Effects of chronic systemic hypoxia on contraction evoked by noradrenaline in the rat iliac artery.

Comparisons were made between responses evoked by noradrenaline (NA) in iliac artery rings from normoxic (N) rats and chronically hypoxic (CH) rats kept in 12 % O(2) for 3-4 weeks. At P(O(2)) of 100 mmHg, cumulative concentration-response curves (CCRC) to NA were greatly depressed in endothelium-intact (E+) rings, but not endothelium-denuded (E-) rings, of CH rats relative to N rats. However, CCRCs evoked by NA in E+ and E- rings during nitric oxide (NO) synthase inhibition were similar in N and CH rats. Reducing P(O(2)) to 55 mmHg depressed CCRCs to NA in E+ and E- rings of CH and N rats in the absence and presence of NO synthase inhibition. At P(O(2)) of 100 mmHg, CCRCs evoked by phenylephrine were comparable in E+ and E- rings of N and CH rats as were CCRCs for the relaxation evoked by isoprenaline, which were similarly rightward shifted by NO synthase inhibition. However, CCRCs evoked by the NO donor sodium nitroprusside were leftward shifted in E- rings of CH rats relative to N rats. Further, in the presence of the alpha(2) adrenoceptor inhibitor rauwolscine, CCRCs to NA were comparable in E+ rings of CH and N rats. Thus, the depressive effects of chronic hypoxia on NA-evoked contractions of iliac artery are additional to those of acute hypoxia. We propose that they reflect a facilitation of the contribution of NO to alpha(2) adrenoceptor-evoked relaxation that includes an increased sensitivity of the vascular smooth muscle of arteries from CH rats to NO.

Resolution of smooth muscle and endothelial pathways for conduction along hamster cheek pouch arterioles.

In the cheek pouch of anesthetized male hamsters, microiontophoresis of Ach (endothelium-dependent vasodilator) or phenylephrine (PE; smooth muscle-specific vasoconstrictor) onto an arteriole (resting diameter, 30-40 microm) evokes vasodilation or vasoconstriction (amplitude, 15-25 microm), respectively, that conducts along the arteriolar wall. In previous studies of conduction, endothelial and smooth muscle layers of the arteriolar wall have remained intact. We tested whether selective damage to endothelium or to smooth muscle would disrupt the initiation and conduction of vasodilation or vasoconstriction. Luminal (endothelial) or abluminal (smooth muscle) light-dye damage was produced within an arteriolar segment centered 500 microm upstream from the distal site of stimulation; conducted responses (amplitude, 10-15 microm) were observed at a proximal site located 1,000 microm upstream. Endothelial damage abolished local responses to ACh in the central segment without affecting those to PE. Nevertheless, ACh delivered at the distal site evoked vasodilation that conducted through the central segment and appeared unhindered at the proximal site. Smooth muscle damage inhibited responses to PE in the central segment and abolished the conduction of vasoconstriction but did not affect conducted vasodilation. We suggest that for cheek pouch arterioles in vivo, vasoconstriction to PE is initiated and conducted within the smooth muscle layer alone. In contrast, once vasodilation to ACh is initiated via intact endothelial cells, the signal is conducted along smooth muscle as well as endothelial cell layers.

Electrophysiological basis of arteriolar vasomotion in vivo.

We tested the hypothesis that cyclic changes in membrane potential (E(m)) underlie spontaneous vasomotion in cheek pouch arterioles of anesthetized hamsters. Diameter oscillations (approximately 3 min(-1)) were preceded (approximately 3 s) by oscillations in E(m) of smooth muscle cells (SMC) and endothelial cells (EC). Oscillations in E(m) were resolved into six phases: (1) a period (6 +/- 2 s) at the most negative E(m) observed during vasomotion (-46 +/- 2 mV) correlating (r = 0.87, p < 0.01) with time (8 +/- 2 s) at the largest diameter observed during vasomotion (41 +/- 2 microm); (2) a slow depolarization (1.8 +/- 0.2 mV s(-1)) with no diameter change; (3) a fast (9.1 +/- 0.8 mV s(-1)) depolarization (to -28 +/- 2 mV) and constriction; (4) a transient partial repolarization (3-4 mV); (5) a sustained (5 +/- 1 s) depolarization (-28 +/- 2 mV) correlating (r = 0.78, p < 0.01) with time (3 +/- 1 s) at the smallest diameter (27 +/- 2 microm) during vasomotion; (6) a slow repolarization (2.5 +/- 0.2 mV s(-1)) and relaxation. The absolute change in E(m) correlated (r = 0.60, p < 0.01) with the most negative E(m). Sodium nitroprusside or nifedipine caused sustained hyperpolarization and dilation, whereas tetraethylammonium or elevated PO(2) caused sustained depolarization and constriction. We suggest that vasomotion in vivo reflects spontaneous, cyclic changes in E(m) of SMC and EC corresponding with cation fluxes across plasma membranes.