Cyclic GMP-independent mechanisms of nitric oxide-induced vasodilation.

1. The aim of the present study was to test in vitro if NO acts through a cyclic GMP-independent mechanism to activate Ca2+-dependent potassium channels (K+(Ca)), leading to membrane hyperpolarization and vasodilation in rat tail artery. 2. Acetylcholine and sodium nitroprusside stimulated a significant increase in cyclic GMP (190+/-23 and 180+/-15 pmol/g, respectively) compared with agonist-free conditions (132+/-15 and 130+/-15 pmol/g, respectively); these agonist-mediated increases in cyclic GMP were completely abolished by treatment with the guanylate cyclase inhibitor methylene blue (122+/-10 and 60+/-8 pmol/g, respectively). 3. In contrast, relaxation to acetylcholine (10(-7) mol/l; 61+/-3%) and sodium nitroprusside (10(-8) mol/l; 97+/-1%) were significantly, but not completely, attenuated by methylene blue (30+/-5 and 79+/-3%, respectively); maximum relaxation to sodium nitroprusside (10(-7) mol/l) was unaffected by methylene blue. 4. Depolarization-induced contraction of vessels with KCl inhibited relaxation to both acetylcholine (10(-7) mol/l; 18+/-4%) and sodium nitroprusside (10(-8) mol/l; 57+/-7%). Furthermore, the specific K+(Ca) antagonist charybdotoxin significantly inhibited relaxation to sodium nitroprusside (10(-8) mol/l; 52+/-7%). 5. An additive inhibitory effect on relaxation to sodium nitroprusside (10(-8) mol/l) was observed with a combination of methylene blue and KCl (26+/-6%) or charybdotoxin (34+/-3%). 6. These data suggest that NO stimulates membrane hyperpolarization via K+(Ca) activation, in addition to guanylate cyclase, to cause relaxation in rat tail artery.

Vascular responses to sodium arachidonate in experimental hypertension.

This study characterizes vascular responsiveness to sodium arachidonate (C 20:4) in four models of hypertension [deoxycorticosterone acetate (DOCA) hypertensive rats, two kidney-one clip (2K-1C) renal hypertensive rats, spontaneously hypertensive rats (SHR), and psychosocial hypertensive mice]. Isolated arterial strips (aorta, mesenteric artery, tail artery) were equilibrated under optimal resting tension in physiological salt solution for measurement of isometric force generation. Dose-response curves to arachidonate (10(-10) to 10(-4) g/ml) in arteries from DOCA and 2K-1C hypertensive rats were shifted to the left compared to those in arteries from control rats. In arteries from SHR and psychosocial hypertensive mice, the dose-response relationships were unchanged compared to normotensive values. Arteries from DOCA hypertensive and 2K-1C hypertensive rats developed greater maximal contractile responses to arachidonate than controls; maximal responses in arteries from SHR and psychosocial hypertensive mice were unchanged compared to normotensive values. Contractions to arachidonate were inhibited by indomethacin (0.5 and 5 micrograms/ml) and by aspirin (5 and 50 micrograms/ml). The fatty acid, oleate (C 18:1), had no effect on the contractile state of the arteries, whereas prostaglandin F2 alpha caused contraction. These results indicate altered responsiveness to exogenous arachidonate in arteries from DOCA and 2K-1C hypertensive rats, but not in arteries from SHR and psychosocial hypertensive mice.

Vascular reactivity and high dietary eicosapentaenoic acid.

Epidemiologic studies suggest that high dietary intake of eicosapentaenoic acid (EPA), a precursor of the trienoic prostaglandins, is associated with a low incidence and reduced extent of myocardial infarction. Vascular reactivity of isolated aortic strips from rats maintained for 3 weeks on a control diet or on a diet supplemented with menhaden fish oil (17% EPA) was examined with norepinephrine, sodium arachidonate, KC1, PGF2 alpha and nitroprusside. Aortic strips from rats fed the fish oil diet were significantly less responsive to the contractile effects of norepinephrine and arachidonate compared to those from control diet rats. Treatment of aortic strips with indomethacin decreased responsiveness to norepinephrine. The magnitude of the decrease was greater in control rats resulting in a similar vascular response between the 2 groups after blockade. Contractions to arachidonate were abolished by indomethacin. There were no differences in vascular responses to KC1, PGF2 alpha and nitroprusside in aortic strips from control diet rats and those from the fish oil diet rats. Aortic strips from the fish oil diet rats contained more EPA than those from the control diet rats. Thus, the contractile effect of norepinephrine in isolated rat aortic strips is normally augmented by intrinsic prostaglandins, and this augmentation is diminished by dietary intake of EPA.

Prostaglandins and potassium relaxation in vascular smooth muscle of the rat. The role of Na-K ATPase.

We explored the hypothesis that postaglandin-induced vasodilation is caused by activation of the electrogenic sodium-potassium pump which results in membrane hyperpolarization and relaxation of vascular smooth muscle. Helical strips of rat tail artery relax in response to potassium after norepinephrine-induced contractions in physiological salt solution containing a low-potassium concentration. The amplitude of this potassium relaxation is used as an index of sodium-potassium ATPase activity. It was observed that PGA1, PGE2, and PGF2alpha (10(-6) g/ml) significantly enhanced the magnitut. PGE2 caused relaxation of contractions induced by either 25 mM KCl or norepinephrine (10(-9) g/ml), and these relaxations were inhibited by 10(-4) M ouabain. Indomethacin (5.3 x 10(-6) g/ml) and meclofenamate (10(-6) g/ml) reduced the magnitude of potassium-induced relaxation by more than 30% of control. PGF2alpha (10(-5) g/ml) reversed the inhibition of potassium relaxation by meclofenamate. These observations suggest that prostaglandins induce vascular smooth muscle relaxation by stimulation of the sodium pump and that endogenous prostaglandins normally potassium relaxation.