Sodium Metabisulfite Modulation of Potassium Channels in Pain-Sensing Dorsal Root Ganglion Neurons

The effects of sodium metabisulfite (SMB), a general food preservative, on potassium currents in rat dorsal root ganglion (DRG) neurons were investigated using the whole-cell patch-clamp technique. SMB increased the amplitudes of both transient outward potassium currents and delayed rectifier potassium current in concentration- and voltage-dependent manner. The transient outward potassium currents (TOCs) include a fast inactivating (A-current or I _A) current and a slow inactivating (D-current or I _D) current. SMB majorly increased I_A, and I_D was little affected. SMB did not affect the activation process of transient outward currents (TOCs), but the inactivation curve of TOCs was shifted to more positive potentials. The inactivation time constants of TOCs were also increased by SMB. For delayed rectifier potassium current (I _K), SMB shifted the activation curve to hyperpolarizing direction. SMB differently affected TOCs and I _K, its effects major on A-type K⁺ channels, which play a role in adjusting pain sensitivity in response to peripheral redox conditions. SMB did not increase TOCs and I _K when adding DTT in pipette solution. These results suggested that SMB might oxidize potassium channels, which relate to adjusting pain sensitivity in pain-sensing DRG neurons.     

Potassium Ion Current in the Squid Giant Axon: Dynamic Characteristic

Measurements of the potassium current in the squid axon membrane have been made, after changes of the membrane potential to the sodium potential of Hodgkin and Huxley (HH), from near the resting potential, from depolarizations of various durations and amplitudes, and from hyperpolarizations of up to 150 mv. The potassium currents I given by I = I_∞ {1 - exp [- (t + t₀)/τ]}²⁵, where t₀ is determined by the initial conditions, represent the new data and approximate the HH functions in the regions for which they are adequate. A corresponding modification for the sodium current does not appear necessary. The results support the HH assumptions of the independence of the potassium and sodium currents, the dependence of the potassium current upon a single parameter determined by the membrane potential, and the expression of this parameter by a first order differential equation, and, although the results drastically modify the analytical expressions, they very considerably extend the range of apparent validity of these assumptions. The delay in the potassium current after severe hyperpolarization is used to estimate a potassium ion mobility in the membrane as 10^-5 of its value in aqueous solutions.     

Effects of Estradiol on Voltage-Gated Potassium Channels in Mouse Dorsal Root Ganglion Neurons

Voltage-gated potassium channels are regulators of membrane potentials, action potential shape, firing adaptation, and neuronal excitability in excitable tissues including in the primary sensory neurons of dorsal root ganglion (DRG). In this study, using the whole-cell patch-clamp technique, the effect of estradiol (E2) on voltage-gated total outward potassium currents, the component currents transient “A-type” current (I _A) currents, and “delayed rectifier type” (I _KDR) currents in isolated mouse DRG neurons was examined. We found that the extracellularly applied 17β-E2 inhibited voltage-gated total outward potassium currents; the effects were rapid, reversible, and concentration-dependent. Moreover, the membrane impermeable E2-BSA was as efficacious as 17β-E2, whereas 17α-E2 had no effect. 17β-E2-stimulated decrease in the potassium current was unaffected by treatment with ICI 182780 (classic estrogen receptor antagonist), actinomycin D (RNA synthesis inhibitor), or cycloheximide (protein synthesis inhibitor). We also found that I _A and I _KDR were decreased after 17β-E2 application. 17β-E2 significantly shifted the activation curve for I _A and I _KDR channels in the hyperpolarizing direction. In conclusion, our results demonstrate that E2 inhibited voltage-gated K⁺ channels in mouse DRG neurons through a membrane ER-activated non-genomic pathway.     

Impact of slow K<Superscript>+</Superscript> currents on spike generation can be described by an adaptive threshold model

A neuron that is stimulated by rectangular current injections initially responds with a high firing rate, followed by a decrease in the firing rate. This phenomenon is called spike-frequency adaptation and is usually mediated by slow K⁺ currents, such as the M-type K⁺ current (I _M ) or the Ca²⁺-activated K⁺ current (I _AHP ). It is not clear how the detailed biophysical mechanisms regulate spike generation in a cortical neuron. In this study, we investigated the impact of slow K⁺ currents on spike generation mechanism by reducing a detailed conductance-based neuron model. We showed that the detailed model can be reduced to a multi-timescale adaptive threshold model, and derived the formulae that describe the relationship between slow K⁺ current parameters and reduced model parameters. Our analysis of the reduced model suggests that slow K⁺ currents have a differential effect on the noise tolerance in neural coding.     

Potassium currents in cultured rabbit retinal pigment epithelial cells

Membrane potential and ionic currents were studied in cultured rabbit retinal pigment epithelial (RPE) cells using whole-cell patch clamp and perforated-patch recording techniques. RPE cells exhibited both outward and inward voltage-dependent currents and had a mean membrane capacitance of 26±12 pF (sd, n=92). The resting membrane potential averaged ?31±15 mV (n=37), but it was as high as ?60 mV in some cells. When K⁺ was the principal cation in the recording electrode, depolarization-activated outward currents were apparent in 91% of cells studied. Tail current analysis revealed that the outward currents were primarily K⁺ selective. The most frequently observed outward K⁺ current was a voltage- and time-dependent outward current (I _K) which resembled the delayed rectifier K⁺ current described in other cells. I _K was blocked by tetraethylammonium ions (TEA) and barium (Ba²⁺) and reduced by 4-aminopyridine (4-AP). In a few cells (3–4%), depolarization to ?50 mV or more negative potentials evoked an outwardly rectifying K⁺ current (I _Kt) which showed more rapid inactivation at depolarized potentials. Inwardly rectifying K⁺ current (I _KI) was also present in 41% of cells. I _KI was blocked by extracellular Ba²⁺ or Cs⁺ and exhibited time-dependent decay, due to Na⁺ blockade, at negative potentials. We conclude that cultured rabbit RPE cells exhibit at least three voltage-dependent K⁺ currents. The K⁺ conductances reported here may provide conductive pathways important in maintaining ion and fluid homeostasis in the subretinal space.     

Pharmacological properties of the potassium-activated inward current in pyramidal hippocampal neurons

Elevation of the external potassium concentration induced a two-phase inward current in freshly isolated pyramidal hippocampal neurons. This current was voltage-dependent and demonstrated strong inward rectification. The current consisted of a leakage current and a time-dependent current (τ=40–50 msec at 21°C); the latter was designated asI _ΔK. As was shown earlier, K⁺ is a major charge carrier in the development of slow potassium-activated current. The pharmacological properties ofI _ΔK were studied using a patch-clamp technique.I _ΔK was completely blocked by external 10 mM TEA or 5 mM Ba²⁺ (IC₅₀=480±90mM) and exhibited low sensitivity to extracellular Cs⁺ (2 mM). This current was not affected by 1 mM 4-aminopyridine and was insensitive to a muscarinic agonist, carbachol (50 μM), and to 1 mM extracellular Cd²⁺. Elevation of external Ca²⁺ from 2.5 mM to 10 mM did not changeI _ΔK. Our data indicate that the pharmacological properties ofI _ΔK differ from those of other voltage-gated potassium currents, but more specific blockers must be used to make this evidence conclusive.     

Ionic currents in cardiac myocytes of squid, Alloteuthis subulata

This paper provides the first study of voltage-sensitive membrane currents present in heart myocytes from cephalopods. Whole cell patch clamp recordings have revealed six different ionic currents in myocytes freshly dissociated from squid cardiac tissues (branchial and systemic hearts). Three types of outward potassium currents were identified: first, a transient outward voltage-activated A-current (I_A), blocked by 4-aminopyridine, and inactivated by holding the cells at a potential of −40 mV; second, an outward, voltage-activated, delayed rectifier current with a sustained time course (I_K); and third, an outward, calcium-dependent, potassium current (I_K(Ca)) sensitive to Co²⁺ and apamin, and with the characteristic N-shaped current voltage relationship. Three inward voltage-activated currents were also identified. First, a rapidly activating and inactivating, sodium current (I_Na), blocked by tetrodotoxin, inactivated at holding potentials more positive than −40 mV, and abolished when external sodium was replaced by choline. Second, an L-type calcium current (I_Ca,L) with a sustained time course, suppressed by nifedipine or Co²⁺, and enhanced by substituting Ca²⁺ for Ba²⁺ in the external medium. The third inward current was also carried by calcium ions, but could be distinguished from the L-type current by differences in its voltage dependence. It also had a more transient time course, was activated at more negative potentials, and resembled the previously described low-voltage-activated, T-type calcium current. Accepted: 24 September 1999     

Interaction of galantamine with ionic channels in molluscan neurons

Galantamine is widely used for the treatment of Alzheimer’s disease. According to the generally accepted viewpoint, its therapeutic effect is based on inhibition of acetylcholinesterase (AChE) and potentiation of nicotinic receptors. Alternative molecular targets for galanatamine, namely, voltage-gated Ca²⁺ and K⁺ channels of the neuronal membrane, are also widely discussed in the current literature. The present study is devoted to the analysis of effects of galantamine on high-threshold Ca²⁺ currents (I _Ca) and three different kinds of highthreshold K⁺ current, viz.: Ca²⁺-dependent K⁺ current (I _C), delayed rectifier (I _DR), and fast-inactivating K₊ current (I _Adepol). Experiments were conducted on molluscan neurons with the help of two-microelectrode voltageclamp technique. It was found that galantamine caused a fast, reversible and dose-dependent suppression of all types of high-threshold ionic currents. The maximal blocking effect of the alkaloid for I _Ca, I _C, and I _DR, was 100%, while for I Adepol the maximal suppression was only 60%. The mean values of IC ₅₀ for I _C, I _DR, I _Adepol, and I _Ca were 109, 237, 66, and 515 μ M, respectively, i.e., substantially higher than the corresponding values for the alkaloid-induced inhibition of AChE and potentiation of nicotinic receptors. It is concluded that the blockade of Ca₂₊ and K₊ channels has little or no contribution to the therapeutic activity of galantamine.     

Membrane responses to changes in the extracellular potassium concentration in isolated hippocampal pyramidal neurons

The responses of freshly isolated hippocampal pyramidal neurons to rapid, elevations of the external potassium concentration ([K⁺] _out ) were investigated using the whole-cell variation of a patch-clamp technique. An elevation of [K⁺] _out induced a two-phase inward current at the membrane potentials more negative than the reversal potential for K ions. This current consisted of a leakage, current and a time-dependent current (τ=40–50 msec at 21°C), the latter designated below asI _ΔK. It displayed first-order activation kinetics that showed neither voltage, nor concentration dependence. The amplitude of this current was determined by the external K⁺ concentration and increased with hyperpolarization. Voltage dependence ofI _ΔK measured within the range from −20 to −120 mV was similar to that for inward rectifier. Activation ofI _ΔK was utterly dependent on Na⁺; substitution of extracellular Na⁺ with choline chloride almost completely depressedI _ΔK.I _ΔK was absent in the cells freshly dissociated from the nodosal and dorsal root ganglia. This suggests that this earlier unrecognized current is instrumental in preserving densely packed hippocampal pyramidal neurons from sudden increases in [K⁺] _out and following spontaneous over-excitation. It prevents the neurons from responding to K⁺-induced depolarizations by slowing down potassium influx.     

Potassium Currents in Freshly Dissociated Uterine Myocytes from Nonpregnant and Late-Pregnant Rats

In freshly dissociated uterine myocytes, the outward current is carried by K⁺ through channels highly selective for K⁺. Typically, nonpregnant myocytes have rather noisy K⁺ currents; half of them also have a fast-inactivating transient outward current (I_TO). In contrast, the current records are not noisy in late pregnant myocytes, and I_TO densities are low. The whole-cell I_K of nonpregnant myocytes respond strongly to changes in [Ca²⁺]_o or changes in [Ca²⁺]_i caused by photolysis of caged Ca²⁺ compounds, nitr 5 or DM-nitrophene, but that of late-pregnant myocytes respond weakly or not at all. The Ca²⁺ insensitivity of the latter is present before any exposure to dissociating enzymes. By holding at −80, −40, or 0 mV and digital subtractions, the whole-cell I_K of each type of myocyte can be separated into one noninactivating and two inactivating components with half-inactivation at approximately −61 and −22 mV. The noninactivating components, which consist mainly of iberiotoxin-susceptible large-conductance Ca²⁺-activated K⁺ currents, are half-activated at 39 mV in nonpregnant myocytes, but at 63 mV in late-pregnant myocytes. In detached membrane patches from the latter, identified 139 pS, Ca²⁺-sensitive K⁺ channels also have a half-open probability at 68 mV, and are less sensitive to Ca²⁺ than similar channels in taenia coli myocytes. Ca²⁺-activated K⁺ currents, susceptible to tetraethylammonium, charybdotoxin, and iberiotoxin contribute 30–35% of the total I_K in nonpregnant myocytes, but <20% in late-pregnant myocytes. Dendrotoxin-susceptible, small-conductance delayed rectifier currents are not seen in nonpregnant myocytes, but contribute ∼20% of total I_K in late-pregnant myocytes. Thus, in late-pregnancy, myometrial excitability is increased by changes in K⁺ currents that include a suppression of the I_TO, a redistribution of I_K expression from large-conductance Ca²⁺-activated channels to smaller-conductance delayed rectifier channels, a lowered Ca²⁺ sensitivity, and a positive shift of the activation of some large-conductance Ca²⁺-activated channels.     

Chronic resveratrol consumption prevents hypertension development altering electrophysiological currents and Ca2+ signaling in chromaffin cells from SHR rats

Resveratrol (RESV) is one of the most abundant polyphenol-stilbene compounds found in red wine with well-established cardioprotective and antihypertensive effects. Hyperactivity of the sympathoadrenal axis seems to be one of the major contributing factors in the pathogenesis of human essential hypertension. Alterations in outward voltage-dependent potassium currents (I_K) and inward voltage-dependent sodium (I_Na), calcium (I_Ca) and nicotinic (IACh) currents, CCs excitability, Ca²⁺ homeostasis, and catecholamine exocytosis were previously related to the hypertensive state. This raised the issue of whether in vivo long-term RESV treatment can directly act as a modulator of Ca²⁺ influx or a regulator of ion channel permeability in CCs. We monitored outward and inward currents, and cytosolic Ca²⁺ concentrations ([Ca²⁺]_c) using different pharmacological approaches in CCs from normotensive (WKY) and hypertensive (SHR) animals chronically exposed to trans-RESV (50 mg/L/v.o, 28 days). The long-term RESV treatment prevented the increase of the systolic blood pressure (SBP) in SHR, without reversion of cardiac hypertrophy. We also found an increase of the outward I_K, reduction in inward I_Na, I_Ca, and IACh, and the mitigation of [Ca²⁺]_c overload in CCs from SHR at the end of RESV treatment. Our data revealed that electrophysiological alterations of the CCs and in its Ca²⁺ homeostasis are potential new targets related to the antihypertensive effects of long-term RESV treatment.     

Effects of Cationic Substitutions on Delayed Rectifier Current in Type I Vestibular Hair Cells

The resting potassium current (I _KI ) in gerbil dissociated type I vestibular hair cells has been characterized under various ionic conditions in whole cell voltage-clamp. When all K⁺ in the patch electrode solution was replaced with Na⁺, (Na⁺) _in or Cs⁺, (Cs⁺) _in , large inward currents were evoked in response to voltage steps between −90 and −50 mV. Activation of these currents could be described by a Hodgkin-Huxley-type kinetic scheme, the order of best fit increasing with depolarization. Above ∼−40 mV currents became outward and inactivated with a monoexponential time course. Membrane resistance was inversely correlated with external K⁺ concentration. With (Na⁺) _in , currents were eliminated when K⁺ was removed from the external solution or following extracellular perfusion of 4-aminopyridine, indicating that currents flowed through I _KI channels. Also, reduction of K⁺ entry through manipulation of membrane potential reduced the magnitude of the outward current. Under symmetrical Cs⁺, 0 K⁺ conditions I _KI is highly permeable to Cs⁺. However, inward currents were reduced when small amounts of external K⁺ were added. Higher concentrations of K⁺ resulted in larger currents indicating an anomalous mole fraction effect in mixtures of external Cs⁺ and K⁺. Received: 23 June 1999/Revised: 27 September 1999     

The Extracellular K+ Concentration Dependence of Outward Currents through Kir2.1 Channels Is Regulated by Extracellular Na+ and Ca2+

It has been known for more than three decades that outward Kir currents (I_K1) increase with increasing extracellular K⁺ concentration ([K⁺]_o). Although this increase in I_K1 can have significant impacts under pathophysiological cardiac conditions, where [K⁺]_o can be as high as 18 mm and thus predispose the heart to re-entrant ventricular arrhythmias, the underlying mechanism has remained unclear. Here, we show that the steep [K⁺]_o dependence of Kir2.1-mediated outward I_K1 was due to [K⁺]_o-dependent inhibition of outward I_K1 by extracellular Na⁺ and Ca²⁺. This could be accounted for by Na⁺/Ca²⁺ inhibition of I_K1 through screening of local negative surface charges. Consistent with this, extracellular Na⁺ and Ca²⁺ reduced the outward single-channel current and did not increase open-state noise or decrease the mean open time. In addition, neutralizing negative surface charges with a carboxylate esterifying agent inhibited outward I_K1 in a similar [K⁺]_o-dependent manner as Na⁺/Ca²⁺. Site-directed mutagenesis studies identified Asp¹¹⁴ and Glu¹⁵³ as the source of surface charges. Reducing K⁺ activation and surface electrostatic effects in an R148Y mutant mimicked the action of extracellular Na⁺ and Ca²⁺, suggesting that in addition to exerting a surface electrostatic effect, Na⁺ and Ca²⁺ might inhibit outward I_K1 by inhibiting K⁺ activation. This study identified interactions of K⁺ with Na⁺ and Ca²⁺ that are important for the [K⁺]_o dependence of Kir2.1-mediated outward I_K1.     

Swelling-activated Gd3+-sensitive Cation Current and Cell Volume Regulation in Rabbit Ventricular Myocytes

The role of swelling-activated currents in cell volume regulation is unclear. Currents elicited by swelling rabbit ventricular myocytes in solutions with 0.6–0.9× normal osmolarity were studied using amphotericin perforated patch clamp techniques, and cell volume was examined concurrently by digital video microscopy. Graded swelling caused graded activation of an inwardly rectifying, time-independent cation current (I_Cir,swell) that was reversibly blocked by Gd³⁺, but I_Cir,swell was not detected in isotonic or hypertonic media. This current was not related to I_K1 because it was insensitive to Ba²⁺. The P_K/P_Na ratio for I_Cir,swell was 5.9 ± 0.3, implying that inward current is largely Na⁺ under physiological conditions. Increasing bath K⁺ increased g_Cir,swell but decreased rectification. Gd³⁺ block was fitted with a K _0.5 of 1.7 ± 0.3 μM and Hill coefficient, n, of 1.7 ± 0.4. Exposure to Gd³⁺ also reduced hypotonic swelling by up to ∼30%, and block of current preceded the volume change by ∼1 min. Gd³⁺-induced cell shrinkage was proportional to I_Cir,swell when I_Cir,swell was varied by graded swelling or Gd³⁺ concentration and was voltage dependent, reflecting the voltage dependence of I_Cir,swell. Integrating the blocked ion flux and calculating the resulting change in osmolarity suggested that I_Cir,swell was sufficient to explain the majority of the volume change at –80 mV. In addition, swelling activated an outwardly rectifying Cl⁻ current, I_Cl,swell. This current was absent after Cl⁻ replacement, reversed at E_Cl, and was blocked by 1 mM 9-anthracene carboxylic acid. Block of I_Cl,swell provoked a 28% increase in swelling in hypotonic media. Thus, both cation and anion swelling-activated currents modulated the volume of ventricular myocytes. Besides its effects on cell volume, I_Cir,swell is expected to cause diastolic depolarization. Activation of I_Cir,swell also is likely to affect contraction and other physiological processes in myocytes.     

Human Adipose Cells Have Voltage-dependent Potassium Currents

The whole-cell patch-clamp method was used to study the membrane electrical properties of human adipocyte cells obtained by differentiating from precursors of human abdominal and mammary tissues. All differentiated cells exhibited outward currents with sigmoidal activation kinetics. The outward currents showed activation thresholds between –20 to –30 mV and slow inactivation. The ionic channels underlying the macroscopic current were highly selective for K⁺. Their selectivity was for typical K⁺ channels with relative permeabilities of K⁺>NH ₄ ⁺ >Cs⁺>Na⁺. No evidence of any other type of voltage-gated channel was found. The potassium currents (I _KV) were blocked reversibly by tetraethylammonium and barium. The IC ₅₀ value and Hill coefficient of tetraethylammonium inhibition of I _KV were 0.56 mM and 1.17 respectively. These results demonstrate that human adipose cells have voltage-dependent potassium currents.     

二氧化硫衍生物对大鼠背根神经元瞬间外向钾电流和延迟整流钾电流的影响

运用全细胞膜片钳技术研究二氧化硫衍生物对大鼠背根神经元瞬间外向钾电流(IA和ID)和延迟整流钾电流(IK)的影响。结果发现二氧化硫衍生物剂量依赖性地增大钾通道的电导,电压依赖性地增大钾电流的幅度,且这种增大作用部分可逆。二氧化硫非常显著地使延迟整流钾电流的激活过程向超极化方向移动,使瞬间外向钾电流的失活过程向去极化方向移动。10μmol/L二氧化硫衍生物作用前后,延迟整流钾电流的半数激活电压分别是(20.3±2.1)mV和(15.0±1.5)mV;IA和ID的半数失活电压分别朝去极化方向移动了6mV和7.4mV。这些结果表明二氧化硫改变了钾通道的特性,改变了神经元的兴奋性。     

Inhibitory Effects of Capsaicin on Voltage-Gated Potassium Channels by TRPV1-Independent Pathway

Previously we observed that capsaicin, a transient receptor potential vanilloid 1 (TRPV1) receptor activator, inhibited transient potassium current (I_A) in capsaicin-sensitive and capsaicin-insensitive trigeminal ganglion (TG) neurons from rats. It suggested that the inhibitory effects of capsaicin on I_A have two different mechanisms: TRPV1-dependent and TRPV1-independent pathways. The main purpose of this study is to further investigate the TRPV1-independent effects of capsaicin on voltage-gated potassium channels (VGPCs). Whole cell patch-clamp technique was used to record I_A and sustained potassium current (I_K) in cultured TG neurons from trpv1 knockout (TRPV1^?/?) mice. We found that capsaicin reversibly inhibited I_A and I_K in a dose-dependent manner. Capsaicin (30 μM) did not alter the activation curve of I_A and I_K but shifted the inactivation–voltage curve to hyperpolarizing direction, thereby increasing the number of inactivated VGPCs at the resting potential. Administrations of high concentrations capsaicin, no use-dependent block, and delay of recovery time course were found on I_K and I_A. Moreover, forskolin, an adenylate cyclase agonist, selectively decreased the inhibitory effects of I_K by capsaicin, whereas none influenced the inhibitions of I_A. These results suggest that capsaicin inhibits the VGPCs through TRPV1-independent and PKA-dependent mechanisms, which may contribute to the capsaicin-induced nociception.     

Effects of mono- and multi-valent cations on the inward-rectifying potassium channel in isolated protoplasts from maize roots

Transport properties mediated by ionic channels were studied by the patch-clamp technique in protoplasts from cortical parenchyma cells of maize roots (CPMR). While outward currents could be seen only occasionally, macroscopic voltage- and time-dependent potassium-selective inward currents (I_K+in) were frequently observed in the whole-cell configuration. These currents increased continuously as a function of K⁺ concentration (in the range 3 – 200 mm) and the slow-saturating macroscopic chord-conductance was fitted by a Michaelis-Menten function with K_m = 195 ± 39 mm. Other ions, like sodium and lithium, did not permeate at all through the maize root inward-channel, or like ammonium (P_NH4+/ P_K+ = 0.16 0.25) and rubidium (P_Rb+/P_K+≈ 0.10) displayed a very low permeability ratio. Up to 5 mm Rb⁺ did not induce any inhibition of the K⁺ inward current, whereas submillimolar concentrations of Cs⁺ were sufficient to block, in a voltage-dependent manner, the inward currents. A decrease of the external potassium concentration favoured Cs⁺ inhibition (K_m = 89 ± 6 μm and 26 ± 2 μm in 200 and 100 mm KCl, respectively). The potassium inward-currents were reversibly and consistently inhibited by submillimolar external concentrations of the metal ions Ni²⁺, Zn²⁺ and Co²⁺, while 1 mm La³⁺ only slightly decreased (≈10%) both the single channel conductance (9.2 ± 1.2 pS in 100 mm potassium) and the macroscopic current. In contrast to the case with Cs⁺, inhibition induced by other metal ions did not show any voltage dependence. These results suggest that, as with animal potassium channels, the inward channel of maize-root cortical cells has a narrow pore of permeation and metal ions decrease the K⁺ current, possibly by acting on binding sites located outside the pore. Received: 21 February 1997 / Accepted: 27 May 1997     

Gender disparities in torsade de pointes ventricular tachycardia

Background Gender disparities in the incidence of torsade de pointes (TdP) ventricular tachycardia exist, but the mechanisms in humans are unresolved. We addressed this issue using a mathematical model of a human ventricular cell. MethodsWe implemented gender differences in the Priebe-Beuckelmann model cell by modifying the amplitudes of the L-type Ca²⁺ current (I_Ca,L), transient outward K₊ current (I_to), and rapid component of the delayed rectifier K₊current (I_Kr), according to experimental data from animal male and female hearts. Gender disparities in electrical heterogeneity between transmural layers (subepicardium, midmyocardium, subendocardium) were implemented by modifying various ion currents according to experimental data. ResultsAction potentials in female cells have longer durations and steeper duration versus frequency relationships than male cells. In the female cells, electrical heterogeneity between transmural layers is larger and the susceptibility to early afterdepolarisations is higher than in male cells. ConclusionGender-related differences in I_Ca,L, I_to, and I_Kr may explain the gender disparities in human cardiac electrophysiology. Female cells have an increased susceptibility to early afterdepolarisations following mild reductions in net repolarising forces. Combined with their greater electrical heterogeneity, this renders them more vulnerable to TdP. (Neth Heart J 2007;15:405-11.)     

The cardiac acetylcholine-activated,inwardly rectifying K+-channel subunit GIRK1 gives rise to an inward current induced by free oxygen radicals

Reactive oxygen species (ROS) play a crucial role in pathophysiology of the cardiovascular system. The present study was designed to analyze the redox sensitivity of G-protein-activated inward rectifier K⁺ (GIRK) channels, which control cardiac contractility and excitability. GIRK1 subunits were heterologously expressed in Xenopus laevis oocytes and the resulting K⁺ currents were measured with the two-electrode voltage clamp technique. Oxygen free radicals generated by the hypoxanthine/xanthine oxidase system led to a marked increase in the current through GIRK channels, termed superoxide-induced current (I_SO). Furthermore, I_SO did not depend on G-protein-dependent activation of GIRK currents by coexpressed muscarinic m₂-receptors, but could also be observed when no agonist was present in the bathing solution. Niflumic acid at a concentration of 0.5 mmol/l did not abolish I_SO, whereas 100 μmol/l Ba²⁺ attenuated I_SO completely. Catalase (10⁶ i.u./l) failed to suppress I_SO, whereas H₂O₂ concentration was kept close to zero, as measured by chemiluminescence. Hence, we conclude that O₂^•− or a closely related species is responsible for I_SO induction. Our results demonstrate a significant redox sensitivity of GIRK1 channels and suggest redox-activation of G-protein-activated inward rectifier K⁺ channels as a key mechanism in oxidative stress-associated cardiac dysfunction.