Electrophysiological study on rat conduit pulmonary artery smooth muscle cells under normoxia and acute hypoxia.
- Author:
Ying HU
1
;
Fei ZOU
;
Chun-Qing CAI
;
Hang-Yu WU
;
Hai-Xia YUN
;
Yun-Tian CHEN
;
Guo-En JIN
;
Ri-Li GE
Author Information
1. Research Center For High Altitude Medicine of Qinghai University, Xining 810001, China.
- Publication Type:Journal Article
- MeSH:
4-Aminopyridine;
pharmacology;
Animals;
Calcium;
metabolism;
Cell Hypoxia;
Male;
Membrane Potentials;
drug effects;
Muscle, Smooth, Vascular;
cytology;
physiology;
Myocytes, Smooth Muscle;
physiology;
Peptides;
pharmacology;
Potassium Channels;
physiology;
Pulmonary Artery;
cytology;
physiology;
Rats;
Rats, Sprague-Dawley
- From:
Acta Physiologica Sinica
2006;58(5):477-482
- CountryChina
- Language:Chinese
-
Abstract:
The present study was designed to investigate the electrophysiological characteristics of rat conduit pulmonary artery smooth muscle cells (PASMCs) and the response to acute hypoxia. PASMCs of the 1st to 2nd order branches in the conduit pulmonary arteries were obtained by enzymatic isolation. The PASMCs were divided into acute hypoxia preconditioned group and normoxia group. Hypoxia solutions were achieved by bubbling with 5% CO2 plus 95% N2 for at least 30 min before cell perfusion. Potassium currents were compared between these two groups using whole-cell patch clamp technique. The total outward current of PASMCs was measured under normoxia condition when iBTX [specific blocking agent of large conductance Ca-activated K(+) (BK(Ca)) channel] and 4-AP [specific blocking agent of delayed rectifier K(+) (K(DR)) channel] were added consequently into bath solution. PASMCs were classified into three types according to their size, shape and electrophysiological characteristics. Type I cells are the smallest with spindle shape, smooth surface and discrete perinuclear bulge. Type II cells show the biggest size with banana-like appearance. Type III cells have the similar size with type I, and present intermediary shape between type I and type II. iBTX had little effect on the total outward current in type I cells, while 4-AP almost completely blocked it. Most of the total outward current in type II cells was inhibited by iBTX, and the remaining was sensitive to 4-AP. In type III cells, the total outward current was sensitive to both iBTX and 4-AP. Acute hypoxia reduced the current in all three types of cells: (1614.8+/-62.5) pA to (892.4+/-33.6) pA for type I cells (P<0.01); (438.3+/-42.8) pA to (277.5+/-44.7) pA for type II cells (P<0.01); (1 042.0+/-37.2) pA to (613.6+/-23.8) pA for type III (P<0.01), and raised the resting membrane potentials (E(m)) in all these three types of cells: (-41.6+/-1.6) mV to (-18.6+/-1.5) mV (P<0.01), (-42.3+/-3.8) mV to (-30.6+/-3.0) mV (P<0.01), (-43.3+/-1.6) mV to (-28.4+/-1.4) mV (P<0.01), for type I, II, III cells, respectively. These results suggest that acute hypoxia suppresses the potassium current and improves the E(m) in PASMCs. These effects may be involved in the modulation of constriction/relaxation of conduit artery under acute hypoxia. Different distribution of K(DR) and BK(Ca) channels in these three types of PASMCs might account for their different constriction/relaxation response to acute hypoxia.
