Reduction of Ca(2+) channel activity by hypoxia in human and porcine coronary myocytes.

OBJECTIVE: Oxygen (O(2)) tension is a major regulator of blood flow in the coronary circulation. Hypoxia can produce vasodilation through activation of ATP regulated K(+) (K(ATP)) channels in the myocyte membrane, which leads to hyperpolarization and closure of voltage-gated Ca(2+) channels. However, there are other O(2)-sensitive mechanisms intrinsic to the vascular smooth muscle since hypoxia can relax vessels precontracted with high extracellular K(+), a condition that prevents hyperpolarization following opening of K(+) channels. The objective of the present study was to determine whether inhibition of Ca(2+) influx through voltage-dependent channels participates in the response of coronary myocytes to hypoxia. METHODS: Experiments were performed on porcine anterior descendent coronary arterial rings and on enzymatically dispersed human and porcine myocytes of the same artery. Cytosolic [Ca(2+)] was measured by microfluorimetry and whole-cell currents were recorded with the patch clamp technique. RESULTS: Hypoxia (O(2) tension approximately 20 mmHg) dilated endothelium-denuded porcine coronary arterial rings precontracted with high K(+) in the presence of glibenclamide (5 microM), a blocker of K(ATP) channels. In dispersed human and porcine myocytes, low O(2) tension decreased basal cytosolic [Ca(2+)] and transmembrane Ca(2+) influx independently of K(+) channel activation. In patch clamped cells, hypoxia reversibly inhibited L-type Ca(2+) channels. RT-PCR indicated that rHT is the predominant mRNA variant of the alpha(1C) Ca(2+) channel subunit in human coronary myocytes. CONCLUSION: Our study demonstrates, for the first time in a human preparation, that voltage-gated Ca(2+)channels in coronary myocytes are under control of O(2) tension.

Pore mutations in Shaker K+ channels distinguish between the sites of tetraethylammonium blockade and C-type inactivation.

1. We have studied the effect of external K+ and tetraethylammonium (TEA) on several mutants of Shaker B K+ channels with amino acid substitutions in the pore which alter TEA affinity and the rate of C-type inactivation. In all channels studied high external K+ makes C-type inactivation slower. 2. In the wild-type channel, TEA blockade is voltage dependent and produces slowing of the inactivation time course. However, in the double mutant channel (T449Y, D447E) TEA blockade, although of higher affinity, is voltage independent and does not affect the rate of C-type inactivation. 3. Mutants with a charged amino acid at position 449 (T449K and T449E) are resistant to TEA block. In these channels, C-type inactivation is also unaffected by TEA. 4. These results indicate that the sites where TEA blocks and competes with C-type inactivation can be segregated. To modulate inactivation, TEA must enter deeply into the channel mouth. These results suggest that C-type inactivation is not due to a large molecular rearrangement in the outer channel vestibule, but it is essentially produced by a conformational change restricted to a local site in the pore.