Differential activation of potassium channels in cerebral and hindquarter arteries of rats during simulated microgravity

The purpose of this study was to test the hypothesis that differential autoregulation of cerebral and hindquarter arteries during simulated microgravity is mediated or modulated by differential activation of K + channels in vascular smooth muscle cells (VSMCs) of arteries in different anatomic regions. Sprague-Dawley rats were subjected to 1-and 4-wk tail suspension to simulate the cardiovascular deconditioning effect due to short- and medium-term microgravity. K+ channel function of VSMCs was studied by pharmacological methods and patch-clamp techniques. Large-conductance Ca2+-activated K+ (BKCa) and voltage-gated K+ (Kv) currents were determined by subtracting the current recorded after applications of 1 mM tetraethylammonium (TEA) and 1 mM TEA + 3 mM 4-aminopyridine (4-AP), respectively, from that of before. For cerebral vessels, the normalized contractility of basilar arterial rings to TEA, a BKCa blocker, and 4-AP, a Kv blocker, was significantly decreased after 1-and 4-wk simulated microgravity, respectively. VSMCs isolated from the middle cerebral artery branches of suspended rats had a more depolarized membrane potential (Em) and a smaller K+ current density compared with those of control rats. Furthermore, the reduced total current density was due to smaller BKCa and smaller K v current density in cerebral VSMCs after 1- and 4-wk tail suspension, respectively. For hindquarter vessels, VSMCs isolated from second- to sixth-order small mesenteric arteries of both 1 - and 4-wk suspended rats had a more negative Em and larger K+ current densities for total, BKCa, and Kv currents. These results indicate that differential activation of K+ channels occur in cerebral and hindquarter VSMCs during short- and medium-term simulated microgravity. It is further suggested that different profiles of channel remodeling might occur in VSMCs as one of the important underlying cellular mechanisms to mediate and modulate differential vascular adaptation during microgravity.