Endothelial connexin hemichannels as a novel endothelial regulatory mechanism of vasodilation

Abstract

The vascular endothelium regulates vasomotor tone in arterioles through intercellular conduction of electrical signals by gap junctions. Endothelial vasodilation is mediated by nitric oxide (NO) and by a hyperpolarizing current initiated in the endothelium. Both signals are transmitted to smooth muscle cells evoking relaxation. Endothelial cells express connexin (Cx) 37,40,43. Cx hemichannels allow the exchange of ions and molecules between intracellular and extracellular compartments that may be associated with endothelial electrical activity. Whether or not Cx hemichannels regulate vasomotor tone is unknown. We evaluated the role of Cx‐hemichannels in the vasodilation process by measuring dye uptake in primary culture of endothelial cells and in isolated mouse mesenteric arterioles. We detected that both acetylcholine (ACh) and bradykinin (BK) increase dye permeability, which was inhibited by connexin mimetic peptides that block Cx43 hemichannels (Gap19). We determined that NO mediates Cx43 hemichannels activity inasmuch as blocking NOS inhibits hemichannel activity. Using biotin switch assay, we observed that ACh induced S‐nitrosylation only in Cx43 at cysteine 271. ACh and BK open endothelial Cx43 hemichannels activity and promote endothelial Ca2+entry from the extracellular space and lead to endothelium hyperpolarization signaling in isolated mesenteric arteries. Blocking Cx43‐hemichannels reduces calcium entry and hyperpolarization. To further assess the physiological role of Cx43 endothelial hemichannels activity, we cannulated isolated mesenteric arterioles and studied ACh‐induced arteriolar relaxation in the presence and absence of connexin mimetic peptides that block Cx43 hemichannels (Gap19) and Cx40 (40Gap 27, a connexin mimetic peptide). Gap19 attenuates ACh‐induced relaxation, but 40Gap27 fails to reduce relaxation. These results indicate that endothelial Cx43 hemichannels participate in arteriolar dilatation. In addition, we replaced cysteine 271 by serine to create a Cx43C271S mouse that failed to cause S‐nitrosylation of Cx43. We detected that this knockin mouse displayed hypertension compared to wild type mice, indicating that Cx43 hemichannels and S‐nitrosylated Cx43 play a role in vascular resistance. Our results suggest that Cx43 hemichannels are a potential therapeutic target in hypertension and vascular disease.