Khai Le Quang

Bradycardia and Slowing of the Atrioventricular Conduction in Mice Lacking CaV3.1/α1G T-Type Calcium Channels

The generation of the mammalian heartbeat is a complex and vital function requiring multiple and coordinated ionic channel activities. The functional role of low-voltage activated (LVA) T-type calcium channels in the pacemaker activity of the sinoatrial node (SAN) is, to date, unresolved. Here we show that disruption of the gene coding for Cav3.1/&agr;1G T-type calcium channels (cacna1g) abolishes T-type calcium current (ICa,T) in isolated cells from the SAN and the atrioventricular node without affecting the L-type Ca2+ current (ICa,L). By using telemetric electrocardiograms on unrestrained mice and intracardiac recordings, we find that cacna1g inactivation causes bradycardia and delays atrioventricular conduction without affecting the excitability of the right atrium. Consistently, no ICa,T was detected in right atrium myocytes in both wild-type and Cav3.1−/− mice. Furthermore, inactivation of cacna1g significantly slowed the intrinsic in vivo heart rate, prolonged the SAN recovery time, and slowed pacemaker activity of individual SAN cells through a reduction of the slope of the diastolic depolarization. Our results demonstrate that Cav3.1/T-type Ca2+ channels contribute to SAN pacemaker activity and atrioventricular conduction.

Conditional Mineralocorticoid Receptor Expression in the Heart Leads to Life-Threatening Arrhythmias

Background—Life-threatening cardiac arrhythmia is a major source of mortality worldwide. Besides rare inherited monogenic diseases such as long-QT or Brugada syndromes, which reflect abnormalities in ion fluxes across cardiac ion channels as a final common pathway, arrhythmias are most frequently acquired and associated with heart disease. The mineralocorticoid hormone aldosterone is an important contributor to morbidity and mortality in heart failure, but its mechanisms of action are incompletely understood. Methods and Results—To specifically assess the role of the mineralocorticoid receptor (MR) in the heart, in the absence of changes in aldosteronemia, we generated a transgenic mouse model with conditional cardiac-specific overexpression of the human MR. Mice exhibit a high rate of death prevented by spironolactone, an MR antagonist used in human therapy. Cardiac MR overexpression led to ion channel remodeling, resulting in prolonged ventricular repolarization at both the cellular and integrated levels and in severe ventricular arrhythmias. Conclusions—Our results indicate that cardiac MR triggers cardiac arrhythmias, suggesting novel opportunities for prevention of arrhythmia-related sudden death.

Long-Term Amiodarone Administration Remodels Expression of Ion Channel Transcripts in the Mouse Heart

Background—The basis for the unique effectiveness of long-term amiodarone treatment on cardiac arrhythmias is incompletely understood. The present study investigated the pharmacogenomic profile of amiodarone on genes encoding ion-channel subunits. Methods and Results—Adult male mice were treated for 6 weeks with vehicle or oral amiodarone at 30, 90, or 180 mg · kg−1 · d−1. Plasma and myocardial levels of amiodarone and N-desethylamiodarone increased dose-dependently, reaching therapeutic ranges observed in human. Plasma triiodothyronine levels decreased, whereas reverse triiodothyronine levels increased in amiodarone-treated animals. In ECG recordings, amiodarone dose-dependently prolonged the RR, PR, QRS, and corrected QT intervals. Specific microarrays containing probes for the complete ion-channel repertoire (IonChips) and real-time reverse transcription–polymerase chain reaction experiments demonstrated that amiodarone induced a dose-dependent remodeling in multiple ion-channel subunits. Genes encoding Na+ (SCN4A, SCN5A, SCN1B), connexin (GJA1), Ca2+ (CaCNA1C), and K+ channels (KCNA5, KCNB1, KCND2) were downregulated. In patch-clamp experiments, lower expression of K+ and Na+ channel genes was associated with decreased Ito,f, IK,slow, and INa currents. Inversely, other K+ channel &agr;- and &bgr;-subunits, such as KCNA4, KCNK1, KCNAB1, and KCNE3, were upregulated. Conclusions—Long-term amiodarone treatment induces a dose-dependent remodeling of ion-channel expression that is correlated with the cardiac electrophysiologic effects of the drug. This profile cannot be attributed solely to the amiodarone-induced cardiac hypothyroidism syndrome. Thus, in addition to the direct effect of the drug on membrane proteins, part of the therapeutic action of long-term amiodarone treatment is likely related to its effect on ion-channel transcripts.

A high-fat diet increases risk of ventricular arrhythmia in female rats: enhanced arrhythmic risk in the absence of obesity or hyperlipidemia

Obesity increases the incidence of cardiac arrhythmias and impairs wound healing. However, it is presently unknown whether a high-fat diet affects arrhythmic risk or wound healing before the onset of overt obesity or hyperlipidemia. After 8 wk of feeding a high-fat diet to adult female rats, a nonsignificant increase in body weight was observed and associated with a normal plasma lipid profile. Following ischemia/reperfusion injury, scar length (standard diet 0.29 +/- 0.09 vs. high-fat 0.32 +/- 0.13 cm), thickness (standard diet 0.047 +/- 0.02 vs. high-fat 0.059 +/- 0.01 cm), and collagen alpha(1) type 1 content (standard diet 0.21 +/- 0.04 vs. high-fat 0.20 +/- 0.04 arbitrary units/mm(2)) of infarcted hearts were not altered by the high-fat diet. However, the mortality rate was greatly increased 24 h postinfarction (from 5% to 46%, P < 0.01 for ischemia/reperfusion rats; from 20% to 89%, P < 0.0001, in complete-occlusion rats) in high-fat fed rats, in association with a higher prevalence of ventricular arrhythmias. Ventricular arrhythmia inducibility was also significantly increased in noninfarcted rats fed a high-fat diet. In the hearts of rats fed a high-fat diet, connexin-40 expression was absent, connexin-43 was hypophosphorylated and lateralized, and neurofilament-M immunoreactive fiber density (standard diet 2,020 +/- 260 vs. high-fat diet 2,830 +/- 250 microm(2)/mm(2)) and tyrosine hydroxylase protein expression were increased (P < 0.05). Thus, in the absence of overt obesity and hyperlipidemia, sympathetic hyperinnervation and an aberrant pattern of gap junctional protein expression and regulation in the heart of female rats fed a high-fat diet may have contributed in part to the higher incidence of inducible cardiac arrhythmias.

Biological Pacemaker Engineered by Nonviral Gene Transfer in a Mouse Model of Complete Atrioventricular Block

We hypothesized that a nonviral gene delivery of the hyperpolarization-activated HCN2 channel combined with the beta(2)-adrenergic receptor (ADRB2) would generate a functional pacemaker in a mouse model of complete atrioventricular block (CAVB) induced by radiofrequency ablation of the His bundle. Plasmids encoding HCN2 and ADRB2 mixed with tetronic 304, a poloxamine block copolymer, were injected in the left ventricular free wall (HCN2-ADRB2 mice). Sham mice received a noncoding plasmid. CAVB was induced 5 days later. Ventricular escape rhythms in HCN2-ADRB2 mice were significantly faster than in sham mice at day 15 after ablation and later. In HCN2-ADRB2 mice, QRS complexes were larger than in sham mice and characterized by abnormal axes. Immunostaining of GFP-HCN2 fusion protein showed an expression of HCN2 channel in left ventricular myocardium for at least 45 days after injection. In the mouse, CAVB induces progressive hypertrophy and heart failure leading to 50% mortality after 110 days. HCN2-ADRB2 mice survived 3 weeks longer than sham mice. Finally, beta-adrenergic input increased ventricular escape rhythms significantly more in HCN2-ADRB2 mice than in sham mice. In conclusion, nonviral gene transfer can produce a functional cardiac biological pacemaker regulated by sympathetic input, which improves life expectancy in a mouse model of CAVB.

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

Significance The “sick sinus” syndrome (SSS) is characterized by abnormal formation and/or propagation of the cardiac impulse. SSS is responsible for about half of the total implantations of electronic pacemakers, which constitute the only currently available therapy for this disorder. We show that genetic ablation or pharmacological inhibition of the muscarinic-gated K+ channel (IKACh) prevents SSS and abolishes atrioventricular block in model mice without affecting the relative degree of heart rate regulation. We propose that “compensatory” genetic or pharmacological targeting of IKACh channels may constitute a new paradigm for restoring defects in the balance between inward and outward currents in pacemaker cells. Our study may thus open a new therapeutic perspective to manage dysfunction of formation and conduction of the cardiac impulse. 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 Ca2+ 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 Ca2+ (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.

Early ion-channel remodeling and arrhythmias precede hypertrophy in a mouse model of complete atrioventricular block

Complete atrioventricular block (CAVB) and related ventricular bradycardia are known to induce ventricular hypertrophy and arrhythmias. Different animal models of CAVB have been established with the most common being the dog model. Related studies were mainly focused on the consequences on the main repolarizing currents in these species, i.e. IKr and IKs, with a limited time point kinetics post-AVB. In order to explore at a genomic scale the electrical remodeling induced by AVB and its chronology, we have developed a novel model of CAVB in the mouse using a radiofrequency-mediated ablation procedure. We investigated transcriptional changes in ion channels and contractile proteins in the left ventricles as a function of time (12h, 1, 2 and 5 days after CAVB), using high-throughput real-time RT-PCR. ECG in conscious and anesthetized mice, left ventricular pressure recordings and patch-clamp were used for characterization of this new mouse model. As expected, CAVB was associated with a lengthening of the QT interval. Moreover, polymorphic ventricular tachycardia was recorded in 6/9 freely-moving mice during the first 24h post-ablation. Remarkably, myocardial hypertrophy was only evident 48 h post-ablation and was associated with increased heart weight and altered expression of contractile proteins. During the first 24 hours post-CAVB, genes encoding ion channel subunits were either up-regulated (such as Nav1.5, +74%) or down-regulated (Kv4.2, -43%; KChIP2, -47%; Navβ1, -31%; Cx43, -29%). Consistent with the transient alteration of Kv4.2 expression, I(to) was reduced at day 1, but restored at day 5. In conclusion, CAVB induces two waves of molecular remodeling: an early one (≤24 h) leading to arrhythmias, a later one related to hypertrophy. These results provide new molecular basis for ventricular tachycardia induced by AV block.