Endothelial modulation and changes in endothelin pressor activity during hypoxia in the rat isolated perfused superior mesenteric arterial bed

Abstract

1 The isolated superior mesenteric arterial bed of the rat, perfused with Krebs-Henseleit solution containing 10 μm indomethacin, was used to study the effects of reducing dissolved O₂ tension on the pressor responses to endothelin-1, endothelin-3 and sarafotoxin S6b. The modulation of these responses by the endothelium was investigated by removing the intima with the detergent CHAPS and, for endothelin-1, by inhibiting nitric oxide production with N_ω-nitro-l-arginine methyl ester (l-NAME). Comparison was made with the effects of lowering O₂ tension on the pressor responses to noradrenaline and 5-hydroxytryptamine. 2 Lowering the perfusate O₂ tension from 551 ± 2 mmHg to 14.0 ± 0.5 mmHg did not change the ED₅₀ for endothelin-1 but its maximal responses (R_max) were increased by 2.1 and 2.7 fold, respectively, in the presence and absence of endothelium. The R_max values for endothelin-3 were also greater in hypoxia either in the presence (by 2.3 fold) or absence of the endothelium (by 1.6 times) but those for sarafotoxin S6b were only enhanced significantly by hypoxia in the absence of the intima. Hypoxia reduced the potencies of endothelin-3 and sarafotoxin S6b whether or not endothelium was present. 3 Endothelial destruction, whether in hypoxic or oxygenated conditions, increased the R_max values for endothelin-1 and endothelin-3; at both O₂ tensions those for endothelin-3 increased more than those for endothelin-1. The ED₅₀ for endothelin-1 was unchanged by destroying the endothelium but endothelin-3 was less potent in the absence of an endothelium than in its presence. Removal of the endothelium did not change the R_max for sarafotoxin S6b but increased its potency in both hypoxic and oxygenated tissues. 4 In hypoxia, and in the presence of both the endothelium and 100 μm l-NAME, the R_max for endothelin-1 was 1.6 times greater than that in hypoxia in the absence of l-NAME. Co-infusion of 100 μm l-arginine, but not of 100 μm d-arginine, with 100 μm l-NAME reversed this effect. The presence of l-NAME decreased the potency of endothelin-1. 5 Destroying the endothelium did not affect the R_max for noradrenaline in either oxygenated conditions or hypoxia. Changing O₂ tension when the endothelium was intact had no effect on the R_max but it was 11% greater in oxygenated, than in hypoxic, endothelium denuded preparations. Endothelial destruction decreased the potency of noradrenaline in hypoxia but increased it in oxygenated tissues. In hypoxia, l-NAME had no effect on the ED₅₀ relative to control preparations with endothelium but the R_max was 30% greater. 6 5-Hydroxytryptamine gave very small pressor responses in the presence of endothelium in both oxygenated and hypoxic tissues but the R_max was 1.7 times greater in hypoxia. l-NAME increased the R_max by 9.8 times in oxygenated preparations and 6.3 fold in hypoxia. The ED₅₀ values were the same in all conditions. 7 It is concluded that, although hypoxia generally increased the R_max for the endothelin/sarafotoxin peptides, the changes could not be explained by a simple increase in receptor number since hypoxia decreased the potency of endothelin-3 and sarafotoxin S6b. Thus alterations in receptor binding or activation properties, or both, also occurred. The changes associated with hypoxia were not common to all vasoconstrictor agonists since, in the absence of endothelial function, hypoxia did not affect the R_max values for either noradrenaline or 5-hydroxytryptamine. Also, the pressor responses to the peptides and both the amines can be modulated by the endothelium in hypoxia as well as in oxygenated conditions.