Effects of ApC, a sea anemone toxin, on sodium currents of mammalian neurons

We have characterized the actions of ApC, a sea anemone polypeptide toxin isolated from Anthopleura elegantissima, on neuronal sodium currents (I(Na)) using current and voltage-clamp techniques. Neurons of the dorsal root ganglia of Wistar rats (P5-9) in primary culture were used for this study. These cells express tetrodotoxin-sensitive (TTX-S) and tetrodotoxin-resistant (TTX-R) I(Na). In current-clamp experiments, application of ApC increased the average duration of the action potential. Under voltage-clamp conditions, the main effect of ApC was a concentration-dependent increase in the TTX-S I(Na) inactivation time course. No significant effects were observed on the activation time course or on the current peak-amplitude. ApC also produced a hyperpolarizing shift in the voltage at which 50% of the channels are inactivated and caused a significant decrease in the voltage dependence of Na+ channel inactivation. No effects were observed on TTX-R I(Na). Our results suggest that ApC slows the conformational changes required for fast inactivation of the mammalian Na+ channels in a form similar to other site-3 toxins, although with a greater potency than ATX-II, a highly homologous anemone toxin.     

Anandamide suppression of Na+ currents in rat dorsal root ganglion neurons

Anandamide, the ethanolamide of arachidonic acid, is an endogenous cannabinoid. It is an agonist at CB1 and CB2 cannabinoid receptors as well as the vanilloid receptor, VR1. It is analgesic in inflammatory and neuropathic pain. Both central and peripheral mechanisms are considered to participate in its analgesia. Primary sensory neurons express Na+ currents that are involved in the pathogenesis of pain. We examined the effect of anandamide on tetrodotoxin-sensitive (TTX-S) and tetrodotoxin-resistant (TTX-R) Na+ currents in rat dorsal root ganglion neurons. Anandamide inhibited both Na+ currents in a concentration-dependent manner. At a membrane potential of -80 mV, the current inhibition was greater in TTX-S than TTX-R currents (K(d); 5.4 microM vs. 38.4 microM). The activation and inactivation became faster in TTX-R current but not in TTX-S current. Anandamide did not alter the activation voltage in either type of current. It, however, produced a hyperpolarizing shift of the steady-state inactivation voltage in both types of currents. The maximum availability at a large negative potential was not reduced by anandamide. Thus, anandamide seems to affect inactivated Na+ channels rather than resting channels. The inhibition of Na+ currents was not reversed by AM 251 (a CB1 antagonist), AM 630 (a CB2 antagonist) or capsazepine (a VR1 antagonist), suggestive of a direct action of anandamide on Na+ channels. The inhibition of Na+ currents in sensory neurons may contribute to the anandamide analgesia.     

Neuroprotective effect of interleukin-6 regulation of voltage-gated Na~+ channels of cortical neurons is time-and dose-dependent

Interleukin-6 has been shown to be involved in nerve injury and nerve regeneration, but the effects of long-term administration of high concentrations of interleukin-6 on neurons in the central nervous system is poorly understood. This study investigated the effects of 24 hour exposure of interleukin-6 on cortical neurons at various concentrations(0.1, 1, 5 and 10 ng/m L) and the effects of 10 ng/m L interleukin-6 exposure to cortical neurons for various durations(2, 4, 8, 24 and 48 hours) by studying voltage-gated Na+ channels using a patch-clamp technique. Voltage-clamp recording results demonstrated that interleukin-6 suppressed Na+ currents through its receptor in a time- and dose-dependent manner, but did not alter voltage-dependent activation and inactivation. Current-clamp recording results were consistent with voltage-clamp recording results. Interleukin-6 reduced the action potential amplitude of cortical neurons, but did not change the action potential threshold. The regulation of voltage-gated Na+ channels in rat cortical neurons by interleukin-6 is time- and dose-dependent.     

Taurine-induced modulation of voltage-sensitive Na+ channels in rat dorsal root ganglion neurons

The physiological role of taurine, an abundant free amino acid in the neural system, is still poorly understood. The aim of this study was to investigate its effect on TTX-sensitive (TTX-S) and TTX-resistant (TTX-R) Na+ currents in enzymatically dissociated neurons from rat dorsal root ganglion (DRG) with conventional whole-cell recording manner under voltage-clamp conditions. A TTX-S Na+ current was recorded preferentially from large DRG neurons and a TTX-R Na+ current preferentially from small ones. For TTX-S Na+ channel, taurine of the concentration > or = 10 mM shifted the activation curve in the depolarizing direction and the inactivation curve in the hyperpolarizing direction. There was no change in the activation curve for TTX-R Na+ channel and the inactivation curve was shifted in the hyperpolarizing direction slightly in the presence of taurine > or = 20 mM. When the recovery kinetics was examined, the presence of taurine resulted in a slower recovery from inactivation of TTX-S currents and no change of TTX-R ones. All the effects of taurine were weakly concentration-dependent and partly recovered quite slowly after washout. Our data indicate that taurine alters the properties of Na+ currents in intact DRG neurons. These may contribute to the understanding of taurine as a natural neuroprotectant and the potential of taurine as a useful medicine for the treatment of sensory neuropathies.     

Gating and modulation of presumptive NaV1.9 channels in enteric and spinal sensory neurons

The NaV1.9 subunit is expressed in nociceptive dorsal root ganglion (DRG) neurons and sensory myenteric neurons in which it generates 'persistent' tetrodotoxin-resistant (TTX-R) Na+ currents of yet unknown physiological functions. Here, we have analyzed these currents in details by combining single-channel and whole-cell recordings from cultured rat DRG and myenteric neurons. Comparison of single-channel with whole-cell data indicates that recording using internal CsCl best reflects the basic electrical features of NaV1.9 currents. Inclusion of fluoride in the pipette solution caused a negative shift in the activation and inactivation gates of NaV1.9 but not NaV1.8. Fluoride acts by promoting entry of NaV1.9 channels into a preopen closed state, which causes a strong bias towards opening and enhances the ability of sensory neurons to sustain spiking. Thus, the modulation of the resting-closed states of NaV1.9 channels strongly influences nociceptor excitability and may provide a mechanism by which inflammatory mediators alter pain threshold.     

A new class of neurotoxin from wasp venom slows inactivation of sodium current

The effects of alpha-pompilidotoxin (alpha-PMTX), a new neurotoxin isolated from the venom of a solitary wasp, were studied on the neuromuscular synapses in lobster walking leg and the rat trigeminal ganglion (TG) neurons. Paired intracellular recordings from the presynaptic axon terminals and the innervating lobster leg muscles revealed that alpha-PMTX induced long bursts of action potentials in the presynaptic axon, which resulted in facilitated excitatory and inhibitory synaptic transmission. The action of alpha-PMTX was distinct from that of other known facilitatory presynaptic toxins, including sea anemone toxins and alpha-scorpion toxins, which modify the fast inactivation of Na+ current. We further characterized the action of alpha-PMTX on Na+ channels by whole-cell recordings from rat trigeminal neurons. We found that alpha-PMTX slowed the Na+ channels inactivation process without changing the peak current-voltage relationship or the activation time course of tetrodotoxin (TTX)-sensitive Na+ currents, and that alpha-PMTX had voltage-dependent effects on the rate of recovery from Na+ current inactivation and deactivating tail currents. The results suggest that alpha-PMTX slows or blocks conformational changes required for fast inactivation of the Na+ channels on the extracellular surface. The simple structure of alpha-PMTX, consisting of 13 amino acids, would be advantageous for understanding the functional architecture of Na+ channel protein.     

Opioid mu receptor activation inhibits sodium currents in prefrontal cortical neurons via a protein kinase A- and C-dependent mechanism

Opioid transmission in the medial prefrontal cortex is involved in mood regulation and is altered by drug dependency. However, the mechanism by which ionic channels in cortical neurons are controlled by mu opioid receptors has not been elucidated. In this study, the effect of mu opioid receptor activation on voltage-dependent Na(+) currents was assessed in medial prefrontal cortical neurons. In 66 out of 98 nonpyramidal neurons, the application of 1 microM of DAMGO ([D-Ala(2), N-Me-Phe(4), Gly(5)-OL]-enkephalin), a specific mu receptor agonist, caused a decrease in the Na(+) current amplitude to approximately 79% of that observed in controls (half blocking concentration = 0.094 microM). Moreover, DAMGO decreased the maximum current activation rate, prolonged its time-dependent inactivation, and shifted the half inactivation voltage from -63.4 mV to -71.5 mV. DAMGO prolonged the time constant of recovery from inactivation from 5.4 ms to 7.4 ms. The DAMGO-evoked inhibition of Na(+) current was attenuated when GDP-beta-S (0.4 mM, Guanosine 5-[beta-thio]diphosphate trilithium salt) was included in the intracellular solution. Inhibitors of kinase A and C greatly attenuated the DAMGO-induced inhibition, while adenylyl cyclase and kinase C activators mirrored the DAMGO inhibitory effect. Na(+) currents in pyramidal neurons were insensitive to DAMGO. We conclude that the activation of mu opioid receptors inhibits the voltage-dependent Na(+) currents expressed in nonpyramidal neurons of the medial prefrontal cortex, and that kinases A and C are involved in this inhibitory pathway.     

The chemokine CCL2 increases Nav1.8 sodium channel activity in primary sensory neurons through a Gβγ-dependent mechanism

Changes in function of voltage-gated sodium channels in nociceptive primary sensory neurons participate in the development of peripheral hyperexcitability that occurs in neuropathic and inflammatory chronic pain conditions. Among them, the tetrodotoxin-resistant (TTX-R) sodium channel Na(v)1.8, primarily expressed by small- and medium-sized dorsal root ganglion (DRG) neurons, substantially contributes to the upstroke of action potential in these neurons. Compelling evidence also revealed that the chemokine CCL2 plays a critical role in chronic pain facilitation via its binding to CCR2 receptors. In this study, we therefore investigated the effects of CCL2 on the density and kinetic properties of TTX-R Na(v)1.8 currents in acutely small/medium dissociated lumbar DRG neurons from naive adult rats. Whole-cell patch-clamp recordings demonstrated that CCL2 concentration-dependently increased TTX-resistant Na(v)1.8 current densities in both small- and medium-diameter sensory neurons. Incubation with CCL2 also shifted the activation and steady-state inactivation curves of Na(v)1.8 in a hyperpolarizing direction in small sensory neurons. No change in the activation and inactivation kinetics was, however, observed in medium-sized nociceptive neurons. Our electrophysiological recordings also demonstrated that the selective CCR2 antagonist INCB3344 [N-[2-[[(3S,4S)-1-E4-(1,3-benzodioxol-5-yl)-4-hydroxycyclohexyl]-4-ethoxy-3-pyrrolidinyl]amino]-2-oxoethyl]-3-(trifluoromethyl)benzamide] blocks the potentiation of Na(v)1.8 currents by CCL2 in a concentration-dependent manner. Furthermore, the enhancement in Na(v)1.8 currents was prevented by pretreatment with pertussis toxin (PTX) or gallein (a Gβγ inhibitor), indicating the involvement of Gβγ released from PTX-sensitive G(i/o)-proteins in the cross talk between CCR2 and Na(v)1.8. Together, our data clearly demonstrate that CCL2 may excite primary sensory neurons by acting on the biophysical properties of Na(v)1.8 currents via a CCR2/Gβγ-dependent mechanism.     

Brevetoxin modulates neuronal sodium channels in two cell lines derived from rat brain

Single Na+ channel currents were recorded from cell-attached membrane patches from two neuronal cell lines derived from rat brain, B50 and B104, and compared before and after exposure of the cells to purified brevetoxin, PbTx-3. B50 and B104 Na+ channels usually exhibited fast activation and inactivation as is typical of TTX-sensitive Na+ channels. PbTx-3 modified channel gating in both cell lines. PbTx-3 caused (1) significant increases in the frequency of channel reopening, indicating a slowing of channel inactivation, (2) a change in the voltage dependence of the channels, promoting channel opening during steady-state voltage clamp of the membrane at voltages throughout the activation range of Na+ currents, but notably near the resting potential of these cells (-60 - -50 mV), and (3) a significant, 6.7 mV hyperpolarized shift in the threshold potential for channel opening. Na+ channel slope conductance did not change in PbTx-3-exposed B50 and B104 neurons. These effects of Pbx-3 may cause hyperexcitability as well as inhibitory effects in intact brain.     

Ontogenic development of the TTX-sensitive and TTX-insensitive Na+ channels in neurons of the rat dorsal root ganglia.

Developmental changes in the sensitivity of neurons to tetrodotoxin (TTX) were studied in relation to the cell size in rat dorsal root ganglia (DRG). Na+ currents were recorded from neurons of various stages of development. Two types of Na+ channels were identified on the basis of their sensitivity to TTX. One type was insensitive to a very high concentration (0.1 mM) of TTX, while the other type was blocked by a low concentration (1 nM) of TTX. These two types of Na+ channels were observed throughout the developmental stages examined from day 17 of gestation and adulthood. Thus, both types of Na+ channels are already established at the early stage of neuronal development and appear to be retained throughout the life-span of the DRG neuron. The concentration-response relationships for the block of TTX-sensitive Na+ current by TTX did not appreciably change during development. Although two types of Na+ channels had strikingly different kinetic properties, the kinetic properties of each channel type were basically similar throughout development. The TTX-sensitive Na+ channels were mainly concentrated in cells with large cell diameters throughout developmental stages examined. These large cells appear to correspond to the 'large-light' cells. On the contrary, the TTX-insensitive Na+ channels were found in smaller diameter cells which may correspond to the 'small-dark' cells. Thus, it is concluded that there are heterogeneous categories of neurons which have Na+ channels with different physiological and pharmacological properties. Since Na+ channels play a pivotal role in the action potential generation, these heterogeneity of DRG neurons appear to be instrumental in integrating the sensory signals.     

Anticonvulsant pharmacology of voltage-gated Na+ channels in hippocampal neurons of control and chronically epileptic rats

Voltage-gated Na+ channels are a main target of many first-line anticonvulsant drugs and their mechanism of action has been extensively investigated in cell lines and native neurons. Nevertheless, it is unknown whether the efficacy of these drugs might be altered following chronic epileptogenesis. We have, therefore, analysed the effects of phenytoin (100 micro m), lamotrigine (100 micro m) and valproate (600 micro m) on Na+ currents in dissociated rat hippocampal granule neurons in the pilocarpine model of chronic epilepsy. In control animals, all three substances exhibited modest tonic blocking effects on Na+ channels in their resting state. These effects of phenytoin and lamotrigine were reduced (by 77 and 64%) in epileptic compared with control animals. Phenytoin and valproate caused a shift in the voltage dependence of fast inactivation in a hyperpolarizing direction, while all three substances shifted the voltage dependence of activation in a depolarizing direction. The anticonvulsant effects on Na+ channel voltage dependence proved to be similar in control and epileptic animals. The time course of fast recovery from inactivation was potently slowed by lamotrigine and phenytoin in control animals, while valproate had no effect. Interestingly, the effects of phenytoin on fast recovery from inactivation were significantly reduced in chronic epilepsy. Taken together, these results reveal that different anticonvulsant drugs may exert a distinct pattern of effects on native Na+ channels. Furthermore, the reduction of phenytoin and, to a less pronounced extent, lamotrigine effects in chronic epilepsy raises the possibility that reduced pharmacosensitivity of Na+ channels may contribute to the development of drug resistance.     

Carbamazepine effects on Na+ currents in human dentate granule cells from epileptogenic tissue

PURPOSE: Carbamazepine (CBZ) is a well-established drug in the therapy of temporal lobe epilepsy (TLE). The anticonvulsant action of CBZ has been explained mainly by use-dependent effects on voltage-dependent Na+ channels in various nonhuman cell type. However, it is unclear whether Na+ currents in neurons within the focal epileptogenic area of patients with medically intractable TLE show similar characteristics. METHODS: Therefore we used the whole-cell patch-clamp technique to investigate the effects of CBZ on voltage-dependent Na+ currents in 23 acutely isolated dentate granule cells (DGCs) from the resected hippocampus of eight patients with medically intractable TLE. RESULTS: As in findings in animal preparations, CBZ significantly reduced the amplitude of the Na+ current and significantly shifted the current-voltage dependence of the steady-state inactivation in the hyperpolarizing direction. In contrast, the rapid component of the recovery from inactivation of the Na+ currents was not affected by CBZ. In addition, the reduction of the Na+ current amplitude observed during repetitive stimulation with depolarizing pulses was not significantly altered by CBZ. CONCLUSIONS: In summary, CBZ strongly affects the voltage-dependent steady-state inactivation, with no effects on the removal of inactivation in Na+ currents of human DGCs. In spite of the lack of suitable control material, the CBZ insensitivity of the removal of inactivation may be an interesting concept to explain the medically intractable TLE in these patients.     

Block of sodium currents in rat dorsal root ganglion neurons by diphenhydramine

To elucidate the local anesthetic mechanism of diphenhydramine, its effects on tetrodotoxin-sensitive (TTX-S) and tetrodotoxin-resistant (TTX-R) sodium currents in rat dorsal root ganglion (DRG) neurons were examined by the whole-cell voltage clamp method. Diphenhydramine blocked TTX-S and TTX-R sodium currents with K(d) values of 48 and 86 microM, respectively, at a holding potential of -80 mV. It shifted the conductance-voltage curve for TTX-S sodium currents in the depolarizing direction but had little effect on that for TTX-R sodium currents. Diphenhydramine caused a shift of the steady-state inactivation curve for both types of sodium currents in the hyperpolarizing direction. The time-dependent inactivation became faster and the recovery from the inactivation was slowed by diphenhydramine in both types of sodium currents. Diphenhydramine produced a profound use-dependent block when the cells were repeatedly stimulated with high-frequency depolarizing pulses. The use-dependent block was more pronounced in TTX-R sodium currents. The results show that diphenhydramine blocks sodium channels of sensory neurons similarly to local anesthetics.     

Lidocaine stabilizes the open state of CNS voltage-dependent sodium channels

We have previously reported that the lidocaine action is different between CNS and muscle batrachotoxin-modified Na+ channels [Salazar et al., J. Gen. Physiol. 107 (1996) 743-754; Brain Res. 699 (1995) 305-314]. In this study we examined lidocaine action on CNS Na+ currents, to investigate the mechanism of lidocaine action on this channel isoform and to compare it with that proposed for muscle Na+ currents. Na+ currents were measured with the whole cell voltage clamp configuration in stably transfected cells expressing the brain alpha-subunit (type IIA) by itself (alpha-brain) or together with the brain beta(1)-subunit (alphabeta(1)-brain), or the cardiac alpha-subunit (hH1) (alpha-cardiac). Lidocaine (100 microM) produced comparable levels of Na+ current block at positive potentials and of hyperpolarizing shift of the steady-state inactivation curve in alpha-brain and alphabeta(1)-brain Na+ currents. Lidocaine accelerated the rates of activation and inactivation, produced an hyperpolarizing shift in the steady-state activation curve and increased the current magnitude at negative potentials in alpha-brain but not in alphabeta(1)-brain Na+ currents. The lidocaine action in alphabeta(1)-brain resembled that observed in alpha-cardiac Na+ currents. The lidocaine-induced increase in current magnitude at negative potentials and the hyperpolarizing shift in the steady-state activation curve of alpha-brain, are novel effects and suggest that lidocaine treatment does not always lead to current reduction/block when it interacts with Na+ channels. The data are explained by using a modified version of the model proposed by Vedantham and Cannon [J. Gen. Physiol., 113 (1999) 7-16] in which we postulate that the difference in lidocaine action between alpha-brain and alphabeta(1)-brain Na+ currents could be explained by differences in the lidocaine action on the open channel state.     

Effects of arachidonic acid on sodium currents in rat dorsal root ganglion neurons

The effects of arachidonic acid on tetrodotoxin-sensitive (TTX-S) and tetrodotoxin-resistant (TTX-R) sodium currents in rat dorsal root ganglion neurons were assessed using the whole-cell patch-clamp method. Both sodium currents were modulated in a similar way by extracellular application of arachidonic acid. Arachidonic acid increased the currents at lower depolarizing potentials, while it suppressed the currents at higher depolarizing potentials and at less negative holding potentials. These effects were due to the shifts of both the conductance–voltage curve and the steady-state inactivation curve in the hyperpolarizing direction. Indomethacin, a cyclooxygenase inhibitor, suppressed the arachidonic acid-induced shift of the conductance–voltage curve but not that of the steady-state inactivation curve. 5,8,11,14-Eicosatetraynoic acid, a non-metabolizable arachidonic acid analog, failed to shift the conductance–voltage curve but still produced the shift of the steady-state inactivation curve. Thus it is assumed that the effect of arachidonic acid on the sodium channel activation is caused by the metabolite(s) of arachidonic acid. However, the effect on the steady-state sodium channel inactivation is exerted by arachidonic acid itself. It is suggested that arachidonic acid, by modulating sodium currents, may alter the excitability of sensory neurons depending on the resting membrane potential.     

Resveratrol inhibits Na+ currents in rat dorsal root ganglion neurons

Resveratrol, a phytoalexin found in grapevines, exerts neuroprotective, cancer chemopreventive, antiinflammatory and cardioprotective activities. Studies have also shown that resveratrol exhibits analgesic effects. Cyclooxygenase inhibition and K+ channel opening have been suggested as underlying mechanisms for the resveratrol-induced analgesia. Here, we investigated the effects of resveratrol on tetrodotoxin-sensitive (TTX-S) and tetrodotoxin-resistant (TTX-R) Na+ currents in rat dorsal root ganglion (DRG) neurons. Resveratrol suppressed both Na+ currents evoked at 0 mV from -80 mV. TTX-S Na+ current (K(d), 72 microM) was more susceptible to resveratrol than TTX-R Na+ current (K(d), 211 microM). Although the activation voltage of TTX-S Na+ current was shifted in the depolarizing direction by resveratrol, that of TTX-R Na+ current was not. Resveratrol caused a hyperpolarizing shift of the steady-state inactivation voltage and slowed the recovery from inactivation of both Na+ currents. However, no frequency-dependent inhibition of resveratrol on either type of Na+ current was observed. The suppression and the unfavorable effects on the kinetics of Na+ currents in terms of the excitability of DRG neurons may make a great contribution to the analgesia by resveratrol.     

Ethanol inhibits voltage-gated sodium channels in cultured superior cervical ganglion neurons

To determine whether actions on sodium channels contribute to ethanol's depressant effects on the autonomic nervous system, the acute effects of ethanol on Na+ currents in primary cultured superior cervical ganglion were examined by whole-cell patch clamp recordings. Ethanol inhibited Na+ currents concentration dependently, and decreased action potential firing. Ethanol (100 mM) did not affect activation curve, but resulted in a left shift of the inactivation curve and prolonged the recovery from inactivation. This finding indicates that the channels in the inactivated state are more susceptible to ethanol than those in the resting state. For the first time, this study demonstrates acute inhibitory effects of ethanol on sodium channel gating in sympathetic neurons.     

Effects of free fatty acids on sodium currents in rat dorsal root ganglion neurons

Free fatty acids (FFAs), especially polyunsaturated fatty acids (PUFAs), are potent modulators of muscle-type sodium channels. It is not known if they also modulate sodium channels of sensory neurons. In this study, we investigated the effects of FFAs on the fast tetrodotoxin-sensitive (fTTX-S) and the slow tetrodotoxin-resistant (sTTX-R) sodium currents in rat dorsal root ganglion neurons. At a holding potential of -80 mV, PUFAs potently inhibited fTTX-S current, but monounsaturated fatty acids (MUFAs) and saturated fatty acids (SFAs) to a lesser extent. All FFAs initially increased sTTX-R current, and then decreased it slightly. PUFAs and MUFAs produced a hyperpolarizing shift of the steady-state inactivation voltage for both types of sodium currents. The shift generally increased with the number of unsaturated bonds. FFAs did not change the maximum amplitude of fTTX-S current, but increased that of sTTX-R current. Most FFAs shifted the activation voltage for fTTX-S current in the hyperpolarizing direction, which was not dependent on the degree of unsaturation. MUFAs and SFAs shifted the activation voltage for sTTX-R current in the hyperpolarizing direction, but PUFAs were without effect. The modulation of sodium currents by FFAs, especially PUFAs, may have considerable impact on the excitability of sensory neurons.     

The neuroleptic drug, fluphenazine, blocks neuronal voltage-gated sodium channels

Fluphenazine (Prolixin(R)) is a potent phenothiazine-based dopamine receptor antagonist, first introduced into clinical practice in the late 1950s as a novel antipsychotic. The drug emerged as a 'hit' during a routine ion channel screening assay, the present studies describe our electrophysiological examination of fluphenazine at tetrodotoxin-sensitive (TTX-S) and resistant (TTX-R) voltage-gated sodium channel variants expressed in three different cell populations. Constitutively expressed TTX-S conductances were studied in ND7/23 cells (a dorsal root ganglion-derived clonal cell line) and rat primary cerebrocortical neurons. Recombinant rat Na(V)1.8 currents were studied using ND7/23 cells as a host line for heterologous expression. Sodium currents were examined using standard whole-cell voltage-clamp electrophysiology. Current-voltage relationships for either ND7/23 cell or Na(V)1.8 currents revealed a prominent fluphenazine block of sodium channel activity. Steady-state inactivation curves were shifted by approximately 10 mV in the hyperpolarizing direction by fluphenazine (3 microM for ND7/23 currents and 10 microM for Na(V)1.8), suggesting that the drug stabilizes the inactivated channel state. Fluphenazine's apparent potency for blocking either ND7/23 or Na(V)1.8 sodium channels was increased by membrane depolarization, corresponding IC(50) values for the ND7/23 cell conductances were 18 microM and 960 nM at holding potentials of -120 mV and -50 mV, respectively. Frequency-dependent channel block was evident for each of the cell/channel variants, again suggesting a preferential binding to inactivated channel state(s). These experiments show fluphenazine to be capable of blocking neuronal sodium channels. Several unusual pharmacokinetic features of this drug suggest that sodium channel block may contribute to the overall clinical profile of this classical neuroleptic agent.     

Differential modulation of sodium channel Na(v)1.6 by two members of the fibroblast growth factor homologous factor 2 subfamily

FHF2A and FHF2B are two members of the fibroblast growth factor homologous factor 2 (FHF2) subfamily with distinct N termini. Using a generic antibody and electrophysiological methods, we previously showed that FHF2 is expressed in hippocampus and dorsal root ganglion (DRG) neurons and is colocalized with sodium channel Na(v)1.6 at sensory but not motor nodes of Ranvier, and that FHF2B associates with Na(v)1.6, causing an increase in current density and a small depolarizing shift in availability of channels. Using immunolabeling of adult rat tissue, we demonstrate that FHF2A is present within DRG but not in hippocampal or cerebellar neurons or at nodes of Ranvier in sciatic nerve, and that Na(v)1.6 and FHF2A are colocalized in nonmyelinated fibers. We also show that FHF2A binds directly to Na(v)1.6, and that the two proteins coimmunoprecipitate from transfected HEK293 cells. Because Na(v)1.6 has been associated with rapid firing rates, we examined the possible effects of FHF2B and the sister isoform, FHF2A, on electrophysiological properties of this channel in the DRG-derived ND7/23 cell line. We show that FHF2B inhibits accumulation of inactivation in response to trains of stimulation at high frequencies. In marked contrast, FHF2A causes an accumulation of inactivated channels at all frequencies tested due to a slowing of recovery from inactivation. Thus different FHF2 subfamily members have different functional effects on Na(v)1.6 and are differentially distributed in DRG neurons and their axons. This suggests that FHF2A and FHF2B may selectively alter firing behaviour of specific neuronal compartments via differential modulation of Na(v)1.6.