Ca(V)1.2/Ca(V)3.x channels mediate divergent vasomotor responses in human cerebral arteries

The regulation of arterial tone is critical in the spatial and temporal control of cerebral blood flow. Voltage-gated Ca(2+) (Ca(V)) channels are key regulators of excitation–contraction coupling in arterial smooth muscle, and thereby of arterial tone. Although L- and T-type Ca(V) channels have been identified in rodent smooth muscle, little is known about the expression and function of specific Ca(V) subtypes in human arteries. Here, we determined which Ca(V) subtypes are present in human cerebral arteries and defined their roles in determining arterial tone. Quantitative polymerase chain reaction and Western blot analysis, respectively, identified mRNA and protein for L- and T-type channels in smooth muscle of cerebral arteries harvested from patients undergoing resection surgery. Analogous to rodents, Ca(V)1.2 (L-type) and Ca(V)3.2 (T-type) α(1) subunits were expressed in human cerebral arterial smooth muscle; intriguingly, the Ca(V)3.1 (T-type) subtype present in rodents was replaced with a different T-type isoform, Ca(V)3.3, in humans. Using established pharmacological and electrophysiological tools, we separated and characterized the unique profiles of Ca(2+) channel subtypes. Pressurized vessel myography identified a key role for Ca(V)1.2 and Ca(V)3.3 channels in mediating cerebral arterial constriction, with the former and latter predominating at higher and lower intraluminal pressures, respectively. In contrast, Ca(V)3.2 antagonized arterial tone through downstream regulation of the large-conductance Ca(2+)-activated K(+) channel. Computational analysis indicated that each Ca(2+) channel subtype will uniquely contribute to the dynamic regulation of cerebral blood flow. In conclusion, this study documents the expression of three distinct Ca(2+) channel subtypes in human cerebral arteries and further shows how they act together to orchestrate arterial tone.