Intracranial-Extracranial Differences in the Ca2+ Sensitivity of Rabbit Arteries

Abstract

We have previously demonstrated that the ratio of calcium uptake to force production varies widely with age, artery size, and method of contraction in cerebral arteries. The present experiments were conducted to examine the possibility that these differences involve corresponding variations in contractile force-calcium relations. Common carotid (COM), basilar (BAS), and middle cerebral (MCA) arteries from adult were denuded of endothelium and mounted in vitro for measurement of contractility. Following equilibration at optimum resting diameter, the arteries were permeabilized (β-escin, 50 μg/ml) and depleted of intracellular Ca2+ by treatment with 1 μM A23187. Ca2+ depletion was verified by absence of any contracile response to either 25 mM caffeine or 1 μM inositol 1,4,5-trisphosphate. Then, in the continuous presence of 1 μM calmodulin, bath calcium concentration was raised from zero through 10 μM in half-log increments and the corresponding contractions were recorded. For all permeabilized arteries, the maximum force produced by 10 μM Ca was greater than or equal to that produced by 120 mM potassium-Krebs in the same segment before skinning. The pD2 (-log ED50) values for calcium averaged 6.39 ± 0.03, 6.77 ± 0.04, and 6.92 ± 0.03 in COM, BA, and MCA segments, respectively. In arteries contracted by a constant submaximal concentration of calcium (0.1 μM for BAS and MCA, 0.3 μM for COM), the addition of 5HT produced a dose-dependent and GDPβS-sensitive increase in tension of up to 44% maximum. GTPγS mimicked the effects of 5HT and prevented further increases in Ca force induced by 5HT. Together, these data demonstrate that cerebrovascular calcium sensitivity is an anatomically heterogenous, physiologically regulated parameter responsive to agonist-induced perturbations.