Episodic ataxia type 1 mutations in the KCNA1 gene impair the fast inactivation properties of the human potassium channels Kv1.4-1.1/Kvbeta1.1 and Kv1.4-1.1/Kvbeta1.2

Episodic ataxia type 1 (EA1) is an autosomal dominant neurological disorder characterized by constant muscle rippling movements (myokymia) and episodic attacks of ataxia. Several heterozygous point mutations have been found in the coding sequence of the voltage-gated potassium channel gene KCNA1 (hKv1.1), which alter the delayed-rectifier function of the channel. Shaker-like channels of different cell types may be formed by unique hetero-oligomeric complexes comprising Kv1.1, Kv1.4 and Kvbeta1.x subunits. Here we show that the human Kvbeta1.1 and Kvbeta1.2 subunits modulated the functional properties of tandemly linked Kv1.4-1.1 wild-type channels expressed in Xenopus laevis oocytes by (i) increasing the rate and amount of N-type inactivation, (ii) slowing the recovery rate from inactivation, (iii) accelerating the cumulative inactivation of the channel and (iv) negatively shifting the voltage dependence of inactivation. To date, the role of the human Kv1.4-1.1, Kv1.4-1.1/Kvbeta1.1 and Kv1.4-1.1/Kvbeta1.2 channels in the aetiopathogenesis of EA1 has not been investigated. Here we also show that the EA1 mutations E325D, V404I and V408A, which line the ion-conducting pore, and I177N, which resides within the S1 segment, alter the fast inactivation and repriming properties of the channels by decreasing both the rate and degree of N-type inactivation and by accelerating the recovery from fast inactivation. Furthermore, the E325D, V404I and I177N mutations shifted the voltage dependence of the steady-state inactivation to more positive potentials. The results demonstrate that the human Kvbeta1.1 and Kvbeta1.2 subunits regulate the proportion of wild-type Kv1.4-1.1 channels that are available to open. Furthermore, EA1 mutations alter heteromeric channel availability which probably modifies the integration properties and firing patterns of neurones controlling cognitive processes and body movements.     

HCN通道相关性疾病在心脏中的表现

超极化激活环核苷酸门控阳离子通道(HCN)在心脏起搏细胞中呈高表达,并参与心脏起搏的产生及心率调控。而调控该通道蛋白的基因突变、错义均可导致心律失常的发生。目前已发现5种HCN基因突变所致的心律失常,且存在家族遗传性。不仅如此,该基因在心肌不同的微环境中可能呈现出不同的表达,进一步影响心律的变化。现对HCN通道生物生理特点及HCN通道相关性疾病的研究进展进行综述。     

Is there a role for potassium channel openers in neuronal ion channel disorders?

Malfunction in ion channels, due to mutations in genes encoding channel proteins or the presence of autoantibodies, are increasing being implicated in causing disease conditions, termed channelopathies. Dysfunction of potassium (K⁺) channels has been associated with the pathophysiology of a number of neurological, as well as peripheral, disorders (e.g., episodic ataxia, epilepsy, neuromyotonia, Parkinson’s disease, congenital deafness, long QT syndrome). K⁺ channels, which demonstrate a high degree of diversity and ubiquity, are fundamental in the control of membrane depolarisation and cell excitability. A common feature of K⁺ channelopathies is a reduction or loss of membrane potential repolarisation. The identification of K⁺ channel subtype specific openers will allow the recovery of the mechanism(s) responsible for counteraction of uncontrolled cellular depolarisation. Synthetic agents that demonstrate K⁺ channel opening properties are available for a variety of K⁺ channel subtypes (e.g., K_ATP, BK_Ca, GIRK and M-channel). This study reviews the realistic therapeutic potential that may be gained in a broad spectrum of clinical conditions by K⁺ channel openers. K⁺ channel openers would therefore identify dysfunctional K⁺ channel as therapeutic targets for clinical benefit, in addition being able to modulate normally functioning K⁺ channels to gain clinical management of pathophysiological events irrespective of the cause.     

KCNJ2 mutation in short QT syndrome 3 results in atrial fibrillation and ventricular proarrhythmia

We describe a mutation (E299V) in KCNJ2, the gene that encodes the strong inward rectifier K⁺ channel protein (Kir2.1), in an 11-y-old boy. The unique short QT syndrome type-3 phenotype is associated with an extremely abbreviated QT interval (200 ms) on ECG and paroxysmal atrial fibrillation. Genetic screening identified an A896T substitution in a highly conserved region of KCNJ2 that resulted in a de novo mutation E299V. Whole-cell patch-clamp experiments showed that E299V presents an abnormally large outward I_K1 at potentials above −55 mV (P < 0.001 versus wild type) due to a lack of inward rectification. Coexpression of wild-type and mutant channels to mimic the heterozygous condition still resulted in a large outward current. Coimmunoprecipitation and kinetic analysis showed that E299V and wild-type isoforms may heteromerize and that their interaction impairs function. The homomeric assembly of E299V mutant proteins actually results in gain of function. Computer simulations of ventricular excitation and propagation using both the homozygous and heterozygous conditions at three different levels of integration (single cell, 2D, and 3D) accurately reproduced the electrocardiographic phenotype of the proband, including an exceedingly short QT interval with merging of the QRS and the T wave, absence of ST segment, and peaked T waves. Numerical experiments predict that, in addition to the short QT interval, absence of inward rectification in the E299V mutation should result in atrial fibrillation. In addition, as predicted by simulations using a geometrically accurate three-dimensional ventricular model that included the His–Purkinje network, a slight reduction in ventricular excitability via 20% reduction of the sodium current should increase vulnerability to life-threatening ventricular tachyarrhythmia.     

Genotype–phenotype correlations in neonatal epilepsies caused by mutations in the voltage sensor of Kv7.2 potassium channel subunits

Mutations in the K_V7.2 gene encoding for voltage-dependent K⁺ channel subunits cause neonatal epilepsies with wide phenotypic heterogeneity. Two mutations affecting the same positively charged residue in the S₄ domain of K_V7.2 have been found in children affected with benign familial neonatal seizures (R213W mutation) or with neonatal epileptic encephalopathy with severe pharmacoresistant seizures and neurocognitive delay, suppression-burst pattern at EEG, and distinct neuroradiological features (R213Q mutation). To examine the molecular basis for this strikingly different phenotype, we studied the functional characteristics of mutant channels by using electrophysiological techniques, computational modeling, and homology modeling. Functional studies revealed that, in homomeric or heteromeric configuration with K_V7.2 and/or K_V7.3 subunits, both mutations markedly destabilized the open state, causing a dramatic decrease in channel voltage sensitivity. These functional changes were (i) more pronounced for channels incorporating R213Q- than R213W-carrying K_V7.2 subunits; (ii) proportional to the number of mutant subunits incorporated; and (iii) fully restored by the neuronal K_v7 activator retigabine. Homology modeling confirmed a critical role for the R213 residue in stabilizing the activated voltage sensor configuration. Modeling experiments in CA1 hippocampal pyramidal cells revealed that both mutations increased cell firing frequency, with the R213Q mutation prompting more dramatic functional changes compared with the R213W mutation. These results suggest that the clinical disease severity may be related to the extent of the mutation-induced functional K⁺ channel impairment, and set the preclinical basis for the potential use of K_v7 openers as a targeted anticonvulsant therapy to improve developmental outcome in neonates with K_V7.2 encephalopathy.     

A Population-Based Registry of Patients With Inherited Cardiac Conditions and Resuscitated Cardiac Arrest

BackgroundThe relative proportion of each cardiac inherited disease (CID) causing resuscitated sudden cardiac arrest (RSCA) on a population basis is unknown.ObjectivesThis study describes the profile of patients with CIDs presenting with RSCA; their data were collected by the national Cardiac Inherited Diseases Registry New Zealand (CIDRNZ).MethodsData were collated from CIDRNZ probands presenting with RSCA (2002 to 2018).ResultsCID was identified in 115 (51%) of 225 RSCA cases: long QT syndrome (LQTS) (n = 48 [42%]), hypertrophic cardiomyopathy (HCM) (n = 28 [24%]), Brugada syndrome (BrS) (n = 16 [14%]), catecholaminergic polymorphic ventricular tachycardia (CPVT) (n = 9 [8%]), arrhythmogenic right ventricular cardiomyopathy (ARVC) (n = 9 [8%]), and dilated cardiomyopathy (n = 5 [4%]). Seventy-one (62%) of 115 were male. Of 725 probands from the CIDRNZ with CID, the proportion presenting with RSCA was: CPVT, 9 (53%) of 17; BrS, 16 (33%) of 49; ARVC, 9 (25%) of 36; LQTS, 48 (20%) of 238; dilated cardiomyopathy, 5 (9%) of 58; and HCM, 28 (8%) of 354. Incident activity was: normal everyday activities, 44 (40%); exercising, 33 (30%); concurrent illness, 13 (12%); sleeping, 10 (9%); drugs/medication, 9 (8%); and emotion, 2 (2%). LQTS and CPVT predominated in those <24 years of age, 30 (77%) of 39; cardiomyopathies and BrS predominated in those >24 years of age, 49 (64%) of 76. For those >40 years of age, HCM was the most common (33%) CID. A genetic diagnosis in patients with CID was made in 48 (49%) of 98 tested. Diagnosis by age range was as follows: age 1 to 14 years, 78%; age 15 to 24 years, 53%; age 25 to 39 years, 54%; and age >40 years, 26%.ConclusionsThe commonest CID identified after RSCA was LQTS; the most common CID cause of RSCA for those >40 years of age was HCM. CPVT was the CID most likely to present with RSCA and HCM the least. Genetic yield decreases with age. Only one-third of RSCA cases due to CID occurred while exercising.