Transient Outward Potassium Channel Research Articles

Abstract Mo058: Cellular and Subcellular Ventricular Localization of the Fast Transient Outward Potassium Channels in the Murine Heart

Introduction: Cardiac fast transient outward potassium currents (I to,f ) are formed by KCND2 (Kv4.2) and KCND3 (Kv4.3) channels in mice and primarily KCND3 in humans. Rapid I to,f activation induces early phase 1 repolarization of action potentials (APs), which has been linked strongly to the modulation of excitation-contraction coupling (ECC). Consequently, variations in I to,f densities underlie regional differences in ventricular APs and myocardial contractile properties. To investigate further the role of I to,f in cardiac function, we created mice with fluorescently labelled KCND2 (KCND2-GFP) and KCND3 (KCND3-RFP). Methods and Results: The expression patterns of I to,f in the ventricles were examined using frozen histological sections. Remarkably, KCND2 and KCND3 were preferentially localized to the intercalated discs (ICDs) by >50%, with expression also in lateral membranes and within t-tubules (i.e. a sarcomeric pattern), yet KCND3 showed a greater t-tubule localization. Additionally, KCND2 expression was, as expected, greater ( P <0.048, two-way ANOVA; n=3) in the epi- versus endo-myocardium of both ventricles, whereas KCND3 lacked ( P >0.172; n=3) a distinct gradient. Moreover, KCND2 expression inversely correlated with the temporal sequence of ventricular activation, whereby the posterobasal regions that depolarize last show elevated Kv4.2 ( P =0.009, unpaired t-test; n=3) compared to the anterolateral endocardium activated first. In contrast, Kv4.3 demonstrates a relatively uniform expression. Conclusions: The regional expression patterns of I to,f in ventricles and preferential I to,f expression in t-tubules support previous studies suggesting that I to,f controls the regional variations in the timing and amplitude of ECC. We are currently exploring the possible differential actions of KCND2 versus KCND3 in ECC and the potential consequence of ICD localization of I to,f on ephaptic coupling.

In Silico Human Cardiomyocyte Action Potential Modeling: Exploring Ion Channel Input Combinations.

In silico modeling offers an opportunity to supplement and accelerate cardiac safety testing. With in silico modeling, computational simulation methods are used to predict electrophysiological interactions and pharmacological effects of novel drugs on critical physiological processes. The O'Hara-Rudy's model was developed to predict the response to different ion channel inhibition levels on cardiac action potential duration (APD) which is known to directly correlate with the QT interval. APD data at 30% 60% and 90% inhibition were derived from the model to delineate possible ventricular arrhythmia scenarios and the marginal contribution of each ion channel to the model. Action potential values were calculated for epicardial, myocardial, and endocardial cells, with action potential curve modeling. This study assessed cardiac ion channel inhibition data combinations to consider when undertaking in silico modeling of proarrhythmic effects as stipulated in the Comprehensive in Vitro Proarrhythmia Assay (CiPA). As expected, our data highlight the importance of the delayed rectifier potassium channel (IKr) as the most impactful channel for APD prolongation. The impact of the transient outward potassium channel (Ito) inhibition on APD was minimal while the inward rectifier (IK1) and slow component of the delayed rectifier potassium channel (IKs) also had limited APD effects. In contrast, the contribution of fast sodium channel (INa) and/or L-type calcium channel (ICa) inhibition resulted in substantial APD alterations supporting the pharmacological relevance of in silico modeling using input from a limited number of cardiac ion channels including IKr, INa, and ICa, at least at an early stage of drug development.

An emerging role for DPP6: reciprocal regulation of INa-Ito and implications for arrhythmogenesis

Abstract Background Since the association of a chromosomal risk haplotype harboring dipeptidyl peptidase-like protein-6 (DPP6) to familial idiopathic ventricular fibrillation (iVF), a growing number of DPP6 missense variants has been reported in patients with ventricular tachyarrhythmias. The mechanisms underlying DPP6 mediated-arrhythmogenesis are not yet fully elucidated. DPP6 is a subunit of the transient outward potassium (Ito) channel complex in Purkinje cells (PC) and ventricular myocytes (VM). Purpose Since other Ito-channel subunits (Navβ1, KChIP2, KCNE4 and DPP10) are also known to antagonize INa, we examined whether DPP6 could play a broader role in the inter-regulation of Kv4.3 and Nav1.5 channels. We identified two novel DPP6 variants (p.Arg274His and p.His213Tyr), each segregating in families with QT/QU prolongation. DPP6 p.Arg274His carriers suffered from iVF, ectopic beats from the conduction system, and mitral valve prolapse. Other DPP6 variants (p.Ala751Val identified in this study; p.Gln526His and DPP6-T p.His332Arg published) are associated with Brugada syndrome (BrS). We hypothesized that DPP6 has opposing effects on INa and Ito displaying a reciprocal regulation of these currents. Methods and results First, we determined the effect of the DPP6 variants on INa and Ito in transfected CHO cells. Ito density was significantly reduced only when PC subunits were co-expressed with the DPP6 p.Arg274His or p.His213Tyr variants. Indeed, DPP6 modulates Nav1.5 channels in CHO cells by reducing INa Peak and INa Late, whereas DPP6 mutants p.Arg274His or p.His213Tyr resulted in an increase of both components compared to WT. Co-immunoprecipitation experiments in human endocardium confirmed an interaction between DPP6 and Nav1.5 channels. Computing of mutant DPP6-driven Ito-INa changes in a published human PC model led to significant prolongation of the action potential duration, mainly caused by increased INa Late. On the other hand, the DPP6 p.Gln526His and p.Ala751Val variants, linked to BrS, led to a decreased INa Peak compared to the WT, while there was a tendency towards increased Ito density in both PC and VM molecular setups. DPP6 (p.Arg274His and p.Ala751Val) transfection experiments in hiPSC cardiomyocytes, expressing endogenous INa and Ito, confirmed the reciprocal results obtained in CHO cells. Conclusions DPP6 regulates INa and Ito in a reciprocal manner. The cardiac phenotype of DPP6 variants could encompass a spectrum between two opposite poles: 1) QT/QU prolongation by DPP6 variants causing loss of Ito and gain of INa, like p.Arg274His and p.His213Tyr versus 2) BrS by DPP6 variants leading to gain of Ito and loss of INa, like p.Gln526His and p.Ala751Val. Funding Acknowledgement Type of funding sources: Private grant(s) and/or Sponsorship. Main funding source(s): ESC Personal research grant, obtained in 2019

Abstract P2096: Long Qt Syndrome Type 3 Phenotype Dependence On Extracellular Sodium And The Perinexus In A Genetic Mouse Model

Background: Long QT Syndrome Type 3 (LQT3) is caused by cardiac voltage-gated sodium channel (Nav1.5) gain of function and characterized by action potential duration (APD) prolongation. A guinea pig model of drug-induced LQT3 demonstrated that elevating sodium and widening the perinexus, an intercalated disc cleft adjacent to gap junctions, individually and synergistically exacerbate APD prolongation. The synergistic effect suggests that high sodium with cardiac edema is a risk factor for LQT3 patients. However, it remains unclear if this synergistic effect occurs in a genetic model of LQT3. Purpose: To investigate individual and combined effects of sodium concentration and perinexal widening in a genetic mouse model of LQT3. Methods: Ventricular action potential duration at 30 (APD30) and 90 (APD90) percent of repolarization was measured from optically mapped, Langendorff-perfused wild type (WT) and ΔKPQ mouse hearts. Hearts were perfused with sodium concentrations of 145 or 160 mM, in the absence or presence of an intercalated disc adhesion inhibitor (βadp1) inducing perinexal widening. Results: At baseline with 145 mM sodium, APD30 and APD90 were significantly greater in ΔKPQ than WT hearts. Surprisingly, increased sodium (160 mM), significantly decreased APD90 in WT but not ΔKPQ hearts, which is inconsistent with results from the drug-induced LQT3 guinea pig model. In contrast, 160mM sodium significantly decreased APD30 in both genotypes suggesting elevated sodium increases the transient outward potassium current (Ito). Interestingly, with 145 mM sodium, βadp1 treatment did not significantly change APD30 or APD90 in either genotype. However, increasing sodium from 145 to 160 mM with βadp1 significantly increased APD90 in ΔKPQ hearts but not WT. Conclusions: Synergistic APD prolongation was modest in a genetic LQT3 mouse when elevating sodium and widening the perinexus relative to drug-induced LQT3 in guinea pig. A significant difference in action potential morphology between mice and guinea pig is the over-expression of Ito in mice and its absence in guinea pig. Future studies will investigate whether transient outward potassium channels contribute to the effect of high sodium on APD shortening during early repolarization.

Effects of magnetic stimulation at different frequencies on neuronal excitability and voltage-gated potassium channels in vitro brain slices

As a noninvasive neuromodulation technique, transcranial magnetic stimulation (TMS) is widely used in the clinical treatment of neurological and psychiatric diseases, but the mechanism of its action is still unclear. The purpose of this paper is to investigate the effects of different frequencies of magnetic stimulation (MS) on neuronal excitability and voltage-gated potassium channels in the in vitro brain slices from the electrophysiological perspective of neurons. The experiment was divided into stimulus groups and control group, and acute isolated mice brain slices were applied to MS with the same intensity (0.3 T) at different frequencies (20 Hz and 0.5 Hz, 500 pulses) respectively in the stimulus groups. The whole-cell patch clamp technique was used to record the resting membrane potential (RMP), action potential (AP), voltage-gated potassium channels current of hippocampal dentate gyrus (DG) granule cells. The results showed that 20 Hz MS significantly increased the number of APs released and the maximum slope of a single AP, reduced the threshold of AP, half width and time to AP peak amplitude, and improved the excitability of hippocampal neurons. The peak currents of potassium channels were decreased, the inactivation curve of transient outward potassium channels shifted to the left significantly, and the time constant of recovery after inactivation increased significantly. 0.5 Hz MS significantly inhibited neuronal excitability and increased the peak currents of potassium channels, but the dynamic characteristics of potassium channels had little change. The results suggest that the dynamic characteristics of voltage-gated potassium channels and the excitability of hippocampal DG granule neurons may be one of the potential mechanisms of neuromodulation by MS.

Effects of modulation on sodium and potassium channel currents by extremely low frequency electromagnetic fields stimulation on hippocampal CA1 pyramidal cells

ABSTRACT To investigate the effects of extremely low-frequency electromagnetic fields (ELF-EMFs) stimulation on sodium channel currents (INa), transient outward potassium channel currents (IA) and delayed rectifier potassium channel currents (IK) on hippocampal CA1 pyramidal neurons of young Sprague–Dawley rats. CA1 pyramidal neurons of rat hippocampal slices were subjected to ELF-EMFs stimulation with different frequencies (15 and 50 Hz), intensities (0.5, 1 and 2 mT) and durations (10, 20 and 30 min). The INa, IA and IK of neurons were recorded by a whole-cell patch-clamp method. ELF-EMFs stimulation enhanced INa densities, and depressed IA and IK densities. In detail, INa was more sensitive to the variation of intensities and frequencies of ELF-EMFs, whereas IA and IK were mainly affected by the variation of the duration of ELF-EMFs. ELF-EMFs stimulation altered activation and deactivation properties of INa, IA and IK. ELF-EMFs stimulation plays a role as a regulator rather than an inducer for ion channels. It might change the transition probability of ion channel opening or closing, and might also change the structure and function of the ion channel which need to be proved by the further technical method.

5-HT7 receptors increase the excitability of hippocampal CA1 pyramidal neurons by inhibiting the A-type potassium current

Accumulating evidence suggests a widespread role of serotonin 5-HT7 receptors (5-HT7Rs) in the physiology of cognitive and affective processing. However, we still lack insights into 5-HT7R electrophysiology. Studies analyzing the 5-HT7R-mediated changes in CA1 pyramidal neuron activity revealed that 5-HT7R activation leads to the opening of hyperpolarization-activated cyclic nucleotide-gated cation channels (HCNs). However, our group and others have shown that CA1 pyramidal cells increase their excitability following 5-HT7R activation, an effect which cannot be explained by HCN channel opening. This suggests a different ionic mechanism might be responsible. To investigate this, we performed whole-cell patch clamp recordings of CA1 pyramidal cells in rat brain slices. It was found that acute 5-HT7R activation increased membrane excitability and decreased spiking latency. Both effects were blocked by a selective 5-HT7R antagonist. Spike latency in CA1 pyramidal cells is known to be regulated by transient outward voltage-dependent A-type potassium channels. Subsequent voltage clamp recordings revealed that acute 5-HT7R activation inhibited A-type potassium currents. Pharmacological block of Kv4.2/4.3 potassium channel subunits prevented the 5-HT7R agonist-induced changes in excitability and spiking latency, whereas blocking HCN channels had no influence on these effects. Taken together, the results reveal an ionic mechanism previously not known to be associated with 5-HT7R activation. Inhibition of A-type potassium channels can fully account for increased CA1 pyramidal cell excitability after 5-HT7R activation. These results can help explain a number of behavioral and physiological findings and will hopefully lead to a better understanding of 5-HT7 receptor signaling in health and disease.

Impact of the DSP-H1684R Genetic Variant on Ion Channels Activity in iPSC-Derived Cardiomyocytes.

Mutations of desmosomal genes are known to cause arrhythmogenic cardiomyopathy characterized by arrhythmias and sudden cardiac death. Previously, we described a novel genetic variant H1684R in desmoplakin gene (DSP), associated with a progressive cardiac conduction disease (PCCD). In the present study, we aimed to investigate an effect of the DSP-H1684R genetic variant on the activity of ion channels. We used cardiomyocytes derived from induced pluripotent stem cells (iPSC cardiomyocytes) from a patient with DSP-H1684R genetic variant and from two healthy donors. Immunofluorescent staining and western blot analyses were used to characterize patient-specific cardiomyocytes. By the whole-cell voltage-clamp technique we estimated the activity of voltage-gated sodium, calcium, and potassium channels that are responsible for action potential generation and its shape. Action potentials' parameters were measured using whole-cell current-clamp technique. In patient-specific cardiomyocytes we observed both lower amplitudes of currents through sodium Nav1.5 channels and L-type calcium channels, but higher amplitude of current through transient-outward potassium channels in comparison to donor cardiomyocytes. Current-clamp measurements revealed shortening of action-potential in DSP-H1684R-carrying iPSC cardiomyocytes. Therefore, observed alterations in the channels activity might have a great impact on the properties of action potential and development of PCCD. Our results show that desmoplakin genetic variants, besides conduction slowing caused by structural heart remodeling, could affect multiple ion channel activity aggravating arrhythmia manifestation in PCCD.

Toll-like receptor 3 controls QT interval on the electrocardiogram by targeting the degradation of Kv4.2/4.3 channels in the endoplasmic reticulum.

TLRs have been proven to be essential mediators for the early innate immune response. Overactivation of TLR-mediated immune signaling promotes deterioration of cardiovascular diseases; however, the role of TLRs in the heart under physiologic conditions remains neglected. Here, we show that Tlr3 deficiency induced the endoplasmic reticulum (ER) retention of Kv4.2/4.3 proteins and consequent degradation via the ubiquitin-proteasome pathway. Knockout of Tlr3 resulted in a prolonged QT interval (the space between the start of the Q wave and the end of the T wave) in mice with no significant signs of inflammation and tissue abnormality in cardiac muscles. Prolongation of action potential duration resulted from the depression of transient outward potassium channel (Ito) currents in Tlr3-deficient ventricular myocytes mirrored the change in QT interval. Mechanistically, we found that Tlr3 was exclusively localized in the ER of cardiomyocytes where it interacted with Kv4.2/4.3 subunits of Ito channel. Thus, our data indicated that TLR3 directly regulates Ito channel protein dynamics to maintain cardiac repolarization, which may implicate a new molecular surveillance system for cardiac electrophysiological homeostasis.-Gao, X., Gao, S., Guan, Y., Huang, L., Huang, J., Lin, L., Liu, Y., Zhao, H., Huang, B., Yuan, T., Liu, Y., Liang, D., Zhang, Y., Ma, X., Li, L., Li, J., Zhou, D., Shi, D., Xu, L., Chen, Y.-H. Toll-like receptor 3 controls QT interval on the electrocardiogram by targeting the degradation of Kv4.2/4.3 channels in the endoplasmic reticulum.

Effects of Modulation of Ion Channel Currents by Salidroside in H9C2 Myocardial Cells in Hypoxia and Reoxygenation.

Salidroside, a phenyl-propanoid glycoside isolated from the medicinal plant Rhodiola rosea, has potent cardioprotective effects, especially against myocardial hypoxia and reoxygenation injury. However, the molecular mechanism underlying its action is still unclear. The aim of this study was to determine the effect of salidroside on sodium channel current (INa) and transient outward potassium channel current (Ito) in H9C2 cardiomyocytes. H9C2 cells were subcultured under anoxic conditions to mimic myocardial hypoxia and subsequently treated with salidroside. Whole cell patch clamp was performed to determine the effect of hypoxia/reoxygenation and salidroside on myocardial electrophysiological properties. In the differentiated H9C2 cells, hypoxia/reoxygenation reduced INa and Ito amplitude, while salidroside significantly restored both and altered the INa and Ito activation/inactivation kinetics in a dose-dependent manner. Our findings demonstrate that salidroside protects myocardial cells against hypoxia-reoxygenation by restoring the function of sodium and potassium channels.

Effects of isovitexin on transient outward potassium current of ventricular myocytes in rats

To investigate the effects of isovitexin Ⅳ on transient outward potassium current in rat ventricular myocytes. In this study, MTT assay was used to investigate the safe range of isovitexin. The results showed that the IC₅₀ of the drug was in the range of 10-30 μmol•L⁻¹, and the drug concentration of 1-3 μmol•L⁻¹ for the patch clamp test was within the safe range. In addition, the single ventricular myocytes were obtained by single-enzymatic hydrolysis through aortic retrograde perfusion. The transient outward potassium current (Ito) of rat ventricular myocytes was guided and measured by whole-cell patch-clamp technique and the changes of current characteristics were recorded after isovite was applied. When the concentration of IV was less than 0.1 μmol•L⁻¹, there was no significant effect on Ito. However, with the increase in the concentration of IV (≥0.3 μmol•L⁻¹), the peak of Ito was decreased gradually, from (32.32±2.9) pA/pF to （25.83±4.3） pA/pF, 1 μmol•L⁻¹ IV and (19.51±3.5) pA/pF, 3 μmol•L⁻¹ IV respectively, with an inhibition effect in a concentration-dependent manner. In the range of 1-3 μmol•L⁻¹, IV down-regulated the I-V curve of Ito significantly. The activation curve showed that IV can enable the maximum half activation potential (V1/2) to move to the positive direction, and the V1/2 was increased from (19.59±1.6) mV to (22.81±1.7) mV and (28.86±1.4) mV at concentration of 1, 3 μmol•L⁻¹, meanwhile the activation curve moved to the right. However, the maximum half inactivating potential (V1/2) of the steady-state inactivation curve of Ito was significantly decreased from (－51.43±0.99) mV to (－61.81±1.3) mV with concentration of 1 μmol•L⁻¹ and (－71.50±1.4) mV with concentration of 3 μmol•L⁻¹. The inactivation time constant of recovery from inactivation (τ) was up-regulated significantly from (94.89±0.73) ms to (118.5±1.5) ms and (162.4±1.4) ms at concentration of 1, 3 μmol•L⁻¹ respectively. Meanwhile IV could enable the inactivation recovery curve to move to the right, which suggested that it can prolong the recovery time from inactivation of the transient outward potassium channel. In conclusion, isovitexin had a high inhibitory effect on Ito in rat ventricular myocytes.

Isopimaric acid - a multi-targeting ion channel modulator reducing excitability and arrhythmicity in a spontaneously beating mouse atrial cell line.

Atrial fibrillation is the most common persistent cardiac arrhythmia, and it is not well controlled by present drugs. Because some resin acids open voltage-gated potassium channels and reduce neuronal excitability, we explored the effects of the resin acid isopimaric acid (IPA) on action potentials and ion currents in cardiomyocytes. Spontaneously beating mouse atrial HL-1 cells were investigated with the whole-cell patch-clamp technique. 1-25 μmol L-1 IPA reduced the action potential frequency by up to 50%. The effect of IPA on six different voltage-gated ion channels was investigated; most voltage-dependent parameters of ion channel gating were shifted in the negative direction along the voltage axis, consistent with a hypothesis that a lipophilic and negatively charged compound binds to the lipid membrane close to the positively charged voltage sensor of the ion channels. The major finding was that IPA inactivated sodium channels and L- and T-type calcium channels and activated the rapidly activating potassium channel and the transient outward potassium channel. Computer simulations of IPA effects on all of the ion currents were consistent with a reduced excitability, and they also showed that effects on the Na channel played the largest role to reduce the action potential frequency. Finally, induced arrhythmia in the HL-1 cells was reversed by IPA. Low concentrations of IPA reduced the action potential frequency and restored regular firing by altering the voltage dependencies of several voltage-gated ion channels. These findings can form the basis for a new pharmacological strategy to treat atrial fibrillation.

Isosteviol prevents the prolongation of action potential in hypertrophied cardiomyoctyes by regulating transient outward potassium and L-type calcium channels

Cardiac hypertrophy is a thickening of the heart muscle that is associated with cardiovascular diseases such as hypertension and myocardial infarction. It occurs initially as an adaptive process against increased workloads and often leads to sudden arrhythmic deaths. Studies suggest that the lethal arrhythmia is attributed to hypertrophy-induced destabilization of cardiac electrical activity, especially the prolongation of the action potential. The reduced activity of Ito is demonstrated to be responsible for the ionic mechanism of prolonged action potential duration and arrhythmogeneity. Isosteviol (STV), a derivative of stevioside, plays a protective role in a variety of stress-induced cardiac diseases. Here we report effects of STV on rat ISO-induced hypertrophic cardiomyocytes. STV alleviated ISO-induced hypertrophy of cardiomyocytes by decreasing cell area of hypertrophied cardiomyocytes. STV application prevented the prolongation of action potential which was prominent in hypertrophied cells. The decrease and increase of current densities for Ito and ICaL observed in hypertrophied myocytes were both prevented by STV application. In addition, the results of qRT-PCR suggested that the changes of electrophysiological activity of Ito and ICaL are correlated to the alterations of the mRNA transcription level.

Characterization of ion channels on subesophageal ganglion neurons from Chinese tarantula Ornithoctonus huwena: Exploring the myth of the spider insensitive to its venom

Chinese tarantula Ornithoctonus huwena is one of the most venomous spiders distributing in the hilly areas of southern China. In this study, using whole-cell patch-clamp technique we investigated electrophysiological and pharmacological properties of ion channels from tarantula subesophageal ganglion neurons. It was found that the neurons express multiple kinds of ion channels at least including voltage-gated calcium channels, TTX-sensitive sodium channels and two types of potassium channels. They exhibit pharmacological properties similar to mammalian subtypes. Spider calcium channels were sensitive to ω-conotoxin GVIA and diltiazem, two well-known inhibitors of mammalian neuronal high-voltage-activated (HVA) subtypes. 4-Aminopyridine and tetraethylammonium could inhibit spider outward transient and delayed-rectifier potassium channels, respectively. Huwentoxin-I and huwentoxin-IV are two abundant toxic components in the venom of Ornithoctonus huwena. Interestingly, although in our previous work they inhibit HVA calcium channels and TTX-sensitive sodium channels from mammalian sensory neurons, respectively, they fail to affect the subtypes from spider neurons. Moreover, the crude venom has no effect on delayed-rectifier potassium channels and only slightly reduces transient outward potassium channels with an IC50 value of ∼51.3 mg/L. Therefore, our findings provide important evidence for ion channels from spiders having an evolution as self-defense and prey mechanism.

Isopimaric Acid - A Promiscuous Ion Channel Modulator and a Potential Drug Candidate Against Atrial Fibrillation

Atrial fibrillation is a common cardiac arrhythmia in adulthood, and it is not well controlled by the present-day drugs. Previously, resin acids has been shown to open voltage-gated potassium channels and reduce cellular excitability in dorsal-root ganglion neurons. In this study we explored the effects of a resin acid, Isopimaric acid (IPA), on excitability in cardiomyocytes. Whole-cell patch-clamp recordings showed that 1-25 µmol/L IPA reduced the action potential frequency by up to 50 % in spontaneously beating mouse atrial HL-1 cells. The effect of IPA on six different voltage-gated ion channels were investigated; most voltage-dependent parameters of ion-channel gating were shifted in negative direction along the voltage axis, consistent with an hypothesis that a lipophilic and negatively charged compound binds to the lipid membrane close to the positively charged voltage sensor of the ion channels. The major finding was that IPA inactivated sodium channels and L- and T-type calcium channels more than it activated these channels. It also activated the rapid delayed rectifier potassium channel, the transient outward potassium channel, but had no effect of the pace-maker f-channel. Computer simulations of all IPA effects on the ion currents were consistent with a reduced excitability. They also showed that the effect on the sodium channel played a large role for IPAs ability to reduce the action potential frequency. Finally, induced arrhythmia in the HL-1 cells was shown to be reversed by IPA. In conclusion, low concentrations of IPA reduced the action potential frequency and reversed arrhythmic firing via a new pharmacological mechanism. These findings can form the basis for a new pharmacological strategy to treat atrial fibrillation.

Cold-Inducible RNA-Binding Protein Regulates Cardiac Repolarization by Targeting Transient Outward Potassium Channels

Cold-inducible RNA-binding protein (CIRP) is constitutively expressed at low levels across various tissues. It is rapidly upregulated by multiple stresses, underlying a general role for CIRP in organic adaptations to pathophysiological conditions. However, the role of CIRP in the heart remains unclear. To examine the biofunctions of CIRP in the mammalian heart. Rats with targeted disruption of Cirp were generated using the TALEN (transcription activator-like effector nucleases)-based genome editing technique. The Cirp-knockout rats had structurally and functionally normal hearts. Resting ECG recordings revealed a short rate-corrected QT (QTc) interval in Cirp-null rats without any abnormalities in PR interval, RR interval or QRS waves as compared to wild-type animals. The shortened QTc interval from Cirp ablation was tightly linked to an abbreviated action potential duration in cardiac myocytes, which was attributable to increased transient outward potassium current (Ito). Furthermore, our findings uncovered that CIRP protein selectively bonded to KCND2 and KCND3 mRNAs encoding the functional α-subunits of Ito channel proteins. CIRP deficiency did not change the transcriptional activity of KCND2 or KCND3, but it facilitated their translation. Cirp knockout had no effect on the functional expression of ion channels other than Ito channels. CIRP modulates cardiac repolarization by negatively adjusting the expression and function of Ito channels. Our study may open a window to decipher the potential function of RNA-binding proteins in bioelectric activity.

Prolonged leptin treatment increases transient outward K+ current via upregulation of Kv4.2 and Kv4.3 channel subunits in adult rat ventricular myocytes

Circulating leptin levels are elevated in obesity and hyperleptinaemia has been postulated to be an independent risk factor for the development of cardiovascular diseases. Although many studies have been published on the mechanisms involved in the effects of leptin on cardiac function and pathological remodeling, scarce information is currently available analyzing the influence of prolonged leptin treatment on ionic cardiac channels remodeling in adult ventricular myocytes. Enzymatically isolated adult rat ventricular myocytes were treated with leptin or vehicle for 48h. Real-Time RT-PCR were used to analyze mRNA expression of Kir2.1, Cav1.2, Cav 3.1, Kv4.2 and Kv4.3 α-subunits and KChIP2 auxiliary subunit. The fast transient outward potassium channels (Itof) α-subunits Kv4.2, Kv4.3 and KChIP2 were analyzed by Western-blot. The fast transient outward potassium current and the action potentials were recorded in isolated myocytes by the whole-cell patch-clamp technique. Leptin treatment induced an up-regulation of Kv4.2, Kv4.3 and KChIP2 subunits mRNA expression. However, transcriptional levels of Kir2.1, Cav1.2, or Cav3.1 α-subunit channels were unmodified by leptin. Protein expression levels of Kv4.2, Kv4.3 and KChIP2 subunits were also increased by leptin. The electrophysiological study showed that leptin increases the fast transient outward potassium current amplitudes and densities shortening action potential duration. In addition, leptin activated Akt signaling in cardiomyocytes and this mechanism was involved in the effect of leptin on Itof channels. In conclusión, leptin increases both the expression and function of Itof channels in adult ventricular myocytes and this mechanism involves Akt signaling. Altogether these data suggest that leptin could exert beneficial or detrimental effects depending on the initial ventricular myocyte repolarizing reserve.

Classification of potassium and chlorine ionic currents in retinal ganglion cell line (RGC-5) by whole-cell patch clamp

Retinal ganglion cell line (RGC-5) has been widely used as a valuable model for studying pathophysiology and physiology of retinal ganglion cells in vitro. However, the electrophysiological characteristics, especially a thorough classification of ionic currents in the cell line, remain to be elucidated in details. In the present study, we determined the resting membrane potential (RMP) in RGC-5 cell line and then identified different types of ionic currents by using the whole-cell patch-clamp technique. The RMP recorded in the cell line was between -30 and -6 mV (-17.6 ± 2.6 mV, n = 10). We observed the following voltage-gated ion channel currents: (1) inwardly rectifying Cl- current (I Cl,ir), which could be blocked by Zn2+; (2) Ca2+-activated Cl- current (I Cl,Ca), which was sensitive to extracellular Ca2+ and could be inhibited by disodium 4,4'-diisothiocyanatostilbene-2,2'-disulfonate; (3) inwardly rectifying K+ currents (I K1), which could be blocked by Ba2+; (4) a small amount of delayed rectifier K+ current (I K). On the other hand, the voltage-gated sodium channels current (I Na) and transient outward potassium channels current (I A) were not observed in this cell line. These results further characterize the ionic currents in the RGC-5 cell line and are beneficial for future studies especially on ion channel (patho)physiology and pharmacology in the RGC-5 cell line.

Effects of 50 Hz Magnetic Fields With Different Intensities Exposure on Transient Outward Potassium Channel of Cortical Neurons*

Despite growing concern about electromagnetic radiation,the biological effects of the frequency magnetic fields remain obscure.The cortical neurons isolated from the mice were exposed to a 50 Hz electromagnetic field(EMF 1 mT,5 mT,10 mT) for 15 min.Using the whole-cell patch clamp technique,the currents of the transient outward potassium channel were recorded off-line,and then the effects of EMF on the channels were investigated.Compared to the control group,a significant inhibition on the IA was reported,and the rate of inhibition were(63.0 ± 2.2)%(1 mT),(55.0 ± 1.7)%(5 mT),(38.0 ± 1.8)%(10 mT),respectively.Moreover,the characteristics of activation and inactivation were both influenced by EMF,because there were a decreasing both on the half activation voltage and the half inactivation voltage.Additionally,different effects on the channels had been found for the different intensities.In the research,the maximum inhibition rate of current was induced by 1 mT,and the changing of the half activation voltage and the half inactivation voltage were the biggest after exposure to 5 mT,and 10 mT EMF increased the slope factor of inactivation.The results indicated that EMF affected the conformational changes of ion channel protein on cell membrane,and further influenced the normal function of ion channels.

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