Cardiovascular Research

Cardiovascular Research 2003 58(3):498-500; doi:10.1016/S0008-6363(03)00370-5
© 2003 by European Society of Cardiology

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Copyright © 2003, European Society of Cardiology

Pharmacological electrical remodelling in human atria induced by chronic β-blockade

Carmen Valenzuela^*

Institute of Pharmacology and Toxicology CSIC/UCM, School of Medicine, Universidad Complutense, 28040 Madrid, Spain

carmenva{at}med.ucm.es

^* Tel.: +34-91-384-1474; fax: +34-91-394-1470.

Received 28 March 2003; accepted 1 April 2003

See article by Workman et al. [5] (pages 518–525) in this issue.

Atrial fibrillation (AF) is the most common sustained cardiac arrhythmia found in clinical practice. AF is a supraventricular tachyarrhythmia characterised by uncoordinated atrial activation with consequent deterioration of atrial mechanical function [1]. The ventricular response to AF depends on the electrophysiological properties of the atrio-ventricular (AV) node, the level of vagal or sympathetic tone, and the action of drugs with which the patient is being treated [2]. Very often, AF occurs in conjunction with other cardiovascular diseases, such as hypertension, ischaemic heart disease, valve disease, or cardiac failure. However, in a certain percentage of patients (20–50%) AF is not associated with any underlying pathology [3]. Treatment with β-blockers is considered to be efficacious for controlling the ventricular heart rate during AF, which is likely due to the ability of these drugs to depress the conduction velocity through the AV node. Moreover, in patients with adrenergically mediated AF, β-blockers represent a first-line treatment [4]. However, the underlying mechanism of action of β-blockers in human atrial fibrillation has not been established. In fact, the mechanisms by which most cardioactive drugs are effective in clinical practice are unknown, despite the knowledge of their effects on ionic currents, receptors, signal transduction, etc. Indeed, there is an important gap of knowledge that involves drug effects on the target cells; atrial myocytes from patients with AF, in this case. In this regard, different ethical and technical problems have limited these studies.

In the present issue of Cardiovascular Research, Workman et al. [5] present experimental evidence of an electrical remodelling in human atrial cells from patients chronically treated with β-blockers, the so-called ‘pharmacological remodelling’, consistent with a partial reversion of the electrical AF remodelling. This study represents the first one dealing with the effects of chronic β-blockade in AF patients at the cellular level.

	1 Electrical remodelling during AF

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An abrupt increase in heart frequency, like that observed in AF, induces an immediate (within one action potential) and then a gradual (that arises steady state after several minutes) decrease in the action potential duration (APD) [6]. This shortening of the APD leads to a parallel decrease in the atrial effective refractory period (ERP), shortening the wavelength for re-entry and thus facilitating the occurrence and maintenance of re-entrant arrhythmias like AF. This coincides with functional changes in the L-type Ca²⁺ channel following calcium overload [7–9]. During human AF an electrical remodelling has been described [10,11] that involves changes in several ionic channels and leading to the shortening of the atrial ERP. In fact, patients with paroxysmal and persistent AF show a marked reduction in L-type Ca²⁺ channel expression [12]. The decrease in L-type Ca²⁺ current occurs much faster in experimental animal models than in human beings suffering from AF, indicating the existence of other (likely protective) adaptation mechanisms in human AF [13]. Since the observed shortening of the APD can also be explained by an increased K⁺ conductance, there have been a number of studies performed that have focused on the analysis of a possible electrical remodelling during human AF involving different K⁺ channels [14–17]. A result in contradiction with a shortening of the APD observed during the AF is the finding that both mRNA and protein levels of K⁺ channels are reduced in human atrial cells with persistent AF. Remodelling is likely composed of a series of responses to maintain cell integrity in the face of tachycardia-induced Ca²⁺ overload, starting immediately upon tachycardia onset and developing in different time domains as long as the arrhythmia persists [1]. An acute increase in rate is associated with a significant increase in intracellular Ca²⁺ concentration that persists for up to 50 min after the onset of rapid stimulation [18]. This increase in [Ca²⁺]_i decreases I_Ca by a Ca²⁺-dependent inactivation [19,20], thus preventing Ca²⁺ overload. With regard to K⁺ channels, it has been described that in cells from AF patients I_TO is decreased in a parallel manner with a decreased transcription of Kv4.3, but not of Kv1.4 subunits. Unfortunately, there is very limited information available concerning the effects of AF on I_Kur, I_Kr, and I_Ks. It has been reported that I_K1 and the acetylcholine-activated inward-rectifier I_KACh are increased in patients with AF [21]. The outward component of these currents is important in the late phase of repolarisation and, thus, a decrease in I_K1 and I_KACh could contribute to the observed shortening of the action potential.

	2 Effects of chronic treatment with β-blockers on atrial human action potentials and ionic currents

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In the present issue of this journal, Workman et al. [5] demonstrate that chronic β-blockade of patients with AF leads to an adaptive response concomitant with atrial electrophysiological changes. At the action potential level, the authors observed a lengthening of both APD and ERP in atrial cells from patients chronically treated with β-blockers in comparison with that observed in cells from untreated patients. They also observed a reduced action potential phase 1 velocity as well as a reduction of the heart rate in the atrial cells obtained from the first group of patients. All these electrophysiological changes were found in the absence of any other modification of the overshoot, amplitude or maximum upstroke velocity (V_max). The increase observed in ERP in cells obtained from atria of patients chronically treated with β-blockers was not observed in those obtained from patients with AF and treated with calcium channel antagonists or angiotensin converting enzyme (ACE) inhibitors.

Workman et al. [5] also report the effects of chronic β-blockade on ionic currents recorded in atrial cells obtained from patients suffering from AF. They show a decrease in the amplitude and density of the atrial I_TO in atrial myocytes obtained from patients under chronic β-blockade. From records of I_TO, the authors conclude that chronic β-blockade does not modify the amplitude of I_Ksus, which has been mostly attributed to I_Kur carried by hKv1.5 channels. Workman et al. also compare the effects of chronic β-blockade on the phase 1 V_max and the ERP with the effects induced by 4-aminopyridine (4-AP) in order to correlate these effects with those observed on I_TO. The results obtained with 4-AP mimic those obtained in cells from chronically β-blocked patients. However, although 4-AP is an I_TO blocker, it is also a potent I_Kur antagonist and, therefore, these results have to be taken with caution. Additionally, the authors find a higher R₁ in atrial myocytes from patients who underwent β-blockade than in untreated patients, occurring in parallel with an apparent decrease in the amplitude of I_K1. Thus, the observed changes in the amplitude and density of I_TO, as well as those in R₁, appeared in the absence of changes in I_Ca and I_Ksus.

In contrast to that observed after chronic treatment with β-blockers, chronic administration of calcium channel blockers or ACE inhibitors did not modify APD (both measured at the 50% or 90% repolarization) or ERP. The underlying molecular mechanisms by which the chronic β-blockade induces the electrophysiological effects reported in the present study are unknown at the present time. These changes could be due to modifications either: (1) in the transcription or RNA processing (involving pre RNA splicing, pre RNA editing and RNA destabilisation), or (2) in the translation and post-translational processing (including folding, trafficking, subunit assembly or degradation at the endoplasmic reticulum or Golgi apparatus level, as well as phosphorylation or protein–protein interactions). These modifications could affect the level of functional ion channels in the plasma membrane and, thus, the magnitude of the ionic current [22]. The authors speculate with the notion that if chronic β-stimulation has been shown to alter ion channels via mechanisms including cAMP-regulated modification of transcription [23–25], chronic β-blockade could induce the opposite effects. Whether or not this is the mechanism by which chronic β-blockade induces such electrical remodelling remains to be elucidated in future studies.

	3 Conclusions

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The analysis of the electrophysiological consequences of pharmacological treatment of AF that have proven its efficacy in the clinical practice is undoubtedly of interest. These kinds of studies will help to unravel the mechanisms that underlie the advantages of the use of a given drug. The distinct electrophysiological profiles observed in cells from patients treated with Ca²⁺ channel antagonists, ACE inhibitors, and β-blockers are of crucial interest in the development of new strategies of AF treatment not only based on clinical criteria, but also on molecular and cellular electrophysiological aspects.

Time for primary review 3 days.

	Acknowledgments

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Supported by CICYT SAF2002-02160 and FIS 01/1130 Grants. The author thanks Drs Teresa González and Leandro Sastre for critical reading of the manuscript and useful comments.

	References

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1. Bosch R.F., Nattel S. Cellular electrophysiology of atrial fibrillation. Cardiovasc Res (2002) 54:259–269.[Free Full Text]
2. Fuster V., Ryden L., Asinger R., et al. ACC/AHA/ESC Guidelines for the management of patients with atrial fibrillation. J Am Coll Cardiol (2001) 38:1231–1266.[Free Full Text]
3. Nattel S. New ideas about atrial fibrillation 50 years on. Nature (2002) 415:219–226.[CrossRef][Medline]
4. Kuhlkamp V., Schirdewan A., Stangl K., et al. Use of metoprolol CR/XL to maintain sinus rhythm after conversion from persistent atrial fibrillation: a randomized, double-blind, placebo-controlled study. J Am Coll Cardiol (2000) 36:139–146.[Abstract/Free Full Text]
5. Workman A., Kane K., Russell J., Norrie J., Rankin A. Chronic beta-adrenoceptor blockade and human atrial cell electrophysiology: evidence of pharmacological remodelling. Cardiovasc Res (2003) 58:518–525.[Abstract/Free Full Text]
6. Boyett M.R., Jewell B.R. Analysis of the effects of changes in rate and rhythm upon electrical activity in the heart. Prog Biophys Mol Biol (1980) 36:903–923.
7. Yue L., Feng J., Gaspo R., et al. Ionic remodeling underlying action potential changes in a canine model of atrial fibrillation. Circ Res (1997) 81:512–525.[Abstract/Free Full Text]
8. Yu W.C., Chen S.A., Lee S.H., et al. Tachycardia-induced change of atrial refractory period in humans. Rate dependency and effects of antiarrhythmic drugs. Circulation (1998) 97:2331–2337.[Abstract/Free Full Text]
9. Daoud E.G., Knight B.P., Weiss R., et al. Effect of verapamil and procainamide on atrial fibrillation-induced electrical remodeling in humans. Circulation (1997) 96:1542–1550.[Abstract/Free Full Text]
10. Allessie M., Ausma J., Schotten U. Electrical, contractile and structural remodeling during atrial fibrillation. Cardiovasc Res (2002) 54:230–246.[Abstract/Free Full Text]
11. Wijffels M.C., Kirchhof C.J., Dorland R., Power J., Allessie M.A. Electrical remodeling due to atrial fibrillation in chronically instrumented conscious goats: roles of neurohumoral changes, ischemia, atrial stretch, and high rate of electrical activation. Circulation (1997) 96:3710–3720.[Abstract/Free Full Text]
12. Van Wagoner D.R., Pond A.L., et al. Atrial L-type Ca²⁺ currents and human atrial fibrillation. Circ Res (1999) 85:428–436.[Abstract/Free Full Text]
13. Brundel B.J., Henning R.H., Kampinga H.H., Van Gelder I.C., Crijns H.J. Molecular mechanisms of remodeling in human atrial fibrillation. Cardiovasc Res (2002) 54:315–324.[Abstract/Free Full Text]
14. Brundel B.J., Van Gelder I.C., Henning R.H., et al. Ion channel remodeling is related to intraoperative atrial effective refractory periods in patients with paroxysmal and persistent atrial fibrillation. Circulation (2001) 103:684–690.[Abstract/Free Full Text]
15. Brundel B.J., Van Gelder I.C., Henning R.H., et al. Alterations in potassium channel gene expression in atria of patients with persistent and paroxysmal atrial fibrillation: differential regulation of protein and mRNA levels for K⁺ channels. J Am Coll Cardiol (2001) 37:926–932.[Abstract/Free Full Text]
16. Van Wagoner D.R., Pond A.L., McCarthy P.M., Trimmer J.S., Nerbonne J.M. Outward K⁺ current densities and Kv1.5 expression are reduced in chronic human atrial fibrillation. Circ Res (1997) 80:772–781.[Abstract/Free Full Text]
17. Dobrev D., Graf E., Wettwer E., et al. Molecular basis of downregulation of G-protein-coupled inward rectifying K⁺ current (I_K,ACh) in chronic human atrial fibrillation: decrease in GIRK4 mRNA correlates with reduced I_K,ACh and muscarinic receptor-mediated shortening of action potentials. Circulation (2001) 104:2551–2557.[Abstract/Free Full Text]
18. Sun H., Chartier D., Leblanc N., Nattel S. Intracellular calcium changes and tachycardia-induced contractile dysfunction in canine atrial myocytes. Cardiovasc Res (2001) 49:751–761.[Abstract/Free Full Text]
19. Lee K.S., Marban E., Tsien R.W. Inactivation of calcium channels in mammalian heart cells: joint dependence on membrane potential and intracellular calcium. J Physiol (1985) 364:395–411.[Abstract/Free Full Text]
20. Zuhlke R.D., Pitt G.S., Deisseroth K., Tsien R.W., Reuter H. Calmodulin supports both inactivation and facilitation of L-type calcium channels. Nature (1999) 399:159–162.[CrossRef][Medline]
21. Bosch R.F., Zeng X., Grammer J.B., et al. Ionic mechanisms of electrical remodeling in human atrial fibrillation. Cardiovasc Res (1999) 44:121–131.[Abstract/Free Full Text]
22. Roden D.M., Kupershmidt S. From genes to channels: normal mechanisms. Cardiovasc Res (1999) 42:318–326.[Abstract/Free Full Text]
23. Zhang L.M., Wang Z., Nattel S. Effects of sustained beta-adrenergic stimulation on ionic currents of cultured adult guinea pig cardiomyocytes. Am J Physiol Heart Circ Physiol (2002) 282:H880–H889.[Abstract/Free Full Text]
24. Maki T., Gruver E.J., Davidoff A.J., et al. Regulation of calcium channel expression in neonatal myocytes by catecholamines. J Clin Invest (1996) 97:656–663.[Web of Science][Medline]
25. Liu Q.Y., Rosen M.R., McKinnon D., Robinson R.B. Sympathetic innervation modulates repolarizing K⁺ currents in rat epicardial myocytes. Am J Physiol (1998) 274:H915–H922.[Web of Science][Medline]

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