Increase in Functional Ca2+ Channels in Cerebral Smooth Muscle With Renal Hypertension

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Circulation Research. 1998;82:1330-1337

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(Circulation Research. 1998;82:1330-1337.)
© 1998 American Heart Association, Inc.

Original Contributions

Increase in Functional Ca²⁺ Channels in Cerebral Smooth Muscle With Renal Hypertension

J. Marc Simard, Xing Li, , Kirti Tewari

From the Departments of Neurosurgery and Physiology, University of Maryland School of Medicine, Baltimore, Md.

Abstract—The hypothesis that availability of functionalCa²⁺ channels in vascular smooth muscle is augmented in hypertensionwas tested in basilar artery cells from Wistar rats exhibitingstable systolic blood pressure (BP_sys) for 2 to 11 weeks afterpartial renal artery ligation (Goldblatt 2-kidney 1-clip [2K1C]model). Cells were freshly isolated and patch-clamped usinga nystatin–perforated patch method. BP_sys ranged from110 to 280 mm Hg and correlated with normalized kidney mass.Macroscopic current-voltage curves were fit to a Boltzmann functionto obtain maximum conductance (g_max), steepness and midpointpotential for the voltage dependence of activation (k and E_1/2,respectively), and extrapolated reversal potential for the chordconductance (E_rev). Linear regression of normalized conductance (ng_max=g_max/cellcapacitance) versus BP_sys for 103 cells indicated a strong relationship,with a slope of 0.0019 nS · pF^-1 · mm Hg^-1 (P<0.0001).Similar analysis of data from 35 other cells exposed to 500nmol/L Bay K 8644 gave a slope of 0.0041 nS · pF^-1 ·mm Hg^-1 (P=0.001). Voltage-dependent parameters, k, E_1/2, and E_rev,were not significantly related to BP_sys. Single-channel measurementsin cell-attached patches revealed that the number of channelsin 32 patches was significantly related to BP_sys (P=0.0024)but that slope conductance, open dwell times at 0 mV, and distributionbetween 2 open states were not. Finally, in a subgroup of 61cells from animals made hypertensive (180 mm Hg<BP_sys<200mm Hg) for ${approx}$ 1/2 to 6 weeks, we found that elevation of ng_maxdepended on duration of hypertension (P=0.003), with no elevationat ${approx}$ 1/2 week. We conclude that in the 2K1C model, availabilityof functional Ca²⁺ channels increases with BP_sys with no changein channel properties and that measurable BP_sys elevation occursbefore the increase in functional channels.

Key Words: hypertension • Goldblatt model • two-kidney one-clip model • Ca²⁺ channel • smooth muscle cell

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