Your search keyword '"Ruben PC"' showing total 89 results

1. SCN5A mutations in 442 neonates and children: genotype-phenotype correlation and identification of higher-risk subgroups.

Author

Baruteau, A, Kyndt, F, Behr, E, Vink, A, Lachaud, M, Joong, A, Schott, J, Horie, M, Denjoy, I, Crotti, L, Shimizu, W, Bos, J, Stephenson, E, Wong, L, Abrams, D, Davis, A, Winbo, A, Dubin, A, Sanatani, S, Liberman, L, Kaski, J, Rudic, B, Kwok, S, Rieubland, C, Tfelt-Hansen, J, Van Hare, G, Guyomarc'h-Delasalle, B, Blom, N, Wijeyeratne, Y, Gourraud, J, Le Marec, H, Ozawa, J, Fressart, V, Lupoglazoff, J, Dagradi, F, Spazzolini, C, Aiba, T, Tester, D, Zahavich, L, Beauséjour-Ladouceur, V, Jadhav, M, Skinner, J, Franciosi, S, Krahn, A, Abdelsayed, M, Ruben, P, Yung, T, Ackerman, M, Wilde, A, Schwartz, P, Probst, V, Baruteau, AE, Behr, ER, Vink, AS, Schott, JJ, Bos, JM, Stephenson, EA, Abrams, DJ, Davis, AM, Dubin, AM, Kaski, JP, Kwok, SY, Van Hare, GF, Blom, NA, Wijeyeratne, YD, Gourraud, JB, Lupoglazoff, JM, Tester, DJ, Zahavich, LA, Skinner, JR, Krahn, AD, Ruben, PC, Yung, TC, Ackerman, MJ, Wilde, AA, Schwartz, PJ, Probst, V., Baruteau, A, Kyndt, F, Behr, E, Vink, A, Lachaud, M, Joong, A, Schott, J, Horie, M, Denjoy, I, Crotti, L, Shimizu, W, Bos, J, Stephenson, E, Wong, L, Abrams, D, Davis, A, Winbo, A, Dubin, A, Sanatani, S, Liberman, L, Kaski, J, Rudic, B, Kwok, S, Rieubland, C, Tfelt-Hansen, J, Van Hare, G, Guyomarc'h-Delasalle, B, Blom, N, Wijeyeratne, Y, Gourraud, J, Le Marec, H, Ozawa, J, Fressart, V, Lupoglazoff, J, Dagradi, F, Spazzolini, C, Aiba, T, Tester, D, Zahavich, L, Beauséjour-Ladouceur, V, Jadhav, M, Skinner, J, Franciosi, S, Krahn, A, Abdelsayed, M, Ruben, P, Yung, T, Ackerman, M, Wilde, A, Schwartz, P, Probst, V, Baruteau, AE, Behr, ER, Vink, AS, Schott, JJ, Bos, JM, Stephenson, EA, Abrams, DJ, Davis, AM, Dubin, AM, Kaski, JP, Kwok, SY, Van Hare, GF, Blom, NA, Wijeyeratne, YD, Gourraud, JB, Lupoglazoff, JM, Tester, DJ, Zahavich, LA, Skinner, JR, Krahn, AD, Ruben, PC, Yung, TC, Ackerman, MJ, Wilde, AA, Schwartz, PJ, and Probst, V.

Abstract

Aims: To clarify the clinical characteristics and outcomes of children with SCN5A-mediated disease and to improve theirrisk stratification. Methods and results: A multicentre, international, retrospective cohort study was conducted in 25 tertiary hospitals in 13 countries between1990 and 2015. All patients <_16 years of age diagnosed with a genetically confirmed SCN5A mutation wereincluded in the analysis. There was no restriction made based on their clinical diagnosis. A total of 442 children{55.7% boys, 40.3% probands, median age: 8.0 [interquartile range (IQR) 9.5] years} from 350 families wereincluded; 67.9% were asymptomatic at diagnosis. Four main phenotypes were identified: isolated progressive cardiacconduction disorders (25.6%), overlap phenotype (15.6%), isolated long QT syndrome type 3 (10.6%), and isolatedBrugada syndrome type 1 (1.8%); 44.3% had a negative electrocardiogram phenotype. During a medianfollow-up of 5.9 (IQR 5.9) years, 272 cardiac events (CEs) occurred in 139 (31.5%) patients. Patients whose mutationlocalized in the C-terminus had a lower risk. Compound genotype, both gain- and loss-of-function SCN5A mutation,age <_1 year at diagnosis in probands and age <_1 year at diagnosis in non-probands were independent predictorsof CE.Conclusion In this large paediatric cohort of SCN5A mutation-positive subjects, cardiac conduction disorders were the mostprevalent phenotype; CEs occurred in about one-third of genotype-positive children, and several independent riskfactors were identified, including age <_1 year at diagnosis, compound mutation, and mutation with both gain- andloss-of-function.

Published

2018

2. Effects of the antianginal drug, ranolazine, on the brain sodium channel NaV1.2 and its modulation by extracellular protons

Author

Peters, CH, primary, Sokolov, S, additional, Rajamani, S, additional, and Ruben, PC, additional

Published

2013

3. Effects of the antianginal drug, ranolazine, on the brain sodium channel NaV1.2 and its modulation by extracellular protons.

Author

Peters, CH, Sokolov, S, Rajamani, S, and Ruben, PC

Subjects

SODIUM channels, BRAIN physiology, ANGINA pectoris treatment, ANTICONVULSANTS, DRUG efficacy, ISCHEMIA, PATCH-clamp techniques (Electrophysiology)

Abstract

Background and Purpose Ranolazine is an antianginal drug currently approved for treatment of angina pectoris in the United States. Recent studies have focused on its effects on neuronal channels and its possible therapeutic uses in the nervous system. We characterized how ranolazine affects the brain sodium channel, NaV1.2, and how its actions are modulated by low pH. In this way, we further explore ranolazine's potential as an anticonvulsant and its efficacy in conditions like those during an ischaemic stroke. Experimental Approach We performed whole-cell patch-clamp experiments on the voltage-gated sodium channel, NaV1.2. Experiments were performed with extracellular solution titrated to either pH 7.4 or pH 6.0 before and after ranolazine perfusion. Key Results Ranolazine accelerates onset and slows recovery of fast and slow inactivation. Ranolazine increases the maximum probability of use-dependent inactivation and reduces macroscopic and ramp sodium currents at pH 7.4. pH 6.0 reduced the slowing of fast inactivation recovery and inhibited use-dependent block by ranolazine. In the presence of ranolazine, the time constants of slow inactivation recovery and onset were significantly increased at pH 6.0 relative to pH 7.4 with 100 μM ranolazine. Conclusions and Implications Our work provides novel insights into the modulation of brain sodium channel, NaV1.2, by ranolazine. We demonstrate that ranolazine binds NaV1.2 in a state-dependent manner, and that the effects of ranolazine are slowed but not abolished by protons. Our results suggest that further research performed on channels with epilepsy-causing mutations may prove ranolazine to be an efficacious therapy. [ABSTRACT FROM AUTHOR]

Published

2013

4. Structural basis for the rescue of hyperexcitable cells by the amyotrophic lateral sclerosis drug Riluzole.

Author

Hollingworth D, Thomas F, Page DA, Fouda MA, De Castro RL, Sula A, Mykhaylyk VB, Kelly G, Ulmschneider MB, Ruben PC, and Wallace BA

Subjects

Humans, Voltage-Gated Sodium Channels metabolism, Voltage-Gated Sodium Channels chemistry, HEK293 Cells, Animals, Sodium metabolism, Motor Neurons drug effects, Motor Neurons metabolism, Riluzole pharmacology, Amyotrophic Lateral Sclerosis drug therapy, Amyotrophic Lateral Sclerosis metabolism, Amyotrophic Lateral Sclerosis genetics, Neuroprotective Agents pharmacology

Abstract

Neuronal hyperexcitability is a key element of many neurodegenerative disorders including the motor neuron disease Amyotrophic Lateral Sclerosis (ALS), where it occurs associated with elevated late sodium current (I NaL ). I NaL results from incomplete inactivation of voltage-gated sodium channels (VGSCs) after their opening and shapes physiological membrane excitability. However, dysfunctional increases can cause hyperexcitability-associated diseases. Here we reveal the atypical binding mechanism which explains how the neuroprotective ALS-treatment drug riluzole stabilises VGSCs in their inactivated state to cause the suppression of I NaL that leads to reversed cellular overexcitability. Riluzole accumulates in the membrane and enters VGSCs through openings to their membrane-accessible fenestrations. Riluzole binds within these fenestrations to stabilise the inactivated channel state, allowing for the selective allosteric inhibition of I NaL without the physical block of Na + conduction associated with traditional channel pore binding VGSC drugs. We further demonstrate that riluzole can reproduce these effects on a disease variant of the non-neuronal VGSC isoform Nav1.4, where pathologically increased I NaL is caused directly by mutation. Overall, we identify a model for VGSC inhibition that produces effects consistent with the inhibitory action of riluzole observed in models of ALS. Our findings will aid future drug design and supports research directed towards riluzole repurposing., (© 2024. The Author(s).)

Published

2024

5. Cannabidiol potentiates hyperpolarization-activated cyclic nucleotide-gated (HCN4) channels.

Author

Page DA and Ruben PC

Subjects

Humans, HEK293 Cells, Potassium Channels metabolism, Potassium Channels drug effects, Ion Channel Gating drug effects, Cannabidiol pharmacology, Hyperpolarization-Activated Cyclic Nucleotide-Gated Channels metabolism, Hyperpolarization-Activated Cyclic Nucleotide-Gated Channels genetics, Muscle Proteins

Abstract

Cannabidiol (CBD), the main non-psychotropic phytocannabinoid produced by the Cannabis sativa plant, blocks a variety of cardiac ion channels. We aimed to identify whether CBD regulated the cardiac pacemaker channel or the hyperpolarization-activated cyclic nucleotide-gated channel (HCN4). HCN4 channels are important for the generation of the action potential in the sinoatrial node of the heart and increased heart rate in response to β-adrenergic stimulation. HCN4 channels were expressed in HEK 293T cells, and the effect of CBD application was examined using a whole-cell patch clamp. We found that CBD depolarized the V1/2 of activation in holo-HCN4 channels, with an EC50 of 1.6 µM, without changing the current density. CBD also sped activation kinetics by approximately threefold. CBD potentiation of HCN4 channels occurred via binding to the closed state of the channel. We found that CBD's mechanism of action was distinct from cAMP, as CBD also potentiated apo-HCN4 channels. The addition of an exogenous PIP2 analog did not alter the ability of CBD to potentiate HCN4 channels, suggesting that CBD also acts using a unique mechanism from the known HCN4 potentiator PIP2. Lastly, to gain insight into CBD's mechanism of action, computational modeling and targeted mutagenesis were used to predict that CBD binds to a lipid-binding pocket at the C-terminus of the voltage sensor. CBD represents the first FDA-approved drug to potentiate HCN4 channels, and our findings suggest a novel starting point for drug development targeting HCN4 channels., (© 2024 Page and Ruben.)

Published

2024

6. Molecular Pharmacology of Selective Na V 1.6 and Dual Na V 1.6/Na V 1.2 Channel Inhibitors that Suppress Excitatory Neuronal Activity Ex Vivo.

Author

Goodchild SJ, Shuart NG, Williams AD, Ye W, Parrish RR, Soriano M, Thouta S, Mezeyova J, Waldbrook M, Dean R, Focken T, Ghovanloo MR, Ruben PC, Scott F, Cohen CJ, Empfield J, and Johnson JP

Subjects

Humans, Neurons metabolism, Brain metabolism, Seizures drug therapy, Seizures metabolism, Action Potentials physiology, Voltage-Gated Sodium Channels metabolism, Epilepsy metabolism

Abstract

Voltage-gated sodium channel (Na V ) inhibitors are used to treat neurological disorders of hyperexcitability such as epilepsy. These drugs act by attenuating neuronal action potential firing to reduce excitability in the brain. However, all currently available Na V -targeting antiseizure medications nonselectively inhibit the brain channels Na V 1.1, Na V 1.2, and Na V 1.6, which potentially limits the efficacy and therapeutic safety margins of these drugs. Here, we report on XPC-7724 and XPC-5462, which represent a new class of small molecule Na V -targeting compounds. These compounds specifically target inhibition of the Na V 1.6 and Na V 1.2 channels, which are abundantly expressed in excitatory pyramidal neurons. They have a > 100-fold molecular selectivity against Na V 1.1 channels, which are predominantly expressed in inhibitory neurons. Sparing Na V 1.1 preserves the inhibitory activity in the brain. These compounds bind to and stabilize the inactivated state of the channels thereby reducing the activity of excitatory neurons. They have higher potency, with longer residency times and slower off-rates, than the clinically used antiseizure medications carbamazepine and phenytoin. The neuronal selectivity of these compounds is demonstrated in brain slices by inhibition of firing in cortical excitatory pyramidal neurons, without impacting fast spiking inhibitory interneurons. XPC-5462 also suppresses epileptiform activity in an ex vivo brain slice seizure model, whereas XPC-7224 does not, suggesting a possible requirement of Nav1.2 inhibition in 0-Mg 2+ - or 4-AP-induced brain slice seizure models. The profiles of these compounds will facilitate pharmacological dissection of the physiological roles of Na V 1.2 and Na V 1.6 in neurons and help define the role of specific channels in disease states. This unique selectivity profile provides a new approach to potentially treat disorders of neuronal hyperexcitability by selectively downregulating excitatory circuits.

Published

2024

7. Multifocal Ectopic Purkinje Premature Contractions due to neutralization of an SCN5A negative charge: structural insights into the gating pore hypothesis.

Author

Glazer AM, Yang T, Li B, Page D, Fouda M, Wada Y, Lancaster MC, O'Neill MJ, Muhammad A, Gao X, Ackerman MJ, Sanatani S, Ruben PC, and Roden DM

Abstract

Background: We identified a novel SCN5A variant, E171Q, in a neonate with very frequent ectopy and reduced ejection fraction which normalized after arrhythmia suppression by flecainide. This clinical picture is consistent with multifocal ectopic Purkinje-related premature contractions (MEPPC). Most previous reports of MEPPC have implicated SCN5A variants such as R222Q that neutralize positive charges in the S4 voltage sensor helix of the channel protein Na V 1.5 and generate a gating pore current., Methods and Results: E171 is a highly conserved negatively-charged residue located in the S2 transmembrane helix of Na V 1.5 domain I. E171 is a key component of the Gating Charge Transfer Center, a region thought to be critical for normal movement of the S4 voltage sensor helix. We used heterologous expression, CRISPR-edited induced pluripotent stem cell-derived cardiomyocytes (iPSC-CMs), and molecular dynamics simulations to demonstrate that E171Q generates a gating pore current, which was suppressed by a low concentration of flecainide (IC50 = 0.71±0.07 µM). R222Q shifts voltage dependence of activation and inactivation in a negative direction but we observed positive shifts with E171Q. E171Q iPSC-CMs demonstrated abnormal spontaneous activity and prolonged action potentials. Molecular dynamics simulations revealed that both R222Q and E171Q proteins generate a water-filled permeation pathway that underlies generation of the gating pore current., Conclusion: Previously identified MEPPC-associated variants that create gating pore currents are located in positively-charged residues in the S4 voltage sensor and generate negative shifts in the voltage dependence of activation and inactivation. We demonstrate that neutralizing a negatively charged S2 helix residue in the Gating Charge Transfer Center generates positive shifts but also create a gating pore pathway. These findings implicate the gating pore pathway as the primary functional and structural determinant of MEPPC and widen the spectrum of variants that are associated with gating pore-related disease in voltage-gated ion channels.

Published

2024

8. Editorial: Cannabinoid interactions with ion channels, receptors, and the bio-membrane.

Author

Ghovanloo MR, Arnold JC, and Ruben PC

Abstract

Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.

Published

2023

9. Mechanisms underlying the antiarrhythmic effect of ARumenamide-787 in experimental models of the J wave syndromes and hypothermia.

Author

Di Diego JM, Barajas-Martinez H, Cox R, Robinson VM, Jung J, Fouda M, Patocskai B, Abdelsayed M, Ruben PC, and Antzelevitch C

Subjects

Humans, Animals, Dogs, HEK293 Cells, Syndrome, Anti-Arrhythmia Agents pharmacology, Anti-Arrhythmia Agents therapeutic use, Arrhythmias, Cardiac drug therapy, Myocytes, Cardiac, Hypothermia

Abstract

Background: Brugada (BrS) and early repolarization syndromes (ERS), the so-called J wave syndromes (JWS), are associated with life-threatening ventricular arrhythmias. Pharmacologic approaches to therapy are currently limited. In this study, we examine the effects of ARumenamide-787 (AR-787) to suppress the electrocardiographic and arrhythmic manifestations of JWS and hypothermia., Methods: We studied the effects of AR-787 on INa and IKr in HEK-293 cells stably expressing the α- and β1-subunits of the cardiac (NaV1.5) sodium channel and hERG channel, respectively. In addition, we studied its effect on Ito, INa and ICa in dissociated canine ventricular myocytes along with action potentials and ECG from coronary-perfused right (RV) and left (LV) ventricular wedge preparations. The Ito agonist, NS5806 (5-10 μM), ICa blocker, verapamil (2.5 μM), and INa blocker, ajmaline (2.5 μM), were used to mimic the genetic defects associated with JWS and to induce the electrocardiographic and arrhythmic manifestations of JWS (prominent J waves/ST segment elevation, phase 2 reentry and polymorphic VT/VF) in canine ventricular wedge preparations., Results: AR-787 (1, 10 and 50 μM) exerted pleiotropic effects on cardiac ion channels. The predominant effect was inhibition of the transient outward current (Ito) and enhancement of the sodium channel current (INa), with lesser effects to inhibit IKr and augment calcium channel current (ICa). AR-787 diminished the electrocardiographic J wave and prevented and/or suppressed all arrhythmic activity in canine RV and LV experimental models of BrS, ERS and hypothermia., Conclusions: Our findings point to AR-787 as promising candidate for the pharmacologic treatment of JWS and hypothermia., Competing Interests: I have read the journal’s policy and the authors of this manuscript have the following competing interests: Dr. Antzelevitch has served as a consultant for Trevena Pharmaceutical Inc. and has received research funding from Trevena Pharmaceutical, In Carda Pharmaceutical and Kymera Pharmaceutical. The other co-authors have nothing to declare. This does not alter our adherence to PLOS ONE policies on sharing data and materials., (Copyright: © 2023 Di Diego et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.)

Published

2023

10. Anti-inflammatory effects of cannabidiol against lipopolysaccharides in cardiac sodium channels.

Author

Fouda MA, Fathy Mohamed Y, Fernandez R, and Ruben PC

Subjects

Humans, Anti-Inflammatory Agents pharmacology, Cytokines metabolism, Inflammation, Interleukin-6, Lipopolysaccharides pharmacology, Toll-Like Receptor 4 metabolism, Tumor Necrosis Factor-alpha, Cannabidiol pharmacology, Sepsis, Sodium Channels

Abstract

Background: Sepsis, caused by a dysregulated response to infections, can lead to cardiac arrhythmias. However, the mechanisms underlying sepsis-induced inflammation, and how inflammation provokes cardiac arrhythmias, are not well understood. We hypothesized that cannabidiol (CBD) may ameliorate lipopolysaccharide (LPS)-induced cardiotoxicity, via Toll-like receptors (TLR4) and cardiac sodium channels (Na V 1.5)., Methods and Results: We incubated human immune cells (THP-1 macrophages) with LPS for 24 h, then extracted the THP-1 incubation media. ELISA assays showed that LPS (1 or 5 μg·ml -1 ), in a concentration-dependent manner, or MPLA (TLR4 agonist, 5 μg·ml -1 ) stimulated the THP-1 cells to release inflammatory cytokines (TNF-α and IL-6). Prior incubation (4 h) with CBD (5 μM) or C34 (TLR4 antagonist: 5 μg·ml -1 ) inhibited LPS and MPLA-induced release of both IL-6 and TNF-α. Human-induced pluripotent stem cell-derived cardiomyocytes (hiPSC-CM) were subsequently incubated for 24 h in the media extracted from THP-1 cells incubated with LPS, MPLA alone, or in combination with CBD or C34. Voltage-clamp experiments showed a right shift in the voltage dependence of Na V 1.5 activation, steady state fast inactivation (SSFI), increased persistent current and prolonged in silico action potential duration in hiSPC-CMs incubated in the LPS or MPLA-THP-1 media. Co-incubation with CBD or C34 rescued the biophysical dysfunction caused by LPS and MPLA., Conclusion: Our results suggest that CBD may protect against sepsis-induced inflammation and subsequent arrhythmias through (i) inhibition of the release of inflammatory cytokines, antioxidant and anti-apoptotic effects and/or (ii) a direct effect on Na V 1.5., (© 2022 British Pharmacological Society.)

Published

2022

11. Non-psychotropic phytocannabinoid interactions with voltage-gated sodium channels: An update on cannabidiol and cannabigerol.

Author

Ghovanloo MR, Dib-Hajj SD, Goodchild SJ, Ruben PC, and Waxman SG

Abstract

Phytocannabinoids, found in the plant, Cannabis sativa , are an important class of natural compounds with physiological effects. These compounds can be generally divided into two classes: psychoactive and non-psychoactive. Those which do not impart psychoactivity are assumed to predominantly function via endocannabinoid receptor (CB) -independent pathways and molecular targets, including other receptors and ion channels. Among these targets, the voltage-gated sodium (Nav) channels are particularly interesting due to their well-established role in electrical signalling in the nervous system. The interactions between the main non-psychoactive phytocannabinoid, cannabidiol (CBD), and Nav channels were studied in detail. In addition to CBD, cannabigerol (CBG), is another non-psychoactive molecule implicated as a potential therapeutic for several conditions, including pain via interactions with Nav channels. In this mini review, we provide an update on the interactions of Nav channels with CBD and CBG., Competing Interests: SG is an employee of Xenon Pharmaceuticals Inc. No funders were involved in the study design, collection, analysis, interpretation of data, the writing of this article or the decision to submit it for publication. The remaining authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2022 Ghovanloo, Dib-Hajj, Goodchild, Ruben and Waxman.)

Published

2022

12. ARumenamides : A novel class of potential antiarrhythmic compounds.

Author

Abdelsayed M, Page D, and Ruben PC

Abstract

Background: Most therapeutics targeting cardiac voltage-gated sodium channels (Nav1.5) attenuate the sodium current (I Na ) conducted through the pore of the protein. Whereas these drugs may be beneficial for disease states associated with gain-of-function (GoF) in Nav1.5, few attempts have been made to therapeutically treat loss-of-function (LoF) conditions. The primary impediment to designing efficacious therapies for LoF is a tendency for drugs to occlude the Nav1.5 central pore. We hypothesized that molecular candidates with a high affinity for the fenestrations would potentially reduce pore block. Methods and Results: Virtual docking was performed on 21 compounds, selected based on their affinity for the fenestrations in Nav1.5, which included a class of sulfonamides and carboxamides we identify as ARumenamide (AR) . Six ARs , AR-051, AR-189, AR-674, AR-802, AR-807 and AR-811, were further docked against Nav1.5 built on NavAb and rNav1.5. Based on the virtual docking results, these particular AR s have a high affinity for Domain III-IV and Domain VI-I fenestrations. Upon functional characterization, a trend was observed in the effects of the six ARs on I Na . An inverse correlation was established between the aromaticity of the AR 's functional moieties and compound block. Due to its aromaticity, AR-811 blocked I Na the least compared with other aromatic ARs , which also decelerated fast inactivation onset. AR-674, with its aliphatic functional group, significantly suppresses I Na and enhances use-dependence in Nav1.5. AR-802 and AR-811, in particular, decelerated fast inactivation kinetics in the most common Brugada Syndrome Type 1 and Long-QT Syndrome Type 3 mutant, E1784K, without affecting peak or persistent I Na . Conclusion: Our hypothesis that LoF in Nav1.5 may be therapeutically treated was supported by the discovery of ARs , which appear to preferentially block the fenestrations. ARs with aromatic functional groups as opposed to aliphatic groups efficaciously maintained Nav1.5 availability. We predict that these bulkier side groups may have a higher affinity for the hydrophobic milieu of the fenestrations, remaining there rather than in the central pore of the channel. Future refinements of AR compound structures and additional validation by molecular dynamic simulations and screening against more Brugada variants will further support their potential benefits in treating certain LoF cardiac arrhythmias., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2022 Abdelsayed, Page and Ruben.)

Published

2022

13. Cannabidiol increases gramicidin current in human embryonic kidney cells: An observational study.

Author

Ghovanloo MR, Goodchild SJ, and Ruben PC

Subjects

Anti-Bacterial Agents therapeutic use, Gramicidin pharmacology, Humans, Kidney metabolism, Cannabidiol therapeutic use, Cannabis metabolism

Abstract

Gramicidin is a monomeric protein that is thought to non-selectively conduct cationic currents and water. Linear gramicidin is considered an antibiotic. This function is considered to be mediated by the formation of pores within the lipid membrane, thereby killing bacterial cells. The main non-psychoactive active constituent of the cannabis plant, cannabidiol (CBD), has recently gained interest, and is proposed to possess various potential therapeutic properties, including being an antibiotic. We previously determined that CBD's activity on ion channels could be, in part, mediated by altering membrane biophysical properties, including elasticity. In this study, our goal was to determine the empirical effects of CBD on gramicidin currents in human embryonic kidney (HEK) cells, seeking to infer potential direct compound-protein interactions. Our results indicate that gramicidin, when applied to the extracellular HEK cell membrane, followed by CBD perfusion, increases the gramicidin current., Competing Interests: The authors have declared that no competing interests exist.

Published

2022

14. Cannabidiol and Sodium Channel Pharmacology: General Overview, Mechanism, and Clinical Implications.

Author

Ghovanloo MR and Ruben PC

Subjects

Action Potentials, Humans, Cannabidiol pharmacology, Cannabidiol therapeutic use, Epilepsy drug therapy, Voltage-Gated Sodium Channels

Abstract

Voltage-gated sodium (Nav) channels initiate action potentials in excitable tissues. Altering these channels' function can lead to many pathophysiological conditions. Nav channels are composed of several functional and structural domains that could be targeted pharmacologically as potential therapeutic means against various neurological conditions. Mutations in Nav channels have been suggested to underlie various clinical syndromes in different tissues and in association with conditions ranging from epileptic to muscular problems. Treating those mutations that increase the excitability of Nav channels requires inhibitors that could effectively reduce channel firing. The main non-psychotropic constituent of the cannabis plant, cannabidiol (CBD), has recently gained interest as a viable compound to treat some of the conditions that are associated with Nav malfunctions. In this review, we discuss an overview of Nav channels followed by an in-depth description of the interactions of CBD and Nav channels. We conclude with some clinical implications of CBD use against Nav hyperexcitability based on a series of preclinical studies published to date, with a focus on Nav/CBD interactions.

Published

2022

15. Late sodium current: incomplete inactivation triggers seizures, myotonias, arrhythmias, and pain syndromes.

Author

Fouda MA, Ghovanloo MR, and Ruben PC

Subjects

Arrhythmias, Cardiac, Humans, Pain, Sodium metabolism, Syndrome, Myotonia metabolism

Abstract

Acquired and inherited dysfunction in voltage-gated sodium channels underlies a wide range of diseases. In addition to defects in trafficking and expression, sodium channelopathies are caused by dysfunction in one or several gating properties, for instance activation or inactivation. Disruption of channel inactivation leads to increased late sodium current, which is a common defect in seizure disorders, cardiac arrhythmias skeletal muscle myotonia and pain. An increase in late sodium current leads to repetitive action potentials in neurons and skeletal muscles, and prolonged action potential duration in the heart. In this Topical Review, we compare the effects of late sodium current in brain, heart, skeletal muscle and peripheral nerves., (© 2022 The Authors. The Journal of Physiology © 2022 The Physiological Society.)

Published

2022

16. The L1624Q Variant in SCN1A Causes Familial Epilepsy Through a Mixed Gain and Loss of Channel Function.

Author

Jones LB, Peters CH, Rosch RE, Owers M, Hughes E, Pal DK, and Ruben PC

Abstract

Variants of the SCN1A gene encoding the neuronal voltage-gated sodium channel Na V 1.1 cause over 85% of all cases of Dravet syndrome, a severe and often pharmacoresistent epileptic encephalopathy with mostly infantile onset. But with the increased availability of genetic testing for patients with epilepsy, variants in SCN1A have now also been described in a range of other epilepsy phenotypes. The vast majority of these epilepsy-associated variants are de novo , and most are either nonsense variants that truncate the channel or missense variants that are presumed to cause loss of channel function. However, biophysical analysis has revealed a significant subset of missense mutations that result in increased excitability, further complicating approaches to precision pharmacotherapy for patients with SCN1A variants and epilepsy. We describe clinical and biophysical data of a familial SCN1A variant encoding the Na V 1.1 L1624Q mutant. This substitution is located on the extracellular linker between S3 and S4 of Domain IV of Na V 1.1 and is a rare case of a familial SCN1A variant causing an autosomal dominant frontal lobe epilepsy. We expressed wild-type (WT) and L1642Q channels in CHO cells. Using patch-clamp to characterize channel properties at several temperatures, we show that the L1624Q variant increases persistent current, accelerates fast inactivation onset and decreases current density. While SCN1A -associated epilepsy is typically considered a loss-of-function disease, our results put L1624Q into a growing set of mixed gain and loss-of-function variants in SCN1A responsible for epilepsy., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2021 Jones, Peters, Rosch, Owers, Hughes, Pal and Ruben.)

Published

2021

17. Persistent sodium currents in SCN1A developmental and degenerative epileptic dyskinetic encephalopathy.

Author

Gorman KM, Peters CH, Lynch B, Jones L, Bassett DS, King MD, Ruben PC, and Rosch RE

Abstract

Pathogenic variants in the voltage-gated sodium channel gene ( SCN1A ) are amongst the most common genetic causes of childhood epilepsies. There is considerable heterogeneity in both the types of causative variants and associated phenotypes; a recent expansion of the phenotypic spectrum of SCN1A associated epilepsies now includes an early onset severe developmental and epileptic encephalopathy with regression and a hyperkinetic movement disorder. Herein, we report a female with a developmental and degenerative epileptic-dyskinetic encephalopathy, distinct and more severe than classic Dravet syndrome. Clinical diagnostics indicated a paternally inherited c.5053G>T; p. A1685S variant of uncertain significance in SCN1A . Whole-exome sequencing detected a second de novo mosaic (18%) c.2345G>A; p. T782I likely pathogenic variant in SCN1A (maternal allele). Biophysical characterization of both mutant channels in a heterologous expression system identified gain-of-function effects in both, with a milder shift in fast inactivation of the p. A1685S channels; and a more severe persistent sodium current in the p. T782I. Using computational models, we show that large persistent sodium currents induce hyper-excitability in individual cortical neurons, thus relating the severe phenotype to the empirically quantified sodium channel dysfunction. These findings further broaden the phenotypic spectrum of SCN1A associated epilepsies and highlight the importance of testing for mosaicism in epileptic encephalopathies. Detailed biophysical evaluation and computational modelling further highlight the role of gain-of-function variants in the pathophysiology of the most severe phenotypes associated with SCN1A ., (© The Author(s) (2021). Published by Oxford University Press on behalf of the Guarantors of Brain.)

Published

2021

18. Cannabidiol inhibits the skeletal muscle Nav1.4 by blocking its pore and by altering membrane elasticity.

Author

Ghovanloo MR, Choudhury K, Bandaru TS, Fouda MA, Rayani K, Rusinova R, Phaterpekar T, Nelkenbrecher K, Watkins AR, Poburko D, Thewalt J, Andersen OS, Delemotte L, Goodchild SJ, and Ruben PC

Subjects

Elasticity, Humans, Muscle, Skeletal, Cannabidiol pharmacology, Channelopathies, NAV1.4 Voltage-Gated Sodium Channel metabolism, Voltage-Gated Sodium Channels

Abstract

Cannabidiol (CBD) is the primary nonpsychotropic phytocannabinoid found in Cannabis sativa, which has been proposed to be therapeutic against many conditions, including muscle spasms. Among its putative targets are voltage-gated sodium channels (Navs), which have been implicated in many conditions. We investigated the effects of CBD on Nav1.4, the skeletal muscle Nav subtype. We explored direct effects, involving physical block of the Nav pore, as well as indirect effects, involving modulation of membrane elasticity that contributes to Nav inhibition. MD simulations revealed CBD's localization inside the membrane and effects on bilayer properties. Nuclear magnetic resonance (NMR) confirmed these results, showing CBD localizing below membrane headgroups. To determine the functional implications of these findings, we used a gramicidin-based fluorescence assay to show that CBD alters membrane elasticity or thickness, which could alter Nav function through bilayer-mediated regulation. Site-directed mutagenesis in the vicinity of the Nav1.4 pore revealed that removing the local anesthetic binding site with F1586A reduces the block of INa by CBD. Altering the fenestrations in the bilayer-spanning domain with Nav1.4-WWWW blocked CBD access from the membrane into the Nav1.4 pore (as judged by MD). The stabilization of inactivation, however, persisted in WWWW, which we ascribe to CBD-induced changes in membrane elasticity. To investigate the potential therapeutic value of CBD against Nav1.4 channelopathies, we used a pathogenic Nav1.4 variant, P1158S, which causes myotonia and periodic paralysis. CBD reduces excitability in both wild-type and the P1158S variant. Our in vitro and in silico results suggest that CBD may have therapeutic value against Nav1.4 hyperexcitability., (© 2021 Ghovanloo et al.)

Published

2021

19. Protein Kinases Mediate Anti-Inflammatory Effects of Cannabidiol and Estradiol Against High Glucose in Cardiac Sodium Channels.

Author

Fouda MA and Ruben PC

Abstract

Background: Cardiovascular anomalies are predisposing factors for diabetes-induced morbidity and mortality. Recently, we showed that high glucose induces changes in the biophysical properties of the cardiac voltage-gated sodium channel (Nav1.5) that could be strongly correlated to diabetes-induced arrhythmia. However, the mechanisms underlying hyperglycemia-induced inflammation, and how inflammation provokes cardiac arrhythmia, are not well understood. We hypothesized that inflammation could mediate the high glucose-induced biophyscial changes on Nav1.5 through protein phosphorylation by protein kinases A and C. We also hypothesized that this signaling pathway is, at least partly, involved in the cardiprotective effects of cannabidiol (CBD) and 17β-estradiol (E 2 ). Methods and Results: To test these ideas, we used Chinese hamster ovarian (CHO) cells transiently co-transfected with cDNA encoding human Nav1.5 α-subunit under control, a cocktail of inflammatory mediators or 100 mM glucose conditions (for 24 h). We used electrophysiological experiments and action potential modeling. Inflammatory mediators, similar to 100 mM glucose, right shifted the voltage dependence of conductance and steady-state fast inactivation and increased persistent current leading to computational prolongation of action potential (hyperexcitability) which could result in long QT3 arrhythmia. We also used human iCell cardiomyocytes derived from inducible pluripotent stem cells (iPSC-CMs) as a physiologically relevant system, and they replicated the effects produced by inflammatory mediators observed in CHO cells. In addition, activators of PK-A or PK-C replicated the inflammation-induced gating changes of Nav1.5. Inhibitors of PK-A or PK-C, CBD or E 2 mitigated all the potentially deleterious effects provoked by high glucose/inflammation. Conclusion: These findings suggest that PK-A and PK-C may mediate the anti-inflammatory effects of CBD and E 2 against high glucose-induced arrhythmia. CBD, via Nav1.5, may be a cardioprotective therapeutic approach in diabetic postmenopausal population., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2021 Fouda and Ruben.)

Published

2021

20. Biophysical Characterization of a Novel SCN5A Mutation Associated With an Atypical Phenotype of Atrial and Ventricular Arrhythmias and Sudden Death.

Author

Ghovanloo MR, Atallah J, Escudero CA, and Ruben PC

Abstract

Background: Sudden cardiac death (SCD) is an unexpected death that occurs within an hour of the onset of symptoms. Hereditary primary electrical disorders account for up to 1/3 of all SCD cases in younger individuals and include conditions such as catecholaminergic polymorphic ventricular tachycardia (CPVT). These disorders are caused by mutations in the genes encoding cardiac ion channels, hence they are known as cardiac channelopathies. We identified a novel variant, T1857I, in the C-terminus of Nav1.5 ( SCN5A ) linked to a family with a CPVT-like phenotype characterized by atrial tachy-arrhythmias and polymorphic ventricular ectopy occurring at rest and with adrenergic stimulation, and a strong family history of SCD., Objective: Our goal was to functionally characterize the novel Nav1.5 variant and determine a possible link between channel gating and clinical phenotype., Methods: We first used electrocardiogram recordings to visualize the patient cardiac electrical properties. Then, we performed voltage-clamp of transiently transfected CHO cells. Lastly, we used the ventricular/atrial models to visualize gating defects on cardiac excitability., Results: Voltage-dependences of both activation and inactivation were right-shifted, the overlap between activation and inactivation predicted increased window currents, the recovery from fast inactivation was slowed, there was no significant difference in late currents, and there was no difference in use-dependent inactivation. The O'Hara-Rudy model suggests ventricular after depolarizations and atrial Grandi-based model suggests a slight prolongation of atrial action potential duration., Conclusion: We conclude that T1857I likely causes a net gain-of-function in Nav1.5 gating, which may in turn lead to ventricular after depolarization, predisposing carriers to tachy-arrhythmias., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2020 Ghovanloo, Atallah, Escudero and Ruben.)

Published

2020

21. Cannabidiol interactions with voltage-gated sodium channels.

Author

Sait LG, Sula A, Ghovanloo MR, Hollingworth D, Ruben PC, and Wallace BA

Subjects

Binding Sites, Cannabidiol pharmacology, Crystallography, X-Ray, Electrophysiology, Protein Conformation, Sequence Alignment, Voltage-Gated Sodium Channels chemistry, Voltage-Gated Sodium Channels drug effects, Voltage-Gated Sodium Channels genetics, Cannabidiol metabolism, Voltage-Gated Sodium Channels metabolism

Abstract

Voltage-gated sodium channels are targets for a range of pharmaceutical drugs developed for the treatment of neurological diseases. Cannabidiol (CBD), the non-psychoactive compound isolated from cannabis plants, was recently approved for treatment of two types of epilepsy associated with sodium channel mutations. This study used high-resolution X-ray crystallography to demonstrate the detailed nature of the interactions between CBD and the NavMs voltage-gated sodium channel, and electrophysiology to show the functional effects of binding CBD to these channels. CBD binds at a novel site at the interface of the fenestrations and the central hydrophobic cavity of the channel. Binding at this site blocks the transmembrane-spanning sodium ion translocation pathway, providing a molecular mechanism for channel inhibition. Modelling studies suggest why the closely-related psychoactive compound tetrahydrocannabinol may not have the same effects on these channels. Finally, comparisons are made with the TRPV2 channel, also recently proposed as a target site for CBD. In summary, this study provides novel insight into a possible mechanism for CBD interactions with sodium channels., Competing Interests: LS, AS, MG, DH, PR, BW No competing interests declared, (© 2020, Sait et al.)

Published

2020

22. E1784K, the most common Brugada syndrome and long-QT syndrome type 3 mutant, disrupts sodium channel inactivation through two separate mechanisms.

Author

Peters CH, Watkins AR, Poirier OL, and Ruben PC

Subjects

Humans, Mutation, Brugada Syndrome genetics, Long QT Syndrome genetics, NAV1.5 Voltage-Gated Sodium Channel genetics

Abstract

Inheritable and de novo variants in the cardiac voltage-gated sodium channel, Nav1.5, are responsible for both long-QT syndrome type 3 (LQT3) and Brugada syndrome type 1 (BrS1). Interestingly, a subset of Nav1.5 variants can cause both LQT3 and BrS1. Many of these variants are found in channel structures that form the channel fast inactivation machinery, altering the rate, voltage dependence, and completeness of the fast inactivation process. We used a series of mutants at position 1784 to show that the most common inheritable Nav1.5 variant, E1784K, alters fast inactivation through two separable mechanisms: (1) a charge-dependent interaction that increases the noninactivating current characteristic of E1784K; and (2) a hyperpolarized voltage dependence and accelerated rate of fast inactivation that decreases the peak sodium current. Using a homology model built on the NavPaS structure, we find that the charge-dependent interaction is between E1784 and K1493 in the DIII-DIV linker of the channel, five residues downstream of the putative inactivation gate. This interaction can be disrupted by a positive charge at position 1784 and rescued with the K1493E/E1784K double mutant that abolishes the noninactivating current. However, the double mutant does not restore either the voltage dependence or rates of fast inactivation. Conversely, a mutant at the bottom of DIVS4, K1641D, causes a hyperpolarizing shift in the voltage dependence of fast inactivation and accelerates the rate of fast inactivation without causing an increase in noninactivating current. These findings provide novel mechanistic insights into how the most common inheritable arrhythmogenic mixed syndrome variant, E1784K, simultaneously decreases transient sodium currents and increases noninactivating currents, leading to both BrS1 and LQT3., (© 2020 Peters et al.)

Published

2020

23. Cannabidiol protects against high glucose-induced oxidative stress and cytotoxicity in cardiac voltage-gated sodium channels.

Author

Fouda MA, Ghovanloo MR, and Ruben PC

Subjects

Animals, Cricetinae, Cricetulus, Glucose toxicity, Humans, Oxidative Stress, Cannabidiol pharmacology, Voltage-Gated Sodium Channels

Abstract

Background and Purpose: Cardiovascular complications are the major cause of mortality in diabetic patients. However, the molecular mechanisms underlying diabetes-associated arrhythmias are unclear. We hypothesized that high glucose could adversely affect Na v 1.5, the major cardiac sodium channel isoform of the heart, at least partially via oxidative stress. We further hypothesized that cannabidiol (CBD), one of the main constituents of Cannabis sativa, through its effects on Na v 1.5, could protect against high glucose-elicited oxidative stress and cytotoxicity., Experimental Approach: To test these ideas, we used CHO cells transiently co-transfected with cDNA encoding human Na v 1.5 α-subunit under control and high glucose conditions (50 or 100 mM for 24 hr). Several experimental and computational techniques were used, including voltage clamp of heterologous expression systems, cell viability assays, fluorescence assays and action potential modelling., Key Results: High glucose evoked cell death associated with elevation in reactive oxygen species (ROS) right shifted the voltage dependence of conductance and steady-state fast inactivation, and increased persistent current leading to computational prolongation of action potential (hyperexcitability) which could result in long QT3 arrhythmia. CBD mitigated all the deleterious effects provoked by high glucose. Perfusion with lidocaine (a well-known sodium channel inhibitor with antioxidant effects) or co-incubation of Tempol (a well-known antioxidant) elicited protection, comparable to CBD, against the deleterious effects of high glucose., Conclusion and Implications: These findings suggest that, through its favourable antioxidant and sodium channel inhibitory effects, CBD may protect against high glucose-induced arrhythmia and cytotoxicity., (© 2020 The British Pharmacological Society.)

Published

2020

24. Say Cheese: Structure of the Cardiac Electrical Engine Is Captured.

Author

Ghovanloo MR and Ruben PC

Subjects

Animals, Mutation, Rats, Cheese, NAV1.5 Voltage-Gated Sodium Channel genetics

Abstract

Voltage-gated sodium channel (Nav)1.5 is the predominantly expressed sodium channel in the myocardium. Mutations in the gene encoding Nav1.5 are associated with several types of cardiac arrhythmias. In their recent study, Jiang et al. provide a detailed structure of the rat Nav1.5, with major implications regarding its physiology, pharmacology, and pathophysiology., (Copyright © 2020 Elsevier Ltd. All rights reserved.)

Published

2020

25. Case studies in neuroscience: a novel amino acid duplication in the NH 2 -terminus of the brain sodium channel Na V 1.1 underlying Dravet syndrome.

Author

Angus M, Peters CH, Poburko D, Brimble E, Spelbrink EM, and Ruben PC

Subjects

Epilepsies, Myoclonic physiopathology, Female, Humans, Immunohistochemistry, Infant, Neurosciences methods, Patch-Clamp Techniques, Epilepsies, Myoclonic genetics, NAV1.1 Voltage-Gated Sodium Channel genetics

Abstract

Dravet syndrome is a severe form of childhood epilepsy characterized by frequent temperature-sensitive seizures and delays in cognitive development. In the majority (80%) of cases, Dravet syndrome is caused by mutations in the SCN1A gene, encoding the voltage-gated sodium channel Na V 1.1, which is abundant in the central nervous system. Dravet syndrome can be caused by either gain-of-function mutation or loss of function in Na V 1.1, making it necessary to characterize each novel mutation. Here we use a combination of patch-clamp recordings and immunocytochemistry to characterize the first known NH 2 -terminal amino acid duplication mutation found in a patient with Dravet syndrome, M72dup. M72dup does not significantly alter rate of fast inactivation recovery or rate of fast inactivation onset at any measured membrane potential. M72dup significantly shifts the midpoint of the conductance voltage relationship to more hyperpolarized potentials. Most interestingly, M72dup significantly reduces peak current of Na V 1.1 and reduces membrane expression. This suggests that M72dup acts as a loss-of-function mutation primarily by impacting the ability of the channel to localize to the plasma membrane. NEW & NOTEWORTHY Genetic screening of a patient with Dravet syndrome revealed a novel mutation in SCN1A. Of over 700 SCN1A mutations known to cause Dravet syndrome, M72dup is the first to be identified in the NH 2 -terminus of Na V 1.1. We studied M72dup using patch-clamp electrophysiology and immunocytochemistry. M72dup causes a decrease in membrane expression of Na V 1.1 and overall loss of function, consistent with the role of the NH 2 -terminal region in membrane trafficking of Na V 1.1.

Published

2019

26. Inhibitory effects of cannabidiol on voltage-dependent sodium currents.

Author

Ghovanloo MR, Shuart NG, Mezeyova J, Dean RA, Ruben PC, and Goodchild SJ

Subjects

HEK293 Cells, Humans, NAV1.1 Voltage-Gated Sodium Channel genetics, NAV1.1 Voltage-Gated Sodium Channel metabolism, NAV1.6 Voltage-Gated Sodium Channel genetics, NAV1.6 Voltage-Gated Sodium Channel metabolism, Neurons drug effects, Neurons metabolism, Sodium metabolism, Voltage-Gated Sodium Channel beta-1 Subunit genetics, Voltage-Gated Sodium Channel beta-1 Subunit metabolism, Cannabidiol pharmacology, Gene Expression Regulation drug effects, NAV1.1 Voltage-Gated Sodium Channel chemistry, NAV1.6 Voltage-Gated Sodium Channel chemistry, Neurons pathology, Voltage-Gated Sodium Channel beta-1 Subunit chemistry

Abstract

Cannabis sativa contains many related compounds known as phytocannabinoids. The main psychoactive and nonpsychoactive compounds are Δ9-tetrahydrocannabinol (THC) and cannabidiol (CBD), respectively. Much of the evidence for clinical efficacy of CBD-mediated antiepileptic effects has been from case reports or smaller surveys. The mechanisms for CBD's anticonvulsant effects are unclear and likely involve noncannabinoid receptor pathways. CBD is reported to modulate several ion channels, including sodium channels (Nav). Evaluating the therapeutic mechanisms and safety of CBD demands a richer understanding of its interactions with central nervous system targets. Here, we used voltage-clamp electrophysiology of HEK-293 cells and iPSC neurons to characterize the effects of CBD on Nav channels. Our results show that CBD inhibits hNav1.1-1.7 currents, with an IC 50 of 1.9-3.8 μm, suggesting that this inhibition could occur at therapeutically relevant concentrations. A steep Hill slope of ∼3 suggested multiple interactions of CBD with Nav channels. CBD exhibited resting-state blockade, became more potent at depolarized potentials, and also slowed recovery from inactivation, supporting the idea that CBD binding preferentially stabilizes inactivated Nav channel states. We also found that CBD inhibits other voltage-dependent currents from diverse channels, including bacterial homomeric Nav channel (NaChBac) and voltage-gated potassium channel subunit Kv2.1. Lastly, the CBD block of Nav was temperature-dependent, with potency increasing at lower temperatures. We conclude that CBD's mode of action likely involves 1) compound partitioning in lipid membranes, which alters membrane fluidity affecting gating, and 2) undetermined direct interactions with sodium and potassium channels, whose combined effects are loss of channel excitability., (© 2018 Ghovanloo et al.)

Published

2018

27. SCN5A mutations in 442 neonates and children: genotype-phenotype correlation and identification of higher-risk subgroups.

Author

Baruteau AE, Kyndt F, Behr ER, Vink AS, Lachaud M, Joong A, Schott JJ, Horie M, Denjoy I, Crotti L, Shimizu W, Bos JM, Stephenson EA, Wong L, Abrams DJ, Davis AM, Winbo A, Dubin AM, Sanatani S, Liberman L, Kaski JP, Rudic B, Kwok SY, Rieubland C, Tfelt-Hansen J, Van Hare GF, Guyomarc'h-Delasalle B, Blom NA, Wijeyeratne YD, Gourraud JB, Le Marec H, Ozawa J, Fressart V, Lupoglazoff JM, Dagradi F, Spazzolini C, Aiba T, Tester DJ, Zahavich LA, Beauséjour-Ladouceur V, Jadhav M, Skinner JR, Franciosi S, Krahn AD, Abdelsayed M, Ruben PC, Yung TC, Ackerman MJ, Wilde AA, Schwartz PJ, and Probst V

Subjects

Age Factors, Asymptomatic Diseases, Brugada Syndrome genetics, Child, Child, Preschool, Electrocardiography, Female, Follow-Up Studies, Gain of Function Mutation, Humans, Infant, Infant, Newborn, Long QT Syndrome genetics, Loss of Function Mutation, Male, Retrospective Studies, Risk Factors, Cardiac Conduction System Disease genetics, Genetic Association Studies, NAV1.5 Voltage-Gated Sodium Channel genetics

Abstract

Aims: To clarify the clinical characteristics and outcomes of children with SCN5A-mediated disease and to improve their risk stratification., Methods and Results: A multicentre, international, retrospective cohort study was conducted in 25 tertiary hospitals in 13 countries between 1990 and 2015. All patients ≤16 years of age diagnosed with a genetically confirmed SCN5A mutation were included in the analysis. There was no restriction made based on their clinical diagnosis. A total of 442 children {55.7% boys, 40.3% probands, median age: 8.0 [interquartile range (IQR) 9.5] years} from 350 families were included; 67.9% were asymptomatic at diagnosis. Four main phenotypes were identified: isolated progressive cardiac conduction disorders (25.6%), overlap phenotype (15.6%), isolated long QT syndrome type 3 (10.6%), and isolated Brugada syndrome type 1 (1.8%); 44.3% had a negative electrocardiogram phenotype. During a median follow-up of 5.9 (IQR 5.9) years, 272 cardiac events (CEs) occurred in 139 (31.5%) patients. Patients whose mutation localized in the C-terminus had a lower risk. Compound genotype, both gain- and loss-of-function SCN5A mutation, age ≤1 year at diagnosis in probands and age ≤1 year at diagnosis in non-probands were independent predictors of CE., Conclusion: In this large paediatric cohort of SCN5A mutation-positive subjects, cardiac conduction disorders were the most prevalent phenotype; CEs occurred in about one-third of genotype-positive children, and several independent risk factors were identified, including age ≤1 year at diagnosis, compound mutation, and mutation with both gain- and loss-of-function.

Published

2018

28. A Mixed Periodic Paralysis & Myotonia Mutant, P1158S, Imparts pH-Sensitivity in Skeletal Muscle Voltage-gated Sodium Channels.

Author

Ghovanloo MR, Abdelsayed M, Peters CH, and Ruben PC

Subjects

Action Potentials, Amino Acid Sequence, Animals, CHO Cells, Cricetulus, Humans, Hypokalemic Periodic Paralysis physiopathology, Myotonia physiopathology, Patch-Clamp Techniques, Sequence Homology, Amino Acid, Voltage-Gated Sodium Channels chemistry, Hydrogen-Ion Concentration, Hypokalemic Periodic Paralysis genetics, Muscle, Skeletal physiopathology, Mutation, Myotonia genetics, Voltage-Gated Sodium Channels physiology

Abstract

Skeletal muscle channelopathies, many of which are inherited as autosomal dominant mutations, include myotonia and periodic paralysis. Myotonia is defined by a delayed relaxation after muscular contraction, whereas periodic paralysis is defined by episodic attacks of weakness. One sub-type of periodic paralysis, known as hypokalemic periodic paralysis (hypoPP), is associated with low potassium levels. Interestingly, the P1158S missense mutant, located in the third domain S4-S5 linker of the "skeletal muscle", Nav1.4, has been implicated in causing both myotonia and hypoPP. A common trigger for these conditions is physical activity. We previously reported that Nav1.4 is relatively insensitive to changes in extracellular pH compared to Nav1.2 and Nav1.5. Given that intense exercise is often accompanied by blood acidosis, we decided to test whether changes in pH would push gating in P1158S towards either phenotype. Our results suggest that, unlike in WT-Nav1.4, low pH depolarizes the voltage-dependence of activation and steady-state fast inactivation, decreases current density, and increases late currents in P1185S. Thus, P1185S turns the normally pH-insensitive Nav1.4 into a proton-sensitive channel. Using action potential modeling we predict a pH-to-phenotype correlation in patients with P1158S. We conclude that activities which alter blood pH may trigger the noted phenotypes in P1158S patients.

Published

2018

29. The efficacy of Ranolazine on E1784K is altered by temperature and calcium.

Author

Abdelsayed M, Ruprai M, and Ruben PC

Subjects

Action Potentials drug effects, Brugada Syndrome genetics, Cardiac Conduction System Disease genetics, HEK293 Cells, Humans, Long QT Syndrome genetics, Mutation genetics, NAV1.5 Voltage-Gated Sodium Channel genetics, Sodium metabolism, Temperature, Brugada Syndrome metabolism, Calcium metabolism, Cardiac Conduction System Disease metabolism, Long QT Syndrome metabolism, Ranolazine pharmacology

Abstract

E1784K is the most common mixed syndrome SCN5a mutation underpinning both Brugada syndrome type 1 (BrS1) and Long-QT syndrome type 3 (LQT3). The charge reversal mutant enhances the late sodium current (I Na ) passed by the cardiac voltage-gated sodium channel (Na V 1.5), delaying cardiac repolarization. Exercise-induced triggers, like elevated temperature and cytosolic calcium, exacerbate E1784K late I Na . In this study, we tested the effects of Ranolazine, the late I Na blocker, on voltage-dependent and kinetic properties of E1784K at elevated temperature and cytosolic calcium. We used whole-cell patch clamp to measure I Na from wild type and E1784K channels expressed in HEK293 cells. At elevated temperature, Ranolazine attenuated gain-of-function in E1784K by decreasing late I Na , hyperpolarizing steady-state fast inactivation, and increasing use-dependent inactivation. Both elevated temperature and cytosolic calcium hampered the capacity of Ranolazine to suppress E1784K late I Na . In-silico action potential (AP) simulations were done using a modified O'Hara Rudy (ORd) cardiac model. Simulations showed that Ranolazine failed to shorten AP duration, an effect augmented at febrile temperatures. The drug-channel interaction is clearly affected by external triggers, as reported previously with ischemia. Determining drug efficacy under various physiological states in SCN5a cohorts is crucial for accurate management of arrhythmias.

Published

2018

30. Effects of acidosis on neuronal voltage-gated sodium channels: Nav1.1 and Nav1.3.

Author

Ghovanloo MR, Peters CH, and Ruben PC

Subjects

Animals, CHO Cells, Cells, Cultured, Cricetulus, Patch-Clamp Techniques, Acidosis, Neurons metabolism, Voltage-Gated Sodium Channels metabolism

Abstract

Voltage-gated sodium channels are key contributors to membrane excitability. These channels are expressed in a tissue-specific manner. Mutations and modulation of these channels underlie various physiological and pathophysiological manifestations. The effects of changes in extracellular pH on channel gating have been studied on several sodium channel subtypes. Among these, Nav1.5 is the most pH-sensitive channel, with Nav1.2 and Nav1.4 being mostly pH-resistant channels. However, pH effects have not been characterized on other sodium channel subtypes. In this study, we sought to determine whether Nav1.1 and Nav1.3 display resistance or sensitivity to changes in extracellular pH. These two sodium channel subtypes are predominantly found in inhibitory neurons. The expression of these channels highly depends on age and the developmental stage of neurons, with Nav1.3 being found mostly in neonatal neurons, and Nav1.1 being found in adult neurons. Our present results indicate that, during extracellular acidosis, both channels show a depolarization in the voltage-dependence of activation and moderate reduction in current density. Voltage-dependence of steady-state fast inactivation and recovery from fast inactivation were unchanged. We conclude that Nav1.1 and Nav1.3 have similar pH-sensitivities.

Published

2018

31. Arrhythmogenic triggers associated with Sudden Cardiac Death.

Author

Abdelsayed M, Peters CH, and Ruben PC

Subjects

Humans, Mutation, NAV1.5 Voltage-Gated Sodium Channel genetics, Arrhythmias, Cardiac metabolism, Death, Sudden, Cardiac, NAV1.5 Voltage-Gated Sodium Channel metabolism

Published

2018

32. pH Modulation of Voltage-Gated Sodium Channels.

Author

Peters CH, Ghovanloo MR, Gershome C, and Ruben PC

Subjects

Acidosis complications, Animals, Humans, Ion Channel Gating, Protons, Voltage-Gated Sodium Channels physiology

Abstract

Changes in blood and tissue pH accompany physiological and pathophysiological conditions including exercise, cardiac ischemia, ischemic stroke, and cocaine ingestion. These conditions are known to trigger the symptoms of electrical diseases in patients carrying sodium channel mutations. Protons cause a diverse set of changes to sodium channel gating, which generally lead to decreases in the amplitude of the transient sodium current and increases in the fraction of non-inactivating channels that pass persistent currents. These effects are shared with disease-causing mutants in neuronal, skeletal muscle, and cardiac tissue and may be compounded in mutants that impart greater proton sensitivity to sodium channels, suggesting a role of protons in triggering acute symptoms of electrical disease.In this chapter, we review the mechanisms of proton block of the sodium channel pore and a suggested mode of action by which protons alter channel gating. We discuss the available data on isoform specificity of proton effects and tissue level effects. Finally, we review the role that protons play in disease and our own recent studies on proton-sensitizing mutants in cardiac and skeletal muscle sodium channels.

Published

2018

33. Differential calcium sensitivity in Na V 1.5 mixed syndrome mutants.

Author

Abdelsayed M, Baruteau AE, Gibbs K, Sanatani S, Krahn AD, Probst V, and Ruben PC

Subjects

Action Potentials, Gain of Function Mutation, HEK293 Cells, Heart Rate, Humans, Ion Channel Gating, Long QT Syndrome physiopathology, Loss of Function Mutation, Models, Cardiovascular, NAV1.5 Voltage-Gated Sodium Channel genetics, Sodium metabolism, Calcium metabolism, Long QT Syndrome genetics, Mutation, Missense, NAV1.5 Voltage-Gated Sodium Channel metabolism

Abstract

Key Points: SCN5a mutations may express gain-of-function (Long QT Syndrome-3), loss-of-function (Brugada Syndrome 1) or both (mixed syndromes), depending on the mutation and environmental triggers. One such trigger may be an increase in cytosolic calcium, accompanying exercise. Many mixed syndromes mutants, including ∆KPQ, E1784K, 1795insD and Q1909R, are found in calcium-sensitive regions. Elevated cytosolic calcium attenuates gain-of-function properties in ∆KPQ, 1795insD and Q1909R, but not in E1784K. By contrast, elevated cytosolic calcium further exacerbates gain-of-function in E1784K by destabilizing slow inactivation. Action potential modelling, using a modified O'Hara Rudy model, suggests that elevated heart rate rescues action potential duration in ∆KPQ, 1795insD and Q1909R, but not in E1784K. Action potential simulations suggest that E1784K carriers have an increased intracellular sodium-to-calcium ratio under bradycardia and tachycardia conditions. Elevated cytosolic calcium, which is common during high heart rates, ameliorates or exacerbates the mixed syndrome phenotype depending on the genetic signature., Abstract: Inherited arrhythmias may arise from mutations in the gene for SCN5a, which encodes the cardiac voltage-gated sodium channel, Na V 1.5. Mutants in Na V 1.5 result in Brugada Syndrome (BrS1), Long-QT Syndrome (LQT3) or mixed syndromes (an overlap of BrS1/LQT3). Exercise is a potential arrhythmogenic trigger in mixed syndromes. We aimed to determine the effects of elevated cytosolic calcium, which is common during exercise, in mixed syndrome Na V 1.5 mutants. We used whole-cell patch clamp to assess the biophysical properties of Na V 1.5 wild-type (WT), ∆KPQ, E1784K, 1795insD and Q1909R mutants in human embryonic kidney 293 cells transiently transfected with the Na V 1.5 α subunit (WT or mutants), β1 subunit and enhanced green fluorescent protein. Voltage-dependence and kinetics were measured at cytosolic calcium levels of approximately 0, 500 and 2500 nm. In silico, action potential (AP) model simulations were performed using a modified O'Hara Rudy model. Elevated cytosolic calcium attenuates the late sodium current in ∆KPQ, 1795insD and Q1909R, but not in E1784K. Elevated cytosolic calcium restores steady-state slow inactivation (SSSI) to the WT-form in Q1909R, but depolarized SSSI in E1784K. Our AP simulations showed a frequency-dependent reduction of AP duration in ∆KPQ, 1795insD and Q1909R carriers. In E1784K, AP duration is relatively prolonged at both low and high heart rates, resulting in a sodium overload. Cellular perturbations during exercise may affect BrS1/LQT3 patients differently depending on their individual genetic signature. Thus, exercise may be therapeutic or may be an arrhythmogenic trigger in some SCN5a patients., (© 2017 The Authors. The Journal of Physiology © 2017 The Physiological Society.)

Published

2017

34. Depolarization of the conductance-voltage relationship in the NaV1.5 mutant, E1784K, is due to altered fast inactivation.

Author

Peters CH, Yu A, Zhu W, Silva JR, and Ruben PC

Subjects

Animals, Membrane Potentials, NAV1.5 Voltage-Gated Sodium Channel genetics, Xenopus, Ion Channel Gating, Mutation, Missense, NAV1.5 Voltage-Gated Sodium Channel metabolism

Abstract

E1784K is the most common mixed long QT syndrome/Brugada syndrome mutant in the cardiac voltage-gated sodium channel NaV1.5. E1784K shifts the midpoint of the channel conductance-voltage relationship to more depolarized membrane potentials and accelerates the rate of channel fast inactivation. The depolarizing shift in the midpoint of the conductance curve in E1784K is exacerbated by low extracellular pH. We tested whether the E1784K mutant shifts the channel conductance curve to more depolarized membrane potentials by affecting the channel voltage-sensors. We measured ionic currents and gating currents at pH 7.4 and pH 6.0 in Xenopus laevis oocytes. Contrary to our expectation, the movement of gating charges is shifted to more hyperpolarized membrane potentials by E1784K. Voltage-clamp fluorimetry experiments show that this gating charge shift is due to the movement of the DIVS4 voltage-sensor being shifted to more hyperpolarized membrane potentials. Using a model and experiments on fast inactivation-deficient channels, we show that changes to the rate and voltage-dependence of fast inactivation are sufficient to shift the conductance curve in E1784K. Our results localize the effects of E1784K to DIVS4, and provide novel insight into the role of the DIV-VSD in regulating the voltage-dependencies of activation and fast inactivation.

Published

2017

35. Temperature-dependent changes in neuronal dynamics in a patient with an SCN1A mutation and hyperthermia induced seizures.

Author

Peters C, Rosch RE, Hughes E, and Ruben PC

Subjects

Animals, CHO Cells, Cell Line, Cricetinae, Cricetulus, Epilepsies, Myoclonic genetics, Epilepsies, Myoclonic physiopathology, Epilepsy genetics, Epilepsy physiopathology, Fever genetics, Humans, Infant, Male, Phenotype, Seizures, Febrile genetics, Temperature, Fever physiopathology, Mutation genetics, NAV1.1 Voltage-Gated Sodium Channel genetics, Neurons pathology, Seizures, Febrile physiopathology

Abstract

Dravet syndrome is the prototype of SCN1A-mutation associated epilepsies. It is characterised by prolonged seizures, typically provoked by fever. We describe the evaluation of an SCN1A mutation in a child with early-onset temperature-sensitive seizures. The patient carries a heterozygous missense variant (c3818C > T; pAla1273Val) in the NaV1.1 brain sodium channel. We compared the functional effects of the variant vs. wild type NaV1.1 using patch clamp recordings from channels expressed in Chinese Hamster Ovary Cells at different temperatures (32, 37, and 40 °C). The variant channels produced a temperature-dependent destabilization of activation and fast inactivation. Implementing these empirical abnormalities in a computational model predicts a higher threshold for depolarization block in the variant, particularly at 40 °C, suggesting a failure to autoregulate at high-input states. These results reveal direct effects of abnormalities in NaV1.1 biophysical properties on neuronal dynamics. They illustrate the value of combining cellular measurements with computational models to integrate different observational scales (gene/channel to patient).

Published

2016

36. Effects of Amiodarone and N-desethylamiodarone on Cardiac Voltage-Gated Sodium Channels.

Author

Ghovanloo MR, Abdelsayed M, and Ruben PC

Abstract

Amiodarone (AMD) is a potent antiarrhythmic drug with high efficacy for treating atrial fibrillation and tachycardia. The pharmacologic profile of AMD is complex. AMD possesses biophysical characteristics of all of class I, II, III, and IV agents. Despite its adverse side effects, AMD remains the most commonly prescribed antiarrhythmic drug. AMD was described to prolong the QT interval and can lead to torsades de pointes. Our goal was to study the effects of AMD on peak and late sodium currents (INa,P and INa,L) and determine whether these effects change as AMD is metabolized into N-desethylamiodarone (DES). We hypothesized that AMD and DES block both INa,P and INa,L with similar profiles due to structural similarities. Given the inherent small amounts of INa,L in NaV1.5, we screened AMD and DES against the Long QT-3-causing mutation, ΔKPQ, to better detect any drug-mediated effect on INa,L. Our results show that AMD and DES do not affect WT or ΔKPQ activation; however, both drugs altered the apparent valence of steady-state fast-inactivation. In addition, AMD and DES preferentially block ΔKPQ peak conductance compared to WT. Both compounds significantly increase INa,L and window currents. We conclude that both compounds have pro-arrhythmic effects on NaV1.5, especially ΔKPQ; however, DES seems to have a greater pro-arrhythmic effect than AMD.

Published

2016

37. Physiology and Pathophysiology of Sodium Channel Inactivation.

Author

Ghovanloo MR, Aimar K, Ghadiry-Tavi R, Yu A, and Ruben PC

Subjects

Action Potentials drug effects, Action Potentials physiology, Animals, Central Nervous System metabolism, Central Nervous System physiopathology, Humans, Neurotoxins chemistry, Neurotoxins metabolism, Neurotoxins pharmacology, Protein Isoforms antagonists & inhibitors, Protein Isoforms metabolism, Protein Subunits antagonists & inhibitors, Protein Subunits metabolism, Voltage-Gated Sodium Channel Blockers chemistry, Voltage-Gated Sodium Channel Blockers metabolism, Voltage-Gated Sodium Channel Blockers pharmacology, Voltage-Gated Sodium Channels chemistry, Voltage-Gated Sodium Channels metabolism

Abstract

Voltage-gated sodium channels are present in different tissues within the human body, predominantly nerve, muscle, and heart. The sodium channel is composed of four similar domains, each containing six transmembrane segments. Each domain can be functionally organized into a voltage-sensing region and a pore region. The sodium channel may exist in resting, activated, fast inactivated, or slow inactivated states. Upon depolarization, when the channel opens, the fast inactivation gate is in its open state. Within the time frame of milliseconds, this gate closes and blocks the channel pore from conducting any more sodium ions. Repetitive or continuous stimulations of sodium channels result in a rate-dependent decrease of sodium current. This process may continue until the channel fully shuts down. This collapse is known as slow inactivation. This chapter reviews what is known to date regarding, sodium channel inactivation with a focus on various mutations within each NaV subtype and with clinical implications., (Copyright © 2016 Elsevier Inc. All rights reserved.)

Published

2016

38. Triggers for arrhythmogenesis in the Brugada and long QT 3 syndromes.

Author

Peters CH, Abdelsayed M, and Ruben PC

Subjects

Animals, Brugada Syndrome genetics, Brugada Syndrome physiopathology, Environment, Humans, Hydrogen-Ion Concentration, Long QT Syndrome genetics, Long QT Syndrome physiopathology, Mutation, Brugada Syndrome etiology, Long QT Syndrome etiology

Abstract

Cardiac arrhythmias are a prevalent cause of morbidity and mortality. In many cases, inheritable mutations in the genes encoding cardiac ion channels are the underlying cause of arrhythmias. Relative to other arrhythmogenic disorders, Brugada syndrome (BrS) is recently identified and not well-understood. Although most often referred to as a disease of cardiac sodium channels, familial BrS is now associated with 9 different genes. Of these genes, 4 alter sodium currents, and the most common known genetic cause remains loss-of-function mutants in the cardiac sodium channel gene SCN5A. Long QT syndrome (LQTs) has a much longer history and is associated with at least 17 genes. LQT3, which is the third most common LQTs, is due to gain-of-function mutations in SCN5A. The first sign for BrS and LQTs patients may be sudden death. The triggers for these sudden deaths include exercise, fever, ischemia, and drug use. In this paper we review the effects of acidosis and fever on BrS and LQTs, discuss Brugada phenocopy syndrome drawing from published literature, and present our own patch-clamp data from mutant channels at low pH. We show that, at low pH, there is a preferential block of peak currents and preferential increase of persistent current in a common BrS/LQTs mutant compared to wild type sodium channels. Our data complements the existing literature on the importance of environmental triggers to arrhythmias., (Copyright © 2016 Elsevier Ltd. All rights reserved.)

Published

2016

39. Differential thermosensitivity in mixed syndrome cardiac sodium channel mutants.

Author

Abdelsayed M, Peters CH, and Ruben PC

Subjects

Action Potentials genetics, Animals, CHO Cells, Cardiac Conduction System Disease, Cell Line, Cricetulus, Fever genetics, Arrhythmias, Cardiac genetics, Brugada Syndrome genetics, Heart physiopathology, Heart Conduction System abnormalities, Long QT Syndrome genetics, Mutation genetics, NAV1.5 Voltage-Gated Sodium Channel genetics

Abstract

Cardiac arrhythmias are often associated with mutations in SCN5A the gene that encodes the cardiac paralogue of the voltage-gated sodium channel, NaV 1.5. The NaV 1.5 mutants R1193Q and E1784K give rise to both long QT and Brugada syndromes. Various environmental factors, including temperature, may unmask arrhythmia. We sought to determine whether temperature might be an arrhythmogenic trigger in these two mixed syndrome mutants. Whole-cell patch clamp was used to measure the biophysical properties of NaV 1.5 WT, E1784K and R1193Q mutants. Recordings were performed using Chinese hamster ovary (CHOk1) cells transiently transfected with the NaV 1.5 α subunit (WT, E1784K, or R1193Q), β1 subunit, and eGFP. The channels' voltage-dependent and kinetic properties were measured at three different temperatures: 10ºC, 22ºC, and 34ºC. The E1784K mutant is more thermosensitive than either WT or R1193Q channels. When temperature is elevated from 22°C to 34°C, there is a greater increase in late INa and use-dependent inactivation in E1784K than in WT or R1193Q. However, when temperature is lowered to 10°C, the two mutants show a decrease in channel availability. Action potential modelling using Q10 fit values, extrapolated to physiological and febrile temperatures, show a larger transmural voltage gradient in E1784K compared to R1193Q and WT with hyperthermia. The E1784K mutant is more thermosensitive than WT or R1193Q channels. This enhanced thermosensitivity may be a mechanism for arrhythmogenesis in patients with E1784K sodium channels., (© 2015 The Authors. The Journal of Physiology © 2015 The Physiological Society.)

Published

2015

40. Proton modulation of cardiac I Na: a potential arrhythmogenic trigger.

Author

Jones DK and Ruben PC

Subjects

Acidosis etiology, Acidosis metabolism, Acidosis physiopathology, Animals, Arrhythmias, Cardiac etiology, Arrhythmias, Cardiac physiopathology, Humans, Hydrogen-Ion Concentration, Myocardial Ischemia complications, Signal Transduction, Arrhythmias, Cardiac metabolism, Heart Rate, Ion Channel Gating, Myocytes, Cardiac metabolism, NAV1.5 Voltage-Gated Sodium Channel metabolism, Sodium metabolism

Abstract

Voltage-gated sodium (NaV) channels generate the upstroke and mediate duration of the ventricular action potential, thus they play a critical role in mediating cardiac excitability. Cardiac ischemia triggers extracellular pH to drop as low as pH 6.0, within just 10 min of its onset. Heightened proton concentrations reduce sodium conductance and alter the gating parameters of the cardiac-specific voltage-gated sodium channel, NaV1.5. Most notably, acidosis destabilizes fast inactivation, which plays a critical role in regulating action potential duration. The changes in NaV1.5 channel gating contribute to cardiac dysfunction during ischemia that can cause syncope, cardiac arrhythmia, and even sudden cardiac death. Understanding NaV channel modulation by protons is paramount to treatment and prevention of the deleterious effects of cardiac ischemia and other triggers of cardiac acidosis.

Published

2014

41. Introduction to sodium channels.

Author

Peters CH and Ruben PC

Subjects

Animals, Humans, Membrane Potentials, Protein Conformation, Structure-Activity Relationship, Voltage-Gated Sodium Channels chemistry, Ion Channel Gating, Sodium metabolism, Voltage-Gated Sodium Channels metabolism

Abstract

Voltage-gated sodium channels (VGSCs) are present in many tissue types within the human body including both cardiac and neuronal tissues. Like other channels, VGSCs activate, deactivate, and inactivate in response to changes in membrane potential. VGSCs also have a similar structure to other channels: 24 transmembrane segments arranged into four domains that surround a central pore. The structure and electrical activity of these channels allows them to create and respond to electrical signals in the body. Because of their distribution throughout the body, VGSCs are implicated in a variety of diseases including epilepsy, cardiac arrhythmias, and neuropathic pain. As such the study of these channels is essential. This brief review will introduce sodium channel structure, physiology, and pathophysiology.

Published

2014

42. A thermosensitive mutation alters the effects of lacosamide on slow inactivation in neuronal voltage-gated sodium channels, NaV1.2.

Author

Abdelsayed M, Sokolov S, and Ruben PC

Abstract

Epilepsy is a disorder characterized by seizures and convulsions. The basis of epilepsy is an increase in neuronal excitability that, in some cases, may be caused by functional defects in neuronal voltage gated sodium channels (NaVs). The C121W mutation of the β1 subunit, in particular, gives rise to the thermosensitive generalized epilepsy with febrile seizures plus (GEFS+) phenotype. Lacosamide is used to treat epileptic seizures and is distinct from other anti-seizure drugs by targeting NaV slow-inactivation. We studied the effects of a physiologically relevant concentration of lacosamide on the biophysical properties of NaV1.2 channels associated with either WT-β1 or the mutant C121W-β1 subunit. Biophysical parameters were measured at both normal (22°C) and elevated (34°C) temperatures to elicit the differential temperature-sensitivity of C121W. Lacosamide was more effective in NaV1.2 associated with the WT-β1 than with C121W-β1 at either temperature. There is also a more potent effect by lacosamide on slow inactivation at elevated temperatures. Our data suggest a modulatory role is imparted by the β1 subunit in the interaction between the drug and the channel.

Published

2013

43. Extracellular protons inhibit charge immobilization in the cardiac voltage-gated sodium channel.

Author

Jones DK, Claydon TW, and Ruben PC

Subjects

Animals, Electric Conductivity, Female, Humans, Hydrogen-Ion Concentration, Ion Channel Gating, Kinetics, NAV1.5 Voltage-Gated Sodium Channel chemistry, Electrons, Extracellular Space metabolism, Myocardium metabolism, NAV1.5 Voltage-Gated Sodium Channel metabolism, Protons

Abstract

Low pH depolarizes the voltage-dependence of cardiac voltage-gated sodium (NaV1.5) channel activation and fast inactivation and destabilizes the fast-inactivated state. The molecular basis for these changes in protein behavior has not been reported. We hypothesized that changes in the kinetics of voltage sensor movement may destabilize the fast-inactivated state in NaV1.5. To test this idea, we recorded NaV1.5 gating currents in Xenopus oocytes using a cut-open voltage-clamp with extracellular solution titrated to either pH 7.4 or pH 6.0. Reducing extracellular pH significantly depolarized the voltage-dependence of both the QON/V and QOFF/V curves, and reduced the total charge immobilized during depolarization. We conclude that destabilized fast-inactivation and reduced charge immobilization in NaV1.5 at low pH are functionally related effects., (Copyright © 2013 Biophysical Society. Published by Elsevier Inc. All rights reserved.)

Published

2013

44. Proton-dependent inhibition of the cardiac sodium channel Nav1.5 by ranolazine.

Author

Sokolov S, Peters CH, Rajamani S, and Ruben PC

Abstract

Ranolazine is clinically approved for treatment of angina pectoris and is a potential candidate for antiarrhythmic, antiepileptic, and analgesic applications. These therapeutic effects of ranolazine hinge on its ability to inhibit persistent or late Na(+) currents in a variety of voltage-gated sodium channels. Extracellular acidosis, typical of ischemic events, may alter the efficiency of drug/channel interactions. In this study, we examined pH modulation of ranolazine's interaction with the cardiac sodium channel, Nav1.5. We performed whole-cell path clamp experiments at extracellular pH 7.4 and 6.0 on Nav1.5 transiently expressed in HEK293 cell line. Consistent with previous studies, we found that ranolazine induced a stable conformational state in the cardiac sodium channel with onset/recovery kinetics and voltage-dependence resembling intrinsic slow inactivation. This interaction diminished the availability of the channels in a voltage- and use-dependent manner. Low extracellular pH impaired inactivation states leading to an increase in late Na(+) currents. Ranolazine interaction with the channel was also slowed 4-5 fold. However, ranolazine restored the voltage-dependent steady-state availability profile, thereby reducing window/persistent currents at pH 6.0 in a manner comparable to pH 7.4. These results suggest that ranolazine is effective at therapeutically relevant concentrations (10 μM), in acidic extracellular pH, where it compensates for impaired native slow inactivation.

Published

2013

45. Proton sensors in the pore domain of the cardiac voltage-gated sodium channel.

Author

Jones DK, Peters CH, Allard CR, Claydon TW, and Ruben PC

Subjects

Acidosis metabolism, Amino Acid Sequence, Animals, Arrhythmias, Cardiac metabolism, Electrophysiology methods, Female, Humans, Ischemia, Molecular Sequence Data, Myocardial Ischemia metabolism, NAV1.5 Voltage-Gated Sodium Channel chemistry, Oocytes metabolism, Patch-Clamp Techniques, Sequence Homology, Amino Acid, Sodium Channels, Time Factors, Xenopus, NAV1.5 Voltage-Gated Sodium Channel metabolism, Protons, Voltage-Gated Sodium Channels metabolism

Abstract

Protons impart isoform-specific modulation of inactivation in neuronal, skeletal muscle, and cardiac voltage-gated sodium (Na(V)) channels. Although the structural basis of proton block in Na(V) channels has been well described, the amino acid residues responsible for the changes in Na(V) kinetics during extracellular acidosis are as yet unknown. We expressed wild-type (WT) and two pore mutant constructs (H880Q and C373F) of the human cardiac Na(V) channel, Na(V)1.5, in Xenopus oocytes. C373F and H880Q both attenuated proton block, abolished proton modulation of use-dependent inactivation, and altered pH modulation of the steady-state and kinetic parameters of slow inactivation. Additionally, C373F significantly reduced the maximum probability of use-dependent inactivation and slow inactivation, relative to WT. H880Q also significantly reduced the maximum probability of slow inactivation and shifted the voltage dependence of activation and fast inactivation to more positive potentials, relative to WT. These data suggest that Cys-373 and His-880 in Na(V)1.5 are proton sensors for use-dependent and slow inactivation and have implications in isoform-specific modulation of Na(V) channels.

Published

2013

46. Acidosis differentially modulates inactivation in na(v)1.2, na(v)1.4, and na(v)1.5 channels.

Author

Vilin YY, Peters CH, and Ruben PC

Abstract

Na(V) channels play a crucial role in neuronal and muscle excitability. Using whole-cell recordings we studied effects of low extracellular pH on the biophysical properties of Na(V)1.2, Na(V)1.4, and Na(V)1.5, expressed in cultured mammalian cells. Low pH produced different effects on different channel subtypes. Whereas Na(V)1.4 exhibited very low sensitivity to acidosis, primarily limited to partial block of macroscopic currents, the effects of low pH on gating in Na(V)1.2 and Na(V)1.5 were profound. In Na(V)1.2 low pH reduced apparent valence of steady-state fast inactivation, shifted the τ(V) to depolarizing potentials and decreased channels availability during onset to slow and use-dependent inactivation (UDI). In contrast, low pH delayed open-state inactivation in Na(V)1.5, right-shifted the voltage-dependence of window current, and increased channel availability during onset to slow and UDI. These results suggest that protons affect channel availability in an isoform-specific manner. A computer model incorporating these results demonstrates their effects on membrane excitability.

Published

2012

47. A thermoprotective role of the sodium channel β1 subunit is lost with the β1 (C121W) mutation.

Author

Egri C, Vilin YY, and Ruben PC

Subjects

Animals, Body Temperature genetics, CHO Cells, Cricetinae, Cricetulus, Cytoprotection genetics, Disease Resistance genetics, Epilepsy metabolism, Epilepsy physiopathology, Hot Temperature adverse effects, Membrane Potentials genetics, NAV1.2 Voltage-Gated Sodium Channel, Patch-Clamp Techniques, Protein Subunits genetics, Rats, Seizures, Febrile metabolism, Seizures, Febrile physiopathology, Brain Chemistry genetics, Epilepsy genetics, Genetic Predisposition to Disease genetics, Mutation genetics, Nerve Tissue Proteins genetics, Seizures, Febrile genetics, Sodium Channels genetics

Abstract

Purpose: A mutation in the β(1) subunit of the voltage-gated sodium (Na(V)) channel, β(1) (C121W), causes genetic epilepsy with febrile seizures plus (GEFS+), a pediatric syndrome in which febrile seizures are the predominant phenotype. Previous studies of molecular mechanisms underlying neuronal hyperexcitability caused by this mutation were conducted at room temperature. The prevalence of seizures during febrile states in patients with GEFS+, however, suggests that the phenotypic consequence of β(1) (C121W) may be exacerbated by elevated temperature. We investigated the putative mechanism underlying seizure generation by the β(1) (C121W) mutation with elevated temperature., Methods: Whole-cell voltage clamp experiments were performed at 22 and 34°C using Chinese Hamster Ovary (CHO) cells expressing the α subunit of neuronal Na(V) channel isoform, Na(V) 1.2. Voltage-dependent properties were recorded from CHO cells expressing either Na(V) 1.2 alone, Na(V) 1.2 plus wild-type (WT) β(1) subunit, or Na(V) 1.2 plus β(1) (C121W)., Key Findings: Our results suggest WT β(1) is protective against increased channel excitability induced by elevated temperature; protection is lost in the absence of WT β(1) or with expression of β(1) (C121W). At 34°C, Na(V) 1.2 + β(1) (C121W) channel excitability increased compared to NaV1.2 + WT β(1) by the following mechanisms: decreased use-dependent inactivation, increased persistent current and window current, and delayed onset of, and accelerated recovery from, fast inactivation., Significance: Temperature-dependent changes found in our study are consistent with increased neuronal excitability of GEFS+ patients harboring C121W. These results suggest a novel seizure-causing mechanism for β(1) (C121W): increased channel excitability at elevated temperature., (Wiley Periodicals, Inc. © 2012 International League Against Epilepsy.)

Published

2012

48. A hot topic: temperature sensitive sodium channelopathies.

Author

Egri C and Ruben PC

Subjects

Brugada Syndrome metabolism, Brugada Syndrome physiopathology, Channelopathies metabolism, Channelopathies physiopathology, Electrophysiological Phenomena genetics, Electrophysiological Phenomena physiology, Epilepsies, Myoclonic metabolism, Epilepsies, Myoclonic physiopathology, Erythromelalgia metabolism, Erythromelalgia physiopathology, Homeostasis physiology, Humans, Long QT Syndrome metabolism, Long QT Syndrome physiopathology, Myotonic Disorders metabolism, Myotonic Disorders physiopathology, Seizures, Febrile metabolism, Seizures, Febrile physiopathology, Body Temperature physiology, Channelopathies genetics, Mutation, Sodium Channels genetics

Abstract

Perturbations to body temperature affect almost all cellular processes and, within certain limits, results in minimal effects on overall physiology. Genetic mutations to ion channels, or channelopathies, can shift the fine homeostatic balance resulting in a decreased threshold to temperature induced disturbances. This review summarizes the functional consequences of currently identified voltage-gated sodium (NaV) channelopathies that lead to disorders with a temperature sensitive phenotype. A comprehensive knowledge of the relationships between genotype and environment is not only important for understanding the etiology of disease, but also for developing safe and effective treatment paradigms.

Published

2012

49. Extracellular proton modulation of the cardiac voltage-gated sodium channel, Nav1.5.

Author

Jones DK, Peters CH, Tolhurst SA, Claydon TW, and Ruben PC

Subjects

Action Potentials physiology, Animals, Female, Humans, Hydrogen-Ion Concentration, Models, Biological, NAV1.5 Voltage-Gated Sodium Channel, Oocytes metabolism, Ventricular Function physiology, Xenopus, Extracellular Space metabolism, Ion Channel Gating, Myocardium metabolism, Protons, Sodium Channels metabolism

Abstract

Low pH depolarizes the voltage dependence of voltage-gated sodium (Na(V)) channel activation and fast inactivation. A complete description of Na(V) channel proton modulation, however, has not been reported. The majority of Na(V) channel proton modulation studies have been completed in intact tissue. Additionally, several Na(V) channel isoforms are expressed in cardiac tissue. Characterizing the proton modulation of the cardiac Na(V) channel, Na(V)1.5, will thus help define its contribution to ischemic arrhythmogenesis, where extracellular pH drops from pH 7.4 to as low as pH 6.0 within ~10 min of its onset. We expressed the human variant of Na(V)1.5 with and without the modulating β(1) subunit in Xenopus oocytes. Lowering extracellular pH from 7.4 to 6.0 affected a range of biophysical gating properties heretofore unreported. Specifically, acidic pH destabilized the fast-inactivated and slow-inactivated states, and elevated persistent I(Na). These data were incorporated into a ventricular action potential model that displayed a reduced maximum rate of depolarization as well as disparate increases in epicardial, mid-myocardial, and endocardial action potential durations, indicative of an increased heterogeneity of repolarization. Portions of these data were previously reported in abstract form., (Copyright © 2011 Biophysical Society. Published by Elsevier Inc. All rights reserved.)

Published

2011

50. Biophysical costs associated with tetrodotoxin resistance in the sodium channel pore of the garter snake, Thamnophis sirtalis.

Author

Lee CH, Jones DK, Ahern C, Sarhan MF, and Ruben PC

Subjects

Animals, Biophysical Phenomena genetics, Biophysics methods, Colubridae metabolism, Electric Stimulation methods, Humans, Ion Channel Gating drug effects, Ion Channel Gating genetics, Membrane Potentials genetics, Microinjections methods, Muscle Proteins genetics, NAV1.4 Voltage-Gated Sodium Channel, Oocysts, Patch-Clamp Techniques methods, Sodium Channel Blockers chemistry, Sodium Channels genetics, Tetrodotoxin chemistry, Xenopus, Biophysical Phenomena drug effects, Membrane Potentials drug effects, Muscle Proteins metabolism, Sodium Channel Blockers pharmacology, Sodium Channels metabolism, Tetrodotoxin pharmacology

Abstract

Tetrodotoxin (TTX) is a potent toxin that specifically binds to voltage-gated sodium channels (NaV). TTX binding physically blocks the flow of sodium ions through NaV, thereby preventing action potential generation and propagation. TTX has different binding affinities for different NaV isoforms. These differences are imparted by amino acid substitutions in positions within, or proximal to, the TTX-binding site in the channel pore. These substitutions confer TTX-resistance to a variety of species. The garter snake Thamnophis sirtalis has evolved TTX-resistance over the course of an arms race, allowing some populations of snakes to feed on tetrodotoxic newts, including Taricha granulosa. Different populations of the garter snake have different degrees of TTX-resistance, which is closely related to the number of amino acid substitutions. We tested the biophysical properties and ion selectivity of NaV of three garter snake populations from Bear Lake, Idaho; Warrenton, Oregon; and Willow Creek, California. We observed changes in gating properties of TTX-resistant (TTXr) NaV. In addition, ion selectivity of TTXr NaV was significantly different from that of TTX-sensitive NaV. These results suggest TTX-resistance comes at a cost to performance caused by changes in the biophysical properties and ion selectivity of TTXr NaV.

Published

2011