Differential contribution of endothelial function to vascular reactivity in conduit and resistance arteries from deoxycorticosterone-salt hypertensive rats.

The purpose of these studies was to compare changes in conduit and resistance artery function in deoxycorticosterone-salt hypertensive rats. We hypothesized that if there was a common mechanism producing changes in vascular function in hypertension, then there would be similar alterations in reactivity of conduit and resistance arteries. Helically cut strips of common carotid artery were prepared for measurement of isometric force generation, and segments of small mesenteric arteries were pressurized for video dimension analysis. Sensitivity of arteries to phenylephrine and acetylcholine was determined. Carotid arteries from deoxycorticosterone-salt hypertensive rats were more sensitive to phenylephrine than arteries from control rats, whereas mesenteric resistance arteries from hypertensive rats were less sensitive to phenylephrine. In carotid arteries, endothelial denudation or incubation with N psi-nitro-L-arginine increased phenylephrine sensitivity in control rats to the level seen in deoxycorticosterone-salt rats. These manipulations had no effect on phenylephrine sensitivity in arteries from deoxycorticosterone-salt rats. In mesenteric resistance arteries, endothelium denudation normalized the depressed phenylephrine sensitivity in arteries from hypertensive rats but had no effect on arteries from normotensive rats. This depressed phenylephrine sensitivity in deoxycorticosterone-salt mesenteric arteries was not reversed by incubation with Npsi-nitro-L-arginine. Acetylcholine-induced relaxation was depressed in carotid arteries from deoxycorticosterone-salt hypertensive rats, and Npsi-nitro-L-arginine blocked these relaxations. In contrast, acetylcholine relaxation in the mesenteric arteries from normotensive and hypertensive rats did not differ. N psi-nitro-L-arginine slightly but significantly attenuated acetylcholine dilation only in mesenteric resistance arteries from the hypertensive rats. We conclude that qualitatively different changes in vasoconstrictor sensitivity to phenylephrine occur in carotid arteries and mesenteric resistance arteries of deoxycorticosterone-salt hypertensive rats. The increased phenylephrine sensitivity in carotid arteries in this model of hypertension is due to the loss of endothelium-derived nitric oxide production. In contrast, the decreased phenylephrine sensitivity in mesenteric resistance arteries from deoxy-corticosterone-salt rats is due to a non-nitric oxide-mediated influence of the endothelium that is absent in arteries from normotensive rats.

Diethyldithiocarbamate ameliorates the effect of lipopolysaccharide on both increased nitrite production by vascular smooth muscle cells and decreased contractile response of aortic rings.

The depression of vasoconstrictor responsiveness caused by bacterial lipopolysaccharide (LPS) is mediated, in part, by the induction of nitric oxide synthase (NOS) and the resultant increase in nitric oxide production by vascular smooth muscle. The present study evaluated the ability of the antioxidant, diethyldithiocarbamate (DDTC), to attenuate the LPS-stimulated induction of NOS in cultured vascular smooth muscle cells (VSMC) and the depression of in vitro vascular reactivity caused by LPS administration to rats. The LPS-stimulated increase in nitrite production by cultured VSMC was inhibited 85% by DDTC (100 microM). When VSMC were stimulated with a combination of LPS, interferon-gamma (INF) and tumor necrosis factor (TNF) nitrite production was 5-fold greater than with LPS alone. DDTC inhibited 49% of the increase caused by LPS plus INF and TNF. Aortic rings taken from animals injected with LPS showed a depression of maximum force in response to phenylephrine which was reversed by inhibition of NOS activity. Pretreatment of animals with DDTC attenuated this depression of vascular reactivity. The DDTC treatment did not reduce the increase in serum TNF levels caused by LPS. These results suggest that DDTC can attenuate the LPS-stimulated induction of NOS in vascular smooth muscle and may thereby ameliorate the impairment of vascular reactivity.

The antioxidant, U74389, ameliorates the depression of vascular reactivity caused by lipopolysaccharide.

There is growing evidence that an oxidant stress contributes to the deleterious effects of bacterial lipopolysaccharide (LPS). The present study evaluated the ability of the antioxidant, U74389, to prevent the depression of vascular reactivity caused by LPS. Aortic rings taken from rats given LPS showed a depression of maximum force in response to phenylephrine that was reversed by an inhibitor of nitric oxide synthase. Pretreatment of animals with U74389 attenuated this depression of vascular reactivity. U74389 did not limit the increase in serum tumor necrosis factor levels caused by LPS. These results show that U74389 can ameliorate the depression of vascular reactivity caused by LPS possibly by interfering with the induction of nitric oxide synthase.