Cardiac sodium channel mutation associated with epinephrine-induced QT prolongation and sinus node dysfunction / エピネフリン誘発性QT延長及び洞結節機能不全に関連する心筋ナトリウムチャネル遺伝子変異の解析

Jiarong, Chen

23 March 2016

京都大学 / 0048 / 新制・課程博士 / 博士(医学) / 甲第19609号 / 医博第4116号 / 新制||医||1015(附属図書館) / 32645 / 京都大学大学院医学研究科医学専攻 / (主査)教授 岩井 一宏, 教授 小杉 眞司, 教授 瀬原 淳子 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM

SCN5A

epinephrine

long-QT syndrome

adrenergic stimulation

cardiac sodium channel mutation

490

Human Nav1.5 F1486 deletion associated with long-QT syndrome leads to deficiency in inactivation and reduces lidocaine sensitivity

Song, Weihua

19 March 2012

Indiana University-Purdue University Indianapolis (IUPUI) / The cardiac voltage-gated sodium channel α subunit Nav1.5 generates the cardiac sodium current, which is essential for the initiation and propagation of the cardiac action potentials. Mutations of SCN5A, the gene that encodes Nav1.5, have been well documented to cause long-QT syndrome (LQTs) by disrupting channel inactivation and increasing late sodium current. Previous studies have revealed the importance of the intracellular loop region between transmembrane domain III and IV of sodium channel α subunit in regulating the fast inactivation. A recent clinical case study reported an infant patient with LQTs carrying a phenylalanine (F) deletion at amino acid 1486 of the Nav1.5 channel. This study reported that the patient showed severe cardiac arrhythmia reflected as LQTs and subsequent ventricular tachycardia, which was refractory to antiarrhythmic drug lidocaine treatment. Therefore, it was hypothesized that the deletion of F1486 on Nav1.5 would substantially alter electrophysiological properties of the channel and reduce the potency of lidocaine on sodium channel. Using HEK293 cells and neonatal rat cardiomyocytes, the F1486del channel was functionally characterized by whole-cell patch clamp techniques. Studies revealed that the deletion of F1486 causes a combination of changes including a loss-of-function alteration reflected as a substantial reduction of peak current density and a number of gain-of-function alterations including reduced channel inactivation, substantial augmentation of late sodium current, and an increase in ramp current. In addition, lidocaine sensitivity was dramatically reduced. By contrast, the voltage for half maximal activation (V1/2) and the time constant for channel deactivation for the F1486del channel were identical to the wild type channels. Using neonatal rat cardiomyocytes, we were able to study the functional consequence of F1484del on action potential duration (APD). Cardiomyocytes expressing F1486del channel have substantial APD prolongation and prominent spontaneous early afterdepolarizations, which likely underlie the subsequent LQTs in the patient. Taken together, despite the reduction in peak current density, the substantial gain-of-function changes are sufficient to cause the APD prolongation, which is a prominent characteristic of LQTs. These findings provide knowledge for understanding the relationships between sodium channel structure, pharmacology and the physiological consequence of sodium channel mutations that underlie LQT3.

Sodium channels

Long QT syndrome

Lidocaine

Anesthetics -- Side effects

SLEEP-RELATED GENERALIZED TONIC SEIZURE AND HIGH FREQUENCY OSCILLATION (HFOs) IN A MESIAL TEMPORAL LOBE EPILEPSY MOUSE MODEL

Tian, Nan

20 July 2010

No description available.

Biomedical Research

Modulations of Sodium Channel Long QT and Brugada Syndrome Mutations by a Common Sodium Channel Polymorphism

Shinlapawittayatorn, Krekwit

31 January 2012

No description available.

Biomedical Research

Sodium channel

long QT syndrome

brugada syndrome

arrhythmias

polymorphism

incomplete penetrance

MICRORNA AND mRNA EXPRESSION PROFILES OF THE FAILING HUMAN SINOATRIAL NODE

Artiga, Esthela J.

January 2020

No description available.

Anatomy and Physiology

Sinoatrial node

heart failure

microrna alterations

Adaptive evolution, sex-linkage, and gene conversion in the voltage-gated sodium channels of toxic newts and their snake predators

Gendreau, Kerry

27 May 2022

Understanding how genetic changes ultimately affect morphology and physiology is essential for understanding and predicting how organisms will adapt to environmental changes. Although most traits are complex and involve the interplay of many different genetic loci, some exceptions exist. These include the convergent evolution of tetrodotoxin resistance in snakes, which has a simple genetic basis and can be used as a model system to investigate the genetic basis of adaptive evolution. Tetrodotoxin is a potent neurotoxin used as a chemical defense by various animals, including toxic newts. Snakes have evolved resistance through mutations in voltage-gated sodium channels, the protein targets of tetrodotoxin, sparking an evolutionary arms race between predator and prey. In this dissertation, I describe how genomic rearrangements have led to sex-linkage of four of the voltage-gated sodium channel genes in snakes and compare allele frequencies across populations and sexes to make inferences about how sex linkage has influenced the evolution of resistance in garter snakes. By measuring gene expression in different snake tissues, I show that three of these sex-linked sodium channel genes are dosage compensated in embryos, adult muscle, and adult brain. In contrast, two channels show sexual dimorphism in their expression levels in the heart, which may indicate differences in dosage compensation among tissues. I then use comparative genomics to track the evolutionary history of tetrodotoxin resistance across all nine sodium channel genes in squamate reptiles and show how historical changes have paved the way for full-body resistance in certain snakes. Finally, I use targeted sequence capture to obtain the sodium channel sequences of salamanders and show evidence that tetrodotoxin self-resistance in toxic newts was likely accelerated through gene conversion between resistant and non-resistant sodium channel paralogs. Together, these results illustrate parallelism in evolutionary mechanisms and processes contributing to the appearance of an extreme and complex trait that arose independently in two distinct taxa separated by hundreds of millions of years. / Doctor of Philosophy / Western North America is the site of an ongoing battle between highly toxic species of salamanders (toxic newts) and their garter snake predators. In certain regions, garter snakes have countered newt defenses by evolving resistance to their toxins, and the newts have become more toxic in response. This interaction has been the focus of scientists for decades because it teaches us about the ways in which animals can respond to changes in their environment. In living organisms, DNA is used a blueprint to determine the ultimate traits that are expressed (e.g., whether an organism will have five fingers or four, or whether it will be resistant or sensitive to a toxin). By comparing DNA sequences of different life forms, we are beginning to understand the rules that determine how these blueprints are read and how they can change over time. Because life is built upon the same basic building blocks (DNA, mRNA, and proteins), information about this snake-newt system can be used to understand the way that other systems, such as humans and pathogens, might interact. In my dissertation, I compare DNA sequences from snakes and lizards to identify the history of changes leading to the extreme toxin resistance in the garter snakes. I show that toxin resistance began hundreds of millions of years ago, with all lizards having a low baseline level of resistance, and that resistance built up slowly in the lineages leading to garter snakes. I also show that because of DNA rearrangements, female snakes have fewer copies of some of the genes involved in resistance, and this may have led to differences among the sexes. Lastly, I compare DNA sequences among salamanders, revealing a similar pattern to that in snakes and lizards. Specifically, newts have evolved self-resistance to their own toxin, and this has happened gradually over hundreds of millions of years, with all salamanders having some toxin resistance. I also show that an unusual process occurred within the DNA of toxic newts, resulting in a rapid change from toxin sensitivity to toxin resistance in some genes. Taken together, this work helps advance our understanding of the processes and limitations that determine how organisms can function and change over time.

molecular evolution

toxin resistance

tetrodotoxin

sex-linkage

gene conversion

voltage-gated sodium channel

Régulation du canal sodium épithélial par les acides gras polyinsaturés n-3/ epithelial sodium channel and n-3 polyunsatured fatty acids.

Mies, Frédérique

29 February 2008

I. DESCRIPTION DE PROJET DE RECHERCHE Le canal sodium épithélial bloquable par l’amiloride (ENaC) est une protéine intégrale de la membrane apicale des épithéliums impliqués dans l’absorption du sodium. Deux fonctions majeures sont directement liées au fonctionnement d’ENaC. D’une part, la régulation de la balance sodée par le rein et donc de la pression artérielle et d’autre part, la clairance du fluide alvéolaire pulmonaire. Le transport vectoriel de sel et d’eau à travers ces épithéliums à jonctions serrées repose sur un transport actif de sodium entraînant un flux osmotique d’eau. Ce transport de sodium s’effectue en deux étapes: l’entrée apicale, par diffusion, facilitée via ENaC, et la sortie basolatérale, active, par les pompes Na+/K+ ATPases. Ces dernières années, un intérêt grandissant est porté sur les acides gras polyinsaturés à longues chaînes de type oméga 3 (PUFAs) et leurs implications dans divers processus physiologiques. Entre autres effets, les PUFAs modulent différents types de canaux ioniques (canaux Na+ dépendant du voltage, Ca++ L-type, K+). Les études in vivo impliquant un effet à long terme des PUFAs décrivent des mécanismes inhibiteurs. Cependant, lors d’une étude précédente, axée sur la composition lipidique des membranes de cellules rénales en culture et l’influence de l’ajout d’acides gras saturés et insaturés sur le transport du sodium, nous avons constaté que les acides gras polyinsaturés à longues chaînes de type oméga 3 augmentaient la réabsorption du sodium. Ces résultats pourraient être intéressants, car les canaux sodiques de l’épithélium alvéolaire sont en contact direct avec le surfactant, dont la composition lipidique varie en fonction de l’apport alimentaire en PUFAs. Chez les prématurés humains, le syndrome de détresse respiratoire est une des causes les plus fréquentes de mortalité. Dans un certain nombre de cas, on peut restaurer une fonction pulmonaire satisfaisante par l’administration de surfactant. Dans ce travail, nous avons opté pour une approche fondamentale des mécanismes de régulation du canal sodium épithélial par l’acide eicosapentanoïque (EPA, C 20:5, n-3). Des études électrophysiologiques, biochimiques et d’imagerie cellulaire ont été réalisées sur la lignée cellulaire A6 de rein d’amphibien, qui sert d’épithélium modèle pour l’étude d’ENaC depuis plus de 25 ans. Cette lignée exprime des canaux sodiques très sélectifs et possède des propriétés électrophysiologiques facilitant l’étude de leur régulation. Ce travail nous a permis de mettre en évidence de nouveaux mécanismes fondamentaux dont la pertinence physiologique et /ou clinique ne pourra être établie qu’en transposant cette étude sur un modèle in vivo, comme nous le proposons dans les perspectives. Dans le présent travail, nous avons étudié : 1. La distribution fonctionnelle d’ENaC dans la membrane apicale des cellules A6. 2. Les effets des acides gras polyinsaturés oméga-3 (n-3 PUFAs) sur le transport du sodium et les voies de signalisation impliquées dans ces effets. Nous montrons que les canaux sodiques épithéliaux sont distribués de manière hétérogène dans la membrane apicale des cellules A6, les canaux actifs se localisant au niveau de microdomaines membranaires (Am. J. Renal Physiol. 2003). Nous montrons aussi que l’acide eicosapentanoïque (EPA, C20 :5) augmente la perméabilité au sodium de la membrane apicale des cellules A6. Cette stimulation est transitoire et réversible, et implique l’activation de la protéine kinase A (PKA) en aval d’une augmenation d’adénosine monophosphate cyclique (AMPc) (Am. J. Renal Physiol. 2004). L’EPA ne provoque ni la stimulation de l’adénylate cyclase, ni l’augmentation d’AMPc total, mais inhibe l’activité phosphodiestérasique membranaire. En l’absence d’une augmentation mesurable d’AMPc, nous avons testé l’hypothèse d’une compartimentalisation de la PKA à la membrane apicale, où une faible augmentation d’AMPc pourrait être suffisante pour son activation. Nous montrons qu’une telle compartimentalisation est rendue possible grâce à une A-Kinase Anchoring Protein (AKAP) qui ancre la PKA à la membrane apicale. L’inhibition de la liaison AKAP-PKA empêche la stimulation du courant sodium par l’EPA. La distribution d’ENaC dans les microdomaines membranaires insolubles aux détergents pourrait favoriser l’ancrage de l’AKAP et des protéines régulatrices à proximité du canal ( J. Biol. Chem, 2007). Ce travail montre pour la première fois, un ancrage membranaire de la PKA par une AKAP dans les cellules A6 et met ainsi en évidence un nouveau mécanisme de régulation des canaux sodium épithéliaux.

physiologie/ physiology

Endogenous and Exogenous Regulation of Exhaled Ions in Patients with Cystic Fibrosis

Wheatley, Courtney M.

January 2013

Exercise has become a vital component of the therapy regimen prescribed to cystic fibrosis (CF) patients due to its systemic benefits, such as increased sputum expectoration, attenuation of the expected 2-3% annual decline in pulmonary function, and extended life expectancy. However, exercise still is not viewed as being as beneficial as pharmacological treatments by many CF patients and can be intimidating. My aims in this study were two-fold; first, to determine the ideal exercise intensity for individuals with CF; and second, to determine if exercise at this ideal intensity could provide improvements in ion regulation in the lungs, which was measured using exhaled breath condensate (EBC) collection and nasal potential difference (NPD), that were comparable to one of their standard pharmacological therapies, albuterol. I hypothesized that with moderate intensity exercise, Na⁺ absorption would decrease from baseline due to Na⁺ channel inhibition, rather than increase or remain unchanged, as was expected with albuterol, and cause an even greater increase Cl- secretion compared to albuterol due to activation of both CF-dependent and independent Cl- efflux with exercise. CF (n=14) and healthy (n=16) subjects completed three visits, a baseline screening and two treatment visits. I collected EBC at baseline, 30- and 60-minutes post-albuterol administration on one visit, and at baseline and during three separate 15 min exercise bouts at low, moderate and high intensity on the other visit. Following the EBC collection, NPD was performed at 30- and 80-minutes post albuterol or following moderate and high intensity exercise. We also measured spirometry and diffusing capacity of the lungs for nitric oxide (DLNO) during each visit at the various time points. In CF subjects, moderate intensity exercise resulted in greater improvements in DLNO (39 ± 29vs.15 ± 22% change from baseline, exercise vs. albuterol respectively), similar levels of bronchodilation compared to 60-minutes post-albuterol administration, no change in Na⁺ absorption, and a four-fold increase in Cl- secretion. Our results suggest that moderate intensity exercise is the best dose for CF patients, and can provide comparable changes as its pharmacological counterpart albuterol, when compared over a short term duration.

epithelia sodium channel

exercise

exhaled breath condensate

nasal potential difference

Pharmaceutical Sciences

Cystic Fibrosis

Influence of Genetic Variation of the Alpha-Subunit of the Epithelial Sodium Channel (ENaC) on Baseline Pulmonary Function and Exhaled Sodium Ions (Na+) and Chloride Ions (Cl-) in Healthy Subjects and Patients with Cystic Fibrosis

Foxx-Lupo, William T., Snyder, Eric M.

January 2012

Class of 2012 Abstract / Specific Aims: The epithelial sodium channels (ENaC) found on the apical membranes of epithelial cells including those lining the respiratory tract are the rate limiting step of the absorption of excess fluid from the airspace of the alveoli. ENaC function is modulated by the effects of various physiologic signals such as the adrenergic and purinergic pathways, in addition to other local channels which control the flow of negatively charged ions such as the cystic fibrosis transmembrane conductance regulator (CFTR). We sought to determine the influence of genetic variation on the alpha subunit of ENaC at amino acid position 663 on baseline exhaled ions and pulmonary function in patients with CF. Methods: We assessed pulmonary function ( forced vital capacity[FVC], forced expiratory volume in one second [FEV1], forced expiratory flow maximum[FEFmax]) using a Medical Graphics cardiopulmonary testing device (Minneapolis, MN). Measures of exhaled sodium (Na+) and chloride (Cl-) were obtained using exhaled breathe condensate collected on a Jaeger Ecoscreen condenser unit (Cardinal Health, Yorba Linda, CA) with Na+ quantification using an atomic absorption spectrophotometer (Analyst 100; Perkin Elmer, Norwalk, CT) and Cl- anion quantification using a Dionex AS11 HC column. Healthy n=31 (n=18[58%], 9[29%], and 4[13%] subjects; Body mass index (BMI)=23±1, 25±2, and 25±2kg/ m2 for AA, AT and TT groups respectively). CF n= 42 (n=33[79%], 7[16%], and 2[5%] subjects; BMI equals 23±7, 19±0.4, and 20±2.2kg/m2 for AA, AT and TT groups respectively). Main Results: We found that the distribution of genotypes in CF differed from healthy subjects, with the AA genotype in 80% of CF and 59% in healthy. No significant difference were demonstrated in healthy subjects between genotype groups for pulmonary function and exhaled chloride while the genotypes did differ in exhaled Na (Na=2.9±0.4, 1.7±0.3, and 3.7±1.1mmol/L for AA, AT, and TT respectively, ANOVA p=0.07). CF subjects with the AA genotype had a higher baseline exhaled Cl-, FEV1, and FEFmax than those in the AA group (Cl=0.125±0.038,0.0 27±0.007, and 0.033±0.02 mmol/L ; FEV1=71±5, 68±11, and 40±22L; FEFmax=86±4, 72±7, and 44±24L/sec; for AA, AT, and TT respectively, ANOVA p<0.05, Tukey [AA vs. TT] p<0.05) while exhaled Na+ and FVC were similar between genotypes. Conclusions: Our results suggest that CF subjects with the AA genotype of the alpha subunit of the ENaC have a higher baseline exhaled Cl- and a resulting increase in pulmonary function when compared to the overactive TT groupCF patients with the TT αENaC genotype are likely candidates for early identification and treatment with inhaled ENaC inhibitors or other modulators of this pathway in order to improve survival.

sodium ions (Na+)

chloride ions (Cl-)

epithelial sodium channel (ENaC)

genetic

pulmonary

cystic fibrosis

Gene transfer vector development to treat lung disease : the use of a dual-function lentiviral vector containing ENaC RNAi and the CFTR gene to treat Cystic Fibrosis lung disease

Harding-Smith, Rebekka

January 2014

Cystic Fibrosis (CF) is a degenerative disorder that is often associated with chronic lung disease. CF is caused by mutations in the gene encoding the Cystic Fibrosis Transmembrane Conductance Regulator (CFTR) chloride channel, which lead to defective chloride and sodium ion movement across epithelia. Subsequent dehydration of the airway surface liquid (ASL) on airway epithelia, is associated with poor mucociliary clearance and chronic lung infection. The monogenic nature of CF, along with the accessibility of the lung, makes the disease amenable to gene replacement therapy. Gene therapy clinical trials have focused on replacing the mutated CFTR with a functional copy, which has led to improved chloride transport, but has shown no significant effects on sodium transport. An alternative strategy for CF gene therapy therefore, could be to reduce the expression of the epithelial sodium channel (ENaC) in the lung, using RNA interference (RNAi), combined with CFTR delivery. Developing a dual-function gene transfer vector could potentially restore chloride and sodium levels in the ASL and help alleviate CF lung disease. The aim of this thesis was to develop a recombinant lentivirus delivery system capable of simultaneously delivering CFTR expression and knocking down ENaC expression in the airways. A modular HIV vector genome plasmid was developed to allow simple insertion of various promoter elements, transgenes and knockdown sequences, for subsequent virus production. Insertion of the CFTR transgene and a short-hairpin RNA (shRNA) sequence targeting the ENaC alpha subunit (ENaC&alpha;) resulted in significant knockdown of human ENaC&alpha; and simultaneous expression of CFTR in A549 (human lung carcinoma) cell culture. Replacement of the ENaC&alpha; shRNA with an shRNA targeting the transcription factor BACH1 resulted in target gene knockdown and concomitant HMOX1 up-regulation, confirming specific knockdown effects, and demonstrating that the dual-function rLV vector could mediate target gene knockdown irrespective of the target. Attempts were made to knock down BACH1 in primary cultures of human bronchial epithelial cells grown at the air-liquid interface (ALI), but improved transduction efficiencies from the apical surface will be required to generate successful knockdown in this experimental model. These studies provide proof-of-principle for the utility of this versatile dual-function prototype virus. The dual function vector not only has the potential for treatment of CF lung disease, but could be readily altered to target other lung diseases where combinations of prolonged target gene knockdown and gene expression/up-regulation could collectively provide an appropriate therapy. In conclusion, the focus on the rational design of gene transfer vectors for specific therapeutic effects will aid the development and translation of gene therapy approaches to human studies.