The genetic study of ischemia induced arrhythmia and potassium channels

Objectives Ischemia induced arrhythmia(ventricular tachycardia/ventricular fibrillation) is one of the major causes of death.Potassium channels change are likely to be responsible for the ischemia-related arrhythmias.Cardiac potassium current is the major outward current involved in cardiac repolarization.The properties of potassium channels have been intensively studied.Here,we investigated the association between ischemia induced arrhythmia and potassium channels genetic variations.Methods 23 patients with ventricular tachycardia/ventricular fibrillation induced by ischemia were selected as objects.5ML peripheral blood were taken from each person,from which DNA was extracted us- ing a standard enzymatic phenol-chloroform method.Candidate genes(HERG、KCNJ2、KCNQ1、Mink、Mirp1、Kir2.1、KV4.3、Kir3.1、KV1.5、Kir6.1、Kir6.2、Kir2.1) Were screened for potassium channels gene mutations with direct sequencing methods.Results Here 4 potassium channels gene mutations have been discovered.In the gene coding for the ATP-sensitive K^+ channels subunit Kir6.2,there is a change from valine to isoleucine at the position of 326(V326I).At the position 448,arginine substitutes proline(P448R) in the KC-NQ1 gene.In the gene KCNJ2 two mutations have been found(P156L,Q193H).Conclusions This study implicated that there is a high relationship between ischemia induced arrhythmia and the mutation of potassium channels.In order to identify the precisely relationship there is need functional analysis.

Highly active artificial potassium channels having record-high K^(+)/Na^(+) selectivity of 20.1

Replicating extraordinarily high membrane transport selectivity of protein channels in artificial channel is a challenging task.In this work,we demonstrate that a strategic application of steric code-based social self-sorting offers a novel means to enhance ion transport selectivities of artificial ion channels,alongside with boosted ion transport activities.More specifically,two types of mutually compatible sterically bulky groups(benzo-crown ether and tert-butyl group)were appended onto a monopeptide-based scaffold,which can order the bulky groups onto the same side of a one-dimensionally aligned H-bonded structure.Strong steric repulsions among the same type of bulky groups(either benzo-crown ethers or tert-butyl groups),which are forced into proximity by H-bonds,favor the formation of hetero-oligomeric ensem-bles that carry an alternative arrangement of sterically compatible benzo-crown ethers and tert-butyl groups,rather than homo-oligomeric ensembles containing a single type of either benzo-crown ethers or tert-butyl groups.Coupled with side chain tuning,this social self-sorting strategy delivers highly ac-tive hetero-oligomeric K+-selective ion channel(5F12-BF12)_(n),displaying the highest K+/Na+selectivity of 20.1 among artificial potassium channels and an excellent ECso value of 0.50μmol/L(0.62 mo1%relative to lipids)in terms of single channel concentration.

THz trapped ion model and THz spectroscopy detection of potassium channels

Advanced molecular dynamics(MD)simulation and infrared(IR)spectroscopy have been widely adopted to reveal the detailed dynamic process of high-speed selective permeability of potassium channels.Yet these MD simulations cannot avoid the choice of empirical molecular force fields and high transmembrane voltages(as driving electric fields for ions)far exceeding physiological levels.Moreover,the IR spectroscopy method usually requires isotope labels for carbonyl groups of the channels,which may change the original permeation process.Here,we build the terahertz(THz)trapped ion model for the selectivity filter(SF)of potassium channels KcsA based on the density functional theory(DFT)calculation of ion potentials.In this model,the zero-point energy of trapped ions and quantum tunneling effect provide the physical basis for near diffusion limited permeation rates of ions and explain the high driving electric field in MD simulations.Quantitative calculations of zero-point energy and tunneling probability show that the quantum effect assisted knock-on mechanism may help to realize the physiological functions of potassium channels.Furthermore,based on the trapped ion model,we calculated the ion decoherence timescale under the influence of protein environmental noise.We use the quantum optics method to describe the interaction between THz waves and the trapped ion.Then the novel THz spectroscopy approaches through the THz resonance fluorescence and the intense field non-resonant effect are presented theoretically.These are expected to be isotope label-free detective methods of the rapid ion permeation dynamics.

Potassium channels as potential drug targets for limb wound repair and regeneration

Background:Ion channels are a large family of transmembrane proteins,accessible by soluble membraneimpermeable molecules,and thus are targets for development of therapeutic drugs.Ion channels are the second most common target for existing drugs,after G protein-coupled receptors,and are expected to make a big impact on precision medicine in many different diseases includingwound repair and regeneration.Research has shown that endogenous bioelectric signaling mediated by ion channels is critical in non-mammalian limb regeneration.However,the role of ion channels in regeneration of limbs in mammalian systems is not yet defined.Methods:To explore the role of potassium channels in limb wound repair and regeneration,the hindlimbs of mouse embryos were amputated at E12.5 when the wound is expected to regenerate and E15.5 when the wound is not expected to regenerate,and gene expression of potassium channels was studied.Results:Most of the potassium channels were downregulated,except for the potassium channel kcnj8(Kir6.1)which was upregulated in E12.5 embryos after amputation.Conclusion:This study provides a new mouse limb regeneration model and demonstrates that potassium channels are potential drug targets for limb wound healing and regeneration.

Short Review of Ischemia- and Hypoxia-Protective Roles of “Big Potassium” (BK) Channels

There is accumulating evidence that the subfamily of large-conductance potassium (“big”, “BK”) channels are involved in diverse, and perhaps coordinated, protective or counteractive responses to local or generalized ischemia and hypoxia. Although widely distributed, the physiological differences among BK channels which results from posttranslational modification (alternative splicing) and co-assembly with auxiliary modulatory subunits (β1-4 and γ1-4), bestows localized differences in subunit composition, distribution, 2nd-messenger coupling, and pharmacologic properties. Due to the ubiquitous nature of BK channels and the multiplicity of subtypes, they have many potential therapeutic applications in the maintenance of oxygen homeostasis, cerebro- and cardio-protection, and stimulation of respiration in response to drug-induced respiratory depression. BK channels may also offer other potentially broad and underrecognized promising targets for novel pharmaceutical development.

Ion channels in neurodevelopment:lessons from the Integrin-KCNB1 channel complex

Ion channels modulate cellular excitability by regulating ionic fluxes across biological membranes.Pathogenic mutations in ion channel genes give rise to epileptic disorders that are among the most frequent neurological diseases affecting millions of individuals worldwide.Epilepsies are trigge red by an imbalance between excitatory and inhibitory conductances.However,pathogenic mutations in the same allele can give rise to loss-of-function and/or gain-of-function va riants,all able to trigger epilepsy.Furthermore,certain alleles are associated with brain malformations even in the absence of a clear electrical phenotype.This body of evidence argues that the underlying epileptogenic mechanisms of ion channels are more diverse than originally thought.Studies focusing on ion channels in prenatal cortical development have shed light on this apparent paradox.The picture that emerges is that ion channels play crucial roles in landmark neurodevelopmental processes,including neuronal migration,neurite outgrowth,and synapse formation.Thus,pathogenic channel mutants can not only cause epileptic disorders by alte ring excitability,but further,by inducing morphological and synaptic abnormalities that are initiated during neocortex formation and may persist into the adult brain.

Diabetes-induced changes in cardiac voltage-gated ion channels

Diabetes mellitus affects the heart through various mechanisms such as microvascular defects,metabolic abnormalities,autonomic dysfunction and incompatible immune response.Furthermore,it can also cause functional and structural changes in the myocardium by a disease known as diabetic cardiomyopathy(DCM)in the absence of coronary artery disease.As DCM progresses it causes electrical remodeling of the heart,left ventricular dysfunction and heart failure.Electrophysiological changes in the diabetic heart contribute significantly to the incidence of arrhythmias and sudden cardiac death in diabetes mellitus patients.In recent studies,significant changes in repolarizing K+currents,Na+currents and L-type Ca^(2+)currents along with impaired Ca^(2+ )homeostasis and defective contractile function have been identified in the diabetic heart.In addition,insulin levels and other trophic factors change significantly to maintain the ionic channel expression in diabetic patients.There are many diagnostic tools and management options for DCM,but it is difficult to detect its development and to effectively prevent its progress.In this review,diabetes-associated alterations in voltage-sensitive cardiac ion channels are comprehensively assessed to understand their potential role in the pathophysiology and pathogenesis of DCM.

Repressing iron overload ameliorates central poststroke pain via the Hdac2-Kv1.2 axis in a rat model of hemorrhagic stroke

Thalamic hemorrhage can lead to the development of central post-stroke pain.Changes in histone acetylation levels,which are regulated by histone deacetylases,affect the excitability of neurons surrounding the hemorrhagic area.However,the regulato ry mechanism of histone deacetylases in central post-stroke pain remains unclea r.Here,we show that iron overload leads to an increase in histone deacetylase 2expression in damaged ventral posterolateral nucleus neurons.Inhibiting this increase restored histone H3 acetylation in the Kcna2 promoter region of the voltage-dependent potassium(Kv)channel subunit gene in a rat model of central post-stroke pain,thereby increasing Kcna2expression and relieving central pain.However,in the absence of nerve injury,increasing histone deacetylase 2 expression decreased Kcna2expression,decreased Kv current,increased the excitability of neurons in the ventral posterolateral nucleus area,and led to neuropathic pain symptoms.Moreover,treatment with the iron chelator deferiprone effectively reduced iron overload in the ventral posterolateral nucleus after intracerebral hemorrhage,reversed histone deacetylase 2 upregulation and Kv1.2 downregulation,and alleviated mechanical hypersensitivity in central post-stroke pain rats.These results suggest that histone deacetylase 2 upregulation and Kv1.2 downregulation,mediated by iron overload,are important factors in central post-stroke pain pathogenesis and co uld se rve as new to rgets for central poststroke pain treatment.

Voltage-dependent potassium channel Kv4.2 promotes neurogenesis and alleviates isch⁃emic stroke impairments

OBJECTIVE Stroke has become the top ten leading cause of death in China.Isch⁃emic stroke accounts for 85%of stroke cases,and insufficiency of cerebral blood supply caused by atherosclerosis is one of the important causes of ischemic stroke.Therefore,it is of posi⁃tive significance to study the molecular mecha⁃nism of stroke injury caused by hypoperfusion in the search for drug targets.Voltage-dependent potassium channels are a family of potassium channels widely expressed in the central ner⁃vous system.However,their roles in neurogene⁃sis after stroke insults have not been clearly illus⁃trated.The purpose of this experiment is to explore the expression changes of different sub⁃families of voltage-dependent potassium chan⁃nels after the occurrence of ischemic stroke and their influence on neuroregeneration,to study the molecular mechanism of stroke injury caused by hypoperfusion,and to find potential targets for drug therapy of ischemic stroke.METHODS C57BL/6 mice aged 7-8 weeks and C17.2 cells were used in vivo and in vitro in the experiment.The mice in the experimental group were suf⁃fered from bilateral common carotid artery occlu⁃sion(BCCO)for 1 h and reperfusion for 7 d.In the control group,bilateral carotid artery was dis⁃sected without occlusion.Behavioral assay of suspension test were performed to assess the motor deficits of the mice.In this assay,the time of the first drop(latency),the number of drops within one minute(frequency),and the final scores were recorded as the results of athletic ability.A lower score indicated more severe motor damage of the mice.TTC staining was used to observe the cerebral infarction areas caused by ligation of bilateral common carotid arteries.After seven days,mice were sacrificed and brain tissue protein samples were collected for real-time quantitative PCR(RT-PCR)and Western blotting test to detect the changes of potassium channel subfamily expression levels in different brain regions.Neuronal injuries in all brain regions were detected using Nissl staining methods 7 d following model establishment.To detect the effects and the underlying mechanism of the related potassium channel on neurogene⁃sis,recombinant plasmids of the potassium chan⁃nels were transfected in cultured C17.2 neural stem cells.Afterwards,oxygen glucose depriva⁃tion experiments were performed.RESULTS Behavioral tests showed that BCCO can cause impaired motor performance.TTC staining showed that cerebral infarction existed in the stri⁃atum region,and the motor function decline caused by the injury in this region was consistent with the behavioral experiment results which veri⁃fied the effectiveness of our surgical operation.Nissl staining revealed a large amount of neuronal cell necrosis in the cortex and striatum regions,and dense neuronal cells in the lateral ventricular limbic region,suggesting that neurogenesis may have occurred in this region.The results of real-time quantitative RT-PCR showed that among the detected potassium channels distributed in the measured nervous system,the expression of voltage-dependent potassium channel Kv4.2 decreased significantly in all brain regions after stroke,suggesting that it may be involved in the pathological process of stroke.Immunohisto⁃chemical staining showed that there was neuro⁃genesis in the subgranular zone(SGZ)and sub⁃ventricular zone(SVZ)of the mice,and Kv4.2 expression was significantly changed in the regions,suggesting that it may be involved in the regulation of neuro regeneration after stroke.The transfected Kv4.2 plasmid enhanced the dif⁃ferentiation of the C17.2 neural stem cells to neu⁃rons and astrocytes under normoxia and the oxy⁃gen-glucose deprivation,suggesting that Kv4.2 may induce the differentiation of neural stem cells after stroke.Kv4.2 could induce the neural stem cells to differentiate into neurons in vitro and in vivo,and Western blotting assay showed that Kv4.2 could up-regulate the expression level of ERK1/2,p-ERK1/2,p-STAT3,NGF,p-TtkA,and BDNF.Moreover,the calcium ions and CAMKⅡwas also increased by Kv4.2 in vitro.CONCLUSION BCCO insults can induce the expressions of the potassium channels in the brains,among which the expression of Kv4.2 is down-regulated in the cerebral cortex,hippocam⁃pus and striatum.In vitro experiments confirmed that Kv4.2 can induce the differentiation of C17.2 neural stem cells into neurons and astrocytes under the condition of normoxia and oxygen-glucose deprivation.We concluded that Kv4.2 possibly promoted neurogenesis through ERK1/2/STAT3,NGF/TrkA,and Ca2+/CAMKⅡsignal pathways after stroke.Regulating the physiologi⁃cal functions of Kv4.2 channel might contribute to the rehabilitation of neuronal damage after stroke.

Potassium sulphate induces resistance of rice against the rootknot nematode Meloidogyne graminicola

Potassium(K),an important nutrient element,can improve the stress resistance/tolerance of crops.The application of K in resisting plant-parasitic nematodes shows that the K treatment can reduce the occurrence of nematode diseases and increase crop yield.However,data on K_(2)SO_(4)induced rice resistance against the root-knot nematode Meloidogyne graminicola are still lacking.In this work,K_(2)SO_(4)treatment reduced galls and nematodes in rice plants and delayed the development of nematodes.Rather than affecting the attractiveness of roots to nematodes and the morphological phenotype of giant cells at feeding sites,such an effect is achieved by rapidly priming hydrogen peroxide(H_(2)O_(2))accumulation and increasing callose deposition.Meanwhile,galls and nematodes in rice roots were more in the potassium channel OsAKT11 and transporter OsHAK5 gene-deficient plants than in wild-type,while the K_(2)SO_(4)-induced resistance showed weaker in the defective plants.In addition,during the process of nematode infection,the expression of jasmonic acid(JA)/ethylene(ET)/brassinolide(BR)signaling pathway-related genes and pathogenesis-related(PR)genes OsPR1 a/OsPR1 b was up-regulated in rice after K_(2)SO_(4)treatment.In conclusion,K_(2)SO_(4)induced rice resistance against M.graminicola.The mechanism of inducing resistance was to prime the basal defense and required the participation of the K^(+)channel and transporter in rice.These laid a foundation for further study on the mechanism of rice defense against nematodes and the rational use of potassium fertilizer on improving rice resistance against nematodes in the field.

Effect of acupuncture combined with Xijing Tongmai decoction on the sustained expression of transient outward potassium channel related protein in rats with myocardial infarction

Objective:To observe the sustained expression of transient outward potassium channel related proteins at the end of the treatment and 30 days after the end of the treatment in rats,and to explore the sustained curative effect and mechanism of acupuncture combined with Xijingtongmai decoction in rats with myocardial infarction.Methods:Twenty of 130 male SD rats were random extracted as the control group,and the rest were used to establish myocardial infarction by fed with high-fat diet and then injected with isoproterenol.According to ECG,80 rats were successfully established.Then they were randomly divided into model group,acupuncture combined with Chinese medicine group,acupuncture group and Western medicine group.The content of bFGF protein was measured by ELISA.The protein contents of Kv1.4,Kv4.2,Kv4.3 and KChIP2 were measured by Western blot.Results:At the end of treatment,compared with the model group,the protein contents of Kv1.4,Kv4.2,Kv4.3,KChIP2 and bFGF in each treatment group increased,and the increase was most significant in the acupuncture combined with Chinese medicine group(P<0.05).At the end of treatment,compared with the model group,the protein contents of Kv1.4,Kv4.2,Kv4.3,KChIP2 and bFGF in each treatment group increased,and the increase was most significant in the acupuncture combined with Chinese medicine group(P<0.05).Compared with the treatment group at the end of treatment,the expression of Kv1.4,Kv4.2,Kv4.3,KChIP2 and bFGF protein in each treatment group 30 days after the end of treatment decreased slightly(P<0.05),but still higher than that of the model group at this time(P<0.05).The combination of acupuncture and Chinese medicine group decreased the least of them(P<0.05).Conclusion:The results showed that acupuncture combined with xijingtongmai decoction had a sustained good effect.Its sustained action mechanism may be achieved by continuously increasing the protein content of Kv1.4,Kv4.2,Kv4.3,KChIP2 and bFGF through transient outward potassium channel.

Chronic salt-loading downregulates large-conductance Ca^(2+)-activated potassium channel in mesenteric arterial smooth muscle cells from SD rats

Objective Large-conductance calcium-activated potassium(BKCa)channel modulates vascular smooth muscle tone.In the present study,we tested the hypothesis that salt,one of the factors which significantly influence blood pressure(BP),can regulate BKCa activity and then elevate blood pressure.Methods Male Sprague-Dawley rats aged 6 weeks were randomized into high salt diet group(HS)and control group,fed with high salt diet(containing 5% NaCl)and standard rat chow(containing 0.4% NaCl)respectively for 16 weeks.Tail systolic blood pressure(SBP),body weight(BW)and 24-hour urinary output were tested every 4 weeks.Content of urinary Na+ was detected using flame spectrophotometrical method.At the end of 16 weeks,all the rats were killed,the mesenteric arteries were obtained,and single mesenteric smooth muscle cells were isolated at once.The resting membrane potential(Em),the total potassium currents and the currents after perfusion with TEA solution of the cells were all recorded by whole cell patch clamp.The transcriptions of BKCa channel α and β1 subunits in mesenteric arterial vascular smooth muscle cells(VSMC)of each group were calculated by real-time RT-PCR.Results There was no difference in SBP and BW at each stage between control group and HS group;the urinary Na+ level in HS animals was elevated significantly after 4 weeks.The negative values of Em in HS group VSMCs were reduced compared with those in the control group.Transcriptions of β1 subunit of BKCa channels were decreased in HS group,but α subunit transcriptions did not differ between the two groups.Whole cell potassium currents did not differ between HS and control groups,but BKCa currents of HS group VSMCs were lower than those of control group ones.Conclusion Even without elevating SBP,salt-loading can still modulate the expression and activity of BKCa channel in the mesenteric arterial VSMC and elevate vascular tone.

Effects of acupuncture combined with Kaijingtongmai Decoction on ATP sensitive potassium channel related proteins Kir6.1 and Kir6.2 in myocardial infarction rats

Objective:To study the effect of combination of acupuncture and medicine on the expression of ATP sensitive potassium channel related proteins Kir6.1 and Kir6.2 in rats with myocardial infarction,and to study the possible mechanism of combination of acupuncture and medicine on the improvement of myocardial infarction,so as to provide experimental data basis for the development of new treatment methods for myocardial infarction.Methods:65 healthy male SD rats were randomly selected as the control group.The other rats were fed with high-fat food for three weeks.The rats in the control group were injected with normal saline subcutaneously,and the other rats were injected with isoproterenol hydrochloride in the same way.Through ECG comparison,40 successful Mi rats were randomly divided into model group,acupuncture group,western medicine group and acupuncture drug combination group,with 10 rats in each group.After the corresponding treatment,the ECG changes of rats in each group were observed,the pathological changes of rat cardiomyocytes were observed by HE staining,and the expression of ATP sensitive potassium channel(Kir6.1,Kir6.2)protein was detected by Western blot.Results:compared with the control group,40 experimental specimens in the experimental group showed significant changes in cardiomyocyte protein The expression of Kir6.1 and Kir6.2 increased,and the difference was statistically significant.After treatment,compared with the model group,the protein expression of Kir6.1 and Kir6.2 in cardiomyocytes of Western medicine group,acupuncture group and acupuncture drug combination group showed a downward trend,among which the decline degree of acupuncture drug combination group was the most obvious,and the difference was statistically significant.The decline degree of acupuncture group and Western medicine group was not significant,and there was no significant difference Conclusion:acupuncture combined with medicine has a significant effect on improving myocardial infarction in rats,which may be related to the expression of ATP sensitive potassium channel related proteins Kir6.1 and Kir6.2 in rat cardiomyocytes.

Effects of fluoxetine on protein expression of potassium ion channels in the brain of chronic mild stress rats

The purpose of this study is to investigate the expression of major potassium channel subtypes in the brain of chronical mild stress(CMS) rats and reveal the effects of fluoxetine on the expression of these channels. Rats were exposed to a variety of unpredictable stress for three weeks and induced anhedonia, lower sucrose preference, locomotor activity and lower body weight. The protein expressions were determined by Western blot. CMS significantly increased the expression of Kv2.1 channel in frontal cortex but not in hippocampus, and the expression level was normalized after fluoxetine treatment. The expression of TREK-1 channel was also obviously increased in frontal cortex in CMS rats. Fluoxetine treatment might prevent this increase. However, the expression of Kv3.1 and Kv4.2 channels was considerably decreased in hippocampus after CMS, and was not affected by fluoxetine. These results suggest that different subtypes of potassium channels are associated with the pathophysiology of depression and that the therapeutical effects of fluoxetine may relate to Kv2.1 and TREK-1 potassium channels.

Modeling protein-protein interactions in axon initial segment to understand their potential impact on action potential initiation

The axon initial segment(AIS)region is crucial for action potential initiation due to the presence of high-density AIS protein voltage-gated sodium channels(Nav).Nav channels comprise several serine residues responsible for the recruitment of Nav channels into the structure of AIS through interactions with ankyrin-G(AnkG).In this study,a series of computational experiments are performed to understand the role of AIS proteins casein kinase 2 and AnkG on Nav channel recruitment into the AIS.The computational simulation results using Virtual cell software indicate that Nav channels with all serine sites available for phosphorylation bind to AnkG with strong affinity.At the low initial concentration of AnkG and casein kinase 2,the concentration of Nav channels reduces significantly,suggesting the importance of casein kinase 2 and AnkG in the recruitment of Nav channels.

Adiponectin and the regulation of gastric content volume in the newborn rat

BACKGROUND Oral intake is dependent on the gastric ability to accommodate the food bolus.Comparatively,neonates have a smaller gastric capacity than adults and this may limit the volume of their milk intake.Yet,we previously reported that the newborn rat gastric milk volume is greatest after birth and,when normalized to body weight,decreases with postnatal age.Such age-dependent changes are not the result of intake differences,but greater gastric accommodation and reduced emptying rate.AIM Hypothesizing that breastmilk-derived adiponectin is the factor regulating gastric accommodation in neonates,we comparatively evaluated its effects on the rat fundic muscle tone at different postnatal ages.METHODS In freshly dispersed smooth muscle cells(SMC),we measured the adiponectin effect on the carbachol-induced length changes.RESULTS Adiponectin significantly reduced the carbachol-stimulated SMC shortening independently of age.In the presence of the inhibitor iberiotoxin,the adiponectin effect on SMC shortening was suppressed,suggesting that it is mediated via largeconductance Ca^(2+)sensitive K^(+)channel activation.Lastly,we comparatively measured the newborn rat gastric milk curd adiponectin content in one-and twoweek-old rats and found a 50%lower value in the latter.CONCLUSION Adiponectin,a major component of breastmilk,downregulates fundic smooth muscle contraction potential,thus facilitating gastric volume accommodation.This rodent’s adaptive response maximizes breastmilk intake volume after birth.

A novel mutation—L539fs/47 of hERG in a Chinese long QT syndrome family

Objective To identify the mutation of human ether-a-go-go-related gene(hERG)and analyze the clinical characteristics of a Chinese family with long ST syndrome(LQTS).Methods The electrocardiogram and DNA samples were obtained from a Chinese LQTS family of 26 members.Genotype was performed with polymorphic short tandem repeat(STR)markers at the known LQT1,LQT2,and LQT3 loci.SSCP analysis was used to find aberrant conformers.hERG mutation was confirmed by cloning and sequencing.Results Three gene carriers were linked to chromosome 7q35-36,where the potassium channel gene hERG was encoded.A 19-base pair deletion was identified.The mutation was located at nucleotide position 1 619-1 637 between transmembrane domains S4 and S5.Furthermore,A1692G polymorphism was found both in the normal control and patients.Conclusion A novel 19 bp deletion mutation of hERG is identified in a Chinese family.All gene carriers are demonstrated to be typical LQT2 ECG phenotype.

Effects of potassium channel blockage on inverse stochastic resonance in Hodgkin-Huxley neural systems

Inverse stochastic resonance(ISR)is a phenomenon in which the firing activity of a neuron is inhibited at a certain noise level.In this paper,the effects of potassium channel blockage on ISR in single Hodgkin-Huxley neurons and in small-world networks were investigated.For the single neuron,the ion channel noise-induced ISR phenomenon can occur only in a certain small range of potassium channel blockage ratio.Bifurcation analysis showed that this small range is the bistable region regulated by the external bias current.For small-world networks,the effect of non-homogeneous network blockage on ISR was investigated.The network blockage ratio was used to represent the proportion of potassium-channel-blocked neurons to total network neurons.It is found that an increase in network blockage ratio at small coupling strengths results in shorter ISR duration.When the coupling strength is increased,the ISR is more significant in the case of a large network blockage ratio.The ISR phenomenon is determined by the network blockage ratio,the coupling strength,and the ion channel noise.Our results will provide new perspectives on the observation of ISR in neuroscience experiments.

Genetic Variants of Potassium Voltage-gated Channel Subfamily J Member 11 in Gestational Diabetes Mellitus:A Case-control Study

Objective::To investigate the association of rs5210 in potassium voltage-gated channel subfamily J member 11(KCNJ11)with gestational diabetes mellitus(GDM).Methods::Six hundred and thirty-two uncorrelated pregnancy females were recruited in Tongji hospital from October 2017 to June 2018,in which 241 pregnant women were identified as GDM,and 391 were non-GDM.All the pregnant women recruited in this study their peripheral venous blood of 5 mL were withdrawn,and DNA in the blood was extracted.rs5210 in KCNJ11 were genotyped using TaqMan Assays and genotype models were analyzed using logistic regression analyses.Results::After adjusting age and body mass index,the variant genotypes of rs5210 in genotype models were as follows:P for dominant model was 0.945,(odd ratio:0.987,95%confidence intervals(CI):0.681-1.430);P for recessive model:0.556,(odd ratio:1.217,95%CI:0.633-2.343)and P for addictive model was 0.098(genotype AA vs.GG),(odds ratio:1.435,95%CI:0.936-2.201).Weight-gain during pregnancy and total cholesterol were significantly different in recessive model(P=0.015,P=0.022,respectively)of all participants.Conclusion::No significant association between gene susceptibility of rs5210 in KCNJ11 and GDM occurrence in Chinese pregnant women.But the variant of rs5210 was associated with weight-gain during pregnancy and total cholesterol blood levels.However,more cases are needed in genetic study to check its susceptibility with GDM occurrence in Chinese women.

Neurological diseases associated with autoantibodies targeting the voltage-gated potassium channel complex:immunobiology and clinical characteristics

Voltage-gated potassium channels(VGKCs)represent a group of tetrameric signaling proteins with several functions,including modulation of neuronal excitability and neurotransmitter release.Moreover,VGKCs give a key contribution to the generation of the action potential.VGKCs are complexed with other neuronal proteins,and it is now widely known that serum autoantibodies directed against VGKCs are actually directed against the potassium channel subunits only in a minority of patients.By contrast,these autoantibodies more commonly target three proteins that are complexed with alpha-dendrotoxin-labeled potassium channels in brain extracts.These three proteins are contactin-associated protein-2(Caspr-2),leucine-rich,glioma inactivated 1(LGI-1)protein and the protein Tag-1/contactin-2.Neoplasms are detected only in a minority of seropositive patients for VGKC complex-IgG and do not significantly associate with Caspr-2 or LGI-1.Among all the cancers described in association with VGKC complex-IgG,lung carcinoma,thymoma,and hematologic malignancies are the most commonly detected.We will review all the major neurological conditions associated with VGKC complex-IgG.These include Isaacs’syndrome,Morvan syndrome,limbic encephalitis,facio-brachial dystonic seizures,chorea and other movement disorders,epilepsy,psychosis,gastrointestinal neuromuscular diseases,a subacute encephalopathy that mimics Creutzfeldt-Jakob prion disease both clinically and radiologically and autoimmune chronic pain.The vast majority of these conditions are reversible by immunotherapy,and it is becoming increasingly recognized that early diagnosis and detection of VGKC complex-IgG is critical in order to rapidly start the treatment.As a result,VGKC complex-IgG are now part of the investigation of patients with unexplained subacute onset of epilepsy,memory or cognitive problems,or peripheral nerve hyperexcitability syndromes.