Functional interaction of AT1 and AT2 receptors in fructose-induced insulin resistance and hypertension in rats

Abstract

The present study was performed to evaluate the potential role and functional interaction of angiotensin II AT1 and AT2 receptors (AT1R and AT2R) in the regulation of blood pressure and glucose homeostasis in fructose-induced insulin-resistant, hypertensive rats. Male Sprague-Dawley rats on fructose-enriched or regular diets for 4 weeks were subjected to 2-step euglycemic euinsulinemic (EEI) and euglycemic hyperinsulinemic (EHI) clamp studies with [3- 3H]glucose infusion. After a 40-minute basal period, selective AT1R and AT2R antagonists, losartan (LOS, 10 mg/kg IV bolus) and PD123319 (PD, 50 μg/kg/min), alone or in combination were separately given to control and fructose-fed groups in the 2 clamp periods. The results showed that during the EEI period, LOS significantly reduced the elevated blood pressure in fructose-fed rats, whereas PD further increased fructose-induced high blood pressure. Coadministration of LOS and PD did not alter the elevated blood pressure in fructose-fed rats. Administration of LOS and/or PD failed to change the blood pressure in control rats. During the EHI period, blockade of both AT1R and AT2R eliminated the insulin-induced blood pressure elevation in control and fructose-fed rats. Hepatic glucose production (HGP) did not alter among groups in the basal and EEI periods. Insulin infusion (EHI period) markedly suppressed HGP in control rats, but this suppressive effect was significantly attenuated in fructose-fed rats. LOS administration further reduced the insulin-induced suppression of HGP in fructose-fed rats. The whole-body glucose uptakes (rates of glucose disappearance, R d) during the basal and EEI periods were similar among groups. During the EHI period, R d was markedly increased in all groups and the magnitude of increase was significantly greater in control rats than in fructose-fed rats except those with LOS treatment. LOS treatment also redirected R d in favor of glycolysis in fructose rats, but not in control rats, during the EEI and EHI periods. The effects of LOS on glycolysis during the 2 clamp periods and on HGP during the EHI period were reversed when PD was concomitantly administered, but PD alone did not alter glucose metabolism throughout the experiment in fructose-fed rats. Administration of LOS and/or PD did not change the glucose metabolism in control rats. Our data suggest that AT2R can counterbalance the AT1R-mediated effects on blood pressure and glucose metabolism in fructose-induced insulin-resistant, hypertensive rats. Furthermore, AT1R- and AT2R-mediated effects on blood pressure are disassociated with their actions on glucose metabolism in this hypertensive model.