Electrophysiological response of rat atrial myocytes to acidosis

The effect of acidosis on the electrical activity of isolated rat atrial myocytes was investigated using the patch-clamp technique. Reducing the pH of the bathing solution from 7.4 to 6.5 shortened the action potential. Acidosis had no significant effect on transient outward or inward rectifier currents but increased steady-state outward current. This increase was still present, although reduced, when intracellular Ca(2+) was buffered by 1,2-bis(2-aminophenoxy)ethane-N,N,N',N'-tetraacetic acid (BAPTA); BAPTA also inhibited acidosis-induced shortening of the action potential. Ni(2+) (5 mM) had no significant effect on the acidosis-induced shortening of the action potential. Acidosis also increased inward current at -80 mV and depolarized the resting membrane potential. Acidosis activated an inwardly rectifying Cl(-) current that was blocked by 4,4'-diisothiocyanostilbene-2,2'-disulfonic acid (DIDS), which also inhibited the acidosis-induced depolarization of the resting membrane potential. It is concluded that an acidosis-induced increase in steady-state outward K(+) current underlies the shortening of the action potential and that an acidosis-induced increase in inwardly rectifying Cl(-) current underlies the depolarization of the resting membrane potential during acidosis.     

兔左室壁三层心肌细胞的分离及动作电位、钙和钾电流分布的异质性

探讨兔左室壁三层心肌单个细胞的分离方法以及电生理特征,实验以胶原酶按二步消化法分离兔心肌细胞,其中用剃须刀分离左室游离壁内,中,外三层心肌,采用全细胞膜片钳记录AP和离子电流,结果显示：（1）中层细胞上的动作电位时程明显长于内膜下心肌和外膜下心肌,且存在显著的1相切迹和2相驼峰;（2）中层细胞的Ica,L和Lto较内,外膜下的大,IK,s相反,可见三层心肌细胞上多种电流存在显著差异。     

Altered spatial calcium regulation enhances electrical heterogeneity in the failing canine left ventricle: implications for electrical instability

Myocytes across the left ventricular (LV) wall of the mammalian heart are known to exhibit heterogeneity of electrophysiological properties; however, the transmural variation of cellular electrophysiology and Ca(2+) homeostasis in the failing LV is incompletely understood. We studied action potentials (APs), the L-type calcium (Ca(2+)) current (I(Ca,L)), and intracellular Ca(2+) transients ([Ca(2+)](i)) of subendocardial (Endo), midmyocardial (Mid), and subepicardial (Epi) tissue layers in the canine normal and tachycardia pacing-induced failing left ventricles. Heart failure (HF) was associated with significant prolongation of the AP duration in Mid myocytes. There were no differences in I(Ca,L) density in normal Endo, Mid, and Epi myocytes, whereas in the failing heart, I(Ca,L) density was downregulated by 45% and 26% (at +10 mV) in Endo and Mid myocytes, respectively. The rates of sarcoplasmic reticulum (SR) Ca(2+) release and decay of the [Ca(2+)](i) were slowed, and the amplitude of the [Ca(2+)](i) was depressed in Endo and Epi myocytes isolated from failing, compared with normal, hearts. Experiments in sodium (Na(+))-free solutions showed that Epi and Mid myocytes of the failing ventricle exhibit a greater reliance on the Na(+)-Ca(2+) exchanger to remove cytosolic Ca(2+) than myocytes isolated from normal hearts. Simulation studies in Endo, Mid, and Epi canine myocytes demonstrate the importance of L-type current density and SR Ca(2+) uptake in modulating the potentially arrhythmogenic repolarization in HF. In conclusion, these results demonstrate that spatially heterogeneous decreases in I(Ca,L) and defective cytosolic Ca(2+) removal contribute to the altered [Ca(2+)](i) and AP profiles across the canine failing LV. These distinct electrophysiological features in myocytes from a failing heart contribute to a characteristic electrogram arising from increased dispersion of refractoriness across the LV, which may result in significant arrhythmogenic sequellae.     

Functionally distinct sodium channels in ventricular epicardial and endocardial cells contribute to a greater sensitivity of the epicardium to electrical depression

A greater depression of the action potential (AP) of the ventricular epicardium (Epi) versus endocardium (Endo) is readily observed in experimental models of acute ischemia and Brugada syndrome. Endo and Epi differences in transient outward K(+) current and/or ATP-sensitive K(+) channel current are believed to contribute to the differential response. The present study tested the hypothesis that the greater sensitivity of Epi is due in part to its functionally distinct early fast Na(+) current (I(Na)). APs were recorded from isolated Epi and Endo tissue slices and coronary-perfused wedge preparations before and after exposures to elevated extracellular K(+) concentration ([K(+)](o); 6-12 mM). I(Na) was recorded from Epi and Endo myocytes using whole cell patch-clamp techniques. In tissue slices, increasing [K(+)](o) to 12 mM reduced V(max) to 51.1 +/- 5.3% and 26.8 +/- 9.6% of control in Endo (n = 9) and Epi (n = 14), respectively (P < 0.05). In wedge preparations (n = 12), the increase in [K(+)](o) caused selective depression of Epi APs and transmural conduction slowing and block. I(Na) density was not significantly different between Epi (n = 14) and Endo (n = 15) cells, but Epi cells displayed a more negative half-inactivation voltage [-83.6 +/- 0.1 and -75.5 +/- 0.3 mV for Epi (n = 16) and Endo (n = 16), respectively, P < 0.05]. Our data suggest that reduced I(Na) availability in ventricular Epi may contribute to its greater sensitivity to electrical depression and thus may contribute to the R-ST segment changes observed under a variety of clinical conditions including acute myocardial ischemia, severe hyperkalemia, and Brugada syndrome.     

Regional differences in effects of exercise training on contractile and biochemical properties of rat cardiac myocytes.

Myocardial function is enhanced by endurance exercise training, but the cellular mechanisms underlying this improved function remain unclear. A number of studies have shown that the characteristics of cardiac myocytes vary across the width of the ventricular wall. We have previously shown that endurance exercise training alters the Ca2+ sensitivity of tension as well as contractile protein isoform expression in rat cardiac myocytes. We tested the hypothesis that these effects of training are not uniform across the ventricular wall but are more pronounced in the subendocardial (Endo) region of the myocardium. Female Sprague-Dawley rats were divided into sedentary control (C) and exercise trained (T) groups. T rats underwent 11 wk of progressive treadmill exercise. Myocytes were isolated from the Endo region of the myocardium and from the subepicardial (Epi) region of both T and C hearts. We found an increase in the Ca2+ sensitivity of tension in T cells compared with C cells, but this difference was larger in the Endo cells than in the Epi cells. In addition, we found a training-induced increase in atrial myosin light chain 1 (aMLC1) expression that was larger in the Endo compared with Epi samples. We conclude that effects of exercise training on myocyte contractile and biochemical properties are greater in myocytes from the Endo region of the myocardium than those from the Epi region. In addition, these results provide evidence that the increase in aMLC1 expression may be responsible for some of the training-induced increase in myocyte Ca2+ sensitivity of tension.     

Aging-associated changes in whole cell K(+) and L-type Ca(2+) currents in rat ventricular myocytes

The effect of aging on cardiac membrane currents remains unclear. This study examined the inward rectifier K(+) current (I(K1)), the transient outward K(+) current (I(to)), and the L-type Ca(2+) channel current (I(Ca,L)) in ventricular myocytes isolated from young adult (6 mo) and aged (>27 mo) Fischer 344 rats using whole cell patch-clamp techniques. Along with an increase in the cell size and membrane capacitance, aged myocytes had the same magnitude of peak I(K1) with a greater slope conductance but displayed smaller steady-state I(K1). Aged myocytes also had a greater I(to) with an increased rate of activation, but the I(to) inactivation kinetics, steady-state inactivation, and responsiveness to L-phenylephrine, an alpha(1)-adrenergic agonist, were unaltered. The magnitude of peak I(Ca,L) in aged myocytes was decreased and accompanied by a slower inactivation, but the I(Ca,L) steady-state inactivation was unaltered. Action potential duration in aged myocytes was prolonged only at 90% of full repolarization (APD(90)) when compared with the action potential duration of young adult myocytes. Aged myocytes from Long-Evans rats showed similar changes in I(to) and I(Ca,L) but an increased I(K1). These results demonstrate aging-associated changes in action potential, in morphology, and in I(K1), I(to), and I(Ca,L) of rat ventricular myocytes that possibly contribute to the decreased cardiac function of aged hearts.     

Tamoxifen inhibits Na+ and K+ currents in rat ventricular myocytes

Tamoxifen is an estrogen receptor antagonist used in the treatment of breast cancer. However, tamoxifen has been shown to induce QT prolongation of the electrocardiogram, thereby potentially causing life-threatening polymorphic ventricular arrhythmias. The purpose of the present study was to elucidate the electrophysiological mechanism(s) that underlie the arrhythmogenic effects of tamoxifen. We used standard ruptured whole cell and perforated patch-clamping techniques on rat ventricular myocytes to investigate the effects of tamoxifen on cardiac action potential (AP) waveforms and the underlying K+ currents. Tamoxifen (3 micromol/l) markedly prolonged AP duration, decreased maximal rate of depolarization, and decreased resting membrane potential. At this concentration, tamoxifen significantly depressed the Ca2+-independent transient outward K+ current (Ito), sustained outward delayed rectifier K+ current (Isus), inward rectifier K+ current (IK1), and Na+ current (INa) in the myocytes. Lower concentrations of tamoxifen (1 micromol/l) also decreased the resting membrane potential and significantly depressed IK1 to 79 +/- 5% (n = 5; at -120 mV) of pretreatment values. The results of this study indicate that inhibition of Ito, Isus, and IK1 by tamoxifen may underlie AP prolongation in cardiac myocytes and thereby contribute to prolonged QT interval observed in patients.     

Modeling of IK1 mutations in human left ventricular myocytes and tissue

Elucidation of the cellular basis of arrhythmias in ion channelopathy disorders is complicated by the inherent difficulties in studying human cardiac tissue. Thus we used a computer modeling approach to study the mechanisms of cellular dysfunction induced by mutations in inward rectifier potassium channel (K(ir))2.1 that cause Andersen-Tawil syndrome (ATS). ATS is an autosomal dominant disorder associated with ventricular arrhythmias that uncommonly degenerate into the lethal arrhythmia torsade de pointes. We simulated the cellular and tissue effects of a potent disease-causing mutation D71V K(ir)2.1 with mathematical models of human ventricular myocytes and a bidomain model of transmural conduction. The D71V K(ir)2.1 mutation caused significant action potential duration prolongation in subendocardial, midmyocardial, and subepicardial myocytes but did not significantly increase transmural dispersion of repolarization. Simulations of the D71V mutation at shorter cycle lengths induced stable action potential alternans in midmyocardial, but not subendocardial or subepicardial cells. The action potential alternans was manifested as an abbreviated QRS complex in the transmural ECG, the result of action potential propagation failure in the midmyocardial tissue. In addition, our simulations of D71V mutation recapitulate several key ECG features of ATS, including QT prolongation, T-wave flattening, and QRS widening. Thus our modeling approach faithfully recapitulates several features of ATS and provides a mechanistic explanation for the low frequency of torsade de pointes arrhythmia in ATS.     

Properties of a tonically active, sodium-permeable current in mouse urinary bladder smooth muscle

Urinary bladder smooth muscle (UBSM) elicits depolarizing action potentials, which underlie contractile events of the urinary bladder. The resting membrane potential of UBSM is approximately -40 mV and is critical for action potential generation, with hyperpolarization reducing action potential frequency. We hypothesized that a tonic, depolarizing conductance was present in UBSM, functioning to maintain the membrane potential significantly positive to the equilibrium potential for K(+) (E(K); -85 mV) and thereby facilitate action potentials. Under conditions eliminating the contribution of K(+) and voltage-dependent Ca(2+) channels, and with a clear separation of cation- and Cl(-)-selective conductances, we identified a novel background conductance (I(cat)) in mouse UBSM cells. I(cat) was mediated predominantly by the influx of Na(+), although a small inward Ca(2+) current was detectable with Ca(2+) as the sole cation in the bathing solution. Extracellular Ca(2+), Mg(2+), and Gd(3+) blocked I(cat) in a voltage-dependent manner, with K(i) values at -40 mV of 115, 133, and 1.3 microM, respectively. Although UBSM I(cat) is extensively blocked by physiological extracellular Ca(2+) and Mg(2+), a tonic, depolarizing I(cat) was detected at -40 mV. In addition, inhibition of I(cat) demonstrated a hyperpolarization of the UBSM membrane potential and decreased the amplitude of phasic contractions of isolated UBSM strips. We suggest that I(cat) contributes tonically to the depolarization of the UBSM resting membrane potential, facilitating action potential generation and thereby a maintenance of urinary bladder tone.     

氧自由基致豚鼠心室肌细胞跨膜电位变化的离子电流基础

目的：旨在提示氧自由基参与缺血／再灌注性心委失常发生的离子电流基础。方法：采用膜片钳全细胞式记录技术,观察Ｈ２Ｏ２（１ｍｍｏｌ／Ｌ）对豚鼠心室肌细胞跨膜电位和相关离子电流的影响。结果：Ｈ２Ｏ２使豚鼠心肌单细胞的静息电位（ＲＰ）降低,动作电位时程（ＡＳＤ）显著缩短,对动作电位幅度（ＡＰＡ）和超射（ＯＳ）及钠电流的峰值（ＩＮａ）均无明显影响;明显抑制内向整流钾电流（ＩＫ１）,尤其在超极化时;增强延迟外     

Differential sensitivity of inward rectifier K+ channels to metabolic inhibitors

Inhibition of inward rectifier K(+) channels under ischemic conditions may contribute to electrophysiological consequences of ischemia such as cardiac arrhythmia. Ischemia causes metabolic inhibition, and the use of metabolic inhibitors is one experimental method of simulating ischemia. The effects of metabolic inhibitors on the activity of inward rectifier K(+) channels K(ir)2.1, K(ir)2.2, and K(ir)2.3 were studied by heterologous expression in Xenopus oocytes and two-electrode voltage clamp. 10 microm carbonyl cyanide p-trifluoromethoxyphenylhydrazone (FCCP) inhibited K(ir)2.2 and K(ir)2.3 currents but was without effect on K(ir)2.1 currents. The rate of decline of current in FCCP was faster for K(ir)2.3 than for K(ir)2.2. K(ir)2.3 was inhibited by 3 mm sodium azide (NaN(3)), whereas K(ir)2.1 and K(ir)2.2 were not. K(ir)2.2 was inhibited by 10 mm NaN(3). All three of these inward rectifiers were inhibited by lowering the pH of the solution perfusing inside-out membrane patches. K(ir)2.3 was most sensitive to pH (pK = 6.9), whereas K(ir)2.1 was least sensitive (pK = 5.9). For K(ir)2.2 the pK was 6.2. These results demonstrate the differential sensitivity of these inward rectifiers to metabolic inhibition and internal pH. The electrophysiological response of a particular cell type to ischemia may depend on the relative expression levels of different inward rectifier genes.     

Frequency-dependent and proarrhythmogenic effects of FK-506 in rat ventricular cells

FK-506, a widely used immunosuppressant, has caused a few clinical cases with QT prolongation and torsades de pointe at high blood concentration. The proarrhytmogenic potential of FK-506 was investigated in single rat ventricular cells using the whole cell clamp method to record action potentials (APs) and ionic currents. Fluorescence measurements of Ca2+ transients were performed with indo-1 AM using a multiphotonic microscope. FK-506 (25 micromol/l) hyperpolarized the resting membrane potential (RMP; -3 mV) and prolonged APs (AP duration at 90% repolarization increased by 21%) at 0.1 Hz. Prolongation was enhanced by threefold at 3.3 Hz, and early afterdepolarizations (EADs) occurred in 59% of cells. EADs were prevented by stronger intracellular Ca2+ buffering (EGTA: 10 vs. 0.5 mmol/l in the patch pipette) or replacement of extracellular Na+ by Li+, which abolishes Na+/Ca2+ exchange [Na+/Ca2+ exchanger current (INaCa)]. In indo-1-loaded cells, FK-506 generated doublets of Ca(2+) transients associated with increased diastolic Ca2+ in one-half of the cells. FK-506 reversibly decreased the L-type Ca2+ current (ICaL) by 25%, although high-frequency-dependent facilitation of ICaL persisted, and decreased three distinct K+ currents: delayed rectifier K+ current (IK; >80%), transient outward K+ current (<20%), and inward rectifier K+ current (IK1; >40%). A shift in the reversal potential of IK1 (-5 mV) accounted for RMP hyperpolarization. Numerical simulations, reproducing all experimental effects of FK-506, and the use of nifedipine showed that frequency-dependent facilitation of ICaL plays a role in the occurrence of EADs. In conclusion, the effects of FK-506 on the cardiac AP are more complex than previously reported and include inhibitions of IK1 and ICaL. Alterations in Ca2+ release and INaCa may contribute to FK-506-induced AP prolongation and EADs in addition to the permissive role of ICaL facilitation at high rates of stimulation.     

Dynamical description of sinoatrial node pacemaking: improved mathematical model for primary pacemaker cell

We developed an improved mathematical model for a single primary pacemaker cell of the rabbit sinoatrial node. Original features of our model include 1) incorporation of the sustained inward current (I(st)) recently identified in primary pacemaker cells, 2) reformulation of voltage- and Ca(2+)-dependent inactivation of the L-type Ca(2+) channel current (I(Ca,L)), 3) new expressions for activation kinetics of the rapidly activating delayed rectifier K(+) channel current (I(Kr)), and 4) incorporation of the subsarcolemmal space as a diffusion barrier for Ca(2+). We compared the simulated dynamics of our model with those of previous models, as well as with experimental data, and examined whether the models could accurately simulate the effects of modulating sarcolemmal ionic currents or intracellular Ca(2+) dynamics on pacemaker activity. Our model represents significant improvements over the previous models, because it can 1) simulate whole cell voltage-clamp data for I(Ca,L), I(Kr), and I(st); 2) reproduce the waveshapes of spontaneous action potentials and ionic currents during action potential clamp recordings; and 3) mimic the effects of channel blockers or Ca(2+) buffers on pacemaker activity more accurately than the previous models.     

Targeting intracellular calcium cycling in catecholaminergic polymorphic ventricular tachycardia: a theoretical investigation

Catecholaminergic polymorphic ventricular tachycardia (CPVT) is a malignant arrhythmogenic disorder linked to mutations in the cardiac ryanodine receptor (RyR2) and calsequestrin, predisposing the young to syncope and cardiac arrest. To define the role of β-adrenergic stimulation (BAS) and to identify potential therapeutic targeted sites relating to intracellular calcium cycling, we used a Luo-Rudy dynamic ventricular myocyte model incorporated with interacting Markov models of the L-type Ca(2+) channel (I(Ca,L)) and RyR2 to simulate the heterozygous state of mouse RyR2 R4496C mutation (RyR2(R4496C+/-)) comparable with CPVT patients with RyR2 R4497C mutation. Characteristically, in simulated cells, pacing at 4 Hz or faster or pacing at 2 Hz under BAS with effects equivalent to those of isoproterenol at ≥ 0.1 μM could readily induce delayed afterdepolarizations (DADs) and DAD-mediated triggered activity (TA) in RyR2(R4496C+/-) but not in the wild-type via enhancing both I(Ca,L) and sarcoplasmic reticulum (SR) Ca(2+) ATPase (I(UP)). Moreover, with the use of steady state values of isolated endocardial (Endo), mid-myocardial (M), and epicardial (Epi) cells as initial data for conducting single cell and one-dimensional strand studies, the M cell was more vulnerable for developing DADs and DAD-mediated TA than Endo and Epi cells, and the gap junction coupling represented by diffusion coefficient (D) of ≤ 0.000766*98 cm(2)/ms was required for generating DAD-mediated TA in RyR2(R4496C+/-). Whereas individual reduction of Ca(2+) release channel of SR and Na-Ca exchanger up to 50% was ineffective, 30% or more reduction of either I(Ca,L) or I(UP) could totally suppress the inducibility of arrhythmia under BAS. Of note, 15% reduction of both I(Ca,L) and I(UP) exerted a synergistic antiarrhythmic efficacy. Findings of this model study confirm that BAS facilitates induction of ventricular tachyarrhythmias via its action on intracellular Ca(2+) cycling and a pharmacological regimen capable of reducing I(Ca,L) could be an effective adjunctive to β-adrenergic blockers for suppressing ventricular tachyarrhythmias during CPVT.     

Role of vascular potassium channels in the regulation of renal hemodynamics

K(+) conductance is a major determinant of membrane potential (V(m)) in vascular smooth muscle (VSMC) and endothelial cells (EC). The vascular tone is controlled by V(m) through the action of voltage-operated Ca(2+) channels (VOCC) in VSMC. Increased K(+) conductance leads to hyperpolarization and vasodilation, while inactivation of K(+) channels causes depolarization and vasoconstriction. K(+) channels in EC indirectly participate in the control of vascular tone by several mechanisms, e.g., release of nitric oxide and endothelium-derived hyperpolarizing factor. In the kidney, a change in the activity of one or more classes of K(+) channels will lead to a change in hemodynamic resistance and therefore of renal blood flow and glomerular filtration pressure. Through these effects, the activity of renal vascular K(+) channels influences renal salt and water excretion, fluid homeostasis, and ultimately blood pressure. Four main classes of K(+) channels [calcium activated (K(Ca)), inward rectifier (K(ir)), voltage activated (K(V)), and ATP sensitive (K(ATP))] are found in the renal vasculature. Several in vitro experiments have suggested a role for individual classes of K(+) channels in the regulation of renal vascular function. Results from in vivo experiments are sparse. We discuss the role of the different classes of renal vascular K(+) channels and their possible role in the integrated function of the renal microvasculature. Since several pathological conditions, among them hypertension, are associated with alterations in K(+) channel function, the role of renal vascular K(+) channels in the control of salt and water excretion deserves attention.     

Increasing I(Ks) corrects abnormal repolarization in rabbit models of acquired LQT2 and ventricular hypertrophy

Excessive action potential (AP) prolongation and early afterdepolarizations (EAD) are triggers of malignant ventricular arrhythmias. A slowly activating delayed rectifier K+ current (I(Ks)) is important for repolarization of ventricular AP. We examined the effects of I(Ks) activation by a new benzodiazepine (L3) on the AP of control, dofetilide-treated, and hypertrophied rabbit ventricular myocytes. In both control and hypertrophied myocytes, L3 activated I(Ks) via a negative shift in the voltage dependence of activation and a slowing of deactivation. L3 had no effect on L-type Ca(2+) current or other cardiac K+ currents tested. L3 shortened AP of control, dofetilide-treated, and hypertrophied myocytes more at 0.5 than 2 Hz. Selective activation of I(Ks) by L3 attenuates prolonged AP and eliminated EAD induced by rapidly activating delayed rectifier K+ current inhibition in control myocytes at 0.5 Hz and spontaneous EAD in hypertrophied myocytes at 0.2 Hz. Pharmacological activation of I(Ks) is a promising new strategy to suppress arrhythmias resulting from excessive AP prolongation in patients with certain forms of long QT syndrome or cardiac hypertrophy and failure.     

Regulation of cell proliferation of human induced pluripotent stem cell-derived mesenchymal stem cells via ether-à-go-go 1 (hEAG1) potassium channel

The successful generation of a high yield of mesenchymal stem cells (MSCs) from human induced pluripotent stem cells (iPSCs) may represent an unlimited cell source with superior therapeutic benefits for tissue regeneration to bone marrow (BM)-derived MSCs. We investigated whether the differential expression of ion channels in iPSC-MSCs was responsible for their higher proliferation capacity than BM-MSCs. The expression of ion channels for K(+), Na(+), Ca(2+), and Cl(-) was examined by RT-PCR. The electrophysiological properties of iPSC-MSCs and BM-MSCs were then compared by patch-clamp experiments to verify their functional roles. Significant mRNA expression of ion channel genes including KCa1.1, KCa3.1, KCNH1, Kir2.1, SCN9A, CACNA1C, and Clcn3 was observed in both human iPSC-MSCs and BM-MSCs, whereas Kir2.2 and Kir2.3 were only detected in human iPSC-MSCs. Five types of currents [big-conductance Ca(2+)-activated K(+) current (BK(Ca)), delayed rectifier K(+) current (IK(DR)), inwardly rectifying K(+) current (I(Kir)), Ca(2+)-activated K(+) current (IK(Ca)), and chloride current (I(Cl))] were found in iPSC-MSCs (83%, 47%, 11%, 5%, and 4%, respectively) but only four of them (BK(Ca), IK(DR), I(Kir), and IK(Ca)) were identified in BM-MSCs (76%, 25%, 22%, and 11%, respectively). Cell proliferation was examined with MTT or bromodeoxyuridine assay, and doubling times were 2.66 and 3.72 days for iPSC-MSCs and BM-MSCs, respectively, showing a 1.4-fold discrepancy. Blockade of IK(DR) with short hairpin RNA or human ether-à-go-go 1 (hEAG1) channel blockers, 4-AP and astemizole, significantly reduced the rate of proliferation of human iPSC-MSCs. These treatments also decreased the rate of proliferation of human BM-MSCs albeit to a lesser extent. These findings demonstrate that the hEAG1 channel plays a crucial role in controlling the proliferation rate of human iPSC-MSCs and to a lesser extent in BM-MSCs.     

严重烫伤延长大鼠心室肌细胞动作电位时程的机制

严重烫伤引起心肌细胞动作电位时程（action potential duration,APD）延长,通过加重烫伤心肌细胞钙紊乱和诱发室性心律失常,促进烫伤心功能障碍的发生,但APD延长的机制尚不清楚。通过制作约40％体表面积（total body surface area,TBSA）Ⅲ度烫伤大鼠模型,在伤后12h大鼠心功能明显减弱时分离其心肌细胞,采用膜片钳技术观察心肌细胞APD以及动作电位复极化相关的重要离子通道电流,包括瞬间外向钾电流（transient outward K^＋ current,Ito）,L-型钙电流（L-type Ca^2＋ current,ICa-L）和内向整流钾电流（inward rectifier K^＋ current,IK1）。结果显示,烫伤后12h单个心肌细胞APD明显延长,APD50和APD90在烫伤组分别为（46．02±3．78）ms、（123．24±12．48）ms（n=19）,明显长于对照组的（23．28±4．85）ms、（72．12±3．57）ms（n=17）（P〈0．01）。烫伤引起,Ito电流密度降低,＋60 mV下烫伤组的电流密度（20．39±1．98）pA／pF（n=25）明显低于对照组的（34．15±3．78）pA／pF（n=20,P〈0．01）;烫伤组在-120至-80mV电压刺激下所产生的IK1电流密度显著低于对照组：而两组之间ICa-L电流密度、电压依赖性的激活和失活无显著性差异。结果提示,烫伤引起心肌细胞APD延长的机制与瞬间外向钾通道和内向整流钾通道功能下调有关。     

Two pore residues mediate acidosis-induced enhancement of C-type inactivation of the Kv1.4 K(+) channel

Acidosis inhibits current through the Kv1.4 K(+) channel, perhaps as a result of enhancement of C-type inactivation. The mechanism of action of acidosis on C-type inactivation has been studied. A mutant Kv1.4 channel that lacks N-type inactivation (fKv1.4 Delta2-146) was expressed in Xenopus oocytes, and currents were recorded using two-microelectrode voltage clamp. Acidosis increased fKv1.4 Delta2-146 C-type inactivation. Replacement of a pore histidine with cysteine (H508C) abolished the increase. Application of positively charged thiol-specific methanethiosulfonate to fKv1.4 Delta2-146 H508C increased C-type inactivation, mimicking the effect of acidosis. Replacement of a pore lysine with cysteine (K532C) abolished the acidosis-induced increase of C-type inactivation. A model of the Kv1.4 pore, based on the crystal structure of KcsA, shows that H508 and K532 lie close together. It is suggested that the acidosis-induced increase of C-type inactivation involves the charge on H508 and K532.