Patrice Naud scite author profile

Background Fibroblast proliferation and differentiation are central in atrial fibrillation (AF)–promoting remodeling. Here, we investigated fibroblast regulation by Ca2+-permeable transient receptor potential canonical-3 (TRPC3) channels. Methods and Results Freshly isolated rat cardiac fibroblasts abundantly expressed TRPC3 and had appreciable nonselective cation currents (INSC) sensitive to a selective TPRC3 channel blocker, pyrazole-3 (3 μmol/L). Pyrazole-3 suppressed angiotensin II-induced Ca2+ influx, proliferation, and α-smooth muscle actin protein expression in fibroblasts. Ca2+ removal and TRPC3 blockade suppressed extracellular signal-regulated kinase phosphorylation, and extracellular signal-regulated kinase phosphorylation inhibition reduced fibroblast proliferation. TRPC3 expression was upregulated in atria from AF patients, goats with electrically maintained AF, and dogs with tachypacing-induced heart failure. TRPC3 knockdown (based on short hairpin RNA [shRNA]) decreased canine atrial fibroblast proliferation. In left atrial fibroblasts freshly isolated from dogs kept in AF for 1 week by atrial tachypacing, TRPC3 protein expression, currents, extracellular signal-regulated kinase phosphorylation, and extracellular matrix gene expression were all significantly increased. In cultured left atrial fibroblasts from AF dogs, proliferation rates, α-smooth muscle actin expression, and extracellular signal-regulated kinase phosphorylation were increased and were suppressed by pyrazole-3. MicroRNA-26 was downregulated in canine AF atria; experimental microRNA-26 knockdown reproduced AF-induced TRPC3 upregulation and fibroblast activation. MicroRNA-26 has NFAT (nuclear factor of activated T cells) binding sites in the 5′ promoter region. NFAT activation increased in AF fibroblasts, and NFAT negatively regulated microRNA-26 transcription. In vivo pyrazole-3 administration suppressed AF while decreasing fibroblast proliferation and extracellular matrix gene expression. Conclusions TRPC3 channels regulate cardiac fibroblast proliferation and differentiation, likely by controlling the Ca2+ influx that activates extracellular signal-regulated kinase signaling. AF increases TRPC3 channel expression by causing NFAT-mediated downregulation of microRNA-26 and causes TRPC3-dependent enhancement of fibroblast proliferation and differentiation. In vivo, TRPC3 blockade prevents AF substrate development in a dog model of electrically maintained AF. TRPC3 likely plays an important role in AF by promoting fibroblast pathophysiology and is a novel potential therapeutic target.

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Role of Small-Conductance Calcium-Activated Potassium Channels in Atrial Electrophysiology and Fibrillation in the Dog

Diness

et al. 2014

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+ , Ca 2+, or other K + currents. Whole-cell SK current sensitive to NS8593 was significantly larger in pulmonary vein (PV) versus left atrial (LA) cells, without a difference in SK single-channel open probability (P o ), whereas AT-P enhanced both whole-cell SK currents and single-channel P o . SK-current block increased action potential duration in both PV and LA cells after AT-P; but only in PV cells in absence of AT-P. SK2 expression was more abundant at both mRNA and protein levels for PV versus LA in control dogs, in both control and AT-P; AT-P upregulated only SK1 at the protein level. Intravenous administration of NS8593 (5 mg/kg) significantly prolonged atrial refractoriness and reduced AF duration without affecting the Wenckebach cycle length, left ventricular refractoriness, or blood pressure. Conclusions-SK

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Role for MicroRNA-21 in Atrial Profibrillatory Fibrotic Remodeling Associated With Experimental Postinfarction Heart Failure

Cardin

Guasch²,

Luo

et al. 2012

Circ: Arrhythmia and Electrophysiology

162

122

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Background— Atrial tissue fibrosis is often an important component of the atrial fibrillation (AF) substrate. Small noncoding microRNAs are important mediators in many cardiac remodeling paradigms. MicroRNA-21 (miR-21) has been suggested to be important in ventricular fibrotic remodeling by downregulating Sprouty-1, a protein that suppresses fibroblast proliferation. The present study examined the potential role of miR-21 in the atrial AF substrate resulting from experimental heart failure after myocardial infarction (MI). Methods and Results— Large MIs (based on echocardiographic left ventricular wall motion score index) were created by left anterior descending coronary artery ligation in rats. Changes induced by MI versus sham controls were first characterized with echocardiography, histology, biochemistry, and in vivo electrophysiology. Additional MI rats were then randomized to receive anti–miR-21 (KD21) or scrambled control sequence (Scr21) injections into the left atrial myocardium. Progressive left ventricular enlargement, hypocontractility, left atrial dilation, fibrosis, refractoriness prolongation, and AF promotion occurred in MI rats versus sham controls. Atrial tissues of MI rats showed upregulation of miR-21, along with dysregulation of the target genes Sprouty-1, collagen-1, and collagen-3. KD21 treatment reduced atrial miR-21 expression levels in MI rats to values in sham rats, decreased AF duration from 417 (69–1595; median [Q1–Q3]) seconds to 3 (2–16) seconds (8 weeks after MI; P <0.05), and reduced atrial fibrous tissue content from 14.4±1.8% (mean±SEM) to 4.9±1.2% (8 weeks after MI; P <0.05) versus Scr21 controls. Conclusions— MI-induced heart failure leads to AF-promoting atrial remodeling in rats. Atrial miR-21 knockdown suppresses atrial fibrosis and AF promotion, implicating miR-21 as an important signaling molecule for the AF substrate and pointing to miR-21 as a potential target for molecular interventions designed to prevent AF.

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Atrial Fibrillation Promotion by Endurance Exercise

Guasch

Benito

et al. 2013

Journal of the American College of Cardiology

244

108

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Atrial Fibrillation Promotion With Long-Term Repetitive Obstructive Sleep Apnea in a Rat Model

Iwasaki

Kato

Xiong

et al. 2014

Journal of the American College of Cardiology

171

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Right Atrial Mechanisms of Atrial Fibrillation in a Rat Model of Right Heart Disease

Hiram

Naud

Xiong

et al. 2019

Journal of the American College of Cardiology

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The N-Terminal Juxtamembranous Domain of KCNQ1 Is Critical for Channel Surface Expression

Dahimène

Alcoléa²,

Naud³

et al. 2006

Circulation Research

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Abstract-N-terminal mutations in the KCNQ1 channel are frequently linked to fatal arrhythmias in newborn children and adolescents but the cellular mechanisms involved in this dramatic issue remain, however, to be discovered. Here, we analyzed the trafficking of a series of N-terminal truncation mutants and identified a critical trafficking motif of KCNQ1. This determinant is located in the juxtamembranous region preceding the first transmembrane domain of the protein. Three mutations (Y111C, L114P and P117L) implicated in inherited Romano-Ward LQT1 syndrome, are embedded within this domain. Reexpression studies in both COS-7 cells and cardiomyocytes showed that the mutant proteins fail to exit the endoplasmic reticulum. KCNQ1 subunits harboring Y111C or L114P exert a dominant negative effect on the wild-type KCNQ1 subunit by preventing plasma membrane trafficking of heteromultimeric channels. The P117L mutation had a less pronounced effect on the trafficking of heteromultimeric channels but altered the kinetics of the current. Furthermore, we showed that the trafficking determinant in KCNQ1 is structurally and functionally conserved in other KCNQ channels and constitutes a critical trafficking determinant of the KCNQ channel family.Computed structural predictions correlated the potential structural changes introduced by the mutations with impaired protein trafficking. In conclusion, our studies unveiled a new role of the N-terminus of KCNQ channels in their trafficking and its implication in severe forms of LQT1 syndrome. Key Words: channels Ⅲ KCNQ Ⅲ LQT Ⅲ membrane Ⅲ trafficking T he long QT syndrome (LQTS) is a cause of sudden cardiac death and is characterized by an increased QT interval on patients' ECG. The prolongation of the QT interval predisposes patients to cardiac arrhythmias known as torsades de pointes, eventually leading to ventricular fibrillation. Over the last decade, inherited mutations in genes encoding cardiac ionic channels or associated partners have been identified in 4 different congenital LQT syndromes (LQT1-4). For example, mutations in KCNQ1 have been associated with either autosomal dominant Romano-Ward (RW) or recessive Jervell and Lange-Nielsen (JLN) LQT1 syndromes. [1][2][3] KCNQ1 encodes the pore forming ␣-subunit of a voltage gated K ϩ channel, which associates with an accessory subunit, KCNE1, in the heart to form channels responsible for the slow component of the delayed repolarizing K ϩ current (I Ks ). 4,5 KCNQ1 mutations associated with LQT1 alter channel function through different mechanisms. Carboxy terminal mutations often disrupt channel assembly, alter regulatory subunit association and cause mistrafficking. 6 -9 Mutations in the pore region and transmembrane domains (TMDs), on the other hand, produce dominant negative effects on potassium permeation and KCNQ1 channel gating functions. 10 -12 Although more than a hundred different LQT1-causing mutations have been reported in KCNQ1, only a few are located in its cytoplasmic N-terminus. 2,3 In general, these mutations...

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Arrhythmogenic left atrial cellular electrophysiology in a murine genetic long QT syndrome model

Lemoine

Duverger

Naud

et al. 2011

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Patrice Naud

Transient Receptor Potential Canonical-3 Channel–Dependent Fibroblast Regulation in Atrial Fibrillation

Role of Small-Conductance Calcium-Activated Potassium Channels in Atrial Electrophysiology and Fibrillation in the Dog

Role for MicroRNA-21 in Atrial Profibrillatory Fibrotic Remodeling Associated With Experimental Postinfarction Heart Failure

Atrial Fibrillation Promotion by Endurance Exercise

Atrial Fibrillation Promotion With Long-Term Repetitive Obstructive Sleep Apnea in a Rat Model

Right Atrial Mechanisms of Atrial Fibrillation in a Rat Model of Right Heart Disease

The N-Terminal Juxtamembranous Domain of KCNQ1 Is Critical for Channel Surface Expression

Arrhythmogenic left atrial cellular electrophysiology in a murine genetic long QT syndrome model

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