Link between free radicals and protein kinase C in glucose-induced alteration of vascular dilation

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Development of vascular complications in diabetes has been linked to the quality of glucose regulation and characterized by endothelial dysfunction. The exact mechanism behind vascular complications in diabetes is poorly understood. However, alteration of nitric oxide (NO) biosynthesis or bioactivity is strongly implicated and the mechanism behind such alterations is still a subject for research investigations. In the present study, we tested the hypothesis that glucose-induced attenuation of vascular relaxation involves protein kinase C (PKC)-linked generation of free radicals. Vascular relaxation to acetylcholine (ACh; 10 −9–10 −5 M), isoproterenol (10 −9–10 −5 M), or NO donor, sodium nitropruside (SNP; 10 −9–10 −6 M) was determined in phenylephrine (PE, 10 −7 M) pre-constricted aortic rings from Sprague-Dawley rats in the presence or absence of 30 mM glucose (30 min), L-nitro-arginine methyl ester (L-NAME; 10 −4 M for 15 min), a NO synthase inhibitor, or xanthine (10 −5 M), a free radical generator. ACh dose-dependently caused relaxation that was attenuated by L-NAME, glucose, or xanthine. Pre-incubation (15 min) of the rings with vitamin C (10 −4 M), an antioxidant or calphostin C (10 −6 M), a PKC inhibitor, restored the ACh responses. However, high glucose had no significant effects on SNP or isoproterenol-induced relaxation. ACh-induced NO production by aortic ring was significantly reduced by glucose or xanthine. The reduced NO production was restored by pretreatment with vitamin C or calphostin C in the presence of glucose, but not xanthine. These data demonstrate that oxidants or PKC contribute to glucose-induced attenuation of vasorelaxation which could be mediated via impaired endothelial NO production and bioavailability. Thus, pathogenesis of glucose-induced vasculopathy involves PKC-coupled generation of oxygen free radicals which inhibit NO production and selectively inhibit NO-dependent relaxation.