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Endothelial potassium channels, endothelium‐dependent hyperpolarization and the regulation of vascular tone in health and disease
Author(s) -
Coleman Harold A,
Tare Marianne,
Parkington Helena C
Publication year - 2004
Publication title -
clinical and experimental pharmacology and physiology
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.752
H-Index - 103
eISSN - 1440-1681
pISSN - 0305-1870
DOI - 10.1111/j.1440-1681.2004.04053.x
Subject(s) - apamin , charybdotoxin , hyperpolarization (physics) , potassium channel , biophysics , endothelium derived hyperpolarizing factor , chemistry , endothelium , membrane potential , calcium activated potassium channel , medicine , biology , stereochemistry , nuclear magnetic resonance spectroscopy
Summary 1. The elusive nature of endothelium‐derived hyperpolarizing factor (EDHF) has hampered detailed study of the ionic mechanisms that underlie the EDHF hyperpolarization and relaxation. Most studies have relied on a pharmacological approach in which interpretations of results can be confounded by limited specificity of action of the drugs used. Nevertheless, small‐, intermediate‐ and large‐conductance Ca 2+ ‐activated K + channels (SK Ca , IK Ca and BK Ca , respectively) have been implicated, with inward rectifier K + channels (K IR ) and Na + /K + ‐ATPase also suggested by some studies. 2. Endothelium‐dependent membrane currents recorded using single‐electrode voltage‐clamp from electrically short lengths of arterioles in which the smooth muscle and endothelial cells remained in their normal functional relationship have provided useful insights into the mechanisms mediating EDHF. Charybdotoxin (ChTx) or apamin reduced, whereas apamin plus ChTx abolished, the EDHF current. The ChTx‐ and apamin‐sensitive currents both reversed near the expected K + equilibrium potential, were weakly outwardly rectifying and displayed little, if any, time‐ or voltage‐dependent gating, thus having the biophysical and pharmacological characteristics of IK Ca and SK Ca channels, respectively. 3. The IK Ca and SK Ca channels occur in abundance in endothelial cells and their activation results in EDHF‐like hyperpolarization of these cells. There is little evidence for a significant number of these channels in healthy, contractile vascular smooth muscle cells. 4. In a number of blood vessels in which EDHF occurs, the endothelial and smooth muscle cells are coupled electrically via myoendothelial gap junctions. In contrast, in the adult rat femoral artery, in which the smooth muscle and endothelial layers are not coupled electrically, EDHF does not occur, even though acetylcholine evokes hyperpolarization in the endothelial cells. 5. In vivo studies indicate that EDHF contributes little to basal conductance of the vasculature, but it contributes appreciably to evoked increases in conductance. 6. Endothelium‐derived hyperpolarizing factor responses are diminished in some diseases, including hypertension, pre‐eclampsia and some models of diabetes. 7. The most economical explanation for EDHF in vitro and in vivo in small vessels is that it arises from the activation of IK Ca and SK Ca channels in endothelial cells. The resulting endothelial hyperpolarization spreads via myoendothelial gap junctions to result in the EDHF‐attributed hyperpolarization and relaxation of the smooth muscle.