Endothelial Membrane Potential Changes are Required for Propagated Vasodilation

Abstract

Introduction: The coordination of blood flow in response to localized increases in metabolic activity is vital for tissue function. This adaptive response typically involves the release of vasoactive factors leading to local vasodilation. This local vasodilation must propagate upstream to proximal feed arterioles and arteries to ensure a coordinated increase in blood flow and adequate tissue perfusion. But the mechanisms underlying such propagated vasodilation remain to be fully understood. This study aims to identify the conduction pathway(s) that facilitate this response. The hypothesis is that endothelial membrane potential changes are required for propagated vasodilation to occur. Methods: To dissect the pathways involved in propagated vasodilation, we employed micropuffng techniques to locally apply vasoactive agents to precontracted rat 2nd order mesenteric arteries. Using a 50um tip micropipette activators were applied against a flowing perfusate, to limit the action of the drug, and the precise site of activators determined by co-application of the fluorophore sulforhodamine. Vasodilator responses were recorded at the site of application and at intervals upstream from the application site. Results: Local application of the muscarinic receptor agonist, acetylcholine (ACh), evoked robust vasodilator responses that propagated upstream from the site of application. The propagation of vasodilation terminated at the site of removal of a 100uM wide strip of endothelial cells. A high-potassium solution, which induces depolarization and ‘clamps’ the membrane potential, also inhibited propagated vasodilation. In contrast, the nitric oxide donor, sodium nitroprusside did not initiate propagated vasodilation in arteries with an intact endothelium. Conclusion: Collectively, these results show that the endothelium serves as the primary signalling pathways for propagated vasodilation. Furthermore, our results highlight the necessity of endothelial cell membrane potential change in the initiation of this vasodilator signal. These insights reinforce the endothelium’s pivotal role in coordinating vascular function. British Heart Foundation. This is the full abstract presented at the American Physiology Summit 2024 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.