Cardiovascular Research

Cardiovascular Research 2001 52(3):517-518; doi:10.1016/S0008-6363(01)00482-5
© 2001 by European Society of Cardiology

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Copyright © 2001, European Society of Cardiology

Considerations in studying the transient outward K⁺ current in cells exhibiting the hyperpolarization-activated current

Arie O Verkerk^a,* and Antoni C.G van Ginneken^b

^aDepartment of Physiology, Academic Medical Center, University of Amsterdam, Room M01-09, Meibergdreef 15, 1105 AZ Amsterdam, The Netherlands
^bExperimental and Molecular Cardiology Group, Academic Medical Center, University of Amsterdam, Meibergdreef 15, 1105 AZ Amsterdam, The Netherlands

^* Corresponding author. Tel.: +31-20-566-4670; fax: +31-20-691-9319 a.o.verkerk{at}amc.uva.nl

Received 5 June 2001; accepted 14 September 2001

Recently, we focussed our research on cellular electrophysiological changes involved in the modulated sinoatrial (SA) node function during heart failure [1] and aging [2]. Heart failure and age-dependent changes of ionic membrane currents, especially the transient outward K⁺ current (I_to1), are well documented in working myocardium [3,4]. Therefore, we read with interest the paper in Cardiovascular Research by Lei et al. [5], on the characterization of I_to1 in rabbit SA node cells. In their paper, Lei et al. [5] determined (1) the properties of I_to1, (2) the relationship between the I_to1 density and cell size, and (3) the physiological relevance of I_to1 in SA node cell electrophysiology. Based on their findings we hypothesized that changes in I_to1 may also play a role in the altered SA node cycle length during heart failure and aging. In a first set of experiments, we aimed at measuring I_to1 in SA node cells isolated from control and failing rabbit hearts using the voltage-clamp protocols of Lei et al. [5]. Our experiments, however, indicate that accurate measurement of I_to1 is hampered by the presence of the hyperpolarization-activated current (I_f) in these cells.

A well-known feature of mammalian SA node cells is that they exhibit I_f, which plays a role in pacemaker activity [6,7]. I_f, carried by Na⁺ and K⁺ ions, is typically studied by hyperpolarizing voltage-clamp steps from a holding potential of –40 mV. I_f is activated at potentials negative to –50 mV, reflected as a time-dependent increase in inward current. When I_f is activated (by hyperpolarization) and subsequently depolarized, it shows a tail current due to deactivation. This tail current reflects the fully activated current and is often used for studying the reversal potential of I_f [6]. A typical voltage-clamp protocol for measuring the reversal potential is clamping a cell at –80 mV or at more negative potentials, for activating I_f, followed by depolarizing voltage-clamp steps in a range between –40 and +50 mV. Noteworthy, a comparable voltage-clamp protocol is frequently used for studying activation characteristics of I_to1 and was also used in the study of Lei et al. [5]. Therefore, it is likely that I_f tail currents interfere with I_to1 in SA node cells.

Lei et al. [5] measured membrane currents evoked by 200-ms depolarizing pulses from a holding potential of –80 mV. In these experiments, 300 µM CdCl₂ was present to block Ca²⁺ currents, but no attempts were made to rule out a contribution of I_f. An interference of I_f with the I_to1 measurements of Lei et al. [5] (e.g. see their Fig. 1) is suspected by their findings that at potentials negative to –20 mV the current decays in the outward direction, while at potentials positive to –20 mV the current decays in the inward direction. The reversal potential of I_f was found to be around –20 mV [6]. It remains puzzling, however, that in these SA node cells holding current immediately before and after the depolarizing steps is similar (see their Figs. 1 and 3–7). One would expect that immediately before the step I_f is activated to some extent. It might be that Lei et al. [5] used blockers of I_f without mentioning. However, blockade of I_f by drugs is voltage-dependent. CsCl, for example, better blocks I_f at negative than at positive potentials [6]. Therefore, I_f tail currents will still hinder I_to1 measurements. Another possibility is that I_f is not present in the cells used by Lei et al. [5]. Previous work shows that, while a variety of cells from the SA node region exhibit I_f, those from the crista terminalis region do not [6–8]. An important feature of cells isolated from the crista terminalis is the presence of a large I_to1, while a small percentage (5%) of these cells exhibited spontaneous activity [8]. Incorporation of cells from the crista terminalis in the study of Lei et al. [5] might explain the presence of large I_to1 while other reports suggests that I_to1 in freshly isolated SA node cells is rarely observed [9], very small [10], or absent unless the cells were derived from the most peripheral portions of the node [11]. On the other hand, the experiments of Lei et al. [5] were carried out on spindle and/or spider-shaped cells, typical for SA node cells, while cells from the crista terminalis are rod-shaped [8].

In the last part of the study, Lei et al. [5] used 4-aminopyridine (4-AP) as a blocker of I_to1 to study the relevance of I_to1 in SA node cell electrophysiology. They found that 4-AP affected both the action potential and pacemaker activity. However, 4-AP is not a selective blocker of I_to1. In many cardiac cell types including SA node cells, 4-AP not only blocks the transient current but also a sustained outward current (see their Fig. 2). The nature of this 4-AP-sensitive sustained outward current is unclear, but it could either represent: (1) a non-inactivating component of I_to1 [12], (2) the rapid delayed rectifier current [13], (3) the ultra-rapid delayed rectifier current [14]. In addition, 4-AP results in a depolarizing shift of I_f activation [15]. Thus the use of 4-AP seems neither valid to measure accurately the role of I_to1 in SA node cell electrophysiology nor a valid alternative to determining the presence of I_to1 in spontaneous active SA node cells.

In conclusion, we think that an accurate measurement of the contribution of I_to1 in cells that exhibit I_f is hampered by current tails of I_f or specificity of 4-AP.

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