Insulin downregulates M(2)-muscarinic receptors in adult rat atrial cardiomyocytes: a link between obesity and cardiovascular complications.

OBJECTIVE: To determine whether decreased cardiac parasympathetic activity observed in obesity is due to insulin-induced alterations in cardiac M(2)-muscarinic receptors and/or adenylyl cyclase activity. DESIGN AND METHODS: After incubation with increasing concentrations of insulin, adult rat atrial cardiomyocytes were assayed for M(2)-muscarinic receptor binding density and affinity, and for M(2)R mRNA expression using RT-PCR analysis. Forskolin-stimulated adenylyl cyclase activity and its inhibition by carbachol were also assayed, as was endothelial nitric oxide synthase mRNA expression. The effects of insulin on M(2)-muscarinic receptor density and mRNA expression levels were analyzed using the insulin signaling inhibitors rapamycin, wortmanin and PD 098059. RESULTS: Insulin induces a concentration- and time-dependent decrease in expression of the M(2)R mRNA, and in [(3)H]N-methylscopolamine binding by the receptor. These effects on the M(2)R mRNA levels and on [(3)H]N-methylscopolamine binding were prevented by PD 98059, but not by wortmanin or rapamycin. Basal and forskolin-induced cAMP production did not differ, but the inhibition of forskolin-simulated enzyme activity by carbachol was blunted by insulin. No change in the mRNA levels for endothelial nitric oxide synthase was observed. CONCLUSION: In rat atrial cardiomyocytes, insulin markedly alters both the M(2)-muscarinic receptor density, and its mRNA expression through transcriptional regulation and adenylyl cyclase activity. These data suggest that the obesity-associated decrease in cardiac parasympathetic tone may be related to hyperinsulinemia, which could directly contribute to cardiovascular morbidity in obese patients.

[Early atrial gene regulation of obesity-related arterial hypertension]. / Modifications précoces du transcriptome auriculaire dans l'hypertension artérielle associée à l'obésité chez le chien.

High fat diet (HFD) induces both arterial hypertension and tachycardia in dogs. Changes in heart rate occur early and are in part due to a decrease in the parasympathetic drive to the heart secondary to down-regulation of atrial muscarinic M2 receptors (Pelat et al. Hypertension 1999; 340: 1066-72). These data suggest that HFD is able to modify genic expression at atrial level. Thus, the aim of this work was to perform a systematic study of the genic expression profile in dogs made obese and hypertensive by 9 weeks of HFD. Blood pressure and heart rate were measured by telemetry implanted 15 days before starting regimen in 6 HFD and in 6 control dogs. HFD was the normal canine diet administered to controls but mixed with 300 g of beef fat. At the end of the experience, animals were sacrified and right atria were collected. Gene regulation was assessed in pooled tissue samples from both groups using suppressive substractive hybridization and microarray analysis. Genes with induction or repression rates of at least 20% when compared to controls were sequenced. As previously reported HFD induced a significant increase in body weight, blood pressure and heart rate when compared to controls. The results of SSH experiments led to the identification of 32 genes which are differentially regulated in atria from HFD dogs. Most are genes encoding proteins which have been previously shown to be regulated during various cardiopathies (MMP9, Na/K-ATPase 3...). These changes indicate the existence of early remodeling processes of atrial myocardium secondary to HFD. Other group of genes encodes proteins with no role identified in heart up today (lec-3, ERK-3, TRIP1, nucleophosmin...) or which function remains totally unknown. This work confirms that HFD is associated with early changes in gene expression in atrium. These changes are unlikely to be related to ventricular hypertrophy which is observed only during long-term HFD. Further studies are necessary to demonstrate the role of these modifications in the pathophysiological mechanisms leading to the increase in heart rate in this model of obesity-related arterial hypertension.