Endothelium-dependent L-Arg- and L-NMMA-sensitive mechanisms regulate tone of brain microvessels.

Pial arterioles on the surface of the mouse brain were observed via television microscopy and measured with an image-splitting technique. The vessels were dilated by L-arginine (L-Arg) in concentrations as low as 10(-5) M and were constricted in dose-dependent manner by NG-monomethyl-L-arginine (L-NMMA). Both the dilation and the constriction were abolished by endothelial damage. This damage was produced over a short segment of endothelium by a well-established technique that involves exposing the endothelium to a helium-neon laser in the presence of intravascular Evans blue dye. In arterioles that were responsive to 10(-5) M L-Arg, five other L-amino acids, also at 10(-5) M, failed to have any effect. The data provide direct evidence for the endothelium-dependent nature of the responses to L-Arg and L-NMMA in vivo in a defined segment of the cerebral vasculature. L-NMMA inhibited dilation by either L-Arg or acetylcholine. The data are consistent with data from in vitro studies and from studies demonstrating that L-NMMA acutely raises blood pressure. From all these earlier studies it has been hypothesized that there is a continuously acting, endothelium-dependent, L-Arg-dependent, and L-NMMA-inhibitable mechanism tending to relax blood vessels. The mediator of this mechanism is thought to be the endothelium-dependent relaxing factor for acetylcholine. Our data suggest that this mechanism is acting in the resistance vessels of the brain in vivo.