Veratridine (VTD), a selective activator of voltage-gated Na + (Nav) channels, triggers contractile responses in mesenteric arteries (MA), by increasing intracellular Ca2+ mediated by Na + /Ca 2+ exchanger (NCX) in smooth muscle cells (SMC). However, VTD induces endothelium-dependent relaxation of retinal and cremaster arteries. These opposite VTD-responses gives rise to the question as to whether Nav channels play a role in vascular tone. We aim to characterize the contribution of Nav channels to vascular tone in MA. Since Nav channels are expressed in SMC, endothelial cells (EC) and nerve terminal endings of arteries, our aim is also to identify those which are responsible of VTD-evoked vasomotor responses. The VTD-induced contractile responses of first order mesenteric arteries (FOMA) and cecolic arteries (CA) of mice were recorded by wire myography. EC were used to characterize Ca 2+ responses using FURA-2 probe. Western blot and absolute RT-qPCR were used to characterize Nav channels and NCX expression. Nav1.2 channels are expressed in both SMC and EC of MA. VTD elicits contraction of FOMA, which is abolished by prazosin. Surprisingly, VTD induces relaxation of CA. This vasorelaxation is resistant to prazosin and supressed by atropine. VTD-induced relaxation is inhibited by eNO-synthase inhibitor (L-NNA) and NCX antagonists. Morever, NCX1 is the main NCX isoform expressed in EC. Finally, acetylcholine-induced Ca 2+ reponses are inhibited by NCX antagonists in endothelial cells. VTD induces opposite contractile responses in isolated mesenteric arteries. In fact, VTD activates Nav channels of sympathetic neurons in FOMA, and parasympathetic neurons in CA, leading to noradrenaline and acetylcholine release, respectively. Thus, the vascular tone of both arteries are differently regulated by the autonomic nervous system. Finally, acetylcholine triggers Ca 2+ -activation of eNO-synthase mediated by NCX1 in CA.