Connexin40-deficient mice exhibit atrioventricular nodal and infra-Hisian conduction abnormalities

INTRODUCTION: Previous electrophysiologic investigations have described AV conduction disturbances in connexin40 (Cx40)-deficient mice. Because expression of Cx40 occurs predominantly in the atria and His-Purkinje system of the mouse heart, the AV conduction disturbances were thought to be secondary to disruption in His-Purkinje function. However, the lack of a His-bundle electrogram recording in the mouse has limited further investigation of the importance of Cx40. Using a novel technique to record His-bundle recordings in Cx40-deficient mice, we define the physiologic importance of deficiencies in Cx40. METHODS AND RESULTS: Ten Cx40-/- mice and 11 Cx40+/+ controls underwent a blinded, in vivo, closed chest electrophysiology study at 9 to 12 weeks of age. In the Cx40-/- mice, the PR interval was significantly longer compared with Cx40+/+ mice (44.6+/-6.4 msec vs 36.0+/-4.1 msec, P = 0.002). Not only the HV interval (14.0+/-3.0 msec vs 10.4+/-1.2 msec, P = 0.003) but also the AH interval (33.2+/-4.8 msec vs 27.1+/-3.7 msec, P = 0.006), AV Wenckebach cycle lengths, and AV nodal effective and functional refractory periods were prolonged in Cx40-/- compared with Cx40+/+ mice. CONCLUSION: Cx40-deficient mice exhibit significant delay not only in infra-Hisian conduction, as would be expected from the expression of Cx40 in the His-Purkinje system but also in the electrophysiologic parameters that reflect AV nodal conduction. Our data suggest a significant role of Cx40 in atrionodal conduction and/or in proximal His-bundle conduction.     

A Targeted Disruption in Connexin40 Leads to Distinct Atrioventricular Conduction Defects

Introduction: Gap junctions consist of connexin (Cx) proteins that enable electrical coupling of adjacent cells and propagation of action potentials. Cx40 is solely expressed in the atrium and His-Purkinje system. The purpose of this study was to evaluate atrioventricular (AV) conduction in mice with a homozygous deletion of Connexin40 (Cx40^–/–). Methods: Surface ECGs, intracardiac electrophysi-ology (EP) studies, and ambulatory telemetry were performed in Cx40^–/– mutant mice and wild-type (WT) controls. Atrioventricular (AV) conduction parameters and arrhythmia inducibility were evaluated using programmed stimulation. Analysis of heart rate variability was based on results of ambulatory monitoring. Results: Significant findings included prolonged measures of AV refractoriness and conduction in connexin40-deficient mice, including longer PR, AH, and HV intervals, increased AV refractory periods, and increased AV Wenckebach and 2:1 block cycle lengths. Connexin40-deficient mice also had an increased incidence of inducible ventricular tachycardia, decreased basal heart rates, and increased heart rate variability. Conclusion: A homozygous disruption of Cx40 results in prolonged AV conduction parameters due to abnormal electrical coupling in the specialized conduction system, which may also predispose to arrhythmia vulnerability.     

Altered dye diffusion and upregulation of connexin37 in mouse aortic endothelium deficient in connexin40

Connexin40 (Cx40), connexin37 (Cx37) and connexin43 (Cx43) are subunit proteins of gap junction channels in the vascular wall which are presumably involved in the propagation of vasomotor signals. In this study we have investigated in Cx40-deficient versus wild-type aortic endothelium to which extent loss of Cx40 impairs intercellular communication. We show in Cx40-deficient mice that expression of both Cx37 and Cx43 protein was increased approximately 3- and 2-fold over the level in wild-type endothelium, respectively. Furthermore, Cx37 immunosignals were distributed more homogeneously on contacting plasma membranes in Cx40-deficient versus with wild-type endothelium. Cx43 was not detected in endothelium but only in smooth muscle cells of the vessel wall. Iontophoretic injection of Lucifer Yellow or neurobiotin into aortic endothelium of Cx40-deficient mice showed extensive intercellular transfer of neurobiotin but not of Lucifer Yellow. In contrast, intercellular spreading of Lucifer Yellow was observed in endothelium of wild-type aorta. As shown by electron microscopy, gap junctions in Cx40-deficient endothelium were morphologically different from those of wild-type vessels. These results demonstrate that dye diffusibility of endothelial gap junctions is different in Cx40-deficient and wild-type mice, although Cx40-deficient mice retain the capability of intercellular communication. Apparently, Cx40-deficient endothelial cells upregulate and redistribute Cx37 as a molecular adaptation to the lack of Cx40.     

Depressant effect on the retrograde atrioventricular nodal conduction of beta-adrenergic blockade by propranolol in humans

Propranolol is known to have a depressant effect on anterograde atrioventricular (AV) nodal conduction in normal subjects and in those with AV nodal reentrant tachycardia. Using His bundle recording and programmed ventricular stimulation, the effect of propranolol-induced beta-adrenergic blockade (1 mg/kg intravenously) on retrograde AV nodal conduction was studied in 17 patients without (group I) and nine with (group II) AV nodal reentrant tachycardia. During baseline studies the ventricular pacing cycle length that induced ventriculoatrial block was 338 +/- 60 ms (range 260 to 450 ms) in group I and 305 +/- 39 ms (range 260 to 375 ms) in group II patients (not significant). After injection of propranolol, the ventricular pacing cycle length that induced ventriculoatrial block in group I patients was 416 +/- 97 ms (range 300 to 550 ms) (P less than 0.001, compared to baseline state) in 15 patients, and complete block occurred in two patients. In group II patients ventriculoatrial block occurred at a ventricular pacing cycle length of 375 +/- 97 ms (range 260 to 510 ms) (P less than 0.02 compared to baseline value) in eight patients, and complete block occurred in one patient. Retrograde AV nodal conduction expressed as the H2A2 interval was 75 +/- 33 ms (range 35 to 150 ms) in group I and 49 +/- 16 ms (range 20 to 80 ms) in group II patients (P less than 0.05). Following the administration of propranolol, the H2A2 interval was prolonged in group I patients by 10 to 45 ms in 11 patients, no retrograde AV nodal conduction was observed in three patients, and there was no effect in two patients.(ABSTRACT TRUNCATED AT 250 WORDS)     

Endoscopy-Assisted Radiofrequency Ablation Around the Coronary Sinus Ostium in Dogs:

Endoscopy for Ablation Around the CS Ostium. Introduction : Radiofrequency ablation of the slow pathway can prolong atrioventricular (AV) nodal properties and RR intervals during atrial fibrillation (AF) in many patients with AV nodal reentrant tachycardia. However, it is not well elucidated whether these changes are related to the presence of dual AV nodal pathway physiology. The aim of this study was to evaluate changes of AV nodal properties and RR intervals during AF caused by ablation of two specific areas in dogs.
Methods and Results : Assisted by fiberoptic endoscopy, linear lesions were created between the coronary sinus ostium and tricuspid valve annulus (area 1) or posterior to the ostium (area 2) in 15 dogs. Three additional dogs served as controls. The measurements were made under autonomic blockade. Catheter ablation could be assisted in all dogs by means of endoscopy. Linear lesions were confirmed at autopsy. AV nodal parameters and RR intervals showed no overall changes. Individual data showed that ablation of area I resulted in modification of AV nodal properties in 54.5% (facilitation in 363% and inhibition in 18.2%), whereas ablation of area 2 induced changes in 50% (facilitation in 10% and inhibition in 40%). The RR intervals were shortened in 33.3% and 20% and prolonged in 44.5% and 40% after ablation of areas 1 and 2, respectively. The RR intervals during AF correlated well with the Wenckebach cycle length and the AV node functional refractory period before and after ablation (r = 0.78 to 0.94, P < 0.01 for each).
Conclusions : Ablation of the two specific areas around the coronary sinus ostium was equally effective in modifying AV nodal properties and the ventricular response during AF without dual AV nodal pathway physiology. The ventricular rate to AF after ablation correlated well with the residual AV nodal properties.     

Conduction disturbances and increased atrial vulnerability in Connexin40-deficient mice analyzed by transesophageal stimulation

BACKGROUND: Recently, it has been reported that connexin40 (Cx40) deficiency in targeted mouse mutants is associated with a prolongation of P-wave and QRS complex duration on surface electrograms. The specific effects of Cx40 deficiency on sinus node function, sinoatrial, and atrioventricular conduction properties as well as on atrial vulnerability have not yet been investigated systematically by electrophysiological analysis. METHODS AND RESULTS: Fifty-two mice (18 Cx40(+/+), 15 Cx40(+/-), and 19 Cx40(-/-) mice) were subjected to rapid atrial transesophageal stimulation after anesthesia with avertin. A significant prolongation of sinus node recovery time was noticed in Cx40(-/-) mice compared with Cx40(+/-) and Cx40(+/+) mice (287.8+/-109.0 vs 211.1+/-61.8 vs 204.4+/-60.9 ms; P<0.05). In addition, Wenckebach periodicity occurred at significantly longer atrial pacing cycle lengths in Cx40(-/-) mice than in Cx40(+/-) or Cx40(+/+) mice (93. 3+/-11.8 vs 83.9+/-9.7 vs 82.8+/-8.0 ms, P<0.05). Analysis of 27 Cx40(-/-) mice showed a significant increase in intra-atrial conduction time and atrioventricular conduction time compared with 52 Cx40(+/-) and 31 wild-type (Cx40(+/+)) mice. Furthermore, in Cx40(-/-) mice, atrial tachyarrhythmias could be induced frequently by atrial burst pacing, whereas no atrial arrhythmias were inducible in heterozygous or wild-type mice. CONCLUSIONS: This study demonstrates that Cx40 deficiency is associated with sinoatrial, intra-atrial, and atrioventricular conduction disturbances. In atrial myocardium of the mouse, Cx40 deficiency results in increased atrial vulnerability and might contribute to arrhythmogenesis.     

Increased expression of renal cyclooxygenase-2 and neuronal nitric oxide synthase in hypertensive Cx40-deficient mice

Cx40-deficient mice (Cx40-/-) are hypertensive due to increased renin secretion. We evaluated the renal expression of neuronal nitric oxide synthase (nNOS) and cyclooxygenases COX-1 and COX-2, three macula densa enzymes. The levels of nNOS were increased in kidneys of Cx40-/- mice, as well as in those of wild-type (WT) mice subjected to the two-kidney one-clip model of hypertension. In contrast, the levels of COX-2 expression were only increased in the hypoperfused kidney of Cx40-/- mice. Treatment with indomethacin lowered blood pressure and renin mRNA in Cx40-/- mice without affecting renin levels, indicating that changes in COX-2 do not cause the altered secretion of renin. Suppression of NOS activity by N(G)-nitro-L-arginine methyl ester (L-NAME) decreased renin levels in Cx40-/- animals, indicating that NO regulates renin expression in the absence of Cx40. Treatment with candesartan normalized blood pressure in Cx40-/- mice, and decreased the levels of both COX-2 and nNOS. After a treatment combining candesartan and L-NAME, the blood pressure of Cx40-/- mice was higher than that of WT mice, showing that NO may counterbalance the vasoconstrictor effects of angiotensin II in Cx40-/- mice. These data document that renal COX-2 and nNOS are differentially regulated due to the elevation of renin-dependent blood pressure in mice lacking Cx40.     

Role of connexin 43 in ischemic preconditioning does not involve intercellular communication through gap junctions

Connexin 43 (Cx 43) has recently been implicated in protection of ischemic preconditioning. Cx 43 colocalization with protein kinase C and p38 mitogen-activated protein kinase is increased in preconditioned myocardium, Cx 43 phosphorylation is preserved in preconditioned myocardium, and hearts from Cx 43-deficient mice cannot be preconditioned. It is, however, unclear whether the important role of Cx 43 relates to intercellular communication through gap junctions or its function in volume homeostasis. To address this issue, we used isolated cardiomyocytes, which no longer-form gap junctions, from wild-type (n = 5) and heterozygous Cx 43-deficient mice (n = 8) and subjected them to 2 h simulated ischemia (hypoxia, acidosis) and an additional challenge by extracellular hypo-osmolarity (from 310 to 250 mOsm/l). Viability (trypan blue exclusion) was well maintained in normoxic wild-type cardiomyocytes (54 +/- 5% at baseline vs. 46 +/- 4 (mean +/- S.D.) % at 2 h). With simulated ischemia, viability was reduced to 17 +/- 5%. Preconditioning by a preceding exposure to 10 min simulated ischemia and 15 min reoxygenation preserved viability after 2 h simulated ischemia (36 +/- 1%, P < 0.001 vs. simulated ischemia). In Cx 43-deficient cardiomyocytes, viability was also well maintained in normoxia (56 +/- 10% vs. 44 +/- 10%). Viability was also reduced to 17 +/- 6% with 2 h simulated ischemia. In contrast to wild-type cells, preconditioning did not prevent the reduction in viability (18 +/- 8%). In conclusion, Cx 43 is essential for preconditioning in the absence of gap junctions, supporting its function through improved volume regulation.     

Vagal modulation of the rate-dependent properties of the atrioventricular node

Vagal effects on atrioventricular (AV) nodal conduction are accentuated by increases in heart rate. To establish the mechanism of these rate-dependent negative dromotropic actions, we studied the properties governing AV nodal adaptation to changes in heart rate in chloralose-anesthetized dogs in the absence and presence of bilateral cervical vagal nerve stimulation (20 Hz, 0.2 msec). Stimulation protocols were applied to evaluate the contributions of changes in AV nodal recovery, facilitation, and fatigue independently of each other. Vagal stimulation slowed AV nodal recovery in a voltage-dependent way, increasing the time constant of recovery (tau r) from 80 +/- 7 to 194 +/- 16 msec (mean +/- SEM, p less than 0.01) at the highest voltage studied. The facilitating effect of a premature (A2) beat was manifested by a leftward shift of the recovery curve (A3H3 versus H2A3) of a subsequent A3 beat. The magnitude of shift depended on the A1A2 coupling interval and was reduced by vagal stimulation at all A1A2 intervals (maximum shift: control, 63 +/- 12 msec; vagus, 24 +/- 11 msec; p less than 0.01). When recovery and facilitation were kept constant, abrupt increases in AV nodal activation rate caused a slow (tau = 75 beats) increase in AH interval (fatigue). Vagal stimulation increased the magnitude of this process (maximum: control, 11 +/- 2 msec; vagus, 27 +/- 3 msec; p less than 0.001), without altering its time course. At activation rates comparable to sinus rhythm in humans, vagal stimulation at an intermediate voltage increased the AH interval by 25 msec. As heart rate increased, vagally induced changes in dynamic processes amplified AH prolongation up to fivefold at maximum rate. The role of vagal changes in individual functional properties depended on heart rate, but slowing of recovery was the single most important factor, constituting over 50% of overall vagal action at rapid rates. We conclude that vagal stimulation alters the ways in which the AV node responds to changes in activation rate and that at rapid rates most of the negative dromotropic action of the vagus is due to changes in the AV nodal response to tachycardia. Alterations in rate-dependent AV nodal properties are a novel and potentially important mechanism through which interventions may affect AV nodal conduction.     

Central role of connexin40 in the propagation of electrically activated vasodilation in mouse cremasteric arterioles in vivo

When a short segment of arteriole is stimulated, vasomotor responses spread bidirectionally along the vessel axis purportedly via gap junctions. We used connexin40 knockout (Cx40-/-) mice to study vasomotor responses induced by 10-second trains of electrical stimulation (30 Hz, 1 ms, 30 to 50 V) in 2nd or 3rd order arterioles of the cremaster muscle. Measurements were made at the stimulation site (local) and at conducted sites (500, 1000, and 2000 microm upstream). In wild-type (Cx40+/+) animals, electrical stimulation evoked a local vasoconstriction and a conducted vasodilation that spread very rapidly along the vessel length without detectable decay. In Cx40-/- mice, the conducted dilation was converted into either vasoconstriction or a slowly developing vasodilation that decayed along the vessel length. Tetrodotoxin (TTX, 1 micromol/L) had no effect on the local vasoconstriction in either Cx40+/+ or Cx40-/- mice, but enhanced the conducted vasodilation in Cx40+/+ animals. In Cx40-/- mice, TTX abolished the conducted vasoconstriction when present and revealed a small vasodilation that decayed with distance. In the group of Cx40-/- mice in which electrical stimulation elicited a conducted vasodilation, TTX had no effect. Immunocytochemistry revealed Cx40 only in the endothelial layer of arterioles from Cx40+/+ mice and complete elimination of this connexin in the Cx40-/- animals. These results indicate that focal current stimulation causes vasoconstriction by a combination of perivascular nerve stimulation and smooth muscle activation. Moreover, electrical stimulation activates a nonneuronal, Cx40-dependent vasodilator response that spreads along the vessel length without decay.     

Nadolol and supraventricular tachycardia: an electrophysiologic study

To assess antiarrhythmic efficacy of oral nadolol, 15 patients with recurrent supraventricular tachycardia were studied. Eight patients had atrioventricular (AV) nodal reentrant tachycardia and seven had AV reciprocating tachycardia involving an accessory AV pathway. Electrophysiologic studies were performed before and after intravenous infusion of propranolol (0.20 mg/kg), and were repeated 5 to 8 days after oral nadolol therapy at a daily dose of 80 to 160 mg. Both intravenous propranolol and oral nadolol induced significant prolongation of the sinus cycle length from 741 +/- 73 ms to 834 +/- 97 and 1,029 +/- 95 ms, respectively (p less than 0.001 and p less than 0.0001, respectively). Both intravenous propranolol and oral nadolol depressed AV nodal but not accessory AV pathway conduction, and shifted the dual AV nodal pathway conduction curves (A1A2, A2H2; A1A2, H1H2) upward and to the right by prolonging the conduction time and increasing the refractory period. Ten patients (seven with AV nodal reentry and three with AV reciprocation) who responded to intravenous propranolol also responded to oral nadolol with loss of the inducibility of sustained tachycardia; the remaining five patients (one with AV nodal reentry and four with AV reciprocation) who did not respond to intravenous propranolol also failed to respond to oral nadolol with persistence of the inducibility of sustained tachycardia. Thus, in conclusion, intravenous propranolol testing predicts the therapeutic efficacy of oral nadolol therapy and oral nadolol in once-daily doses may be used for long-term prophylaxis of recurrent supraventricular tachycardia.     

Recovery of retrograde fast pathway excitability in the atrioventricular node reentrant circuit after concealed anterograde impulse penetration

The recovery of the retrograde fast pathway excitability in atrioventricular (AV) node reentry has been difficult to assess with ventricular extrastimulation because of difficulty in achieving sufficiently short intranodal coupling intervals and the potential interposition of "lower common pathway" nodal tissue. To circumvent these methodologic obstacles in 10 patients with inducible AV node reentrant tachycardia, a fixed atrial extrastimulus (A2) coupled to a basic atrial drive (A1) at a cycle length of 500 ms was utilized to reproducibly initiate AV node reentrant echoes. A ventricular extrastimulus (V3) was then introduced after A2 at progressively shorter coupling intervals (A2V3) in an attempt to pre-excite the retrograde fast pathway after concealed anterograde penetration by A2. In six patients, retrograde fast pathway pre-excitation was achieved at critical A2V3 intervals, as evidenced by the appearance of A3 by up to 28 +/- 6 ms in advance of the expected first AV node reentrant echo. In five of the six cases, the V3A3 interval was virtually unaltered (less than or equal to 5 ms decrease) when A2 was omitted. In seven patients, at a critically short A2V3 coupling interval (195 +/- 27 ms ), V3 abruptly failed to elicit A3 and concomitantly abolished all AV node echoes; yet when A2 was omitted, an A3 response returned, with V3A3 identical to previous values.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effect of slow pathway ablation in atrioventricular nodal reentrant tachycardia on the electrophysiologic characteristics of the inferior atrial inputs to the human atrioventricular node

The inferior atrial extensions of the atrioventricular (AV) node have been related to the anatomic substrate of the slow pathway, but their role in AV nodal reentrant tachycardia (AVNRT) is unknown. Ten patients with slow-fast AVNRT were studied before and after successful slow pathway ablation. Simultaneous His bundle recordings from the right and left sides of the septum were made during right and left inferoparaseptal pacing. Longer stimulus to His (St-H) intervals were measured during right inferoparaseptal pacing than during left inferoparaseptal pacing (284 +/- 55 vs 246 +/- 46 ms, p = 0.005 for right His recordings and 283 +/- 56 vs 244 +/- 46 ms, p = 0.005 for left His recordings) at similar coupling intervals during AVNRT induction. After ablation, the St-H intervals at the maximum AV nodal conduction decrement were similar during right inferoparaseptal and left inferoparaseptal pacing (217 +/- 32 vs 207 +/- 21 ms, p = 0.10 for right His and 215 +/- 32 vs 206 +/- 20 ms, p = 0.13 for left His) at similar coupling intervals. The difference (DeltaSt-H) between St-H intervals during AVRNT induction or at the maximum conduction decrement and during constant pacing for right His recordings with right inferoparaseptal pacing were significantly greater than DeltaSt-H measured with left His during left inferoparaseptal pacing (173 +/- 64 vs 137 +/- 55 ms, p = 0.005) before ablation, but not after (117 +/- 39 vs 100 +/- 40 ms, p = 0.44). Resetting of AVNRT with delivery of left inferoparaseptal extrastimuli was achieved in 7 of 10 patients. In conclusion, the electrophysiologic characteristics of the right and left inferior atrial inputs to the human AV node in patients with AVNRT and their response to slow pathway ablation provide further evidence that the inferior nodal extensions represent the anatomic substrate of the slow pathway.     

Phytanic acid accumulation is associated with conduction delay and sudden cardiac death in sterol carrier protein-2/sterol carrier protein-x deficient mice

INTRODUCTION: The sterol carrier protein-2 gene encodes two functionally distinct proteins: sterol carrier protein-2 (SCP2, a peroxisomal lipid carrier) and sterol carrier protein-x (SCPx, a peroxisomal thiolase known as peroxisomal thiolase-2), which is involved in peroxisomal metabolism of bile acids and branched-chain fatty acids. We show in this study that mice deficient in SCP2 and SCPx (SCP2null) develop a cardiac phenotype leading to a high sudden cardiac death rate if mice are maintained on diets enriched for phytol (a metabolic precursor of branched-chain fatty acids). METHODS AND RESULTS: In 210 surface and 305 telemetric ECGs recorded in wild-type (C57BL/6; wt; n = 40) and SCP2 null mice (n = 40), no difference was observed at baseline. However, on diet, cycle lengths were prolonged in SCP2 null mice (262.9 +/- 190 vs 146.3 +/- 43 msec), AV conduction was prolonged (58.3 +/- 17 vs 42.6 +/- 4 ms), and QRS complexes were wider (19.1 +/- 5 vs 14.0 +/- 4 ms). In 11 gene-targeted Langendorff-perfused hearts isolated from SCP2 null mice after dietary challenge, complete AV blocks (n = 5/11) or impaired AV conduction (Wenckebach point 132 +/- 27 vs 92 +/- 10 msec; P < 0.05) could be confirmed. Monophasic action potentials were not different between the two genotypes. Left ventricular function studied by echocardiography was similar in both strains. Phytanic acid but not pristanic acid accumulated in the phospholipid fraction of myocardial membranes isolated from SCP2 null mice. CONCLUSION: Accumulation of phytanic acid in myocardial phospholipid membranes is associated with bradycardia and impaired AV nodal and intraventricular impulse conduction, which could provide an explanation for sudden cardiac death in this model.     

Redistribution of connexin45 in gap junctions of connexin43-deficient hearts

OBJECTIVE: Adult ventricular myocytes express two gap junction channel proteins: connexin43 (Cx43) and connexin45 (Cx45). Cx43-deficient mice exhibit slow ventricular epicardial conduction, suggesting that Cx43 plays an important role in intercellular coupling in the ventricle. Cx45 is much less abundant than Cx43 in working ventricular myocytes. Its role in ventricular conduction has not been defined, nor is it known whether expression or distribution of Cx45 is altered in Cx43-deficient mice. The present study was undertaken to determine (1) whether expression of Cx45 is upregulated and (2) whether gap junction structure and distribution are altered in Cx43-deficient mice. METHODS: Ventricular tissue from neonatal Cx43(+/+), Cx43(+/-) and Cx43(-/-) and adult Cx43(+/+) and Cx43(+/-) mice was analyzed by immunoblotting and confocal immunofluorescence microscopy. RESULTS: Total Cx45 protein abundance measured by immunoblotting was not different in Cx43-deficient or null hearts compared to wild-type control hearts. However, the amount and distribution of Cx45 immunoreactive signal measured by quantitative confocal analysis were markedly reduced in both Cx43(+/-) and Cx43(-/-) hearts. CONCLUSION: Although the total content of Cx45 is not upregulated in Cx43-deficient hearts, the localization of Cx45 to cardiac gap junctions depends on the expression level of Cx43 and is dramatically altered in mice that express no Cx43.     

High incidence of cardiac malformations in connexin40-deficient mice

Gap junctions are intercellular channels formed by oligomerization of a protein called connexin (Cx). The heart expresses at least three connexin isotypes: Cx40, Cx43, and Cx45. A possible role for Cx40 in cardiac morphogenesis remains to be determined. We have characterized the anatomy and histology of fetal and newborn hearts obtained from crossing Cx40-deficient mice of mixed genetic background (C57BL/6x129Sv). Hearts were serial-sectioned (5 microm) along the coronal plane, stained with hematoxylin-eosin, and visualized by conventional light microscopy. Cardiac malformations in mice lacking Cx40 in one allele (Cx40+/-) included bifid atrial appendage, ventricular septal defect, tetralogy of Fallot (TOF), and an aortic arch abnormality. In Cx40-/- mice resulting from crossing of Cx40+/- mice, the most common cardiac malformations were double-outlet right ventricle (DORV), TOF, and endocardial cushion defects. Overall incidence of cardiac malformations was 6/33 (18%) in Cx40+/- mice and 4/12 (33%) in Cx40-/- mice. No cardiac malformations were observed in 15 wild-type mice studied. In addition, we examined 39 hearts from offspring of Cx40-/- matings. Frequency of cardiac malformations was even higher in this group (44%). Over one third of the hearts (14 of 39) showed conotruncal malformations corresponding to either DORV or TOF. Endocardial cushion defects were found in 3 out of 39 hearts. Our results suggest that Cx40 participates in cardiac morphogenesis, likely in association with other (unknown) products whose expression may vary with the genetic background of the mice.     

Gene dose-dependent atrial arrhythmias, heart block, and brady-cardiomyopathy in mice overexpressing A(3) adenosine receptors

OBJECTIVE: An increased expression of adenosine receptors is a promising target for gene therapy aimed at protecting the myocardium against ischemic damage, but may alter cardiac electrophysiology. We therefore studied the effects of heart-directed overexpression of A(3) adenosine receptors (A(3)ARs) at different gene doses on sinus and atrio-ventricular (AV) nodal function in mice. METHODS AND RESULTS: Mice with heart-specific overexpression of A(3)AR at high (A(3)(high)) or low (A(3)(low)) levels and their wild-type littermates were studied. Telemetric electrocardiogram (ECG) recordings in adult freely moving A(3)(high) mice showed profound sinus bradycardia resulting in either ventricular escape rhythms or an incessant bradycardia-tachycardia syndrome (minimal heart rate A(3)(high) 217+/-25*; WT 406+/-21 beats/min, all values as mean+/-S.E.M., n=7 per genotype, *p<0.05). Exercise attenuated bradycardia in A(3)(high) mice (maximal heart rate A(3)(high) 650+/-13*; WT 796+/-13 beats/min) and first-degree AV nodal block was present (PQ interval A(3)(high) 36+/-4*; WT 23+/-5 ms). Isolated hearts showed complete heart block (10/17 A(3)(high)* vs. 1/17 WT). Atrial bradycardia and AV block were already present 3 weeks after birth. Doppler echocardiography revealed atrial dysfunction and progressive atrial enlargement that was moderate at 3 and 8 weeks, and progressed at 12 and 21 weeks of age (all p<0.05 vs. WT). Atrial contractility and sarcoendoplasmic Ca(2+) ATPase (SERCA) 2a protein expression were reduced in isolated left A(3)(high) atria at the age of 14 weeks. Fibrosis was present in left A(3)(high) atria at 14 weeks, but not at 5 weeks of age. A(3)(low) mice had first-degree AV block without arrhythmias or structural changes. CONCLUSIONS: Heart-directed overexpression of A(3)AR resulted in gene dose-dependent AV block and pronounced sinus nodal dysfunction in vivo. Profound bradycardia heralded atrial and ventricular dilatation, dysfunction, and fibrosis. In contrast to A(1) adenosine receptors (A(1)AR), the effects of A(3)AR overexpression were attenuated during exercise. This may have implications for the physiology of sinus nodal regulation and for therapeutic attempts to increase the expression of adenosine receptors.     

Concealed conduction and dual pathway physiology of the atrioventricular node

INTRODUCTION: Both concealed conduction and dual pathway physiology are important electrophysiologic characteristics of the AV node. The interaction of AV nodal concealment and duality, however, is not clearly understood. METHODS AND RESULTS: The properties of AV conduction curves in the presence and absence of a conditioning blocked impulse were prospectively studied during premature atrial stimulation in 20 patients with AV nodal reentrant tachycardia before and after slow pathway ablation and in 14 control patients. AV nodal duality in the control conduction curve in the absence of a conditioning impulse was observed in 19 (95%) of 20 patients with AV nodal reentrant tachycardia. However, AV nodal duality in the modulated conduction curve in the presence of a blocked impulse was only identified in 2 (10%) of 20 patients (2/20 vs 19/20, P < 0.0001). The modulated curve was characterized by a significantly longer AV nodal effective and functional refractory periods compared to the control curve (P < 0.0001) in both patients with and without AV nodal reentry and in AV nodal reentry patients after successful slow pathway ablation. The maximum AH interval (AH(max)) of the modulated curve was significantly shorter than the control curve in both patients with (217 +/- 74 ms vs 347 +/- 55 ms, P < 0.0001) and without AV nodal reentry (178 +/- 50 ms vs 214 +/- 54 ms, P = 0.02). AH(max) of the control curve was significantly longer in AV nodal reentry patients than in controls (P < 0.0001). AH(max) of the modulated curve, however, was not significantly different between the two groups. After slow pathway ablation, AH(max) of the control curve was significantly reduced (347 +/- 55 ms vs 191 +/- 40 ms, P < 0.0001). Significant reduction in AH(max) of the modulated curve was not observed. CONCLUSION: An interaction of AV nodal concealed conduction and dual pathway physiology was demonstrated by our data. Slow pathway conduction of the AV node was prevented by the concealed beat in both patients with and without AV nodal reentry.