This Program, consisting of four Projects and three Cores, focuses on parenchymal (intracerebral) arterioles, which distribute blood within the brain and exhibit unique, albeit poorly understood, properties. The overall goal Is to elucidate the molecular mechanisms by which the endothelium and smooth muscle (SM) of parenchymal arterioles (PAs) regulate vascular tone and neurovascular coupling (NVC) normally, and following ischemia/reperfusion (l/R) injury and subarachnoid hemorrhage (SAH). The central unifying theme is that the precise control of Ca^* signaling in cells composing the "cerebrovascular unit"? endothelium, SM and astrocytes?determines normal brain function;by extension, dysfunction of Ca^* signaling dynamics contributes to cerebrovascular disorders. Each project studies overlapping elements of the biological system to form a whole. Project 1 will provide the first information on properties and function of PA endothelial cells (ECs), exploring Ca^* signaling and Ca^*-sensitive SK and IK potassium channels and their impact on SM function and NVC. Project 2 will focus on parenchymal arteriolar SM, with an emphasis on voltage-dependent Ca^* channels (Cav) and transient receptor potential (TRP) channels. Projects 1 and 2 provide the platform for Projects 3 and 4. Project 3 will interact with Projects 1 and 2 to explore the underlying mechanistic basis for the profound changes in parenchymal arteriolar reactivity that develop following i/R, focusing on EC-SM changes in ion channel functionality. Project 4, which focuses on PAs and NVC following SAH, intersects with Project 2 on the effects of SAH on SM Cav and TRP channels, and with Project 1 on endothelial function and NVC. Because the endothelium and SM function physiologically as one entity, Projects 1 and 2 are inherently highly interdependent. Projects 3 and 4, which focus on dysregulation of cerebrovascular unit function under two divergent, but clinically relevant, pathological conditions, depend on information derived from Projects 1 and 2. The Imaging Core will provide state-of-the-art approaches for Ca^* measurements in complex systems. The Animal and Instrumentation Core will consolidate and coordinate all animal and in vivo work, including the development of novel genetically encoded, ratiometric Ca^* biosensors. The long-term objective is to understand blood flow in the brain in health and disease, and by doing so, to reveal exciting novel targets that can be exploited in the treatment of cerebrovascular disease.
This Program focuses on the small arteries within the brain, which are responsible for the moment-to moment health of the brain. Despite their importance, little is known about these arteries in health and disease. The Program will elucidate how these arteries function normally and after stroke and bleeding in the brain, and in doing so will reveal new therapeutic approaches to treat blood vessel disorders in the brain.
|Wallace, Kedra; Tremble, Sarah M; Owens, Michelle Y et al. (2015) Plasma from patients with HELLP syndrome increases blood-brain barrier permeability. Reprod Sci 22:278-84|
|Cipolla, Marilyn J; Sweet, Julie; Chan, Siu-Lung et al. (2014) Increased pressure-induced tone in rat parenchymal arterioles vs. middle cerebral arteries: role of ion channels and calcium sensitivity. J Appl Physiol (1985) 117:53-9|
|Longden, Thomas A; Dabertrand, Fabrice; Hill-Eubanks, David C et al. (2014) Stress-induced glucocorticoid signaling remodels neurovascular coupling through impairment of cerebrovascular inwardly rectifying K+ channel function. Proc Natl Acad Sci U S A 111:7462-7|
|Dunn, Kathryn M; Nelson, Mark T (2014) Neurovascular signaling in the brain and the pathological consequences of hypertension. Am J Physiol Heart Circ Physiol 306:H1-14|
|Cipolla, Marilyn J; Chan, Siu-Lung; Sweet, Julie et al. (2014) Postischemic reperfusion causes smooth muscle calcium sensitization and vasoconstriction of parenchymal arterioles. Stroke 45:2425-30|
|Mingin, Gerald C; Peterson, Abbey; Erickson, Cuixia Shi et al. (2014) Social stress induces changes in urinary bladder function, bladder NGF content, and generalized bladder inflammation in mice. Am J Physiol Regul Integr Comp Physiol 307:R893-900|
|Schreurs, Malou P H; Cipolla, Marilyn J (2014) Cerebrovascular dysfunction and blood-brain barrier permeability induced by oxidized LDL are prevented by apocynin and magnesium sulfate in female rats. J Cardiovasc Pharmacol 63:33-9|
|Krishnamoorthy, Gayathri; Sonkusare, Swapnil K; Heppner, Thomas J et al. (2014) Opposing roles of smooth muscle BK channels and ryanodine receptors in the regulation of nerve-evoked constriction of mesenteric resistance arteries. Am J Physiol Heart Circ Physiol 306:H981-8|
|Mercado, Jose; Baylie, Rachael; Navedo, Manuel F et al. (2014) Local control of TRPV4 channels by AKAP150-targeted PKC in arterial smooth muscle. J Gen Physiol 143:559-75|
|Hill-Eubanks, David C; Gonzales, Albert L; Sonkusare, Swapnil K et al. (2014) Vascular TRP channels: performing under pressure and going with the flow. Physiology (Bethesda) 29:343-60|
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