Your search keyword '"Torrente AG"' showing total 27 results

1. P118Cardiac arrhythmia induced by genetic silencing of funny (f) channels is rescued by Girk4 inactivation

Author

Mesirca, P, Alig, J, Torrente, AG, Rollin, A, Vincent, A, Dubel, S, Fernandez, A, Seniuk, A, Isbrandt, D, and Mangoni, ME

Published

2014

2. The increase of extracellular Ca2+ from physiological concentrations to hypercalcemia impairs sino-atrial automaticity

Author

Torrente, AG, primary, Fossier, L, additional, Baudot, M, additional, Torre, E, additional, Bidaud, I, additional, Mesirca, P, additional, and Mangoni, ME, additional

Published

2021

3. P1083Heart automaticity in mice lacking pacemaker L-type Cav1.3 and T-type Cav3.1 channels

Author

Baudot, M., primary, Mesirca, P., additional, Torrente, AG., additional, Bidaud, I., additional, Roussel, J., additional, Laaraoui, S., additional, Striessnig, J., additional, Shin, HS., additional, Nargeot, J., additional, Barrere-Lemaire, S., additional, and Mangoni, ME., additional

Published

2017

4. Paradoxical effect of increased diastolic Ca(2+) release and decreased sinoatrial node activity in a mouse model of catecholaminergic polymorphic ventricular tachycardia

Author

Neco P, Torrente AG, Mesirca P, Zorio E, Liu N, Priori SG, Napolitano C, Richard S, Benitah JP, Mangoni ME, and Gómez AM

Subjects

cardiovascular system, cardiovascular diseases

Abstract

Catecholaminergic polymorphic ventricular tachycardia is characterized by stress-triggered syncope and sudden death. Patients with catecholaminergic polymorphic ventricular tachycardia manifest sinoatrial node (SAN) dysfunction, the mechanisms of which remain unexplored.

Published

2012

5. P118 Cardiac arrhythmia induced by genetic silencing of funny (f) channels is rescued by Girk4 inactivation.

Author

Mesirca, P, Alig, J, Torrente, AG, Rollin, A, Vincent, A, Dubel, S, Fernandez, A, Seniuk, A, Isbrandt, D, and Mangoni, ME

Subjects

ARRHYTHMIA, HEART function tests, HYPERPOLARIZATION (Cytology), GENE silencing, HEART beat, PHARMACOLOGY

Abstract

The mechanisms underlying heart automaticity are still poorly understood and controversial. Here we obtained, for the first time, complete conditional and time-controlled silencing of the hyperpolarization-activated "funny" current (If) by expression of a dominant-negative non-conductive human HCN4-channel subunit (hHCN4-AYA). Heart-specific If silencing recapitulated severe human disease of cardiac rhythm and conduction and showed that the functional role of f-channels in pacemaking critically depends on the activity of the autonomic nervous system. In line with this evidence, we were able to rescue failure of impulse generation and conduction by additional genetic deletion of cardiac muscarinic G-protein-activated (GIRK4) channels in If-deficient mice, without impairing heartbeat control. Our study establishes the role of f-channels in cardiac pacemaking and indicates that arrhythmia related to HCN loss-of-function in humans may be managed by pharmacological or genetic inhibition of GIRK4 channels, thus indicating a new unexplored therapeutic strategy to treat heart rhythm diseases. [ABSTRACT FROM AUTHOR]

Published

2014

6. Cardiorespiratory coupling in the bottlenose dolphin ( Tursiops truncatus ).

Author

Fahlman A, Mcknight JC, Blawas AM, West N, Torrente AG, and Aoki K

Abstract

Introduction: The bottlenose dolphin ( Tursiops truncatus ) is an intermittent breather, where the breath begins with an exhalation followed by inhalation and an extended inter-breath interval ranging from 10 to 40 s. Breathing has been shown to alter both the instantaneous heart rate (i f H ) and stroke volume (iSV) in the bottlenose dolphin, with a transitory ventilatory tachycardia following the breath, and an exponential decrease to a stable i f H around 40 beats • min -1 during the inter-breath period. As the total breath duration in the dolphin is around 1 s, it is not possible to assess the contribution of exhalation and inhalation to these changes in cardiac function during normal breathing. Methods: In the current study, we evaluated the i f H response by separating expiration and inspiration of a breath, which allowed us to distinguish their respective contribution to the changes in i f H . We studied 3 individual male bottlenose dolphins trained to hold their breath between the different respiratory phases (expiration and inhalation). Results: Our data show that inspiration causes an increase in i f H , while expiration appears to result in a decrease in i f H . Discussion: These data provide improved understanding of the cardiorespiratory coupling in dolphins, and show how both exhalation and inhalation alters i f H ., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2023 Fahlman, Mcknight, Blawas, West, Torrente and Aoki.)

Published

2023

7. Lipopolysaccharide-induced sepsis impairs M2R-GIRK signaling in the mouse sinoatrial node.

Author

Shrestha N, Zorn-Pauly K, Mesirca P, Koyani CN, Wölkart G, Di Biase V, Torre E, Lang P, Gorischek A, Schreibmayer W, Arnold R, Maechler H, Mayer B, von Lewinski D, Torrente AG, Mangoni ME, Pelzmann B, and Scheruebel S

Subjects

Humans, Animals, Mice, Sinoatrial Node physiology, G Protein-Coupled Inwardly-Rectifying Potassium Channels genetics, G Protein-Coupled Inwardly-Rectifying Potassium Channels metabolism, Signal Transduction physiology, Lipopolysaccharides toxicity, Lipopolysaccharides metabolism, Sepsis chemically induced, Sepsis metabolism

Abstract

Sepsis has emerged as a global health burden associated with multiple organ dysfunction and 20% mortality rate in patients. Numerous clinical studies over the past two decades have correlated the disease severity and mortality in septic patients with impaired heart rate variability (HRV), as a consequence of impaired chronotropic response of sinoatrial node (SAN) pacemaker activity to vagal/parasympathetic stimulation. However, the molecular mechanism(s) downstream to parasympathetic inputs have not been investigated yet in sepsis, particularly in the SAN. Based on electrocardiography, fluorescence Ca 2+ imaging, electrophysiology, and protein assays from organ to subcellular level, we report that impaired muscarinic receptor subtype 2-G protein-activated inwardly-rectifying potassium channel (M2R-GIRK) signaling in a lipopolysaccharide-induced proxy septic mouse model plays a critical role in SAN pacemaking and HRV. The parasympathetic responses to a muscarinic agonist, namely I KACh activation in SAN cells, reduction in Ca 2+ mobilization of SAN tissues, lowering of heart rate and increase in HRV, were profoundly attenuated upon lipopolysaccharide-induced sepsis. These functional alterations manifested as a direct consequence of reduced expression of key ion-channel components (GIRK1, GIRK4, and M2R) in the mouse SAN tissues and cells, which was further evident in the human right atrial appendages of septic patients and likely not mediated by the common proinflammatory cytokines elevated in sepsis.

Published

2023

8. Prolonged Piezo1 Activation Induces Cardiac Arrhythmia.

Author

Rolland L, Torrente AG, Bourinet E, Maskini D, Drouard A, Chevalier P, Jopling C, and Faucherre A

Subjects

Animals, Humans, Cardiac Conduction System Disease, Mechanotransduction, Cellular physiology, Myocytes, Cardiac metabolism, Zebrafish metabolism, Zebrafish Proteins genetics, Arrhythmias, Cardiac genetics, Ion Channels genetics, Ion Channels metabolism

Abstract

The rhythmical nature of the cardiovascular system constantly generates dynamic mechanical forces. At the centre of this system is the heart, which must detect these changes and adjust its performance accordingly. Mechanoelectric feedback provides a rapid mechanism for detecting even subtle changes in the mechanical environment and transducing these signals into electrical responses, which can adjust a variety of cardiac parameters such as heart rate and contractility. However, pathological conditions can disrupt this intricate mechanosensory system and manifest as potentially life-threatening cardiac arrhythmias. Mechanosensitive ion channels are thought to be the main proponents of mechanoelectric feedback as they provide a rapid response to mechanical stimulation and can directly affect cardiac electrical activity. Here, we demonstrate that the mechanosensitive ion channel PIEZO1 is expressed in zebrafish cardiomyocytes. Furthermore, chemically prolonging PIEZO1 activation in zebrafish results in cardiac arrhythmias. indicating that this ion channel plays an important role in mechanoelectric feedback. This also raises the possibility that PIEZO1 gain of function mutations could be linked to heritable cardiac arrhythmias in humans.

Published

2023

9. Characterization of sinoatrial automaticity in Microcebus murinus to study the effect of aging on cardiac activity and the correlation with longevity.

Author

DiFrancesco ML, Marrot M, Torre E, Mesirca P, Davaze R, Lautier C, Fontes P, Cuoq J, Fernandez A, Lamb N, Pifferi F, Mestre-Francés N, Mangoni ME, and Torrente AG

Subjects

Humans, Rats, Animals, Longevity, Aging physiology, Heart, Heart Rate physiology, Mammals, Cheirogaleidae

Abstract

Microcebus murinus, or gray mouse lemur (GML), is one of the smallest primates known, with a size in between mice and rats. The small size, genetic proximity to humans and prolonged senescence, make this lemur an emerging model for neurodegenerative diseases. For the same reasons, it could help understand how aging affects cardiac activity. Here, we provide the first characterization of sinoatrial (SAN) pacemaker activity and of the effect of aging on GML heart rate (HR). According to GML size, its heartbeat and intrinsic pacemaker frequencies lie in between those of mice and rats. To sustain this fast automaticity the GML SAN expresses funny and Ca 2+ currents (I f , I Ca,L and I Ca,T ) at densities similar to that of small rodents. SAN automaticity was also responsive to β-adrenergic and cholinergic pharmacological stimulation, showing a consequent shift in the localization of the origin of pacemaker activity. We found that aging causes decrease of basal HR and atrial remodeling in GML. We also estimated that, over 12 years of a lifetime, GML generates about 3 billion heartbeats, thus, as many as humans and three times more than rodents of equivalent size. In addition, we estimated that the high number of heartbeats per lifetime is a characteristic that distinguishes primates from rodents or other eutherian mammals, independently from body size. Thus, cardiac endurance could contribute to the exceptional longevity of GML and other primates, suggesting that GML's heart sustains a workload comparable to that of humans in a lifetime. In conclusion, despite the fast HR, GML replicates some of the cardiac deficiencies reported in old people, providing a suitable model to study heart rhythm impairment in aging. Moreover, we estimated that, along with humans and other primates, GML presents a remarkable cardiac longevity, enabling longer life span than other mammals of equivalent size., (© 2023. The Author(s).)

Published

2023

10. The Effect of Hypothermia and Osmotic Shock on the Electrocardiogram of Adult Zebrafish.

Author

Arel E, Rolland L, Thireau J, Torrente AG, Bechard E, Bride J, Jopling C, Demion M, and Le Guennec JY

Abstract

The use of zebrafish to explore cardiac physiology has been widely adopted within the scientific community. Whether this animal model can be used to determine drug cardiac toxicity via electrocardiogram (ECG) analysis is still an ongoing question. Several reports indicate that the recording configuration severely affects the ECG waveforms and its derived-parameters, emphasizing the need for improved characterization. To address this problem, we recorded ECGs from adult zebrafish hearts in three different configurations (unexposed heart, exposed heart, and extracted heart) to identify the most reliable method to explore ECG recordings at baseline and in response to commonly used clinical therapies. We found that the exposed heart configuration provided the most reliable and reproducible ECG recordings of waveforms and intervals. We were unable to determine T wave morphology in unexposed hearts. In extracted hearts, ECG intervals were lengthened and P waves were unstable. However, in the exposed heart configuration, we were able to reliably record ECGs and subsequently establish the QT-RR relationship (Holzgrefe correction) in response to changes in heart rate.

Published

2022

11. Genetic Ablation of G Protein-Gated Inwardly Rectifying K + Channels Prevents Training-Induced Sinus Bradycardia.

Author

Bidaud I, D'Souza A, Forte G, Torre E, Greuet D, Thirard S, Anderson C, Chung You Chong A, Torrente AG, Roussel J, Wickman K, Boyett MR, Mangoni ME, and Mesirca P

Abstract

Background: Endurance athletes are prone to bradyarrhythmias, which in the long-term may underscore the increased incidence of pacemaker implantation reported in this population. Our previous work in rodent models has shown training-induced sinus bradycardia to be due to microRNA (miR)-mediated transcriptional remodeling of the HCN4 channel, leading to a reduction of the "funny" ( I f ) current in the sinoatrial node (SAN). Objective: To test if genetic ablation of G-protein-gated inwardly rectifying potassium channel, also known as I KACh channels prevents sinus bradycardia induced by intensive exercise training in mice. Methods: Control wild-type (WT) and mice lacking GIRK4 ( Girk4 -/- ), an integral subunit of I KACh were assigned to trained or sedentary groups. Mice in the trained group underwent 1-h exercise swimming twice a day for 28 days, 7 days per week. We performed electrocardiogram recordings and echocardiography in both groups at baseline, during and after the training period. At training cessation, mice were euthanized and SAN tissues were isolated for patch clamp recordings in isolated SAN cells and molecular profiling by quantitative PCR (qPCR) and western blotting. Results: At swimming cessation trained WT mice presented with a significantly lower resting HR that was reversible by acute I KACh block whereas Girk4 -/- mice failed to develop a training-induced sinus bradycardia. In line with HR reduction, action potential rate, density of I f , as well as of T- and L-type Ca 2+ currents ( I CaT and I CaL ) were significantly reduced only in SAN cells obtained from WT-trained mice. I f reduction in WT mice was concomitant with downregulation of HCN4 transcript and protein, attributable to increased expression of corresponding repressor microRNAs (miRs) whereas reduced I CaL in WT mice was associated with reduced Ca v 1.3 protein levels. Strikingly, I KACh ablation suppressed all training-induced molecular remodeling observed in WT mice. Conclusion: Genetic ablation of cardiac I KACh in mice prevents exercise-induced sinus bradycardia by suppressing training induced remodeling of inward currents I f , I CaT and I CaL due in part to the prevention of miR-mediated transcriptional remodeling of HCN4 and likely post transcriptional remodeling of Ca v 1.3. Strategies targeting cardiac I KACh may therefore represent an alternative to pacemaker implantation for bradyarrhythmias seen in some veteran athletes., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2021 Bidaud, D’Souza, Forte, Torre, Greuet, Thirard, Anderson, Chung You Chong, Torrente, Roussel, Wickman, Boyett, Mangoni and Mesirca.)

Published

2021

12. Pharmacologic Approach to Sinoatrial Node Dysfunction.

Author

Mesirca P, Fedorov VV, Hund TJ, Torrente AG, Bidaud I, Mohler PJ, and Mangoni ME

Subjects

Heart Conduction System, Humans, Sick Sinus Syndrome, Sinoatrial Node

Abstract

The spontaneous activity of the sinoatrial node initiates the heartbeat. Sino-atrial node dysfunction (SND) and sick sinoatrial (sick sinus) syndrome are caused by the heart's inability to generate a normal sinoatrial node action potential. In clinical practice, SND is generally considered an age-related pathology, secondary to degenerative fibrosis of the heart pacemaker tissue. However, other forms of SND exist, including idiopathic primary SND, which is genetic, and forms that are secondary to cardiovascular or systemic disease. The incidence of SND in the general population is expected to increase over the next half century, boosting the need to implant electronic pacemakers. During the last two decades, our knowledge of sino-atrial node physiology and of the pathophysiological mechanisms underlying SND has advanced considerably. This review summarizes the current knowledge about SND mechanisms and discusses the possibility of introducing new pharmacologic therapies for treating SND.

Published

2021

13. Concomitant genetic ablation of L-type Ca v 1.3 (α 1D ) and T-type Ca v 3.1 (α 1G ) Ca 2+ channels disrupts heart automaticity.

Author

Baudot M, Torre E, Bidaud I, Louradour J, Torrente AG, Fossier L, Talssi L, Nargeot J, Barrère-Lemaire S, Mesirca P, and Mangoni ME

Subjects

Animals, Bradycardia genetics, Bradycardia physiopathology, Calcium metabolism, Disease Models, Animal, Electrocardiography, Heart Rate, Mice, Mice, Knockout, Sarcoplasmic Reticulum metabolism, Atrioventricular Node physiopathology, Bradycardia diagnosis, Calcium Channels, L-Type genetics, Calcium Channels, T-Type genetics, Sinoatrial Node physiopathology

Abstract

Cardiac automaticity is set by pacemaker activity of the sinus node (SAN). In addition to the ubiquitously expressed cardiac voltage-gated L-type Ca v 1.2 Ca 2+ channel isoform, pacemaker cells within the SAN and the atrioventricular node co-express voltage-gated L-type Ca v 1.3 and T-type Ca v 3.1 Ca 2+ channels (SAN-VGCCs). The role of SAN-VGCCs in automaticity is incompletely understood. We used knockout mice carrying individual genetic ablation of Ca v 1.3 (Ca v 1.3 -/- ) or Ca v 3.1 (Ca v 3.1 -/- ) channels and double mutant Ca v 1.3 -/- /Ca v 3.1 -/- mice expressing only Ca v 1.2 channels. We show that concomitant loss of SAN-VGCCs prevents physiological SAN automaticity, blocks impulse conduction and compromises ventricular rhythmicity. Coexpression of SAN-VGCCs is necessary for impulse formation in the central SAN. In mice lacking SAN-VGCCs, residual pacemaker activity is predominantly generated in peripheral nodal and extranodal sites by f-channels and TTX-sensitive Na + channels. In beating SAN cells, ablation of SAN-VGCCs disrupted late diastolic local intracellular Ca 2+ release, which demonstrates an important role for these channels in supporting the sarcoplasmic reticulum based "Ca 2+ clock" mechanism during normal pacemaking. These data implicate an underappreciated role for co-expression of SAN-VGCCs in heart automaticity and define an integral role for these channels in mechanisms that control the heartbeat.

Published

2020

14. Correction to: Channelopathies of voltage-gated L-type Cav1.3/α 1D and T-type Cav3.1/α 1G Ca 2+ channels in dysfunction of heart automaticity.

Author

Torrente AG, Mesirca P, Bidaud I, and Mangoni ME

Abstract

The above article was published online with an error in Fig. 1b. There is a doubled action potential at the far right of the left panel of the figure.

Published

2020

15. Sinoatrial Node Structure, Mechanics, Electrophysiology and the Chronotropic Response to Stretch in Rabbit and Mouse.

Author

MacDonald EA, Madl J, Greiner J, Ramadan AF, Wells SM, Torrente AG, Kohl P, Rog-Zielinska EA, and Quinn TA

Abstract

The rhythmic electrical activity of the heart's natural pacemaker, the sinoatrial node (SAN), determines cardiac beating rate (BR). SAN electrical activity is tightly controlled by multiple factors, including tissue stretch, which may contribute to adaptation of BR to changes in venous return. In most animals, including human, there is a robust increase in BR when the SAN is stretched. However, the chronotropic response to sustained stretch differs in mouse SAN, where it causes variable responses, including decreased BR. The reasons for this species difference are unclear. They are thought to relate to dissimilarities in SAN electrophysiology (particularly action potential morphology) between mouse and other species and to how these interact with subcellular stretch-activated mechanisms. Furthermore, species-related differences in structural and mechanical properties of the SAN may influence the chronotropic response to SAN stretch. Here we assess (i) how the BR response to sustained stretch of rabbit and mouse isolated SAN relates to tissue stiffness, (ii) whether structural differences could account for observed differences in BR responsiveness to stretch, and (iii) whether pharmacological modification of mouse SAN electrophysiology alters stretch-induced chronotropy. We found disparities in the relationship between SAN stiffness and the magnitude of the chronotropic response to stretch between rabbit and mouse along with differences in SAN collagen structure, alignment, and changes with stretch. We further observed that pharmacological modification to prolong mouse SAN action potential plateau duration rectified the direction of BR changes during sustained stretch, resulting in a positive chronotropic response akin to that of other species. Overall, our results suggest that structural, mechanical, and background electrophysiological properties of the SAN influence the chronotropic response to stretch. Improved insight into the biophysical determinants of stretch effects on SAN pacemaking is essential for a comprehensive understanding of SAN regulation with important implications for studies of SAN physiology and its dysfunction, such as in the aging and fibrotic heart., (Copyright © 2020 MacDonald, Madl, Greiner, Ramadan, Wells, Torrente, Kohl, Rog-Zielinska and Quinn.)

Published

2020

16. Channelopathies of voltage-gated L-type Cav1.3/α 1D and T-type Cav3.1/α 1G Ca 2+ channels in dysfunction of heart automaticity.

Author

Torrente AG, Mesirca P, Bidaud I, and Mangoni ME

Subjects

Animals, Arrhythmias, Cardiac genetics, Arrhythmias, Cardiac metabolism, Heart Rate genetics, Humans, Sinoatrial Node metabolism, Sinoatrial Node pathology, Calcium Channels, L-Type genetics, Calcium Channels, L-Type metabolism, Calcium Channels, T-Type genetics, Calcium Channels, T-Type metabolism, Channelopathies genetics, Channelopathies metabolism, Myocytes, Cardiac metabolism

Abstract

The heart automaticity is a fundamental physiological function in vertebrates. The cardiac impulse is generated in the sinus node by a specialized population of spontaneously active myocytes known as "pacemaker cells." Failure in generating or conducting spontaneous activity induces dysfunction in cardiac automaticity. Several families of ion channels are involved in the generation and regulation of the heart automaticity. Among those, voltage-gated L-type Cav1.3 (α1D) and T-type Cav3.1 (α1G) Ca 2+ channels play important roles in the spontaneous activity of pacemaker cells. Ca 2+ channel channelopathies specifically affecting cardiac automaticity are considered rare. Recent research on familial disease has identified mutations in the Cav1.3-encoding CACNA1D gene that underlie congenital sinus node dysfunction and deafness (OMIM # 614896). In addition, both Cav1.3 and Cav3.1 channels have been identified as pathophysiological targets of sinus node dysfunction and heart block, caused by congenital autoimmune disease of the cardiac conduction system. The discovery of channelopathies linked to Cav1.3 and Cav3.1 channels underscores the importance of Ca 2+ channels in the generation and regulation of heart's automaticity.

Published

2020

17. Na/Ca exchange in the atrium: Role in sinoatrial node pacemaking and excitation-contraction coupling.

Author

Yue X, Hazan A, Lotteau S, Zhang R, Torrente AG, Philipson KD, Ottolia M, and Goldhaber JI

Subjects

Animals, Humans, Biological Clocks, Calcium metabolism, Excitation Contraction Coupling, Heart Atria metabolism, Sinoatrial Node metabolism, Sodium metabolism, Sodium-Calcium Exchanger metabolism

Abstract

Na/Ca exchange is the dominant calcium (Ca) efflux mechanism in cardiac myocytes. Although our knowledge of exchanger function (NCX1 in the heart) was originally established using biochemical and electrophysiological tools such as cardiac sarcolemmal vesicles and the giant patch technique [1-4], many advances in our understanding of the physiological/pathophysiological roles of NCX1 in the heart have been obtained using a suite of genetically modified mice. Early mouse studies focused on modification of expression levels of NCX1 in the ventricles, with transgenic overexpressors, global NCX1 knockout (KO) mice (which were embryonic lethal if homozygous), and finally ventricular-specific NCX1 KO [5-12]. We found, to our surprise, that ventricular cardiomyocytes lacking NCX1 can survive and function by engaging a clever set of adaptations to minimize Ca entry, while maintaining contractile function through an increase in excitation-contraction (EC) coupling gain [5,6,13]. Having studied ventricular NCX1 ablation in detail, we more recently focused on elucidating the role of NCX1 in the atria through altering NCX1 expression. Using a novel atrial-specific NCX1 KO mouse, we found unexpected changes in atrial cell morphology and calcium handling, together with dramatic alterations in the function of sinoatrial node (SAN) pacemaker activity. In this review, we will discuss these findings and their implications for cardiac disease., (Copyright © 2020 The Author(s). Published by Elsevier Ltd.. All rights reserved.)

Published

2020

18. Canonical Wnt signaling promotes pacemaker cell specification of cardiac mesodermal cells derived from mouse and human embryonic stem cells.

Author

Liang W, Han P, Kim EH, Mak J, Zhang R, Torrente AG, Goldhaber JI, Marbán E, and Cho HC

Subjects

Animals, Cell Differentiation, Humans, Mice, Human Embryonic Stem Cells metabolism, Mesoderm metabolism, Mouse Embryonic Stem Cells metabolism, Wnt Signaling Pathway genetics

Abstract

Cardiac differentiation of embryonic stem cells (ESCs) can give rise to de novo chamber cardiomyocytes and nodal pacemaker cells. Compared with our understanding of direct differentiation toward atrial and ventricular myocytes, the mechanisms for nodal pacemaker cell commitment are not well understood. Taking a cue from the prominence of canonical Wnt signaling during cardiac pacemaker tissue development in chick embryos, we asked if modulations of Wnt signaling influence cardiac progenitors to bifurcate to either chamber cardiomyocytes or pacemaker cells. Omitting an exogenous Wnt inhibitor, which is routinely added to maximize cardiac myocyte yield during differentiation of mouse and human ESCs, led to increased yield of spontaneously beating cardiomyocytes with action potential properties similar to those of native sinoatrial node pacemaker cells. The pacemaker phenotype was accompanied by enhanced expression of genes and gene products that mark nodal pacemaker cells such as Hcn4, Tbx18, Tbx3, and Shox2. Addition of exogenous Wnt3a ligand, which activates canonical Wnt/β-catenin signaling, increased the yield of pacemaker-like myocytes while reducing cTNT-positive pan-cardiac differentiation. Conversely, addition of inhibitors of Wnt/β-catenin signaling led to increased chamber myocyte lineage development at the expense of pacemaker cell specification. The positive impact of canonical Wnt signaling on nodal pacemaker cell differentiation was evidenced in direct differentiation of two human ESC lines and human induced pluripotent stem cells. Our data identify the Wnt/β-catenin pathway as a critical determinant of cardiac myocyte subtype commitment during ESC differentiation: endogenous Wnt signaling favors the pacemaker lineage, whereas its suppression promotes the chamber cardiomyocyte lineage., (©AlphaMed Press 2019.)

Published

2020

19. [Genesis of cardiac sinus automaticity and therapeutic perspectives].

Author

Mesirca P, Torrente AG, Bidaud I, Baudot M, Nargeot J, and Mangoni ME

Abstract

Competing Interests: Déclaration de liens d’intérêts Les auteurs déclarent ne pas avoir de liens d’intérêts.

Published

2018

20. Contribution of small conductance K + channels to sinoatrial node pacemaker activity: insights from atrial-specific Na + /Ca 2+ exchange knockout mice.

Author

Torrente AG, Zhang R, Wang H, Zaini A, Kim B, Yue X, Philipson KD, and Goldhaber JI

Subjects

Action Potentials drug effects, Action Potentials physiology, Animals, Apamin pharmacology, Biological Clocks drug effects, Female, Heart Atria drug effects, Heart Atria metabolism, Ion Transport drug effects, Ion Transport physiology, Male, Mice, Mice, Knockout, Protein Isoforms metabolism, Sinoatrial Node drug effects, Biological Clocks physiology, Calcium metabolism, Sinoatrial Node metabolism, Small-Conductance Calcium-Activated Potassium Channels metabolism, Sodium-Calcium Exchanger metabolism

Abstract

Key Points: Repolarizing currents through K + channels are essential for proper sinoatrial node (SAN) pacemaking, but the influence of intracellular Ca 2+ on repolarization in the SAN is uncertain. We identified all three isoforms of Ca 2+ -activated small conductance K + (SK) channels in the murine SAN. SK channel blockade slows repolarization and subsequent depolarization of SAN cells. In the atrial-specific Na + /Ca 2+ exchanger (NCX) knockout mouse, cellular Ca 2+ accumulation during spontaneous SAN pacemaker activity produces intermittent hyperactivation of SK channels, leading to arrhythmic pauses alternating with bursts of pacing. These findings suggest that Ca 2+ -sensitive SK channels can translate changes in cellular Ca 2+ into a repolarizing current capable of modulating pacemaking. SK channels are a potential pharmacological target for modulating SAN rate or treating SAN dysfunction, particularly under conditions characterized by abnormal increases in diastolic Ca 2+ ., Abstract: Small conductance K + (SK) channels have been implicated as modulators of spontaneous depolarization and electrical conduction that may be involved in cardiac arrhythmia. However, neither their presence nor their contribution to sinoatrial node (SAN) pacemaker activity has been investigated. Using quantitative PCR (q-PCR), immunostaining and patch clamp recordings of membrane current and voltage, we identified all three SK isoforms (SK1, SK2 and SK3) in mouse SAN. Inhibition of SK channels with the specific blocker apamin prolonged action potentials (APs) in isolated SAN cells. Apamin also slowed diastolic depolarization and reduced pacemaker rate in isolated SAN cells and intact tissue. We investigated whether the Ca 2+ -sensitive nature of SK channels could explain arrhythmic SAN pacemaker activity in the atrial-specific Na + /Ca 2+ exchange (NCX) knockout (KO) mouse, a model of cellular Ca 2+ overload. SAN cells isolated from the NCX KO exhibited higher SK current than wildtype (WT) and apamin prolonged their APs. SK blockade partially suppressed the arrhythmic burst pacing pattern of intact NCX KO SAN tissue. We conclude that SK channels have demonstrable effects on SAN pacemaking in the mouse. Their Ca 2+ -dependent activation translates changes in cellular Ca 2+ into a repolarizing current capable of modulating regular pacemaking. This Ca 2+ dependence also promotes abnormal automaticity when these channels are hyperactivated by elevated Ca 2+ . We propose SK channels as a potential target for modulating SAN rate, and for treating patients affected by SAN dysfunction, particularly in the setting of Ca 2+ overload., (© 2017 The Authors. The Journal of Physiology © 2017 The Physiological Society.)

Published

2017

21. L-type Cav1.3 channels regulate ryanodine receptor-dependent Ca2+ release during sino-atrial node pacemaker activity.

Author

Torrente AG, Mesirca P, Neco P, Rizzetto R, Dubel S, Barrere C, Sinegger-Brauns M, Striessnig J, Richard S, Nargeot J, Gomez AM, and Mangoni ME

Subjects

Action Potentials physiology, Animals, Calcium Channels, L-Type genetics, Mice, Inbred C57BL, Mice, Knockout, Pacemaker, Artificial, Ryanodine Receptor Calcium Release Channel genetics, Sinoatrial Node metabolism, Calcium metabolism, Calcium Channels, L-Type metabolism, Sarcoplasmic Reticulum metabolism

Abstract

Aims: Sino-atrial node (SAN) automaticity is an essential mechanism of heart rate generation that is still not completely understood. Recent studies highlighted the importance of intracellular Ca(2+) ([Ca(2+)]i) dynamics during SAN pacemaker activity. Nevertheless, the functional role of voltage-dependent L-type Ca(2+) channels in controlling SAN [Ca(2+)]i release is largely unexplored. Since Cav1.3 is the predominant L-type Ca(2+) channel isoform in SAN cells, we studied [Ca(2+)]i dynamics in isolated cells and ex vivo SAN preparations explanted from wild-type (WT) and Cav1.3 knockout (KO) mice (Cav1.3(-/-))., Methods and Results: We found that Cav1.3 deficiency strongly impaired [Ca(2+)]i dynamics, reducing the frequency of local [Ca(2+)]i release events and preventing their synchronization. This impairment inhibited the generation of Ca(2+) transients and delayed spontaneous activity. We also used action potentials recorded in WT SAN cells as voltage-clamp commands for Cav1.3(-/-) cells. Although these experiments showed abolished Ca(2+) entry through L-type Ca(2+) channels in the diastolic depolarization range of KO SAN cells, their sarcoplasmic reticulum Ca(2+) load remained normal. β-Adrenergic stimulation enhanced pacemaking of both genotypes, though, Cav1.3(-/-) SAN cells remained slower than WT. Conversely, we rescued pacemaker activity in Cav1.3(-/-) SAN cells and intact tissues through caffeine-mediated stimulation of Ca(2+)-induced Ca(2+) release., Conclusions: Cav1.3 channels play a critical role in the regulation of [Ca(2+)]i dynamics, providing an unanticipated mechanism for triggering local [Ca(2+)]i releases and thereby controlling pacemaker activity. Our study also provides an additional pathophysiological mechanism for congenital SAN dysfunction and heart block linked to Cav1.3 loss of function in humans., (Published on behalf of the European Society of Cardiology. All rights reserved. © The Author 2016. For permissions please email: journals.permissions@oup.com.)

Published

2016

22. G protein-gated IKACh channels as therapeutic targets for treatment of sick sinus syndrome and heart block.

Author

Mesirca P, Bidaud I, Briec F, Evain S, Torrente AG, Le Quang K, Leoni AL, Baudot M, Marger L, Chung You Chong A, Nargeot J, Striessnig J, Wickman K, Charpentier F, and Mangoni ME

Subjects

Animals, Calcium Channels, L-Type genetics, Calcium Channels, L-Type physiology, Humans, Mice, Mice, Knockout, Calcium Channels, L-Type drug effects, GTP-Binding Proteins physiology, Heart Block drug therapy, Ion Channel Gating physiology, Sick Sinus Syndrome drug therapy

Abstract

Dysfunction of pacemaker activity in the sinoatrial node (SAN) underlies "sick sinus" syndrome (SSS), a common clinical condition characterized by abnormally low heart rate (bradycardia). If untreated, SSS carries potentially life-threatening symptoms, such as syncope and end-stage organ hypoperfusion. The only currently available therapy for SSS consists of electronic pacemaker implantation. Mice lacking L-type Cav1.3 Ca(2+) channels (Cav1.3(-/-)) recapitulate several symptoms of SSS in humans, including bradycardia and atrioventricular (AV) dysfunction (heart block). Here, we tested whether genetic ablation or pharmacological inhibition of the muscarinic-gated K(+) channel (IKACh) could rescue SSS and heart block in Cav1.3(-/-) mice. We found that genetic inactivation of IKACh abolished SSS symptoms in Cav1.3(-/-) mice without reducing the relative degree of heart rate regulation. Rescuing of SAN and AV dysfunction could be obtained also by pharmacological inhibition of IKACh either in Cav1.3(-/-) mice or following selective inhibition of Cav1.3-mediated L-type Ca(2+) (ICa,L) current in vivo. Ablation of IKACh prevented dysfunction of SAN pacemaker activity by allowing net inward current to flow during the diastolic depolarization phase under cholinergic activation. Our data suggest that patients affected by SSS and heart block may benefit from IKACh suppression achieved by gene therapy or selective pharmacological inhibition.

Published

2016

23. Burst pacemaker activity of the sinoatrial node in sodium-calcium exchanger knockout mice.

Author

Torrente AG, Zhang R, Zaini A, Giani JF, Kang J, Lamp ST, Philipson KD, and Goldhaber JI

Subjects

Animals, Calcium metabolism, Calcium Channels, L-Type metabolism, Connexins metabolism, Diastole, Electric Stimulation, Female, Fibrosis, Intracellular Space metabolism, Male, Mice, Knockout, Receptors, Adrenergic, beta metabolism, Action Potentials, Biological Clocks, Sinoatrial Node physiology, Sodium-Calcium Exchanger metabolism

Abstract

In sinoatrial node (SAN) cells, electrogenic sodium-calcium exchange (NCX) is the dominant calcium (Ca) efflux mechanism. However, the role of NCX in the generation of SAN automaticity is controversial. To investigate the contribution of NCX to pacemaking in the SAN, we performed optical voltage mapping and high-speed 2D laser scanning confocal microscopy (LSCM) of Ca dynamics in an ex vivo intact SAN/atrial tissue preparation from atrial-specific NCX knockout (KO) mice. These mice lack P waves on electrocardiograms, and isolated NCX KO SAN cells are quiescent. Voltage mapping revealed disorganized and arrhythmic depolarizations within the NCX KO SAN that failed to propagate into the atria. LSCM revealed intermittent bursts of Ca transients. Bursts were accompanied by rising diastolic Ca, culminating in long pauses dominated by Ca waves. The L-type Ca channel agonist BayK8644 reduced the rate of Ca transients and inhibited burst generation in the NCX KO SAN whereas the Ca buffer 1,2-Bis(2-aminophenoxy)ethane-N,N,N',N'-tetraacetic acid (acetoxymethyl ester) (BAPTA AM) did the opposite. These results suggest that cellular Ca accumulation hinders spontaneous depolarization in the NCX KO SAN, possibly by inhibiting L-type Ca currents. The funny current (If) blocker ivabradine also suppressed NCX KO SAN automaticity. We conclude that pacemaker activity is present in the NCX KO SAN, generated by a mechanism that depends upon If. However, the absence of NCX-mediated depolarization in combination with impaired Ca efflux results in intermittent bursts of pacemaker activity, reminiscent of human sinus node dysfunction and "tachy-brady" syndrome.

Published

2015

24. Functional role of voltage gated Ca(2+) channels in heart automaticity.

Author

Mesirca P, Torrente AG, and Mangoni ME

Abstract

Pacemaker activity of automatic cardiac myocytes controls the heartbeat in everyday life. Cardiac automaticity is under the control of several neurotransmitters and hormones and is constantly regulated by the autonomic nervous system to match the physiological needs of the organism. Several classes of ion channels and proteins involved in intracellular Ca(2+) dynamics contribute to pacemaker activity. The functional role of voltage-gated calcium channels (VGCCs) in heart automaticity and impulse conduction has been matter of debate for 30 years. However, growing evidence shows that VGCCs are important regulators of the pacemaker mechanisms and play also a major role in atrio-ventricular impulse conduction. Incidentally, studies performed in genetically modified mice lacking L-type Cav1.3 (Cav1.3(-/-)) or T-type Cav3.1 (Cav3.1(-/-)) channels show that genetic inactivation of these channels strongly impacts pacemaking. In cardiac pacemaker cells, VGCCs activate at negative voltages at the beginning of the diastolic depolarization and importantly contribute to this phase by supplying inward current. Loss-of-function of these channels also impairs atrio-ventricular conduction. Furthermore, inactivation of Cav1.3 channels promotes also atrial fibrillation and flutter in knockout mice suggesting that these channels can play a role in stabilizing atrial rhythm. Genomic analysis demonstrated that Cav1.3 and Cav3.1 channels are widely expressed in pacemaker tissue of mice, rabbits and humans. Importantly, human diseases of pacemaker activity such as congenital bradycardia and heart block have been attributed to loss-of-function of Cav1.3 and Cav3.1 channels. In this article, we will review the current knowledge on the role of VGCCs in the generation and regulation of heart rate and rhythm. We will discuss also how loss of Ca(2+) entry through VGCCs could influence intracellular Ca(2+) handling and promote atrial arrhythmias.

Published

2015

25. Cardiac arrhythmia induced by genetic silencing of 'funny' (f) channels is rescued by GIRK4 inactivation.

Author

Mesirca P, Alig J, Torrente AG, Müller JC, Marger L, Rollin A, Marquilly C, Vincent A, Dubel S, Bidaud I, Fernandez A, Seniuk A, Engeland B, Singh J, Miquerol L, Ehmke H, Eschenhagen T, Nargeot J, Wickman K, Isbrandt D, and Mangoni ME

Subjects

Animals, Arrhythmias, Cardiac drug therapy, Benzazepines pharmacology, Calcium Signaling genetics, Disease Models, Animal, Female, G Protein-Coupled Inwardly-Rectifying Potassium Channels genetics, Heart Rate drug effects, Humans, Hyperpolarization-Activated Cyclic Nucleotide-Gated Channels metabolism, Ivabradine, Male, Mice, Mice, Inbred C57BL, Mice, Transgenic, Muscle Proteins metabolism, Myocytes, Cardiac metabolism, Myocytes, Cardiac pathology, Oocytes physiology, Patch-Clamp Techniques, Potassium Channels metabolism, Pregnancy, Xenopus, Arrhythmias, Cardiac genetics, Arrhythmias, Cardiac physiopathology, G Protein-Coupled Inwardly-Rectifying Potassium Channels metabolism, Hyperpolarization-Activated Cyclic Nucleotide-Gated Channels genetics, Muscle Proteins genetics, Potassium Channels genetics

Abstract

The mechanisms underlying cardiac automaticity are still incompletely understood and controversial. Here we report the complete conditional and time-controlled silencing of the 'funny' current (If) by expression of a dominant-negative, non-conductive HCN4-channel subunit (hHCN4-AYA). Heart-specific If silencing caused altered [Ca(2+)]i release and Ca(2+) handling in the sinoatrial node, impaired pacemaker activity and symptoms reminiscent of severe human disease of pacemaking. The effects of If silencing critically depended on the activity of the autonomic nervous system. We were able to rescue the failure of impulse generation and conduction by additional genetic deletion of cardiac muscarinic G-protein-activated (GIRK4) channels in If-deficient mice without impairing heartbeat regulation. Our study establishes the role of f-channels in cardiac automaticity and indicates that arrhythmia related to HCN loss-of-function may be managed by pharmacological or genetic inhibition of GIRK4 channels, thus offering a new therapeutic strategy for the treatment of heart rhythm diseases.

Published

2014

26. T-type channels in the sino-atrial and atrioventricular pacemaker mechanism.

Author

Mesirca P, Torrente AG, and Mangoni ME

Subjects

Action Potentials physiology, Animals, Arrhythmias, Cardiac diagnosis, Arrhythmias, Cardiac physiopathology, Brugada Syndrome, Cardiac Conduction System Disease, Heart Conduction System abnormalities, Heart Conduction System physiology, Heart Conduction System physiopathology, Humans, Atrioventricular Node physiology, Calcium Channels, T-Type physiology, Heart Rate physiology, Sinoatrial Node physiology

Abstract

Cardiac automaticity is a fundamental physiological function in vertebrates. Heart rate is under the control of several neurotransmitters and hormones and is permanently adjusted by the autonomic nervous system to match the physiological demand of the organism. Several classes of ion channels and proteins involved in intracellular Ca(2+) handling contribute to pacemaker activity. Voltage-dependent T-type Ca(2+) channels are an integral part of the complex mechanism underlying pacemaking. T-type channels also contribute to impulse conduction in mice and humans. Strikingly, T-type channel isoforms are co-expressed in the cardiac conduction system with other ion channels that play a major role in pacemaking such as f- (HCN4) and L-type Cav1.3 channels. Pharmacologic inhibition of T-type channels reduces the spontaneous activity of isolated pacemaker myocytes of the sino-atrial node, the dominant heart rhythmogenic centre. Target inactivation of T-type Cav3.1 channels abolishes I Ca,T in both sino-atrial and atrioventricular myocytes and reduces the daily heart rate of freely moving mice. Cav3.1 channels contribute also to automaticity of the atrioventricular node and to ventricular escape rhythms, thereby stressing the importance of these channels in automaticity of the whole cardiac conduction system. Accordingly, loss-of-function of Cav3.1 channels contributes to severe form of congenital bradycardia and atrioventricular block in paediatric patients.

Published

2014

27. The G-protein-gated K+ channel, IKACh, is required for regulation of pacemaker activity and recovery of resting heart rate after sympathetic stimulation.

Author

Mesirca P, Marger L, Toyoda F, Rizzetto R, Audoubert M, Dubel S, Torrente AG, Difrancesco ML, Muller JC, Leoni AL, Couette B, Nargeot J, Clapham DE, Wickman K, and Mangoni ME

Subjects

Action Potentials, Animals, Electrocardiography, G Protein-Coupled Inwardly-Rectifying Potassium Channels genetics, Mice, Mice, Inbred C57BL, Mice, Knockout, Myocardial Reperfusion, Myocytes, Cardiac drug effects, Myocytes, Cardiac metabolism, Myocytes, Cardiac physiology, Physical Exertion, Protein Subunits genetics, Protein Subunits metabolism, Sinoatrial Node cytology, Sinoatrial Node drug effects, Sinoatrial Node innervation, Stress, Physiological, Sympathetic Nervous System physiology, Acetylcholine pharmacology, G Protein-Coupled Inwardly-Rectifying Potassium Channels metabolism, Heart Rate, Sinoatrial Node physiology

Abstract

Parasympathetic regulation of sinoatrial node (SAN) pacemaker activity modulates multiple ion channels to temper heart rate. The functional role of the G-protein-activated K(+) current (IKACh) in the control of SAN pacemaking and heart rate is not completely understood. We have investigated the functional consequences of loss of IKACh in cholinergic regulation of pacemaker activity of SAN cells and in heart rate control under physiological situations mimicking the fight or flight response. We used knockout mice with loss of function of the Girk4 (Kir3.4) gene (Girk4(-/-) mice), which codes for an integral subunit of the cardiac IKACh channel. SAN pacemaker cells from Girk4(-/-) mice completely lacked IKACh. Loss of IKACh strongly reduced cholinergic regulation of pacemaker activity of SAN cells and isolated intact hearts. Telemetric recordings of electrocardiograms of freely moving mice showed that heart rate measured over a 24-h recording period was moderately increased (10%) in Girk4(-/-) animals. Although the relative extent of heart rate regulation of Girk4(-/-) mice was similar to that of wild-type animals, recovery of resting heart rate after stress, physical exercise, or pharmacological β-adrenergic stimulation of SAN pacemaking was significantly delayed in Girk4(-/-) animals. We conclude that IKACh plays a critical role in the kinetics of heart rate recovery to resting levels after sympathetic stimulation or after direct β-adrenergic stimulation of pacemaker activity. Our study thus uncovers a novel role for IKACh in SAN physiology and heart rate regulation.

Published

2013