Alteration of Volume-Regulated Chloride Movement in Rat Cerebrovascular Smooth Muscle Cells During Hypertension

Abstract

The cerebrovascular remodeling is a prominent feature of hypertension and considered a major risk factor for stroke. Cerebrovascular smooth muscle cells meet volume challenge during this pathophysiological process. Our previous studies suggest that volume regulated chloride channels may be critical to the cell cycle of vascular smooth muscle cells. However, it is unknown whether the volume-regulated chloride movement is altered in hypertension. Therefore, we directly measured the concentration of intracellular chloride ([Cl − ] i ) in rat basilar arterial smooth muscle cells isolated from control rats and rats that were made hypertensive for 1 to 12 weeks after partial renal artery constriction (2-kidney, 2-clip method) using a 6-methoxy- N -ethylquinolinium iodide fluorescence probe. The [Cl − ] i in isotonic solution showed no difference in all of the groups. After hypotonic perfusion, the reduction in [Cl − ] i was more prominent in hypertensive cerebrovascular smooth muscle cells than in sham control cells. Genistein, a protein tyrosine kinase inhibitor, inhibited hypotonic-induced reduction in [Cl − ] i , whereas sodium orthovanadate, a protein–tyrosine phosphatase inhibitor, enhanced hypotonic-induced reduction in [Cl − ] i in both groups. The percentage inhibition of reduction in [Cl − ] i by genistein on volume-regulated chloride movement has a positive correlation with blood pressure levels in the 2-kidney, 2-clip hypertensive group, as is the case for the percentage increase of reduction in [Cl − ] i by sodium orthovanadate. Antihypertensive therapy with the angiotensin-converting enzyme inhibitor captopril completely reversed abnormal volume-regulated chloride movement in hypertensive rats. We conclude that volume-regulated chloride movement is augmented in rat cerebrovascular smooth muscle cells in proportion to the severity of hypertension.