AM plasma concentrations are elevated in heart failure. Whether cardiac AM-mRNA synthesis is increased in heart failure is not known. We measured AM-mRNA/GAPDH-mRNA in all four heart chambers in compensated and overt heart failure in rats with two different sizes of aortocaval shunt. Left and right atrial AM-mRNA expressions were unchanged in both heart failure models. Similarly, left and right ventricular AM-mRNA expressions were unchanged in compensated heart failure. In overt heart failure, however, the AM-mRNA expression was significantly increased in the left ventricle (145+/-20 vs. 100+/-3% of control, p<0.05). The right ventricular AM-mRNA expression was significantly increased only in a subgroup of animals with pulmonary congestion (lung weight >2.0 g, 141+/-16 vs. 100+/-11% of control, p<0.05). Ventricular AM concentrations were elevated in both ventricles in overt heart failure. AM plasma concentrations were significantly higher in the subgroup with pulmonary congestion than in rats with compensated heart failure (496+/-95 vs. 143+/-7 pmol/l, p<0.01). These data indicate that ventricular AM-mRNA expression and AM concentrations were upregulated only in advanced stages of heart failure. However, the exact contribution of cardiac AM synthesis to the increased AM plasma levels remains to be established.

Acute hemodynamic and renal effects of adrenomedullin in rats with aortocaval shunt.

Heart failure is characterized by increased vascular resistance and water retention. Adrenomedullin is a peptide hormone with vasodilating and diuretic properties whose efficacy in heart failure has not been well established. We used an aortocaval shunt model of moderate heart failure in rats and infused increasing doses of adrenomedullin, both as bolus injections and 20-min infusions. In controls, a clear dose-dependent 4.8+/-1.0 to 13.6+/-2.3 mm Hg decrease in arterial blood pressure was observed after injection of 1 microg to 30 microg of adrenomedullin. In rats with aortocaval shunt, the hypotensive responses were significantly diminished. The urine flow rate, which was diminished at baseline in rats with aortocaval shunt, was increased and normalized by adrenomedullin administration. The glomerular filtration rate increased after infusion of adrenomedullin (0.5 microg/kg min(-1)) from 2.37+/-0.25 to 3.47+/-0.43 ml/min (P<0.01) in controls and from 1.79+/-0.33 to 2.58+/-0.49 (P<0.05) in rats with aortocaval shunt. Similarly, renal blood flow was significantly increased by adrenomedullin in both groups. Our results indicate a beneficial effect of adrenomedullin on renal function in rats with aortocaval shunt. These data suggest that adrenomedullin might be of potential therapeutic value in heart failure, without inordinately decreasing blood pressure.

Renal function in high-output heart failure in rats: role of endogenous natriuretic peptides.

The physiologic and pathophysiologic importance of natriuretic peptides (NP) has been imperfectly defined. The diminished renal responses to exogenous atrial NP in heart failure have led to the perception that the endogenous NP system might be less effective and thus contribute to renal sodium retention in heart failure. This study tests the hypothesis that in experimental heart failure, the renal responses to an acute volume load are still dependent on the NP system. The specific antagonist HS-142-1 was used to block the effects of NP in a model of high-output heart failure induced by an aortocaval shunt. Plasma cGMP levels and renal cGMP excretion were significantly lower in shunted and sham-operated rats receiving HS-142-1, compared with vehicle-treated controls, indicating effective blockade of guanylate cyclase-coupled receptors. Baseline sodium excretion and urine flow rate were lower in HS-142-1-treated sham-operated rats (15.2+/-1.1 microl/min versus 27.5+/-3.1 microl/min with vehicle, P < 0.001) and in HS-142-1-treated shunted rats (8.1+/-1.3 microl/min versus 19.9+/-2.3 microl/min with vehicle, P < 0.001). After an acute volume load, the diuretic and natriuretic responses were attenuated by HS-142-1 in control and shunted rats. The renal responses were reduced by HS-142-1 to a significantly greater extent in shunted rats than in control rats. HS-142-1 did not induce any significant systemic hemodynamic changes in either group, nor did it alter renal blood flow. However, the GFR in HS-142-1-treated shunted rats was lower than that in vehicle-treated shunted rats, both at baseline (0.6+/-0.3 ml/min versus 2.1+/-0.4 ml/min with vehicle, P < 0.05) and after an acute volume load (1.2+/-0.4 ml/min versus 2.6+/-0.4 ml/min with vehicle, P = 0.01), whereas no such effect was observed in control rats. These data indicate that the maintenance of basal renal function and the responses to acute volume loading are dependent on the NP system. The NP seem to be of particular importance for the maintenance of GFR in this model of experimental heart failure. These observations provide new insights into the importance of the renal NP system in heart failure.