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Cell Physiology Core

$307,319P01FY2014HLNIH

University Of Virginia, Charlottesville VA

Investigators

Linked publications & trials

Abstract

Overall Program Project - Project Summary Inter-cellular communication between cells within a tissue environment is fundamentally important for many physiological processes. Channels and transmembrane transporters that conduct ions and other molecules across the plasma membrane in healthy living cells are also linked to pathologies of the cardiovascular and respiratory systems. Extracellular nucleltides (such as ATP) and their derivatires critically influence many aspects of vascular physiology such as vasoconstriction and blood pressure regulation, as well disease states such as metabolic syndromes. Recent exciting series of observations suggest that the pannexin proteins form channels on the plasma membrane, and by permeating ions and/or the release of nucleotides in a very regulated manner, these pannexin channels allow cells to communicate with other cells. Consistent with this, altered expression of pannexin channels have been linked to cardovascular and metabolic disorders. On an independent and inter-related set of observations, the pannexin channels also play a role in releasing nucleotides from early stage apoptotic cells that appear critical for communicating with phagocytes and in turn promoting prompt corpse removal. Since, failed clearance of dying cells is linked to atherosclerosis and airway inflammation, pannexin channels likely also play a role in regulating inflammation within tissues. The central hypothesis tested via this P01 application is that pannexin channels sit at a critical interphase between normal homeostasis within the cardiovascular system, and the disease states leading inflammation, atherosclerosis, and hypertension. The four projects that comprise this proposal address the role of pannexin channels as follows. Project 1 (Ravichandran) addresses the role of pannexin channels in cell death and recruitment of monocytes during atherosclerosis, cholesterol efflux, and in tissue inflammation; Project 2 (Isakson) addresses how pannexin channels in smooth muscle cells contribute to vasoconstriction in resistance vessels to regulate blood pressure and how this is altered in obesity; Project 3 (Leitinger) addresses how pannexin channels regulate adipocyte functions and the inflammation induced by dying adipocytes in obesity, insulin resistance and hypertension; Project 4 (Bayliss) addresses molecular mechanisms of pannexin channel activation in physiological and diseased states. With the combination of mouse models and ex vivo studies, and mechanistic approaches, and the preliminary identification of new compounds capable of altering Panx1 function, we expect to provide exciting new insights on pannexin channels and purinergic signaling in vascular physiology and hypertension, and provide the basis for novel treatment strategies targeting the regulated opening and closing of these channels in specific disease states. We expect this would have a broad impact to cardiovascular, metabolic, and respiratory diseases.

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