Michaela Schernthaner scite author profile

AimTRPC3 is a non-selective cation channel, which forms a Ca2+ entry pathway involved in cardiac remodelling. Our aim was to analyse acute electrophysiological and contractile consequences of TRPC3 activation in the heart.Methods and resultsWe used a murine model of cardiac TRPC3 overexpression and a novel TRPC3 agonist, GSK1702934A, to uncover (patho)physiological functions of TRPC3. GSK1702934A induced a transient, non-selective conductance and prolonged action potentials in TRPC3-overexpressing myocytes but lacked significant electrophysiological effects in wild-type myocytes. GSK1702934A transiently enhanced contractility and evoked arrhythmias in isolated Langendorff hearts from TRPC3-overexpressing but not wild-type mice. Interestingly, pro-arrhythmic effects outlasted TRPC3 current activation, were prevented by enhanced intracellular Ca2+ buffering, and suppressed by the NCX inhibitor 3′,4′-dichlorobenzamil hydrochloride. GSK1702934A substantially promoted NCX currents in TRPC3-overexpressing myocytes. The TRPC3-dependent electrophysiologic, pro-arrhythmic, and inotropic actions of GSK1702934A were mimicked by angiotensin II (AngII). Immunocytochemistry demonstrated colocalization of TRPC3 with NCX1 and disruption of local interaction upon channel activation by either GSK1702934A or AngII.ConclusionCardiac TRPC3 mediates Ca2+ and Na+ entry in proximity of NCX1, thereby elevating cellular Ca2+ levels and contractility. Excessive activation of TRPC3 is associated with transient cellular Ca2+ overload, spatial uncoupling between TRPC3 and NCX1, and arrhythmogenesis. We propose TRPC3-NCX micro/nanodomain communication as determinant of cardiac contractility and susceptibility to arrhythmogenic stimuli.

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PKC-dependent coupling of calcium permeation through transient receptor potential canonical 3 (TRPC3) to calcineurin signaling in HL-1 myocytes

Poteser

Schleifer

Lichtenegger

et al. 2011

Proc. Natl. Acad. Sci. U.S.A.

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Vascular Bioactivation of Nitroglycerin Is Catalyzed by Cytosolic Aldehyde Dehydrogenase-2

Beretta

Wölkart

Schernthaner

et al. 2012

Circulation Research

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Rationale: According to general view, aldehyde dehydrogenase-2 (ALDH2) catalyzes the high-affinity pathway of vascular nitroglycerin (GTN) bioactivation in smooth muscle mitochondria. Despite having wide implications to GTN pharmacology and raising many questions that are still unresolved, mitochondrial bioactivation of GTN in blood vessels is still lacking experimental support.Objective: In the present study, we investigated whether bioactivation of GTN is affected by the subcellular localization of ALDH2 using immortalized ALDH2-deficient aortic smooth muscle cells and mouse aortas with selective overexpression of the enzyme in either cytosol or mitochondria. Methods and Results:Quantitative Western blotting revealed that ALDH2 is mainly cytosolic in mouse aorta and human coronary arteries, with only approximately 15% (mouse) and approximately 5% (human) of the enzyme being localized in mitochondria. Infection of ALDH2-deficient aortic smooth muscle cells or isolated aortas with adenovirus containing ALDH2 cDNA with or without the mitochondrial signal peptide sequence led to selective expression of the protein in mitochondria and cytosol, respectively. Cytosolic overexpression of ALDH2 restored GTN-induced relaxation and GTN denitration to wild-type levels, whereas overexpression in mitochondria (6-fold vs wild-type) had no effect on relaxation. Overexpression of ALDH2 in the cytosol of ALDH2-deficient aortic smooth muscle cells led to a significant increase in GTN denitration and cyclic GMP accumulation, whereas mitochondrial overexpression had no effect. Key Words: adenovirus Ⅲ aldehyde dehydrogenase-2 Ⅲ mitochondria Ⅲ nitroglycerin Ⅲ vasodilation A ldehyde dehydrogenase-2 (ALDH2) has a wellestablished function in the detoxification of reactive aldehydes, in particular ethanol-derived acetaldehyde, in the liver. Because the liver enzyme is almost exclusively located in the mitochondrial matrix space, it is commonly designated as mitochondrial aldehyde dehydrogenase to differentiate it from the cytosolic isoform (ALDH1). 1 In 2002, Stamler et al 2 discovered that vascular ALDH2 catalyzes bioconversion of nitroglycerin to yield 1,2-glycerol dinitrate (GTN) and inorganic nitrite. This reaction appears to be associated with formation of a disulfide in the catalytic site, leading to mechanism-based enzyme inactivation in the absence of an appropriate reductant, like dithiothreitol, 2 dihydrolipoic acid, 3 or the thioredoxin/thioredoxin reductase system. 4 Based on the mitochondrial localization of liver ALDH2, it has been proposed that GTN bioactivation takes place in mitochondria of vascular smooth muscle cells. Reduction of GTN-derived nitrite to nitric oxide (NO) by components of the respiratory chain would then couple ALDH2-catalyzed GTN metabolism to activation of soluble guanylate cyclase (sGC) and vascular relaxation. 2 Mitochondrial GTN bioactivation, supported by the observation that isolated mitochondria generate NO bioactivity from added GTN, 5,6 has been generally accepted in the field and has fo...

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Laser-induced periodic surface structures on polymers for formation of gold nanowires and activation of human cells

et al. 2014

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A TRPC3 Blocker, Ethyl-1-(4-(2,3,3-Trichloroacrylamide)Phenyl)-5-(Trifluoromethyl)-1H-Pyrazole-4-Carboxylate (Pyr3), Prevents Stent-Induced Arterial Remodeling

Koenig

Schernthaner

Maechler

et al. 2012

J Pharmacol Exp Ther

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TRPC-mediated Ca 21 entry has been implicated in the control of smooth muscle proliferation and might represent a pivotal mechanism underlying in-stent restenosis. As we have observed significant expression of TRPC3 in human smooth muscle from the coronary artery as well as the aorta, we tested the efficiency of a recently discovered TRPC3 selective Ca 21 entry blocker Pyr3 to prevent vascular smooth muscle proliferation and stent implantation-induced hyperplasia of human aorta. The effect of Pyr3 on proliferation was measured by detection of BrdU incorporation and PCNA expression in human coronary smooth muscle and microvascular endothelium, which displays significantly smaller expression levels of TRPC3 as compared with smooth muscle. Pyr3 inhibited smooth muscle proliferation but lacked detectable effects on endothelial proliferation. Measurements of ATP-induced Ca 21 signals revealed that Pyr3 suppressed agonist-induced Ca 21 entry more effectively in vascular smooth muscle than in endothelial cells. Inhibitory effects of Pyr3 on stent implantation-induced arterial injury was tested using a novel in vitro model of in-stent hyperplasia in human arteries based on organ typical culture of human aortic constructs. Pyr3 effectively prevented increases in tissue levels of PCNA and Ki-67 at 2 weeks after stent implantation into human aortae. Similarly, proliferation markers were significantly suppressed when implanting a Pyr3-releasing stent prototype as compared with a bare metal stent (BMS) control. Our results suggest TRPC3 as a potential target for pharmacological control of smooth muscle proliferation. Selectively inhibition of TRPC Ca 21 entry channels in vascular smooth muscle is suggested as a promising strategy for instent restenosis prevention.

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