Molecular basis of funny current (If) in normal and failing human heart

I(f) overexpression has been functionally demonstrated in ventricular myocytes from failing human hearts. Altered expression of I(f)-channels as a consequence of electrophysiological remodeling may represent an arrhythmogenic mechanism in heart failure; however, the molecular basis of I(f) overexpression in human cardiac disease is unknown. HCN1, 2 and 4 subtypes, which encode I(f)-channels, have been identified in the heart. The present study was designed to characterize HCN isoform expression in failing and non-failing hearts. Ventricular and atrial samples were obtained from normal or failing hearts explanted from patients with end-stage ischemic cardiomyopathy. I(f) was recorded in patch-clamped left ventricular myocytes. mRNA and protein expression of HCN subunits were measured in both atria and ventricles of control and diseased hearts. HCN2 and HCN4 were detected in human myocardium. Both mRNA and protein levels of HCN2/4 were significantly augmented in failing ventricles (p<0.01 for mRNA, p<0.05 for protein). These results are consistent with the electrophysiological data showing that, in failing ventricular myocytes, I(f) is of larger amplitude and activates at less negative potential. Changes in mRNA and protein expression of both HCN2/4 isoforms in atrial specimens from patients with heart failure mirrored those observed in ventricles (p<0.001 for mRNA, p<0.05 for protein). No disease-dependent alteration was detected for MiRP1, the putative beta-subunit of the I(f)-channel. In conclusion, HCN4 is the predominant channel subtype in normal human heart, and its expression is further amplified by disease. HCN upregulation likely contributes to increased I(f) and may play a role in ventricular and atrial arrhythmogenesis in heart failure.

Differential behaviors of atrial versus ventricular fibroblasts: a potential role for platelet-derived growth factor in atrial-ventricular remodeling differences

BACKGROUND

In various heart disease paradigms, atria show stronger fibrotic responses than ventricles. The possibility that atrial and ventricular fibroblasts respond differentially to pathological stimuli has not been examined.

METHODS AND RESULTS

We compared various morphological, secretory, and proliferative response indexes of canine atrial versus ventricular fibroblasts. Cultured atrial fibroblasts showed faster cell surface area increases, distinct morphology at confluence, and greater alpha-smooth muscle actin expression than ventricular fibroblasts. Atrial fibroblast proliferation ([(3)H]thymidine incorporation) responses were consistently greater for a range of growth factors, including fetal bovine serum, platelet-derived growth factor (PDGF), basic fibroblast growth factor, angiotensin II, endothelin-1, and transforming growth factor-beta(1). Normal atrial tissue showed larger myofibroblast density compared with ventricular tissue, and the difference was exaggerated by congestive heart failure. Congestive heart failure atria showed larger fractions of fibroblasts in mitotic phases compared with ventricles and displayed enhanced gene expression of fibroblast-selective markers (collagen-1, collagen-3, fibronectin-1). Gene microarrays revealed 225 differentially expressed transcript probe sets between paired atrial and ventricular fibroblast samples, including extracellular matrix (eg, fibronectin, laminin, fibulin), cell signaling (PDGF, PDGF receptor, angiopoietin, vascular endothelial growth factor), structure (keratin), and metabolism (xanthine dehydrogenase) genes, identifying PDGF as a candidate contributor to atrial-ventricular fibroblast differences. PDGF receptor gene expression was greater in normal atrium compared with ventricle, and congestive heart failure differentially enhanced atrial versus ventricular PDGF and PDGF receptor gene expression. PDGF receptor protein expression and alpha-smooth muscle actin protein expression were enhanced in isolated congestive heart failure fibroblasts. The PDGF receptor tyrosine kinase inhibitor AG1295 eliminated fetal bovine serum- and transforming growth factor-beta(1)-stimulated atrial-ventricular fibroblast proliferative response differences.

CONCLUSIONS

Atrial fibroblasts behave differently than ventricular fibroblasts over a range of in vitro and in vivo paradigms, with atrial fibroblasts showing enhanced reactivity that may explain greater atrial fibrotic responses. PDGF signaling is particularly important for atrium-selective fibroblast responses and may represent a novel target for arrhythmogenic atrial structural remodeling prevention.

Heat shock proteins as molecular targets for intervention in atrial fibrillation

Atrial fibrillation (AF) is the most common sustained clinical tachyarrhythmia. AF is a progressive condition as demonstrated by the finding that maintenance of normal rhythm and contractile function becomes more difficult the longer AF exists. AF causes cellular stress, which induces atrial remodelling, involving reduction in the expression of L-type Ca(2+) channels and structural changes (myolysis), finally resulting in contractile dysfunction. Heat shock proteins (HSPs) comprise a family of proteins involved in the protection against different forms of cellular stress. Their classical function is the prevention of toxic protein aggregation by binding to (partially) unfolded proteins. Recent investigations reveal that HSPs prevent atrial remodelling and attenuate the promotion of AF in both cellular and animal experimental models. Furthermore, studies in humans suggest a protective role for HSPs against progression from paroxysmal AF to chronic, persistent AF. Therefore, manipulation of the HSP system may offer novel therapeutic approaches for the prevention of atrial remodelling. Such approaches may contribute to the maintenance or restoration of tissue integrity and contractile function. Ultimately, this concept may offer an additional treatment strategy to delay progression towards chronic AF and/or improve the outcome of cardioversion.

Atrial fibrosis: mechanisms and clinical relevance in atrial fibrillation

Atrial fibrillation (AF) is the most common arrhythmia in the clinical setting, and traditional pharmacological approaches have proved to have important weaknesses. Structural remodeling has been observed in both clinical and experimental AF paradigms, and is an important feature of the AF substrate, producing fibrosis that alters atrial tissue composition and function. The precise mechanisms underlying atrial fibrosis are not fully elucidated, but recent experimental studies and clinical investigations have provided valuable insights. A variety of signaling systems, particularly involving angiotensin II and related mediators, seem to be centrally involved in the promotion of fibrosis. This paper reviews the current understanding of how atrial fibrosis creates a substrate for AF, summarizes what is known about the mechanisms underlying fibrosis and its progression, and highlights emerging therapeutic approaches aimed at attenuating structural remodeling to prevent AF.

Pulmonary vein region ablation in experimental vagal atrial fibrillation: role of pulmonary veins versus autonomic ganglia

BACKGROUND

Pulmonary vein (PV) -encircling radiofrequency ablation frequently is effective in vagal atrial fibrillation (AF), and there is evidence that PVs may be particularly prone to cholinergically induced arrhythmia mechanisms. However, PV ablation procedures also can affect intracardiac autonomic ganglia. The present study examined the relative role of PVs versus peri-PV autonomic ganglia in an experimental vagal AF model.

METHODS AND RESULTS

Cholinergic AF was studied under carbachol infusion in coronary perfused canine left atrial PV preparations in vitro and with cervical vagal stimulation in vivo. Carbachol caused dose-dependent AF promotion in vitro, which was not affected by excision of all PVs. Sustained AF could be induced easily in all dogs during vagal nerve stimulation in vivo both before and after isolation of all PVs with encircling lesions created by a bipolar radiofrequency ablation clamp device. PV elimination had no effect on atrial effective refractory period or its responses to cholinergic stimulation. Autonomic ganglia were identified by bradycardic and/or tachycardic responses to high-frequency subthreshold local stimulation. Ablation of the autonomic ganglia overlying all PV ostia suppressed the effective refractory period-abbreviating and AF-promoting effects of cervical vagal stimulation, whereas ablation of only left- or right-sided PV ostial ganglia failed to suppress AF. Dominant-frequency analysis suggested that the success of ablation in suppressing vagal AF depended on the elimination of high-frequency driver regions.

CONCLUSIONS

Intact PVs are not needed for maintenance of experimental cholinergic AF. Ablation of the autonomic ganglia at the base of the PVs suppresses vagal responses and may contribute to the effectiveness of PV-directed ablation procedures in vagal AF.

Pioglitazone, a peroxisome proliferator-activated receptor-gamma activator, attenuates atrial fibrosis and atrial fibrillation promotion in rabbits with congestive heart failure

BACKGROUND

The peroxisome proliferator-activated receptor-gamma (PPAR-gamma) activator pioglitazone antagonizes angiotensin II actions and possesses anti-inflammatory and antioxidant properties in vitro. There is evidence that pioglitazone improves ventricular remodeling in some experimental models.

OBJECTIVE

The purpose of this study was to assess the effects of pioglitazone on arrhythmogenic atrial structural remodeling versus the effects of the angiotensin II type 1 receptor blocker candesartan in a rabbit model of congestive heart failure.

METHODS

Rabbits subjected to ventricular tachypacing at 380 to 400 bpm for 4 weeks in the absence and presence of treatment with pioglitazone, candesartan, and combined pioglitazone and candesartan were assessed by electrophysiologic study, atrial fibrosis measurements, and cytokine expression analyses.

RESULTS

Atrial fibrillation (AF) lasting longer than 2 seconds was induced in no nonpaced controls but in all ventricular tachypacing-only rabbits (mean duration of AF: 8.0 +/- 1.4 seconds). Pioglitazone reduced the duration of AF (3.5 +/- 0.2 seconds, P <.05) and attenuated atrial structural remodeling, with significant reductions in interatrial activation time (50 +/- 2 ms vs 41 +/- 2 ms, P <.05) and atrial fibrosis (16.8% +/- 0.8% vs 10.9% +/- 0.7%, P <.05; control 1.6% +/- 0.2%), effects comparable to those of candesartan (duration of AF: 3.0 +/- 0.2 seconds; activation time 44 +/- 2 ms; fibrosis: 9.4% +/- 0.6%). Both pioglitazone and candesartan reduced transforming growth factor-beta1, tumor necrosis factor-alpha, and activated extracellular signal-regulated kinase expression similarly, but neither affected p38-kinase or c-Jun N-terminal kinase activation. The effects of combined pioglitazone and candesartan therapy were not significantly different from the effects of pioglitazone or candesartan alone.

CONCLUSION

Pioglitazone can attenuate congestive heart failure-induced atrial structural remodeling and AF promotion, with effects similar to those of candesartan. PPAR-gamma may be a potential therapeutic target for human AF.

Atrial cardiomyocyte tachycardia alters cardiac fibroblast function: a novel consideration in atrial remodeling

OBJECTIVE

Atrial fibrillation (AF) causes tachycardia-induced atrial electrical remodeling, contributing to the progressive nature of the arrhythmia. Ventricular dysfunction due to a rapid response to AF can cause structural remodeling, but whether AF itself directly promotes atrial fibrosis is controversial. This study investigated the hypothesis that rapid atrial cardiomyocyte activation produces factors that influence atrial fibroblast proliferation and secretory functions.

METHODS

Cultured canine atrial fibroblasts were treated with medium from rapidly-paced atrial cardiomyocytes, non-paced cardiomyocytes and cardiomyocyte-pacing medium only, and analyzed by [(3)H]thymidine incorporation, Western blot and real-time RT-PCR.

RESULTS

Rapidly-paced cardiomyocyte-conditioned medium reduced [(3)H]thymidine uptake compared to non-paced cardiomyocyte-conditioned medium and medium alone (approximately 85%, P<0.01). Rapidly-paced cardiomyocyte medium increased alpha SMA protein (approximately 55%, p<0.001), collagen-1 (approximately 85%, P<0.05) and fibronectin-1 (approximately 205%, P<0.05) mRNA expression vs. controls. The angiotensin-1 receptor blocker valsartan attenuated pacing-induced alpha SMA changes but did not affect fibroblast proliferation. Suppression of contraction with blebbistatin did not prevent tachypacing-induced changes in [(3)H]thymidine uptake or alpha SMA upregulation, pointing to a primary role of electrical over mechanical cardiomyocyte activity. Atrial tissue from 1-week atrial-tachypaced dogs with ventricular rate control similarly showed upregulation of alpha SMA protein (approximately 40%, P<0.05), collagen-1 (approximately 380%, P<0.01) and fibronectin-1 (approximately 430%, P<0.001) mRNA versus shams.

CONCLUSIONS

Rapidly-paced cardiomyocytes release substances that profoundly alter cardiac fibroblast function, inducing an activated myofibroblast phenotype that is reflected by increased ECM-gene expression in vivo. These findings are consistent with recent observations that AF per se may cause ECM remodeling, and have potentially important consequences for understanding and preventing the mechanisms underlying AF progression.

Omega-3 polyunsaturated fatty acids prevent atrial fibrillation associated with heart failure but not atrial tachycardia remodeling

BACKGROUND

There is epidemiological evidence that omega-3 polyunsaturated fatty acids (PUFAs) reduce the risk of atrial fibrillation (AF), but clinical data are conflicting. The present study assessed the effects of PUFA on AF in experimental models.

METHODS AND RESULTS

We studied the effects of oral PUFA supplements in 2 experimental AF paradigms: electrical remodeling induced by atrial tachypacing (400 bpm for 1 week) and congestive heart failure-associated structural remodeling induced by ventricular tachypacing (240 bpm for 2 weeks). PUFA pretreatment did not directly change atrial effective refractory period (128+/-6 [mean+/-SEM] versus 127+/-2 ms; all effective refractory periods at 300-ms cycle lengths) or burst pacing-induced AF duration (5+/-4 versus 34+/-18 seconds). Atrial tachypacing dogs had shorter refractory periods (73+/-6 ms) and greater AF duration (1185+/-300 seconds) than shams (119+/-5 ms and 20+/-11 seconds; P<0.01 for each). PUFAs did not significantly alter atrial tachypacing effects on refractory periods (77+/-8 ms) or AF duration (1128+/-412 seconds). PUFAs suppressed ventricular tachypacing-induced increases in AF duration (952+/-221 versus 318+/-249 seconds; P<0.05) and attenuated congestive heart failure-related atrial fibrosis (from 19.2+/-1.1% to 5.8+/-1.0%; P<0.001) and conduction abnormalities. PUFAs also attenuated ventricular tachypacing-induced hemodynamic dysfunction (eg, left ventricular end-diastolic and left atrial pressure from 12.2+/-0.5 and 11.4+/-0.6 mm Hg, respectively, to 6.4+/-0.5 and 7.0+/-0.8 mm Hg; P<0.01) and phosphorylation of mitogen-activated protein kinases (extracellular-signal related and P38 kinase).

CONCLUSIONS

PUFAs suppress congestive heart failure-induced atrial structural remodeling and AF promotion but do not affect atrial tachycardia-induced electrical remodeling. The beneficial effects of PUFAs on structural remodeling, possibly related to prevention of mitogen-activated protein kinase activation, may contribute to their clinical anti-AF potential.

Effects of Resveratrol (trans-3,5,4′-Trihydroxystilbene) Treatment on Cardiac Remodeling following Myocardial Infarction

Resveratrol (RES; trans-3,5,4'-trihydroxystilbene) has been shown to improve health and slow the progression of disease in various models. Several cardioprotective mechanisms have been identified including antioxidant, anti-inflammatory, and antifibrotic actions. Each of these actions is thought to have the ability to attenuate the pathophysiology underlying the deleterious cardiac structural remodeling that results from acute myocardial infarction (MI). Therefore, we evaluated the effect of resveratrol treatment on the progression of cardiac remodeling after MI. Four groups of rats (sham, n = 6; sham + RES, n = 21; MI, n = 26; MI + RES, n = 24) were treated for 13 weeks, starting 7 days before ligation of the left anterior descending coronary artery. Serial transthoracic echocardiography revealed that resveratrol had no effect on MI-induced left-ventricular and left-atrial dilatation or reduction in left-ventricular fractional shortening. Consistent with these findings, resveratrol did not improve the deterioration of hemodynamic function or reduce infarct size at 12 weeks post-MI. Resveratrol-treated animals did, however, show preserved cardiac contractile reserve in response to dobutamine administration. Radioligand binding revealed that MI reduced beta-adrenergic receptor density. Resveratrol administration increased beta-adrenoceptor density, so that resveratrol-treated MI rats had beta-adrenoceptor densities similar to normal rats. Real-time reverse transcription-polymerase chain reaction revealed that MI-induced changes in sarcoplasmic reticulum Ca2+-ATPase 2 and transforming growth factor beta-1 expression were unaltered by resveratrol, whereas MI-induced increases in atrial natriuretic factor (ANF) and connective tissue growth factor (CTGF) expression were attenuated. Resveratrol treatment does not improve cardiac remodeling and global hemodynamic function post-MI but does preserve contractile reserve and attenuate ANF and CTGF up-regulation.

Novel anti-arrhythmic drugs for atrial fibrillation management

Atrial fibrillation (AF) is a highly prevalent arrhythmia and responsible for significant morbidity, mortality and health care cost. Considerable work has been performed to improve medical options but treatment success still remains suboptimal. The use of conventional anti-arrhythmic agents has been limited by potentially fatal ventricular proarrhythmia. Thus, novel drug targets have been characterised and are currently being tested in experimental and clinical studies. The atrially (but not ventricularly) expressed ion channel subunit Kv1.5 (conducting the ultra-rapid delayed rectifier, I(Kur)) is a prominent candidate. A variety of drugs that inhibit this current is being evaluated. Human experience with these agents is limited. Atrial expression of connexin 40 and downregulation of this protein in AF turn its modulation into a potential therapeutic approach. The acetylcholine-activated current (I(KACh)) is another novel candidate target for drug therapy. The constitutively active form of this current is increased in human AF and pharmacological inhibition might be of therapeutic value. Certain drugs have I(KACh) blocking properties, but as for I(Kur)-blockers none to date has shown pure selectivity for this current. This article summarizes relevant aspects of the cellular electrophysiology of AF and reviews the actions of pharmacological agents presently available or in development as novel anti-arrhythmic therapy.

Rapid electrical pacing of cardiomyocytes alters the behavior of cardiac fibroblasts: Implications for atrial fibrillations

Background: Atrial fibrillation (AF) produces atrial tachycardia-related changes in atrial electrophysiology, providing a possible explanation for the progressive nature of the arrhythmia. Structural remodeling results from ventricular dysfunction due to a rapid response to AF, but whether AF itself can cause atrial fibrosis remains unclear. This study investigated the hypothesis that rapid atrial cardiomyocyte activation produces factors that influence atrial fibroblast proliferation and secretory functions. Methods: Cultured canine atrial fibroblasts were treated with medium from rapidly-paced atrial cardiomyocytes (group 5Hz), non-paced cardiomyocytes (group NP) and cardiomyocyte pacing medium alone (group Ø), and analyzed by [3H]thymidine incorporation, Western-blot and real-time RT-PCR. Results: Rapidly-paced cardiomyocyte-conditioned medium had a potent anti-proliferative effect, reducing [3H]thymidine uptake compared to non-paced cardiomyocyte-conditioned medium and medium alone (2,143±1,490** vs. 15,870±3,343 and 16,440±4,193 respectively, **P < 0.01 vs. both NP and Ø). Conditioned medium from rapidly-paced cardiomyocytes increased αSMA protein reflecting an activated myofibroblast phenotype (1.62±0.20** vs. 1.08±0.26 and 1.01±0.24), collagen-1 (2.41±0.22* vs. 1.49±0.33 and 1.10±0.19, *P < 0.05 both NP and Ø) and fibronectin-1 (3.05±0.28* vs. 1.80±0.45 and 1.20±0.19) mRNA expression compared to control cells. Treatment of the conditioned medium with the AT1 receptor blocker valsartan, partially attenuated the pacing-induced αSMA increase but had no effect on fibroblast proliferation. Atrial tissue from 1-week atrial-tachypaced dogs with AV block/ventricular pacing to control ventricular rate similarly showed upregulation of collagen-1 (2.6±0.5 vs. 0.7±0.3, P < 0.01) and fibronectin-1 (4.9±0.6 vs. 1.1±0.4, P < 0.001) mRNA versus unpaced shams. Conclusion: Rapidly-paced cardiomyocytes release substances that profoundly alter cardiac fibroblast function and induce an activated myofibroblast phenotype that is reflected by altered ECM-gene expression in vivo. These findings are consistent with recent observations that AF per se causes ECM remodeling and may have important consequences for understanding and preventing the mechanisms underlying AF progression.

Atrial tachycardia induces remodelling of muscarinic receptors and their coupled potassium currents in canine left atrial and pulmonary vein cardiomyocytes

BACKGROUND AND PURPOSE

Both parasympathetic tone and atrial tachycardia (AT) remodelling of ion channels play important roles in atrial fibrillation (AF) pathophysiology. Different muscarinic cholinergic receptor (mAChR) subtypes (M2, M3, M4) in atrial cardiomyocytes are coupled to distinct K+-currents (called IKM2, IKM3, IKM4, respectively). Pulmonary veins (PVs) are important in AF and differential cholinergic current responses are a potential underlying mechanism. This study investigated AT-induced remodelling of mAChR subtypes and K+-currents in left-atrial (LA) and PV cardiomyocytes.

EXPERIMENTAL APPROACH

Receptor expression was assayed by western blot. IKM2, IKM3 and IKM4 were recorded with whole-cell patch-clamp in LA and PV cardiomyocytes of nonpaced control dogs and dogs after 7 days of AT-pacing (400 bpm).

KEY RESULTS

Current densities of IKM2, IKM3 and IKM4 were significantly reduced by AT-pacing in LA and PV cardiomyocytes. PV cardiomyocyte current-voltage relations were similar to LA for all three cholinergic currents, both in control and AT remodelling. Membrane-protein expression levels corresponding to M2, M3 and M4 subtypes were decreased significantly (by about 50%) after AT pacing. Agonist concentration-response relations for all three currents were unaffected by AT pacing.

CONCLUSIONS AND IMPLICATIONS

AT downregulated all three mAChR-coupled K+-current subtypes, along with corresponding mAChR protein expression. These changes in cholinergic receptor-coupled function may play a role in AF pathophysiology. Cholinergic receptor-coupled K+-currents in PV cardiomyocytes were similar to those in LA under control and AT-pacing conditions, suggesting that differential cholinergic current properties do not explain the role of PVs in AF.

Acute and chronic effects of cardiac resynchronization in patients developing heart failure with long-term pacemaker therapy for acquired complete atrioventricular block

AIMS

We assessed the effects of cardiac re-synchronization therapy (CRT) in patients who developed otherwise unexplained heart failure (HF) during right ventricular apical (RVA)-pacing for acquired complete atrioventricular block (CAVB).

METHODS AND RESULTS

Eighteen consecutive CAVB patients with HF during RVA-pacing were assessed with haemodynamic studies immediately and 12 months after CRT-upgrade. Ten patients had idiopathic CAVB and 13 showed normal left ventricular (LV) function at RVA-pacemaker implantation. HF developed after 81 +/- 10 months. RVA-pacing duration correlated (r = 0.49, P < 0.05) with LV ejection fraction (LVEF) deterioration. Biventricular- (BiV) and LV-pacing acutely improved the systolic function comparably, but only BiV improved diastolic function. One-year post-CRT-initiation, New York Heart Association classification improved 35 +/- 3% (P < 0.05) and the number of hospitalizations decreased 85 +/- 3% (P < 0.0001). CRT decreased LV end-diastolic diameter (LVEDd) 7 +/- 2% (P < 0.01) and increased LVEF by 23 +/- 7% (P < 0.01). The CRT-induced reduction in LVEDd tended to be greater in patients with RVA-pacing for < 5 years vs. > 5 years (7.7 +/- 2.5 vs. 3.6 +/- 1.0 mm, P = 0.08).

CONCLUSION

CRT-upgrade improves the cardiac function and symptoms in CAVB patients with HF progression related to RVA-pacing. Because adverse LV-remodelling may be partly irreversible, consideration should be given to BiV- and LV-pacing upgrade as soon as possible after the indications appear, and prospective studies of the optimal timing of CRT-upgrade may be useful.

Adrenergic control of a constitutively active acetylcholine-regulated potassium current in canine atrial cardiomyocytes

OBJECTIVES

Canine atrial cardiomyocytes display a constitutively active, acetylcholine-regulated, time-dependent K+ current (IKH) that contributes to atrial repolarization and atrial tachycardia-induced atrial-fibrillation promotion. Adrenergic stimulation favors atrial arrhythmogenesis but its effects on IKH are poorly understood.

METHODS AND RESULTS

Adrenergic modulation of IKH was studied in isolated canine atrial cardiomyocytes with whole-cell patch-clamping, and action-potential consequences were assessed in multicellular preparations with fine-tipped microelectrodes. Isoproterenol increased IKH in a concentration-dependent manner (maximum 103+/-22% increase), an effect mimicked by forskolin and 8-bromo-cyclic AMP. Isoproterenol effects were prevented by propranolol and the selective beta1-adrenoceptor blocker CGP-20712A, but not the beta2-blocker ICI-118551. Isoproterenol enhancement was prevented by pipette-administered protein kinase A (PKA) inhibitor peptide or by superfusion of H89 (PKA blocker). Phenylephrine decreased IKH in a reversible, concentration-dependent way. This effect was blocked by the alpha-antagonist prazosin and the selective alpha1A-blocker niguldipine, but not the alpha1B-blocker chloroethylclonidine or the alpha1D inhibitor BMY-7378. Phenylephrine effects were prevented by the phospholipase C (PLC) inhibitor U73122 and the protein kinase C (PKC) inhibitor bisindolylmaleimide. The PKC-activating phorbol ester PDD (but not its inactive analogue alpha-PDD) mimicked phenylephrine effects. Action potential recordings in the presence and absence of the selective IKH blocker tertiapin indicated a functional role of alpha- and beta-adrenergic actions on IKH. Adrenergic regulation of cholinergic agonist-induced K+ current paralleled that of IKH.

CONCLUSIONS

IKH is under dual regulation by the adrenergic system: beta1-adrenergic stimulation enhances IKH via cAMP-dependent PKA pathways, whereas alpha1A-adrenergic stimulation inhibits IKH via PLC-mediated PKC activation. Modulation of constitutive acetylcholine-regulated K+ current is a novel potential mechanism for adrenergic control of atrial repolarization.

Membrane cholesterol modulates Kv1.5 potassium channel distribution and function in rat cardiomyocytes

Membrane lipid composition is a major determinant of cell excitability. In this study, we assessed the role of membrane cholesterol composition in the distribution and function of Kv1.5-based channels in rat cardiac membranes. In isolated rat atrial myocytes, the application of methyl-beta-cyclodextrin (MCD), an agent that depletes membrane cholesterol, caused a delayed increase in the Kv1.5-based sustained component, I(kur), which reached steady state in approximately 7 min. This effect was prevented by preloading the MCD with cholesterol. MCD-increased current was inhibited by low 4-aminopyridine concentration. Neonatal rat cardiomyocytes transfected with Green Fluorescent Protein (GFP)-tagged Kv1.5 channels showed a large ultrarapid delayed-rectifier current (I(Kur)), which was also stimulated by MCD. In atrial cryosections, Kv1.5 channels were mainly located at the intercalated disc, whereas caveolin-3 predominated at the cell periphery. A small portion of Kv1.5 floated in the low-density fractions of step sucrose-gradient preparations. In live neonatal cardiomyocytes, GFP-tagged Kv1.5 channels were predominantly organized in clusters at the basal plasma membrane. MCD caused reorganization of Kv1.5 subunits into larger clusters that redistributed throughout the plasma membrane. The MCD effect on clusters was sizable 7 min after its application. We conclude that Kv1.5 subunits are concentrated in cholesterol-enriched membrane microdomains distinct from caveolae, and that redistribution of Kv1.5 subunits by depletion of membrane cholesterol increases their current-carrying capacity.

Decreased phosphorylation levels of cardiac myosin-binding protein-C in human and experimental heart failure

Cardiac myosin-binding protein-C (cMyBP-C) is an important regulator of cardiac contractility, and its phosphorylation by PKA is a mechanism that contributes to increased cardiac output in response to beta-adrenergic stimulation. It is presently unknown whether heart failure alters cMyBP-C phosphorylation. The present study determined the level of phosphorylated cMyBP-C in failing human hearts and in a canine model of pacing-induced heart failure. A polyclonal antibody directed against the major phosphorylation site of cMyBP-C (Ser-282) was generated and its specificity was confirmed by PKA phosphorylation with isoprenaline in cardiomyocytes and Langendorff-perfused mouse hearts. Left ventricular myocardial tissue from (i) patients with terminal heart failure (hHF; n=12) and nonfailing donor hearts (hNF; n=6) and (ii) dogs with rapid-pacing-induced end-stage heart failure (dHF; n=10) and sham-operated controls (dNF; n=10) were used for quantification of total cMyBP-C and phospho-cMyBP-C by Western blotting. Total cMyBP-C protein levels were similar in hHF and hNF as well as in dHF and dNF. In contrast, the ratio of phospho-cMyBP-C to total cMyBP-C levels were >50% reduced in hHF and >40% reduced in dHF. In summary, cMyBP-C phosphorylation levels are markedly decreased in human and experimental heart failure. Thus, the compromised contractile function of the failing heart might be in part attributable to reduced cMyBP-C phosphorylation levels.

Regional and tissue specific transcript signatures of ion channel genes in the non-diseased human heart

The various cardiac regions have specific action potential properties appropriate to their electrical specialization, resulting from a specific pattern of ion-channel functional expression. The present study addressed regionally defined differential ion-channel expression in the non-diseased human heart with a genomic approach. High-throughput real-time RT-PCR was used to quantify the expression patterns of 79 ion-channel subunit transcripts and related genes in atria, ventricular epicardium and endocardium, and Purkinje fibres isolated from 15 non-diseased human donor hearts. Two-way non-directed hierarchical clustering separated atria, Purkinje fibre and ventricular compartments, but did not show specific patterns for epicardium versus endocardium, nor left- versus right-sided chambers. Genes that characterized the atria (versus ventricles) included Cx40, Kv1.5 and Kir3.1 as expected, but also Cav1.3, Cav3.1, Cav alpha2 delta2, Nav beta1, TWIK1, TASK1 and HCN4. Only Kir2.1, RyR2, phospholamban and Kv1.4 showed higher expression in the ventricles. The Purkinje fibre expression-portrait (versus ventricle) included stronger expression of Cx40, Kv4.3, Kir3.1, TWIK1, HCN4, ClC6 and CALM1, along with weaker expression of mRNA encoding Cx43, Kir2.1, KChIP2, the pumps/exchangers Na(+),K(+)-ATPase, NCX1, SERCA2, and the Ca(2+)-handling proteins RYR2 and CASQ2. Transcripts that were more strongly expressed in epicardium (versus endocardium) included Cav1.2, KChIP2, SERCA2, CALM3 and calcineurin-alpha. Nav1.5 and Nav beta1 were more strongly expressed in the endocardium. For selected genes, RT-PCR data were confirmed at the protein level. This is the first report of the global portrait of regional ion-channel subunit-gene expression in the non-diseased human heart. Our data point to significant regionally determined ion-channel expression differences, with potentially important implications for understanding regional electrophysiology, arrhythmia mechanisms, and responses to ion-channel blocking drugs. Concordance with previous functional studies suggests that regional regulation of cardiac ion-current expression may be primarily transcriptional.