Cardiovascular Research

Cardiovascular Research 1999 44(1):13-16; doi:10.1016/S0008-6363(99)00214-X
© 1999 by European Society of Cardiology

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Copyright © 1999, European Society of Cardiology

Altered expression of cardiac K⁺ channel genes during sub-acute and healing phases of myocardial infarction

Tatsuto Kiyosue^* and Makoto Arita

Department of Physiology, Oita Medical University, Hasama, Oita 879-5593, Japan

^* Corresponding author. Tel.: +81-97-586-5652; fax: +81-97-549-6046 kiyosue{at}oita-med.ac.jp

Received 24 June 1999; accepted 1 July 1999

See article by Yao et al. [2] (pages 132–145) in this issue.

	1 Remodeling of the heart after myocardial infarction

Top 1 Remodeling of the... 2 Inward rectifier K+... 3 Delayed rectifier K+... 4 Transient outward current... 5 Conclusion References

 
In animal models of myocardial infarction (MI), in which the coronary artery is occluded permanently, the incidence of ventricular arrhythmias is classified into three categories according to when they occur after the onset of MI: acute, sub-acute and chronic phase arrhythmias [1]. In men who suffered from MI, ventricular tachyarrhythmias frequently occur in essentially the same manner as that encountered in the animal models. In the acute phase (within several hours from the onset of MI), the occurrence of life-threatening arrhythmias (ventricular tachycardia and ventricular fibrillation) is common. Reentry and triggered activities are the major causes of such fatal arrhythmias seen during the early phase of MI [1].

The hearts that survive acute MI undergo dynamic remodeling to cope with metabolic and mechanical derangements caused by the MI. Most of the myocytes in the ischaemic region die and are replaced by fibrous tissue. Myocytes surrounding the ischaemic region become hypertrophied. This restructuring phase (the sub-acute phase) starts several hours after the event and lasts for several days [1]. Recently, sufficient evidence has appeared to indicate that transcription and expression of sarcolemmal ion-channel genes are modified in this period.

Prominent changes occur in potassium (K⁺) channel currents. In the study appearing in this issue of Cardiovascular Research, Yao et al. [2] report the alteration in K⁺ currents in rat ventricular myocytes that survived 3 days after experimental MI (sub-acute phase). In cells probably isolated from the border zone, the transient outward (I_to), delayed rectifier (I_K) and inward rectifier (I_K1) currents were found to be depressed. Reduction of both I_to and I_K1 was greater in epicardial than in endocardial myocytes, while I_K was reduced equally in the two populations. Reduction in the current density of I_to, I_K1 and I_K was also reported for canine Purkinje fibers that survived 2 days after MI [3,4]. Similar changes in I_to were observed in failing human hearts [5]. Such findings indicate either that K⁺ channels are vulnerable to the insult of MI or that the process of K⁺ channel protein synthesis is vulnerable to such derangements. Most reports thus far support the latter possibility. There is a good correlation among the values for the reduction in the current density of a given channel (measured with patch-clamp techniques), for the decrease in the expressed channel protein (Western blotting) and for the decrease in mRNA (Northern blotting or RNAse protection assay) after MI. In this article, alterations in the three cardiac K⁺ channel families (I_K1, I_K and I_to) during the sub-acute phase to the chronic phase of MI will be discussed.

	2 Inward rectifier K+ channels after MI

Top 1 Remodeling of the... 2 Inward rectifier K+... 3 Delayed rectifier K+... 4 Transient outward current... 5 Conclusion References

 
In addition to voltage-gated K⁺ (Kv) channels (among others I_K and I_to channels), which are characterized by six membrane-spanning regions including a voltage sensor, cardiac myocytes express a family of inwardly rectifying K⁺ (Kir) channels. The latter family includes classic inward rectifiers (I_K1, Kir 2.x), muscarinic M₂ receptor-coupled ACh-activated K⁺ channels (K_ACh, Kir 3.x), and ATP-sensitive K⁺ channels (K_ATP, Kir 6.x+SURs). Kir channels have only two membrane spanning regions and lack voltage sensors. Their inwardly rectifying property is determined by the channel block caused by intracellular polyamines and/or Mg²⁺.

Akao et al. [6] reported that the expression of K_ATP channel subunits in rats was differentially modified after MI. The K_ATP channel in pancreatic cells is composed of an inward rectifier (Kir 6.2) and a sulfonylurea receptor (SUR1) protein [7]. In rat hearts, mRNAs for SUR1 are not expressed, but SUR2 (a cardiac-type sulfonylurea receptor) and both Kir 6.1 and Kir 6.2 subunits are abundantly expressed [6]. Thus, K_ATP channels in rat heart are thought to be a complex of Kir 6.1 and/or Kir 6.2, and SUR2. After 60 min of regional ischaemia followed by 24–72 h of reperfusion, a two- to three-fold increases in Kir 6.1 mRNA and in protein levels was recognized in ischaemic as well as in non-ischaemic regions in the ventricle. In contrast, mRNAs for Kir 6.2 and SUR2 remained unchanged [6]. Thus, it is likely that increased wall stress in ischaemic as well as in non-ischaemic myocardium is a trigger for the induction of Kir 6.1 mRNA expression in the infarcted hearts.

Reduced I_K1-channel expression during the sub-acute phase of MI, which was reported in Purkinje myocytes by Pinto and Boyden [4], may have a particular pathophysiological significance. These authors showed that I_K1 conductance was markedly reduced in sub-endocardial canine Purkinje myocytes that survived 48 h after infarction. Delayed ventricular arrhythmias during the sub-acute phase with a single focus or multiple foci are thought to be caused by enhanced automaticity of subendocardial Purkinje fibers [8] (also see [1]). To recall the importance of I_K1 in determining firing frequency in this tissue, the latter was simulated using the Oxsoft Heart program (OXSOFT ver 4.0, Oxsoft Ltd.). As shown in Fig. 1(A and B), a 50% reduction of the I_K1 conductance markedly increased the frequency of automatic firing in the Purkinje fiber model. In contrast, a 50% reduction of I_K or I_to conductance modifies the action potential configuration (particularly in the case of I_K), while the effects of reduction of these currents on spontaneous activity were minimal (Fig. 1C and D).

View larger version (22K): [in this window] [in a new window] [Download PowerPoint slide]   Fig. 1 Simulation of the effects of reduced (by 50%) conductance of IK1, IK and Ito on automaticity and action potential configuration of a Purkinje fiber, using the Oxsoft Heart program (version 4.0, OXSOFT Ltd.). Decreased K+ conductance during remodeling of the heart after myocardial infarction may be arrhythmogenic either by enhancing the automaticity of subendocardial Purkinje fibers (panel B) or by modifying the time course of repolarization of the action potentials (panels C and D).

 

	3 Delayed rectifier K+ channels after MI

Top 1 Remodeling of the... 2 Inward rectifier K+... 3 Delayed rectifier K+... 4 Transient outward current... 5 Conclusion References

 
Yao et al. [2] reported that the current density of ‘I_K’ was decreased in rat ventricular myocytes that survived 3 days after MI. However, there is some confusion in the terminology of the delayed rectifier K⁺ channel in rats, since ‘I_K’ in this species denotes a slowly inactivating K⁺ channel current [9]. The ‘I_K’ in rat is neither the E-4031-sensitive I_Kr (ERG, ether-a-go-go related gene) nor the chromanol 293B-sensitive I_Ks current (KvLQT1+minK). As noted by Yao et al. [2], the ‘I_K’ is a TEA-sensitive, slowly decaying current, which is activated by depolarizations from deep negative holding potentials. The cDNA that encodes the rat ventricular ‘I_K’ channel is not known at this time.

In canine Purkinje myocytes, an E-4031-sensitive plateau current increased after MI [4]. However, because the current lacks an inward going rectification property at positive potentials, it is not the authentic I_Kr. In the canine model of MI, the mRNAs of ERG, KvLQT1, and minK are all reduced after MI [10]. In human explanted failing hearts (some are from patients with ischaemic cardiomyopathy), however, the mRNA level of HERG (human ERG) was not changed [5]. Anyhow, at present, information on the current and the gene expression of the I_Kr and I_Ks channels after MI is very limited.

	4 Transient outward current after MI

Top 1 Remodeling of the... 2 Inward rectifier K+... 3 Delayed rectifier K+... 4 Transient outward current... 5 Conclusion References

 
Qin et al. [11] have shown that hypertrophied post-MI rat ventricular myocytes (2 to 4 weeks after LAD ligation) had prolonged action potential duration, due to a decreased density of I_to-f and I_to-s (these two components were separated by the decaying time course). Gidh-Jain et al. [12] used the same model and reported that the mRNA and protein levels of Kv 2.1 and Kv 4.2 subunits were both decreased. These authors also suggested that the decreased I_to current density is secondary to the hypertrophy of the cells. Namely, the density of I_to decreased due to an increased membrane surface area, since the amplitude of I_to in a cell that survived MI was not different from the control. Using similar MI model of rat at much a earlier stage of MI (3 days after the coronary ligation) in which hypertrophy of the myocytes was not detectable, Yao et al. [2] demonstrated that both the I_to current and the expression of Kv 4 series channel proteins were significantly reduced.

In rat hearts, I_to plays a major role in action potential repolarization. It is widely accepted that shal-type voltage-gated K⁺ channels (Kv 4.2 and/or Kv 4.3) are the pore-forming subunits of the I_to channel in adult rat, dog and human hearts [13,14]. Recently, it was shown that the Kv 1.4 subunit functions to form rabbit I_to channels [14]. The I_to density was reduced in many pathological conditions, including acute or chronic diabetes mellitus [15,16], hypertrophy induced by pressure or volume overload (see [17]), and failing hearts isolated from patients with dilated or ischaemic cardiomyopathy [5]. Unidentified common pathway(s) may underlie a down-regulation of the expression of I_to channels in these pathological conditions. Possible candidates for triggering such channel remodeling could be altered levels of intracellular Ca²⁺, cAMP, cytokines (interleukins, interferons, tumor necrosis factor and so on) as well as oxygen-free radicals [18].

	5 Conclusion

Top 1 Remodeling of the... 2 Inward rectifier K+... 3 Delayed rectifier K+... 4 Transient outward current... 5 Conclusion References

 
During the sub-acute phase of myocardial infarction, the expression of potassium channels, e. g., the channels of inward rectifiers, delayed rectifiers and transient outward K⁺ currents is modified. The changes in expression may be, at least in part, responsible for the occurrence of ectopic automaticities reported to occur in the subendocardial region of the ventricle [1]. Among these K⁺ channel families, I_K1 may have particular importance, since it acts to maintain the diastolic membrane potential of ventricular and Purkinje myocytes close to the K⁺ equilibrium potential (–90 mV). Thus, the reduction in the I_K1 conductance seen after MI may cause the membrane potential to become less negative and approach the threshold potential of action potential firing, thereby providing a basis for abnormal automaticity. On the other hand, a concomitant reduction in I_K and I_to should delay action potential repolarization and provide electrical substrates for the initiation of early after-depolarization (EAD) or delayed after-depolarization (DAD), in otherwise quiescent ventricular myocardium.

	References

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