Inactivation of human sodium channels and the effect of tocainide

Non-canonical endogenous expression of voltage-gated sodium channel NaV1.7 subtype by the TE671 rhabdomyosarcoma cell line

Abstract

The human TE671 cell line was originally used as a model of medulloblastoma but has since been reassigned as rhabdomyosarcoma. Despite the characterised endogenous expression of voltage‐sensitive sodium currents in these cells, the specific voltage‐gated sodium channel (VGSC) subtype underlying these currents remains unknown. To profile the VGSC subtype in undifferentiated TE671 cells, endpoint and quantitative reverse transcription–PCR (qRT‐PCR), western blot and whole‐cell patch clamp electrophysiology were performed. qRT‐PCR profiling revealed that expression of the SCN9A gene was ∼215‐fold greater than the SCN4A gene and over 400‐fold greater than any of the other VGSC genes, while western blot confirmed that the dominant SCN9A RNA was translated to a protein with a molecular mass of ∼250 kDa. Elicited sodium currents had a mean amplitude of 2.6 ± 0.7 nA with activation and fast inactivation V₅₀ values of −31.9 ± 1.1 and −69.6 ± 1.0 mV, respectively. The currents were completely and reversibly blocked by tetrodotoxin at concentrations greater than 100 nm (IC₅₀ = 22.3 nm). They were also very susceptible to the Na_V1.7 specific blockers Huwentoxin‐IV and Protoxin‐II with IC₅₀ values of 14.6 nm and 0.8 nm, respectively, characteristic of those previously determined for Na_V1.7. Combined, the results revealed the non‐canonical and highly dominant expression of Na_V1.7 in the human TE671 rhabdomyosarcoma cell line. We show that the TE671 cell line is an easy to maintain and cost‐effective model for the study of Na_V1.7, a major target for the development of analgesic drugs and more generally for the study of pain.

Key points

Undifferentiated TE671 cells produce a voltage‐sensitive sodium current when depolarised.

The voltage‐gated sodium channel isoform expressed in undifferentiated TE671 cells was previously unknown.

Through qRT‐PCR, western blot and toxin pharmacology, it is shown that undifferentiated TE671 cells dominantly (>99.5%) express the Na_V1.7 isoform that is strongly associated with pain.

The TE671 cell line is, therefore, a very easy to maintain and cost‐effective model to study Na_V1.7‐targeting drugs.

An in vitro model of skeletal muscle volume regulation

INTRODUCTION

Hypertonic media causes cells to shrink due to water loss through aquaporin channels. After acute shrinkage, cells either regulate their volume or, alternatively, undergo a number of metabolic changes which ultimately lead to cell death. In many cell types, hypertonic shrinkage is followed by apoptosis. Due to the complex 3D morphology of skeletal muscle and the difficulty in obtaining isolated human tissue, we have begun skeletal muscle volume regulation studies using the human skeletal muscle cell line TE671RD. In this study we investigated whether hypertonic challenge of the human skeletal muscle cell line TE671RD triggered cell death or evoked a cell volume recovery response.

METHODS

The cellular volume of TE671RD cells was calculated from the 2D surface area. Cell death was assessed by both the trypan blue live/dead assay and the TUNEL assay.

RESULTS

Medium osmolality was increased by addition of up to 200 mM sucrose. Addition of 200 mM sucrose resulted in mean cell shrinkage of 44±1% after 30 mins. At later time points (2 and 4 hrs) two separate cell subpopulations with differing mean cell volume became apparent. The first subpopulation (15±2% of the total cell number) continued to shrink whereas the second subpopulation had an increased cell volume. Cell death was observed in a small proportion of cells (approximately 6-8%).

CONCLUSION

We have established that a substantial proportion of TE671RD cells respond to hypertonic challenge with RVI, but that these cells are resistant to hypertonicity triggered cell death.

Functional characterization of the pentapeptide QYNAD on rNav1.2 channels and its NMR structure

The endogenous pentapeptide QYNAD (Gln-Tyr-Asn-Ala-Asp) is present in human cerebrospinal fluid (CSF), and its concentration is increased in demyelinating diseases. QYNAD was synthesized and its action on the rNav1.2 voltage-gated sodium channel alpha-subunit was studied using whole-cell recordings in a heterologous expression system. The effects were seen only upon equilibration of the peptide in the external bath solution for at least 10 min before the commencement of whole-cell experiments. The steady-state activation curve showed a rightward shift of 10 mV, while the steady-state inactivation curve showed a leftward shift of 5 mV. Frequency-dependent inhibition of the sodium current amplitude was observed at 2-10 Hz, in the presence of external QYNAD, but was not seen when applied internally. Fits of the whole-cell sodium current traces by Hodgkin-Huxley equations revealed subtle changes in the voltage-dependent rate constants governing the transition of the activation and the inactivation gates. Two dimensional NMR spectroscopy revealed the absence of medium and long-range Nuclear Overhauser effects (NOEs), which indicates that the peptide does not adopt any canonical secondary structure in solution. In summary, our studies show that although the pentapeptide QYNAD does not have a defined structure in solution, it has defined actions on the rNav1.2 voltage-gated sodium channel isoform.

Increased rigidity of the chiral centre of tocainide favours stereoselectivity and use-dependent block of skeletal muscle Na(+) channels enhancing the antimyotonic activity in vivo

1. Searching for the structural requirements improving the potency and the stereoselectivity of Na(+) channel blockers as antimyotonic agents, new derivatives of tocainide, in which the chiral carbon atom is constrained in a rigid alpha-proline or pyrrolo-imidazolic cycle, were synthesized as pure enantiomers. 2. Their ability to block Na(+) currents, elicited from -100 to -20 mV at 0.3 Hz (tonic block) and 2-10 Hz (use-dependent block) frequencies, was investigated in vitro on single fibres of frog semitendinosus muscle using the vaseline-gap voltage-clamp method. 3. The alpha-proline derivative, To5, was 5 and 21 fold more potent than tocainide in producing tonic and 10 Hz-use-dependent block, respectively. Compared to To5, the presence of one methyl group on the aminic (To6) or amidic (To7) nitrogen atom decreased use-dependence by 2- and 6-times, respectively. When methylene moieties were present on both nitrogen atoms (To8), both tonic and use-dependent block were reduced. 4. Contrarily to tocainide, all proline derivatives were stereoselective in relation to an increased rigidity. A further increase in the molecular rigidity as in pyrrolo-imidazolic derivatives markedly decreased the drug potency with respect to tocainide. 5. Antimyotonic activity, evaluated as the shortening of the time of righting reflexes of myotonic adr/adr mice upon acute drug in vivo administration was 3 fold more effective for R-To5 than for R-Tocainide. 6. Thus, constraining the chiral centre of tocainide in alpha-proline cycle leads to more potent and stereoselective use-dependent Na(+) channel blockers with improved therapeutic potential.

Recombinant interleukin-2 acts like a class I antiarrhythmic drug on human cardiac sodium channels

Human recombinant interleukin-2 (rIL-2) was bath-applied to isolated human cardiocytes while sodium currents were triggered and registered using the whole-cell recording technique. In the presence of the cytokine the sodium currents were reversibly blocked, 50% peak current reduction occurring at a concentration of 500 U/ml. The current-voltage relationship was not affected, but the steady-state inactivation curve was not affected, but the steady-state inactivation curve was shifted in the negative direction by 15 mV. When 35% of the sodium current was blocked the time constant of recovery from block at -135 mV was in the range of 63 +/- 27 ms. Use dependence was observed only at stimulation frequencies above 4 Hz. Addition of a polyclonal anti-IL-2 antibody to the extracellular solution prevented all of the above effects, while incubation of the cells with a function-blocking monoclonal anti-IL-2 receptor antibody had no influence on the described rIL-2 action. In contrast to rIL-2, recombinant tumor necrosis factor alpha (rTNF-alpha) did not affect the sodium currents. It is concluded that rIL-2 acts like a class I antiarrhythmic drug on human cardiac sodium channels. This might explain some of its proarrhythmic side effects when given intravenously in high doses.

Plasma from patients with seronegative myasthenia gravis inhibit nAChR responses in the TE671/RD cell line

Myasthenia gravis (MG) is an autoimmune disorder in which anti-acetylcholine receptor (AChR) antibodies cause muscle weakness. In 10-15% of MG patients anti-AChR antibodies are undetectable (seronegative MG, SMG), though clinical and experimental evidence points to causative circulating factors. Using whole-cell patch-clamp techniques, we investigated the effects of heat-inactivated plasma from SMG patients (n = 7) on voltage-gated sodium [INa(V)] and ACh-induced nicotinic AChR (nAChR) currents in the human rhabdomyosarcoma cell line TE671/RD, comparing the results to those obtained with plasma from healthy individuals (HC, n = 6), patients with Guillain-Barré syndrome (GBS, n = 3) or those with other neurological diseases (OND, n = 3). None of the plasma samples inhibited INa(V). nAChR currents were rapidly (< 1 min) and significantly (P < 0.01) reduced by a 1:10 dilution of plasma from SMG patients compared with plasma from healthy controls and were not restored by washing. The inhibition appeared in some cases to be calcium dependent since for one of three plasmas it was prevented by 10 mM EGTA in the patch pipette. Currents were also reduced by two of three plasmas obtained from GBS patients at 1:3 dilution, but not by the three plasmas from patients with ONDs. The rapid action of plasma from SMG patients argues against an antibody-induced reduction in nAChR numbers; its calcium dependence in one case suggests action by a second messenger that might involve nAChR phosphorylation.

Characterization of the sodium currents in isolated human cardiocytes

The whole-cell recording technique was used to register Na+ currents from 403 atrial cardiocytes isolated from 80 human biopsies. With intracellular [Na+] ([Na+]i) raised to 70 mM, and at physiological extracellular [Na+] ([Na+]e, 145 mM) and room temperature, the Na+ currents were small enough for the error of the voltage clamp not to exceed 2 mV (series resistances 0.4-2 M omega). The threshold potential of the Na+ current was -64.0 +/- 7.7 mV. The peak amplitude was at -30.0 +/- 6.2 mV. The time course of fast inactivation was satisfactorily described with a single exponential. The time constant of inactivation was 2.0 ms at -55 mV and asymptotically approached 0.2 ms at positive membrane potentials. The steady-state inactivation curve was well fitted by a single Boltzmann distribution. Increasing the prepulse duration from 32 to 512 ms shifted the inflexion point of the curve from -61.7 +/- 6.4 to -72.2 +/- 2.6 mV. The time course of slow inactivation was also well described by a single exponential, the time constant ranging from 76.1 +/- 29.3 ms at -115 mV to 18.6 +/- 7.8 ms at -55 mV. Fitting the time course of recovery from inactivation required two time constants. At a recovery potential of -135 mV these were 1.6 +/- 0.2 and 8.6 +/- 2.9 ms and 15.9 +/- 9.4 and 53.2 +/- 33.3 ms at -95 mV. A 50% block of the Na+ currents was achieved by tetrodotoxin at 10 microM. It is concluded that the properties of human cardiac Na+ channels are similar to those of the juvenile Na+ channels of human skeletal muscle.

Cholinergic responses in cloned human TE671/RD tumour cells

The cholinergic responses of the human tumour cell line TE671/RD were examined using digital Ca2+ imaging fluorescence microscopy and patch-clamp measurements. In response to stimulation of the muscarinic acetylcholine (ACh) receptor (mAChR), the intracellular concentration of Ca2+ ([Ca2+]i) rose about two-fold, in parallel with inositol 1,4,5-trisphosphate accumulation, measured by chromatographic techniques. By contrast, there was no increment of [Ca2+]i upon stimulation of the nicotinic ACh receptor (nAChR), nor after caffeine application. Electrophysiological experiments showed that TE671/RD cells lack functional voltage-activated Ca2+ channels. The stimulation of the nAChR induced transient whole-cell currents (IACh). Little or no current was detected in isotonic extracellular Ca2+, with Cs+ in the patch pipette. Cell pretreatment with muscarine reduced IACh by about 20%, without consistent modifications of current kinetics. Muscarine applied to the extra-patch membrane under the cell-attached configuration had no obvious effect on ACh-evoked unitary events. In conclusion, in human TE671/RD cells, muscarinic stimulation increases [Ca2+]i, while nicotinic stimulation does not. In addition, the nAChR exhibits peculiar ion permeability properties and is not functionally regulated by the breakdown of phosphoinositides.

Factors in the cerebrospinal fluid of multiple sclerosis patients interfering with voltage-dependent sodium channels

The effect of cerebrospinal fluid (CSF) from patients with multiple sclerosis (MS) on voltage-dependent Na+ channels in human myoballs was studied. The transient Na+ currents, elicited by whole-cell depolarization from -85 to -20 mV, were decreased to 75-25% the control value in the presence of CSF from all 7 MS patients investigated. The effect was complete in about 5 s and was fully reversible on admission of standard external fluid. Such decrease was not or only to a minor extent observed with 10 out of 11 control CSFs from patients without inflammatory neurological disease. The origin of the factors interfering with the Na+ channels is unknown. It is suggested that, in addition to demyelination, impaired Na+ channel function might cause the symptoms in MS.

Specific modifications of the membrane fatty acid composition of human myotubes and their effects on the muscular sodium channels

The fatty acid (FA) composition of human myotube primary cultures was varied by modifications of the contents of FA in the culture medium. An incubation time of 18 h with a defined FA mixture resulted in the most effective alteration of the original FA pattern of the cells. The increases reached for the relative amounts of palmitic acid (16:0), linoleic acid (18:2) or arachidonic acid (20:4) were 3-5-fold. More than 50% of the extra FA were incorporated in the phospholipid fraction, the remaining share in the triglyceride fraction. Shorter incubation times resulted in less FA incorporation, longer incubation times raised the uptake of FA into the triacylglycerol fraction. For a study of the influence of the membrane modification on the function of the sodium channels, the myotubes were converted into myoballs. The sodium channel properties were then determined using the whole-cell clamp technique. The modified cultures showed no significant alterations in the time constants of activation and inactivation, in the voltage dependence of inactivation (h infinity curves) or in the average amplitudes of the sodium currents.

The acute paralysis in Guillain-Barré syndrome is related to a Na+ channel blocking factor in the cerebrospinal fluid

The effect of cerebrospinal fluid (CSF) from patients with severe polyradiculoneuritis (Guillain-Barré syndrome, GBS) on voltage-dependent Na+ channels of myoballs was studied. The transient Na+ currents, elicited by repetitive stimulation at 1 Hz, were inhibited by the CSF from most of the GBS patients to 10%-40% the control value. The inhibition was complete in about 5 s and was fully reversible. Such inhibition was never seen with control CSF. The blocking property of the CSF from GBS patients was lost after the number of cells and the protein content had been lowered by means of a clinical filtration technique for cerebrospinal fluid. The results demonstrate that in Guillain-Barré syndrome blocking factors of Na+ channels are present in the CSF, impairing neuron impulse conduction, and thereby causing muscular weakness and sensory disturbances in the affected patient.

Interleukin-2 inhibits sodium currents in human muscle cells

The effect of the T cell growth factor interleukin-2 (IL-2) on muscular Na+ channels was studied in myoballs produced from primary human muscle cultures. The transient Na+ inward currents of the myoballs, elicited by repetitive stimulation at 1 Hz and recorded in the whole-cell mode, were inhibited by IL-2 applied to the external solution, the half maximum effect occurring at 300 U/ml. The effect was complete within 5 s and was totally reversible, the on and off effects having identical time courses. The h infinity curve was shifted in negative direction indicating that the mechanism of IL-2 action is a conversion of the Na+ channels into a state of inactivation. The reaction of the IL-2 solution with an anti IL-2 antibody neutralized the inhibitory effect on the Na+ currents, indicating a specific effect of the peptide growth factor interleukin-2 on muscular Na+ channels. The connection of IL-2 and Na+ channels may be important in inflammatory processes of muscle and nerve.

Giga-seal formation alters properties of sodium channels of human myoballs

The influence of giga-seal formation on the properties of the Na+ channels within the covered membrane patch was investigated with a whole-cell pipette and a patch pipette applied to the same cell. Current kinetics, current/voltage relation and channel densities were determined in three combinations: (i) voltage-clamping and current recording with the whole-cell pipette, (ii) voltage-clamping with the whole-cell pipette and current recording with the patch pipette and, (iii) voltage-clamping and current recording with the patch pipette. The Hodgkin-Huxley (1952) parameters tau m and tau h were smaller for the patch currents than for the whole cell, and the h infinity curve was shifted in the negative direction. The channel density was of the order of 10 times smaller. All effects were independent of the extracellular Ca2+ concentration. The capacitive current generated in the patch by the whole-cell Na+ current and its effect on the transmembrane voltage of the patch were evaluated. The kinetic parameters of the Na+ channels in the patch did not depend on whether the voltage was clamped with the whole-cell pipette or the patch pipette. Thus, the results are not due to spurious voltage.

Voltage-dependent K+ channels in the sarcolemma of mouse skeletal muscle

The voltage-dependent K+ channels of the mammalian sarcolemma were studied with the patch-clamp technique in intact, enzymatically dissociated fibres from the toe muscle of the mouse. With a physiological solution (containing 2.5 mM K+) in the pipette, depolarizing pulses imposed on a cell-attached membrane patch activated K+ channels with a conductance of about 17 pS. No channel activity was observed when the pipette solution contained 2 mM tetraethylammonium (TEA), or 2 mM 4-aminopyridine (4-AP). Whole cell recordings from these very small muscle fibres showed the well-known delayed rectifier K+ outward current with a threshold of about -40 mV. The whole-cell current was completely blocked by 2 mM TEA in the bath, suggesting that the TEA-sensitive channels in the patch were also delayed rectifier channels. The inactivation properties of the channels were studied in the cell-attached mode. Averaged single-channel traces showed at least two types of channels discernible by their inactivation time course at a test potential of 60 mV. The fast type inactivated with a time constant of about 150 ms, the slow type with a time constant of about 400 ms. A little channel activity always remained during pulses lasting several minutes, indicating either the presence of a very slowly inactivating third type of K+ channel, or the tendency of the fast inactivating channels to re-open at constant voltage. No difference was seen in the single-channel amplitudes of the different types of K+ channels. The well characterized adenosine-5'-triphosphate-(ATP)-sensitive and Ca(2+)-dependent K+ channels, although present, were not active under the conditions used.(ABSTRACT TRUNCATED AT 250 WORDS)

Modulation of rat skeletal muscle chloride channels by activators and inhibitors of protein kinase C

The membrane electrical parameters and component conductances of rat extensor digitorum longus muscle fibres were studied in vitro at 30 degrees C with standard two microelectrode square pulse cable analysis in the presence of protein kinase C (PKC) activators and inhibitors. The PKC activator, 4-beta-phorbol-12,13 dibutyrate (4-beta-PDB), (2-90 nM) blocked up to 67% chloride conductance (GCl) in rat skeletal muscle fibres and induced myotonic hyperexcitability. The concentration necessary to produce a 50% block of the membrane GCl was 23 nM. The "inactive" 4-alpha-phorbol-12,13 dibutyrate had no effect at 2 microM. The blocking effect of 4-beta-PDB on GCl was prevented by preincubation of the preparations with the PKC inhibitors, staurosporine (1-5 microM) and tetrahydropapaverolone (50-100 microM). The blocking effects on membrane GCl of 4-beta-PDB and its antagonism by the inhibitors used support the concept of the involvement of PKC in regulating Cl channels of mammalian skeletal muscle fibres.

Stereoselective interaction of tocainide and its chiral analogs with the sodium channels in human myoballs

The effects of both enantiomers of tocainide and of some of its chiral analogs on the inactivation of the sodium current in human myoballs were investigated with the whole-cell recording technique. Structure and electron densities of the applied compounds were calculated and compared to the results. Both the R(-) and the S(+) enantiomers had little effect on fast inactivation determined with short prepulses according to Hodgkin and Huxley (1952; h infinity curve). When the inactivating prepulses used in this pulse protocol were prolonged to 1024 ms, both tocainide enantiomers increased inactivation severely, suggesting that the drug binds to the channel when it is in the state of intermediate inactivation (Fakler et al. 1990). Tetrodotoxin-resistant "juvenile" sodium channels were more affected than tetrodotoxin-sensitive "adult" channels. The R form was four times as effective as the S form. The compound obtained by substitution of the methyl group on the chiral centre of tocainide with a benzyl group, although in the less potent S form, affected inactivation of the juvenile sodium channels much more than the potent (R)-tocainide. Two additional substitutions, performed on the aromatic ring of tocainide, gave a compound that was most potent in shifting the inactivation curves, but without any selectivity for juvenile or adult channels.

Sodium and potassium channels in epithelial cells from thymus glands and thymomas of myasthenia gravis patients

In both normal and neoplastic epithelial cells from human thymus glands and thymomas, respectively, we found voltage-gated sodium and potassium channels that resemble the adult-type Na channel and the delayed outward rectifier K channel, respectively, of human skeletal muscle and mammalian nervous system. These voltage-gated ion channels might be part of a communication system between epithelial cells and other components of the microenvironment of the thymus.

Human nicotinic acetylcholine receptor: the influence of second messengers on activation and desensitization

The amplitude and time course of acetylcholine(ACh)-induced membrane current were determined in cells of the human medulloblastoma cell line TE 671. ACh was applied and washed out very rapidly (about 50 ms) by a shift of a cell between two streams of solution, one of which contained the transmitter. ACh-induced current was recorded in the whole-cell mode of patch clamping. The time course of activation of the ACh-induced current could not be resolved because the method of ACh application was still too slow. Desensitization started immediately with ACh application; it could be described by two time constants. With an ACh concentration of 3 microM, the fast time constant was about 0.5 s and the slow time constant was about 3.9 s. When the ACh concentration was raised in steps to 100 mM, the peak amplitude of the current increased, reached a maximum at 1 mM and decreased again. The rate of desensitization was directly correlated with increasing ACh concentration. Current amplitude and desensitization time constants were not affected by intracellular application of cAMP or of a catalytic subunit of a cAMP-dependent protein kinase. When the intracellular calcium concentration was raised at a constant magnesium concentration, desensitization time constants remained unaffected, but the current amplitude decreased. This decrease is not caused by a decrease in single-channel conductance, therefore it may represent a decrease in the number of activatable channels.