Hannes Todt scite author profile

While studying the adult rat skeletal muscle Na+ channel outer vestibule, we found that certain mutations of the lysine residue in the domain III P region at amino acid position 1237 of the alpha subunit, which is essential for the Na+ selectivity of the channel, produced substantial changes in the inactivation process. When skeletal muscle alpha subunits (micro1) with K1237 mutated to either serine (K1237S) or glutamic acid (K1237E) were expressed in Xenopus oocytes and depolarized for several minutes, the channels entered a state of inactivation from which recovery was very slow, i.e., the time constants of entry into and exit from this state were in the order of approximately 100 s. We refer to this process as "ultra-slow inactivation". By contrast, wild-type channels and channels with the charge-preserving mutation K1237R largely recovered within approximately 60 s, with only 20-30% of the current showing ultra-slow recovery. Coexpression of the rat brain beta1 subunit along with the K1237E alpha subunit tended to accelerate the faster components of recovery from inactivation, as has been reported previously of native channels, but had no effect on the mutation-induced ultra-slow inactivation. This implied that ultra-slow inactivation was a distinct process different from normal inactivation. Binding to the pore of a partially blocking peptide reduced the number of channels entering the ultra-slow inactivation state, possibly by interference with a structural rearrangement of the outer vestibule. Thus, ultra-slow inactivation, favored by charge-altering mutations at site 1237 in micro1 Na+ channels, may be analogous to C-type inactivation in Shaker K+ channels.

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The Late Prognosis of Epilepsy in Childhood: Results of a Prospective Follow‐up Study

Todt

1984

Epilepsia

145

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By means of a prospective study, relapse after discontinuation of antiepileptic drug treatment in 433 children with epilepsy and 40 patients who were treated after the first seizure was investigated. Independent of the electroencephalographic findings, the age of the patients, and other factors, the antiepileptic drugs were reduced during 1, 3, 6, and 12 months after 2, 3, and 4 seizure-free years; and in children with absences after 1, 2, 3, and 4 seizure-free years. The observation period after stopping therapy was at least 3 (on average, 5-6) years. In 157 of 433 children (36.3%) and 5 of 40 patients (12.5%), relapses occurred during this time. More than half (61.8%) of the relapses occurred during the withdrawal period or within 3 months: altogether, 86% within 1 year after discontinuation of therapy. Eighty-six percent of these patients again became free from seizures on administration of the original therapy. The dependence on predictive factors of the rate of relapse was tested by multivariate statistical analysis. There was a pronounced significant dependence on the duration of the seizure-free period, the duration of the withdrawal period, the length of illness, the frequency and duration of seizures, and the presence of paroxysmal activity in the EEG at the start of the discontinuation of antiepileptic drug treatment. The stopping of therapy during the pubertal period did not present a higher risk.

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A mu-conotoxin-insensitive Na+ channel mutant: possible localization of a binding site at the outer vestibule

Dudley

Todt

Lipkind

et al. 1995

Biophysical Journal

105

101

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We describe a mutation in the outer vestibule region of the adult rat skeletal muscle voltage-gated Na+ channel (microliter) that dramatically alters binding of mu-conotoxin GIIIA (mu-CTX). Mutating the glutamate at position 758 to glutamine (E758Q) decreased mu-CTX binding affinity by 48-fold. Because the mutant channel showed both low tetrodotoxin (TTX) and mu-CTX affinities, these results suggested that mu-CTX bound to the outer vestibule and implied that the TTX- and mu-CTX-binding sites partially overlapped in this region. The mutation decreased the association rate of the toxin with little effect on the dissociation rate, suggesting that Glu-758 could be involved in electrostatic guidance of mu-CTX to its binding site. We propose a mechanism for mu-CTX block of the Na+ channel based on the analogy with saxitoxin (STX) and TTX, on the requirement of mu-CTX to have an arginine in position 13 to occlude the channel, and on this experimental result suggesting that mu-CTX binds in the outer vestibule. In this model, the guanidinium group of Arg-13 of the toxin interacts with two carboxyls known to be important for selectivity (Asp-400 and Glu-755), with the association rate of the toxin increased by interaction with Glu-758 of the channel.

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Voltage-Gated Ion Channel Dysfunction Precedes Cardiomyopathy Development in the Dystrophic Heart

et al. 2011

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BackgroundDuchenne muscular dystrophy (DMD), caused by mutations in the dystrophin gene, is associated with severe cardiac complications including cardiomyopathy and cardiac arrhythmias. Recent research suggests that impaired voltage-gated ion channels in dystrophic cardiomyocytes accompany cardiac pathology. It is, however, unknown if the ion channel defects are primary effects of dystrophic gene mutations, or secondary effects of the developing cardiac pathology.Methodology/Principal FindingsTo address this question, we first investigated sodium channel impairments in cardiomyocytes derived from dystrophic neonatal mice prior to cardiomyopahty development, by using the whole cell patch clamp technique. Besides the most common model for DMD, the dystrophin-deficient mdx mouse, we also used mice additionally carrying an utrophin mutation. In neonatal cardiomyocytes, dystrophin-deficiency generated a 25% reduction in sodium current density. In addition, extra utrophin-deficiency significantly altered sodium channel gating parameters. Moreover, also calcium channel inactivation was considerably reduced in dystrophic neonatal cardiomyocytes, suggesting that ion channel abnormalities are universal primary effects of dystrophic gene mutations. To assess developmental changes, we also studied sodium channel impairments in cardiomyocytes derived from dystrophic adult mice, and compared them with the respective abnormalities in dystrophic neonatal cells. Here, we found a much stronger sodium current reduction in adult cardiomyocytes. The described sodium channel impairments slowed the upstroke of the action potential in adult cardiomyocytes, and only in dystrophic adult mice, the QRS interval of the electrocardiogram was prolonged.Conclusions/SignificanceIon channel impairments precede pathology development in the dystrophic heart, and may thus be considered potential cardiomyopathy triggers.

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Anti-addiction drug ibogaine inhibits voltage-gated ionic currents: A study to assess the drug's cardiac ion channel profile

Koenig

Kovar

Rubi

et al. 2013

Toxicology and Applied Pharmacology

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The plant alkaloid ibogaine has promising anti-addictive properties. Albeit not licenced as a therapeutic drug, and despite hints that ibogaine may perturb the heart rhythm, this alkaloid is used to treat drug addicts. We have recently reported that ibogaine inhibits human ERG (hERG) potassium channels at concentrations similar to the drugs affinity for several of its known brain targets. Thereby the drug may disturb the heart's electrophysiology.Here, to assess the drug's cardiac ion channel profile in more detail, we studied the effects of ibogaine and its congener 18-Methoxycoronaridine (18-MC) on various cardiac voltage-gated ion channels. We confirmed that heterologously expressed hERG currents are reduced by ibogaine in low micromolar concentrations. Moreover, at higher concentrations, the drug also reduced human Nav1.5 sodium and Cav1.2 calcium currents. Ion currents were as well reduced by 18-MC, yet with diminished potency. Unexpectedly, although blocking hERG channels, ibogaine did not prolong the action potential (AP) in guinea pig cardiomyocytes at low micromolar concentrations. Higher concentrations (≥ 10 μM) even shortened the AP. These findings can be explained by the drug's calcium channel inhibition, which counteracts the AP-prolonging effect generated by hERG blockade. Implementation of ibogaine's inhibitory effects on human ion channels in a computer model of a ventricular cardiomyocyte, on the other hand, suggested that ibogaine does prolong the AP in the human heart. We conclude that therapeutic concentrations of ibogaine have the propensity to prolong the QT interval of the electrocardiogram in humans. In some cases this may lead to cardiac arrhythmias.

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Hannes Todt

Ultra-Slow Inactivation in μ1 Na+ Channels Is Produced by a Structural Rearrangement of the Outer Vestibule

The Late Prognosis of Epilepsy in Childhood: Results of a Prospective Follow‐up Study

A mu-conotoxin-insensitive Na+ channel mutant: possible localization of a binding site at the outer vestibule

Voltage-Gated Ion Channel Dysfunction Precedes Cardiomyopathy Development in the Dystrophic Heart

Anti-addiction drug ibogaine inhibits voltage-gated ionic currents: A study to assess the drug's cardiac ion channel profile

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