TTX-sensitive Sodium Channels Research Articles

Hopping Probe Ion Conductance Microscopy and its Combined Patch-Clamping：A Powerful Tool for Structural and Functional Studies in Neural Nanobiology

Continuous high-resolution observations of cell membrane would greatly aid the elucidation of the relationship between structure and function and facilitate the study of physiological processing in cell biology. However, high-resolution studying living neuron membrane structures and its functions is still a challenge in current nanobiology. The new developed Hoping Probe Ion Conductance Microscopy (HPICM) is designed for non-contact continuous high-resolution topographic imaging of living cells under physiological conditions. In this review, we concisely introduced the basic operation principle of HPICM and its applications in high spatial resolution imaging of two living neuron cell models, N-type SK-N-SH cells and NGF-differentiated sympathetic neuron-like PC12 cells. Combining HPICM with patch-clamp technique, we further investigated the functional ion-channel of under-differentiated neuron-like PC12 cells and demonstrated that NGF treatment promoted the outgrowth of neurites and increased the activity of TTX-sensitive sodium channel. All these results demonstrate that HPICM combined with patch-clamp technique offers high-resolution topographic imaging of living neurons with non-contact — making HPICM an ideal high-resolution imaging technique not to interact/interfere with living neurons during image acquisition, and provides detailed information about the relationship between membrane structures and ion-channel functions of living neurons at the same time, which has the potential to become a powerful microscopy for in-depth researching in neural nanobiology.

Influence of the State of TTX-Resistant Sodium Channels on Electrical Activity of a Nociceptive Sensory Fiber: A Model Study

On a model of a thin (C-type) primary afferent fiber, we examined one of the hypotheses related to the phenomenon of initiation of long-lasting tonic discharges in nociceptive afferents. In the membrane of a region corresponding to the free peripheral terminal of the modeled nociceptive C fiber, there were sodium channels of three types (channels of rapidly inactivating TTX-sensitive current and TTX-resistant channels of two types, NaV1.8/SNS/PN3 and NaV1.9/NaN/SNS2). As is known, TTX-resistant sodium currents promote the development of long-lasting trains of action potentials, APs, where the duration of tonic discharges exceeds by orders of magnitude the duration of short stimuli inducing such discharges. Such trains, when transmitted to the spinal cord, are interpreted as pain signals. Using the model, we obtained the time course of changes in the membrane potential in the distal and proximal segments of the nerve fiber and values of the densities of inward and outward TTX-resistant sodium currents through channels NaV1.9/NaN/SNS2 and NaV1.8/SNS/PN3 in the norm and in a state mimicking the action of inflammation factors. Results of modeling demonstrated that TTX-resistant sodium currents provide intensification of slow components in the generated APs (plateau afterdepolarization). Having a higher inactivation threshold, these currents are inactivated more slowly and recover more rapidly after inactivation, as compared with the currents through TTX-sensitive sodium channels. Such behavior presupposes a considerable role of the TTX-resistant currents in facilitation of transmission of nociceptive signals under conditions of neuropathic pain characterized by excessive “upregulation” of the respective channels. It can be concluded that expression of TTX-resistant sodium channels in nociceptive sensory neurons possessing primary afferent C fibers, the presence of these channels in the membranes of peripheral terminals of the above fibers, and modification of biophysical properties of such channels under conditions of action of inflammation mediators, when taken together, create substantial prerequisites for initiation of anomalous long-lasting AP trains in the above peripheral terminals and, therefore, for transmission of such signals to the CNS. Such a situation appears to be a key electrophysiological phenomenon responsible for generation of neuropathic and inflammation-related pain.

Dorsal root tetrodotoxin-resistant sodium channels do not contribute to the augmented exercise pressor reflex in rats with chronic femoral artery occlusion

We investigated the contribution of tetrodotoxin (TTX)-resistant sodium channels to the augmented exercise pressor reflex observed in decerebrated rats with femoral artery ligation. The pressor responses to static contraction, to tendon stretch, and to electrical stimulation of the tibial nerve were compared before and after blocking TTX-sensitive sodium channels on the L3-L6 dorsal roots of rats whose hindlimbs were freely perfused and rats whose femoral arteries were ligated 72 h before the start of the experiment. In the freely perfused group (n=9), pressor (Δ22±4 mmHg) and cardioaccelerator (Δ32±6 beats/min) responses to contraction were attenuated by 1 μM TTX (Δ4±1 mmHg, P<0.05 and Δ17±4 beats/min, P<0.05, respectively). In the 72 h ligated group (n=9), the augmented pressor response to contraction (32±4 mmHg) was also attenuated by 1 μM TTX (Δ8±2 mmHg, P<0.05). The cardioaccelerator response to contraction was not significantly attenuated in these rats. In addition, TTX suppressed the pressor response to tendon stretch in both groups of rats. Electrical stimulation of the tibial nerve evoked similar pressor responses between the two groups (freely perfused: Δ74±9 mmHg and 72 h ligated: Δ78±5 mmHg). TTX attenuated the pressor response to the tibial nerve stimulation by about one-half in both groups. Application of the TTX-resistant sodium channel blocker A-803467 (1 μM) with TTX (1 μM) did not block the pressor response to tibial nerve stimulation to any greater extent than did application of TTX (1 μM) alone. Although the contribution of TTX-resistant sodium channels to the augmented exercise pressor reflex may be slightly increased in rats with chronic femoral artery ligation, TTX-resistant sodium channels on dorsal roots do not play a major role in the augmented exercise pressor reflex.

Functional neural differentiation of human adipose tissue-derived stem cells using bFGF and forskolin

BackgroundAdult mesenchymal stem cells (MSCs) derived from adipose tissue have the capacity to differentiate into mesenchymal as well as endodermal and ectodermal cell lineage in vitro. We characterized the multipotent ability of human adipose tissue-derived stem cells (hADSCs) as MSCs and investigated the neural differentiation potential of these cells.ResultsHuman ADSCs from earlobe fat maintained self-renewing capacity and differentiated into adipocytes, osteoblasts, or chondrocytes under specific culture conditions. Following neural induction with bFGF and forskolin, hADSCs were differentiated into various types of neural cells including neurons and glia in vitro. In neural differentiated-hADSCs (NI-hADSCs), the immunoreactivities for neural stem cell marker (nestin), neuronal markers (Tuj1, MAP2, NFL, NFM, NFH, NSE, and NeuN), astrocyte marker (GFAP), and oligodendrocyte marker (CNPase) were significantly increased than in the primary hADSCs. RT-PCR analysis demonstrated that the mRNA levels encoding for ABCG2, nestin, Tuj1, MAP2, NFL, NFM, NSE, GAP43, SNAP25, GFAP, and CNPase were also highly increased in NI-hADSCs. Moreover, NI-hADSCs acquired neuron-like functions characterized by the display of voltage-dependent tetrodotoxin (TTX)-sensitive sodium currents, outward potassium currents, and prominent negative resting membrane potentials under whole-cell patch clamp recordings. Further examination by RT-PCR showed that NI-hADSCs expressed high level of ionic channel genes for sodium (SCN5A), potassium (MaxiK, Kv4.2, and EAG2), and calcium channels (CACNA1C and CACNA1G), which were expressed constitutively in the primary hADSCs. In addition, we demonstrated that Kv4.3 and Eag1, potassium channel genes, and NE-Na, a TTX-sensitive sodium channel gene, were highly induced following neural differentiation.ConclusionsThese combined results indicate that hADSCs have the same self-renewing capacity and multipotency as stem cells, and can be differentiated into functional neurons using bFGF and forskolin.

Functional protein expression of multiple sodium channel α- and β-subunit isoforms in neonatal cardiomyocytes

Voltage-gated sodium channels are composed of pore-forming α- and auxiliary β-subunits and are responsible for the rapid depolarization of cardiac action potentials. Recent evidence indicates that neuronal tetrodotoxin (TTX) sensitive sodium channel α-subunits are expressed in the heart in addition to the predominant cardiac TTX-resistant Na v1.5 sodium channel α-subunit. These TTX-sensitive isoforms are preferentially localized in the transverse tubules of rodents. Since neonatal cardiomyocytes have yet to develop transverse tubules, we determined the complement of sodium channel subunits expressed in these cells. Neonatal rat ventricular cardiomyocytes were stained with antibodies specific for individual isoforms of sodium channel α- and β-subunits. α-actinin, a component of the z-line, was used as an intracellular marker of sarcomere boundaries. TTX-sensitive sodium channel α-subunit isoforms Na v1.1, Na v1.2, Na v1.3, Na v1.4 and Na v1.6 were detected in neonatal rat heart but at levels reduced compared to the predominant cardiac α-subunit isoform, Na v1.5. Each of the β-subunit isoforms (β1–β4) was also expressed in neonatal cardiac cells. In contrast to adult cardiomyocytes, the α-subunits are distributed in punctate clusters across the membrane surface of neonatal cardiomyocytes; no isoform-specific subcellular localization is observed. Voltage clamp recordings in the absence and presence of 20 nM TTX provided functional evidence for the presence of TTX-sensitive sodium current in neonatal ventricular myocardium which represents between 20 and 30% of the current, depending on membrane potential and experimental conditions. Thus, as in the adult heart, a range of sodium channel α-subunits are expressed in neonatal myocytes in addition to the predominant TTX-resistant Na v1.5 α-subunit and they contribute to the total sodium current.

Regulation of Podosome Formation in Macrophages by a Splice Variant of the Sodium Channel SCN8A

Voltage-gated sodium channels initiate electrical signaling in excitable cells such as muscle and neurons. They also are expressed in non-excitable cells such as macrophages and neoplastic cells. Previously, in macrophages, we demonstrated expression of SCN8A, the gene that encodes the channel NaV1.6, and intracellular localization of NaV1.6 to regions near F-actin bundles, particularly at areas of cell attachment. Here we show that a splice variant of NaV1.6 regulates cellular invasion through its effects on podosome and invadopodia formation in macrophages and melanoma cells. cDNA sequence analysis of SCN8A from THP-1 cells, a human monocyte-macrophage cell line, confirmed the expression of a full-length splice variant that lacks exon 18. Immunoelectron microscopy demonstrated NaV1.6-positive staining within the electron dense podosome rosette structure. Pharmacologic antagonism with tetrodotoxin (TTX) in differentiated THP-1 cells or absence of functional NaV1.6 through a naturally occurring mutation (med) in mouse peritoneal macrophages inhibited podosome formation. Agonist-mediated activation of the channel with veratridine caused release of sodium from cationic vesicular compartments, uptake by mitochondria, and mitochondrial calcium release through the Na/Ca exchanger. Invasion by differentiated THP-1 and HTB-66 cells, an invasive melanoma cell line, through extracellular matrix was inhibited by TTX. THP-1 invasion also was inhibited by small hairpin RNA knockdown of SCN8A. These results demonstrate that a variant of NaV1.6 participates in the control of podosome and invadopodia formation and suggest that intracellular sodium release mediated by NaV1.6 may regulate cellular invasion of macrophages and melanoma cells.

Impact Of NaV1.7-PEPD Missense Mutations That Slow The Rate Of Inactivation On Sensory Neuronal Resurgent Sodium Currents

Voltage-gated sodium (Nav1.1-9) channels are dynamic transmembrane proteins that, in response to changes in the potential across the lipophilic cell membrane, undergo specific conformational (gating) modifications, between ion-conducting (open) and non-conducting (closed and inactivated) states, to selectively conduct sodium ions through their aqueous pore. Importantly, changes in these voltage-dependent gating properties can impact action potential (AP) characteristics. TTX-sensitive sodium channels in cerebellar neurons can produce resurgent currents (Raman & Bean, 1997), intriguing currents that are re-activated during intermediate repolarizations following strong, but short, depolarizations. We observe resurgent currents in some DRG neurons and found that wild-type Nav1.6 but not wild-type Nav1.7 channels can generate resurgent currents in DRG neurons (Cummins et al., 2005). It has been demonstrated that, in cerebellar neurons from Nav1.6-null mice, slowing inactivation of the remaining Nav current can induce resurgent currents (Grieco & Raman, 2004). Interestingly, single-point missense mutations in the SCN9A gene that encode for Nav1.7, implicated in paroxysmal extreme pain disorder (PEPD), slow the rate of Nav1.7 inactivation (Jarecki et al., 2008). Therefore, we hypothesized that slowing of Nav1.7 by PEPD mutations might induce abnormal resurgent currents, thus altering AP properties. To explore this hypothesis, we transiently transfected adult rat DRG neurons with a TTX-resistant form of human Nav1.7-wild-type or PEPD mutant cDNA and rat Nav1.8-targeted shRNA. Voltage-dependent properties were observed using whole-cell voltage-clamp electrophysiology and AP generation was tested using current-clamp electrophysiology. Recordings were made in the presence and absence of extracellular TTX. These experiments should yield insight into (1) the mechanism of resurgent sodium current generation in DRG neurons, (2) a potential additive effect in channel dysfunction observed in PEPD, and (3) how these mutant channels contribute to alterations in AP characteristics.

Tetrodotoxin-sensitive Sodium Channels Contribute Significantly To The Cardiac Sodium Current In Dog Ventricles

Introduction: The role of the late sodium current (INaL) in hereditary sodium channelopathies such as Long QT syndrome (LQTS), Epilepsy and muscoloskeletal diseases has been well characterized. In most of these cases the sodium channel defect causes an increase in the sustained component of the sodium current, INaL that significantly delays the repolarization of the target cells and tissues action potential. Interestingly, some of these neuronal and skeletal muscle diseases also display a clinical phenotype of prolonged QT interval on the electrocardiogram and cardiac rythm disturbance. These observations combined with others made since the 1970.s indirectly suggest that a tetrodotoxin-sensitive (TTX) component contributes to cardiac INaL.Methods: We investigated the contribution of TTX-sensitive sodium channels (tNaVs) to INaL using patch clamp techniques and selective blockade of the cardiac sodium channel isoform NaV1.5 in dog ventricular myocytes. The thiosulfonate reagent (2-aminoethyl) methanethiosulfonate (MTSEA) binds to a specific cysteine in the pore region of NaV1.5 and selectively blocks this isoform. We looked at the distribution of tNaVs within the epicardial, midmyocardial and endocardial layers of the left venricle myocytes. Our results show that tNaVs contribute up to 40.18 ± 8.30 % of the late sodium current in dog cardiac myocytes. Immunoblot and mRNA data show that the molecular correlates of tNAVs: NaV1.1, NaV1.2 and NaV1.4 account for a significant portion of this contribution.Conclusions: We conclude that tNAVS are present in the cardiac ventricles of higher order mammals. In man, such contribution to INaL could explain the incidence of cardiac arrhythmias and QT prolongation observed in neuronal and musculoskeletal diseases and some of the cardiac secondary effects of neuroleptic drugs.

Determination of disulfide bridges of two spider toxins: hainantoxin-III and hainantoxin-IV

Peptide toxins are usually highly bridged proteins with multipairs of intrachain disulfide bonds. Analysis of disulfide connectivity is an important facet of protein structure determination. In this paper, we successfully assigned the disulfide linkage of two novel peptide toxins, called HNTX-III and HNTX-IV, isolated from the venom of Ornithoctonus hainana spider. Both peptides are useful inhibitors of TTX-sensitive voltage-gated sodium channels and are composed of six cysteine residues that form three disulfide bonds, respectively. Firstly, the peptides were partially reduced by tris(2-carboxyethyl)-phosphine (TCEP) in 0.1 M citrate buffer containing 6 M guanidine-HCl at 40° C for ten minutes. Subsequently, the partially reduced intermediates containing free thiols were separated by reversed-phase high-performance liquid chromatography (RP-HPLC) and alkylated by rapid carboxamidomethylation. Then, the disulfide bonds of the intermediates were analyzed by Edman degradation. By using the strategy above, disulfide linkages of HNTX-III and HNTX-IV were determined as I-IV, II-V and III-VI pattern. In addition, this study also showed that this method may have a great potential for determining the disulfide bonds of spider peptide toxins.

Kisspeptin-10 Facilitates a Plasma Membrane-Driven Calcium Oscillator in Gonadotropin-Releasing Hormone-1 Neurons

Kisspeptins, the natural ligands of the G-protein-coupled receptor (GPR)-54, are the most potent stimulators of GnRH-1 secretion and as such are critical to reproductive function. However, the mechanism by which kisspeptins enhance calcium-regulated neuropeptide secretion is not clear. In the present study, we used GnRH-1 neurons maintained in mice nasal explants to examine the expression and signaling of GPR54. Under basal conditions, GnRH-1 cells exhibited spontaneous baseline oscillations in intracellular calcium concentration ([Ca(2+)](i)), which were critically dependent on the operation of voltage-gated, tetrodotoxin (TTX)-sensitive sodium channels and were not coupled to calcium release from intracellular pools. Activation of native GPR54 by kisspeptin-10 initiated [Ca(2+)](i) oscillations in quiescent GnRH-1 cells, increased the frequency of calcium spiking in oscillating cells that led to summation of individual spikes into plateau-bursting type of calcium signals in a subset of active cells. These changes predominantly reflected the stimulatory effect of GPR54 activation on the plasma membrane oscillator activity via coupling of this receptor to phospholipase C signaling pathways. Both components of this pathway, inositol 1,3,4-trisphosphate and protein kinase C, contributed to the receptor-mediated modulation of baseline [Ca(2+)](i) oscillations. TTX and 2-aminoethyl diphenylborinate together abolished agonist-induced elevation in [Ca(2+)](i) in almost all cells, whereas flufenamic acid was less effective. Together these results indicate that a plasma membrane calcium oscillator is spontaneously operative in the majority of prenatal GnRH-1 neurons and is facilitated by kisspeptin-10 through phosphatidyl inositol diphosphate hydrolysis and depolarization of neurons by activating TTX-sensitive sodium channels and nonselective cationic channels.

Isolation and characterization of a T-superfamily conotoxin from Conus litteratus with targeting tetrodotoxin-sensitive sodium channels

A T-1-conotoxin, lt5d, was purified and characterized from the venom of vermivorous hunting cone snails Conus litteratus. The complete amino acid sequence of lt5d (DCCPAKLLCCNP) has been determined by Edman degradation. With two disulfide bonds, the calculated average mass is 1274.57 Da, which is confirmed by MALDI-TOF mass spectrometry (average mass 1274.8778). Under whole cell patch-clamp mode, lt5d inhibits tetrodotoxin-sensitive sodium currents on adult rat dorsal root ganglion neurons, but has no effects on tetrodotoxin-resistant sodium currents. The inhibition of TTX-sensitive sodium currents by lt5d was found to be concentration-dependent with the IC 50 value of 156.16 nM. Thus, this is the first T-superfamily conotoxin identified to block TTX-sensitive sodium channels.

A Cation-π Interaction Discriminates among Sodium Channels That Are Either Sensitive or Resistant to Tetrodotoxin Block

Voltage-gated sodium channels control the upstroke of the action potential in excitable cells of nerve and muscle tissue, making them ideal targets for exogenous toxins that aim to squelch electrical excitability. One such toxin, tetrodotoxin (TTX), blocks sodium channels with nanomolar affinity only when an aromatic Phe or Tyr residue is present at a specific location in the external vestibule of the ion-conducting pore. To test whether TTX is attracted to Tyr401 of NaV1.4 through a cation-pi interaction, this aromatic residue was replaced with fluorinated derivatives of Phe using in vivo nonsense suppression. Consistent with a cation-pi interaction, increased fluorination of Phe401, which reduces the negative electrostatic potential on the aromatic face, caused a monotonic increase in the inhibitory constant for block. Trifluorination of the aromatic ring decreased TTX affinity by approximately 50-fold, a reduction similar to that caused by replacement with the comparably hydrophobic residue Leu. Furthermore, we show that an energetically equivalent cation-pi interaction underlies both use-dependent and tonic block by TTX. Our results are supported by high level ab initio quantum mechanical calculations applied to a model of TTX binding to benzene. Our analysis suggests that the aromatic side chain faces the permeation pathway where it orients TTX optimally and interacts with permeant ions. These results are the first of their kind to show the incorporation of unnatural amino acids into a voltage-gated sodium channel and demonstrate that a cation-pi interaction is responsible for the obligate nature of an aromatic at this position in TTX-sensitive sodium channels.

Isolation and Structure-Activity of μ-Conotoxin TIIIA, A Potent Inhibitor of Tetrodotoxin-Sensitive Voltage-Gated Sodium Channels

Mu-conotoxins are three-loop peptides produced by cone snails to inhibit voltage-gated sodium channels during prey capture. Using polymerase chain reaction techniques, we identified a gene sequence from the venom duct of Conus tulipa encoding a new mu-conotoxin-TIIIA (TIIIA). A 125I-TIIIA binding assay was established to isolate native TIIIA from the crude venom of Conus striatus. The isolated peptide had three post-translational modifications, including two hydroxyproline residues and C-terminal amidation, and <35% homology to other mu-conotoxins. TIIIA potently displaced [3H]saxitoxin and 125I-TIIIA from rat brain (Nav1.2) and skeletal muscle (Nav1.4) membranes. Alanine and glutamine scans of TIIIA revealed several residues, including Arg14, that were critical for high-affinity binding to tetrodotoxin (TTX)-sensitive Na+ channels. We were surprised to find that [E15A]TIIIA had a 10-fold higher affinity than TIIIA for TTX-sensitive sodium channels (IC50, 15 vs. 148 pM at rat brain membrane). TIIIA was selective for Nav1.2 and -1.4 over Nav1.3, -1.5, -1.7, and -1.8 expressed in Xenopus laevis oocytes and had no effect on rat dorsal root ganglion neuron Na+ current. 1H NMR studies revealed that TIIIA adopted a single conformation in solution that was similar to the major conformation described previously for mu-conotoxin PIIIA. TIIIA and analogs provide new biochemical probes as well as insights into the structure-activity of mu-conotoxins.

Chemical and Cold Sensitivity of Two Distinct Populations of TRPM8-Expressing Somatosensory Neurons

The cold- and menthol-sensing TRPM8 receptor has been proposed to have both nonnociceptive and nociceptive functions. However, one puzzle is how this single type of receptor may be used by somatosensory neurons to code for two distinct sensory modalities. Using acutely dissociated rat dorsal root ganglion (DRG) neurons without culture, we show that TRPM8 receptors are expressed on two distinct classes of somatosensory neurons. One class is sensitive to menthol and features nonnociceptive neuron properties, including capsaicin-insensitive, ATP-insensitive, transient acid response, and expression of TTX-sensitive sodium channels only. This class is termed the menthol-sensitive/capsaicin-insensitive neuron class (MS/CIS). The other class is also sensitive to menthol but has characteristics of nociceptive neurons including capsaicin-sensitive, ATP-sensitive, prolonged acid response, and expression of both TTX-sensitive and TTX-resistant sodium channels. This class is termed the menthol-sensitive/capsaicin-sensitive neuron class (MS/CS). The presence of these two neuron classes in acutely dissociated DRG neurons support the idea that TRPM8 receptors can have both nonnociceptive and nociceptive functions. While both neuron classes respond to menthol and cold, the overall responses induced by menthol and cold are significantly larger in MS/CIS than in MS/CS neurons. Furthermore, low concentrations of menthol produce strong selection of the MS/CIS neuron population over the MS/CS neuron population. On the other hand, the population selection becomes weaker with higher concentrations of menthol. TRPM8 current density shows significant higher in MS/CIS neurons than in MS/CS neurons, suggesting different expression levels of TRPM8 receptors between the two neuron populations, and this difference may provide a mean of selective activation of MS/CIS neurons at low stimulation intensity.

Contactin regulates the current density and axonal expression of tetrodotoxin‐resistant but not tetrodotoxin‐sensitive sodium channels in DRG neurons

Contactin, a glycosyl-phosphatidylinositol (GPI)-anchored predominantly neuronal cell surface glycoprotein, associates with sodium channels Nav1.2, Nav1.3 and Nav1.9, and enhances the density of these channels on the plasma membrane in mammalian expression systems. However, a detailed functional analysis of these interactions and of untested putative interactions with other sodium channel isoforms in mammalian neuronal cells has not been carried out. We examined the expression and function of sodium channels in small-diameter dorsal root ganglion (DRG) neurons from contactin-deficient (CNTN-/-) mice, compared to CNTN+/+ litter mates. Nav1.9 is preferentially expressed in isolectin B4 (IB4)-positive neurons and thus we used this marker to subdivide small-diameter DRG neurons. Using whole-cell patch-clamp recording, we observed a greater than two-fold reduction of tetrodotoxin-resistant (TTX-R) Nav1.8 and Nav1.9 current densities in IB4+ DRG neurons cultured from CNTN-/- vs. CNTN+/+ mice. Current densities for TTX-sensitive (TTX-S) sodium channels were unaffected. Contactin's effect was selective for IB4+ neurons as current densities for both TTX-R and TTX-S channels were not significantly different in IB4- DRG neurons from the two genotypes. Consistent with these results, we have demonstrated a reduction in Nav1.8 and Nav1.9 immunostaining on peripherin-positive unmyelinated axons in sciatic nerves from CNTN-/- mice but detected no changes in the expression for the two major TTX-S channels Nav1.6 and Nav1.7. These data provide evidence of a role for contactin in selectively regulating the cell surface expression and current densities of TTX-R but not TTX-S Na+ channel isoforms in nociceptive DRG neurons; this regulation could modulate the membrane properties and excitability of these neurons.

Novel Conotoxins from Conus striatus and Conus kinoshitai Selectively Block TTX-Resistant Sodium Channels

The peptides isolated from venoms of predatory marine Conus snails ("conotoxins") are well-known to be highly potent and selective pharmacological agents for voltage-gated ion channels and receptors. We report the discovery of two novel TTX-resistant sodium channel blockers, mu-conotoxins SIIIA and KIIIA, from two species of cone snails. The two toxins were identified and characterized by combining molecular techniques and chemical synthesis. Both peptides inhibit TTX-resistant sodium currents in neurons of frog sympathetic and dorsal root ganglia but poorly block action potentials in frog skeletal muscle, which are mediated by TTX-sensitive sodium channels. The amino acid sequences in the C-terminal region of the two peptides and of the previously characterized mu-conotoxin SmIIIA (which also blocks TTX-resistant channels) are similar, but the three peptides differ in the length of their first N-terminal loop. We used molecular dynamics simulations to analyze how altering the number of residues in the first loop affects the overall structure of mu-conotoxins. Our results suggest that the naturally occurring truncations do not affect the conformation of the C-terminal loops. Taken together, structural and functional differences among mu-conotoxins SmIIIA, SIIIA, and KIIIA offer a unique insight into the "evolutionary engineering" of conotoxin activity.

Expression and distribution of TTX‐sensitive sodium channel alpha subunits in the enteric nervous system

The expression and distribution of TTX-sensitive voltage-gated sodium channel (VGSC) alpha subunits in the enteric nervous system (ENS) has not been described. Using RT-PCR, expression of Na(v)1.2, Na(v)1.3, Na(v)1.6, and Na(v)1.7 mRNA was detected in small and large intestinal preparations from guinea pigs. Expression of Na(v)1.1 mRNA as well as Na(v)1.1-like immunoreactivity (-li) were not observed in any intestinal region investigated. Na(v)1.2-li was primarily observed within the soma of the majority of myenteric and submucosal neurons, although faint immunoreactivity was occasionally observed in ganglionic and internodal fibers. Na(v)1.3-li was observed in dendrites, soma, and axons in a small group of myenteric neurons, as well as in numerous myenteric internodal fibers; immunoreactivity was rarely observed in the submucosal plexus. Na(v)1.6-li was primarily observed in the initial axonal segment of colonic myenteric neurons. Na(v)1.7-li was observed in dorsal root ganglia neurons but not in the myenteric plexus of the small and large intestine. In the ileum, 37% of Na(v)1.2-li cell bodies colocalized with calbindin-li while colocalization with calretinin-li was rare. In contrast, 22% of Na(v)1.3-li cell bodies colocalized with calretinin-li but colocalization with calbindin-li was not observed. In the colon, both Na(v)1.2-li and Na(v)1.3-li cell bodies frequently colocalized with either calretinin-li or calbindin-li. Na(v)1.2-li cell bodies also colocalized with the majority of NeuN-li cells in the small and large intestine. These data suggest that Na(v)1.1 may not be highly expressed in the ENS, but that Na(v)1.2, Na(v)1.3, and Na(v)1.6, and possibly Na(v)1.7, have broadly important and distinct functions in the ENS.

The Molecular Machinery of Resurgent Sodium Current Revealed

Some TTX-sensitive sodium channels open transiently during recovery from inactivation, generating a "resurgent" sodium current that flows immediately following action potentials. In this issue of Neuron, Grieco and colleagues present evidence that resurgent sodium current results from a novel form of inactivation in which the cytoplasmic tail of the beta4 subunit acts as a classic open-channel blocker.

Persistent tetrodotoxin-sensitive sodium current resulting from U-to-C RNA editing of an insect sodium channel

The persistent tetrodotoxin (TTX)-sensitive sodium current, detected in neurons of many regions of mammalian brains, is associated with many essential neuronal activities, including boosting of excitatory synaptic inputs, acceleration of firing rates, and promotion of oscillatory neuronal activities. However, the origin and molecular basis of the persistent current have remained controversial for decades. Here, we provide direct evidence that U-to-C RNA editing of an insect sodium channel transcript generates a sodium channel with a persistent current. We detected a persistent TTX-sensitive current in a splice variant of the cockroach sodium channel gene BgNa(v) (formerly para(CSMA)). Site-directed mutagenesis experiments revealed that an F-to-S change at the C-terminal domain of this variant was responsible for the persistent current. We demonstrated that this F-to-S change was the result of a U-to-C RNA editing event, which also occurred in the Drosophila para sodium channel transcript. Our work provides direct support for the hypothesis that posttranscriptional modification of a conventional transient sodium channel produces a persistent TTX-sensitive sodium channel.

Sodium Currents in Subthalamic Nucleus Neurons From Nav1.6-Null Mice

In some central neurons, including cerebellar Purkinje neurons and subthalamic nucleus (STN) neurons, TTX-sensitive sodium channels show unusual gating behavior whereby some channels open transiently during recovery from inactivation. This "resurgent" sodium current is effectively activated immediately after action potential-like waveforms. Earlier work using Purkinje neurons suggested that the great majority of resurgent current originates from Na(v)1.6 sodium channels. Here we used a mouse mutant lacking Na(v)1.6 to explore the contribution of these channels to resurgent, transient, and persistent components of TTX-sensitive sodium current in STN neurons. The resurgent current of STN neurons from Na(v)1.6(-/-) mice was reduced by 63% relative to wild-type littermates, a less dramatic reduction than that observed in Purkinje neurons recorded under identical conditions. The transient and persistent currents of Na(v)1.6(-/-) STN neurons were reduced by approximately 40 and 55%, respectively. The resurgent current present in Na(v)1.6(-/-) null STN neurons was similar in voltage dependence to that in wild-type STN and Purkinje neurons, differing only in having somewhat slower decay kinetics. These results show that sodium channels other than Na(v)1.6 can make resurgent sodium current much like that from Na(v)1.6 channels.