[Effects of N-stearoyl- and N-oleoylethanolamine on cardiac voltage-dependent sodium channels].

The group of N-acylethanolamines (NAE) includes lipids that are capable of modulating plasma membrane ion channels without involvement of cannabinoid receptors. However, the action of various members of NAE on voltage-gated Na+ channels (VGSC) in cardiac tissue is still not fully elucidated. Here using patch-clamp technique we have studied the modulation of biophysical properties of VGSC of neonatal cardiomyocytes by saturated N-stearoylethanolamine (NSE) and monounsaturated N-oleoylethanolamine (OEA). NSE in 1-200 tM concentration range did not significantly alter the amplitude of inward Na+ current (I(Na)), but 100 microM NSE shifted its steady-state activation and inactivation curves in hyperpolarization direction by 2.4 mV and 10.6 mV, respectively. Activation kinetics of the current was not changed by NSE, but its inactivation was accelerated by about 1.2-fold in the -60 - -30 mV range of membrane potentials. Unlike NSE, OEA dose-dependently inhibited I(Na) with kappa(D) = 11.4 +/- 1.6 microM and maximal block at saturating concentration of 30 +/- 3%. It also stronger than NSE shifted current's steady-state activation and inactivation curves (-6.4 mV and -14.0 mV, respectively, at 100 microM) in hyperpolarization direction. The effect of OEA on I(Na) activation kinetics was negligible, but it more pronouncedly than NSE accelerated inactivation of the current. Thus, both members of NAE influence the voltage-dependence of activation, inactivation and kinetics of I(Na). These effects were more prominent for monounsaturated OEA, which also partially blocked I(Na). The discovered effects of NSE and OEA on VGSCs may in part be responsible for the decrease of cardiomycytes' excitability by these lipids under normal as well as pathologic conditions.

[Regulation of the excitability of neonatal cardiomyocytes by N-stearoyl- and N-oleoyl-ethanolamines].

N-acylethanolamines (NAE) are biologically active lipids able of modulating ion transport through the cellular plasma membrane, however specific targets of their action and signalling mechanisms involved in cardiac tissue are still poorly understood. Physiological activity of NAEs is known to depend on the level of unsaturation. Therefore, here we investigated the effects of saturated N-stearylethanolamine (NSE) and monounsaturated N-oleylethanolamine on electric excitability of neonatal rat cardiomyocytes. 1 microM of either NSE or OEA decreased the duration of cardiac action potential (AP) from all parts of heart muscle. Shortening of AP was partially reversible, though the reversibility of AP duration upon washout of substances was more complete for endocardial ventricular compared to epicardial and atrial cardiomyocytes. I microM NSE depolarized resting membrane potential (RMP) of epicardial and of 65% of endocardial cells, whilst other cells types showed weakly reversible hyperpolarization. 1 microM OEA caused reversible RMP hyperpolarization of all studied cell types. NSE and OEA decreased the amplitude and upstroke velocity of AP that suggests their effect on sodium channels. NSE and to a lesser extent OEA inhibited the amplitude of AP phase 2 (plateau) which may indicate an inhibition of high-voltage-activated calcium channels. Effects of NSE and OEA on RMP and repolarization phase of AP (phase 3) depended on cardiac cell type suggesting differential regulation of inward rectifier Kir and voltage-gated delayed rectifier potassium channels by these lipids. We cannot also exclude interaction of NSE and OEA with anion channels, backgound K+ channels and ion transporters of the cardiomyocytes' plasma membrane. Overall, NSE-induced changes of AP parameters were less reversible than those induced by OEA, suggesting a slower degradation/ convertion of NSE in plasma membrane compared to OEA.

[Identification of E-4031-sensitive potassium current component in murine P19 embryonic carcinoma cell line differentiated in cardiomyocytes].

Pluripotent mouse P19 embryonic carcinoma cells represent a convenient in vitro model for studying various aspects of cardiac differentiation. Here by using whole-cell patch-clamp recording we have identified the rapid delayed rectifier K+ current, I(Kr) in P19 cell induced to differentiate into cardiac phenotype by DMSO (1%). Cardiac differentiation was confirmed by the appearance of spontaneously beating cells, their morphological features, ultrastructural clusterization of mitochondria around contraction elements, expression of cardiac actin mRNAs and MLC2v, and by the presence of inward sodium and calcium currents. I(Kr) was isolated based on the sensitivity to the specific blocker, E-4031, which at concentration of 1 MM blocked more than 50% of the total outward K+ current. However, in contrast to I(Kr) in native cardiac myocytes and in heterologous systems expressing I(Kr)-carrying ERG1 potassium channel, E-4031-sensitive K+ current in cardiac-like P19 cells lacked characteristic inward rectification, suggesting specific regulation and/or subunit composition of endogenous ERG -based channel in these cells. Establishing the reason(s) for this phenomenon will advance the understanding of the mechanisms of I(Kr)-channel rectification. Cardiac-differentiated P19 cells might also be useful for studying pharmacological modulation of I(Kr), which is recognized target for cardiotoxic side effects of numerous drugs.