ACh-induced endothelial NO synthase translocation, NO release and vasodilation in the hamster microcirculation in vivo

Studies in cultured cells show that activation of endothelial nitric oxide (NO) synthase (eNOS) requires the dissociation of this enzyme from its inhibitory association with caveolin-1 (Cav-1), and perhaps its translocation from plasma membrane caveolae to other cellular compartments. We investigated the hypothesis that in vivo NO-dependent vasodilatation is associated with the translocation of eNOS from the cell membrane. To this end, we applied ACh topically (10-100, μM for 10 min) to the hamster cheek pouch microcirculation and measured NO production, blood flow and vessel diameter, and assessed subcellular eNOS distribution by Western blotting. Baseline NO production was 54.4 ± 5.2 pmol min^- (n = 16). ACh increased NO release, caused arteriolar and venular dilatation and elevated microvascular flow. These responses were inhibited by N^G-nitro-L-arginine (30 μM). The maximal increase in NO production induced by 10 μM and 100 μM ACh was 45 ± 20% and 111 ± 33%, respectively; the corresponding blood flow increases were 50 ± 10% and 130 ± 24%, respectively (n = 4-6). Both responses followed a similar time course, although increases in NO preceded flow changes. In non-stimulated tissues, eNOS was distributed mainly in the microsomal fraction. ACh-induced vasodilatation was associated with eNOS translocation to the cytosolic and Golgi-enriched fractions. After 1.5, 3.0 or 6.0 min of application, 10, μM ACh decreased the level of membrane-bound eNOS by -13 ± 4%, -60 ± 4% and -19 ± 17%, respectively; at the same time points, 100 μM ACh reduced microsomal eNOS content by -38 ± 9% -61 ± 16% and -40 ± 18%, respectively (n = 4-5). In all cases, microsomal Cav-1 content did not change. The close ACh concentration dependence and the concomitance between eNOS subcellular redistribution and NO release support the concept that eNOS translocation from the plasma membrane is part of an activation mechanism that induces NO-dependent vasodilatation in vivo.