A heart-like Na+ current in the medial entorhinal cortex

Measurement of intracellular free zinc in living neurons

Excessive Zn2+ influx has been implicated in the pathogenesis of neuronal death after global ischemia or prolonged seizures, but little is presently known about cellular regulation of intracellular free Zn2+ ([Zn2+]i). In large part, this is because the tools currently available for measuring [Zn2+]i are limited in comparison to those available for measuring [Ca2+]i or other ions. We outline here approaches to this task that have been taken in the past, and summarize our recent experience using mag-fura-5 to measure [Zn2+]i in living cortical neurons exposed to toxic levels of extracellular Zn2+.

Differential expression of sodium channel genes in retinal ganglion cells

Action potential electrogenesis in the axons of retinal ganglion cells is supported by voltage-gated sodium channels, and a tetrodotoxin (TTX)-inhibitable sodium conductance participates in anoxic injury of these axons within the optic nerve. However, the subtypes of sodium channels expressed in retinal ganglion cells have not been identified. In this study, we used reverse transcription-polymerase chain reaction (RT-PCR) and restriction enzyme mapping, together with in situ hybridization, to examine the expression of transcripts for sodium channel alpha-subunits I, II, III, NaG, Na6, hNE/PN1 and SNS, and beta-subunits 1 and 2, in the retina of the adult rat. RT-PCR yielded high levels of amplification of I, II, III, Na6, beta1 and beta2 transcripts. In situ hybridization demonstrated the presence of all these mRNAs in the cell bodies of retinal ganglion cells. Retinal ganglion cells thus express multiple sodium channel mRNAs, suggesting that they deploy several different types of sodium channels.

Cloning and characterization of a mouse sensory neuron tetrodotoxin-resistant voltage-gated sodium channel gene, Scn10a

Small-diameter sensory neurons associated with unmyelinated axons express a tetrodotoxin-insensitive (TTXi) voltage-gated sodium channel (VGSC) that may play an important role in the transmission of nociceptive information to the spinal cord. A TTXi VGSC, named SNS, that accounts for the tetrodotoxin-resistant sodium current described in sensory neurons has been cloned from rat dorsal root ganglia. Using recombinant lambda phage clones encoding a mouse 129/SV genomic library, we have determined the detailed structure of the mouse SNS gene (Scn10a), including the location of exon-intron boundaries and the nucleotide sequence of the exons. The gene consists of 27 exons spanning approximately 90 kb on chromosome 9. Mouse SNS shows 95.3% overall amino acid identity to rat SNS and 98.5% identity throughout the putative transmembrane segments and the intracellular loop linking domains 3 and 4. The sizes of the exons and the exon-intron junction positions of the mouse SNS and the human skeletal muscle VGSC genes are remarkably conserved. These results provide the basis for an evolutionary comparison of sodium channels, the construction and analysis of a mouse SNS null mutant as a direct approach to understanding the biological function of SNS, and the identification of regulatory elements that are responsible for the tissue- and cell-specific expression of SNS.

Isolation and culture of adult rat hippocampal neurons

Inability to culture adult central neurons and the failure of injured neurons to regenerate in the brain could be due to genetic controls or environmental inhibitors. We tested the environmental inhibitor hypothesis by attempting to regenerate adult rat neurons in B27/Neurobasal culture medium, a medium optimized for survival of embryonic neurons. To isolate neurons from their numerous connections, papain was the best of six different proteases screened on slices of hippocampus for survival of isolated cells after 4 days of culture. Use of a density gradient enabled separation of oligodendroglia and some enrichment of neurons and microglia from considerable debris which was inhibitory to sprouting and viability. With these techniques, about 900000 viable neurons were isolated from each hippocampus of any age rat from birth to 24-36 months, near the median mortality. FGF2 was found to enhance viability at least 3-fold to 40-80%, independent of age, without affecting the length of the processes. Neurons were cultured for more than 3 weeks. These methods demonstrate that hippocampal neurons can regenerate axons and dendrites if provided with adequate nutrition and if inhibitors are removed. They also will enable aging studies. Therefore, the concept of environmental growth restriction may be more appropriate for neurons in the brain than the concept of a genetic block that precludes regeneration of processes.

TTX-sensitive and -resistant Na+ currents, and mRNA for the TTX-resistant rH1 channel, are expressed in B104 neuroblastoma cells

To examine the molecular basis for membrane excitability in a neuroblastoma cell line, we used whole cell patch-clamp methods and reverse transcription-polymerase chain reaction (RT-PCR) to study Na+ currents and channels in B104 cells. We distinguished Tetrodotoxin (TTX)-sensitive and -resistant Na+ currents and detected the mRNA for the cardiac rH1 channel in B104 cells. Na+ currents could be recorded in 65% of cells. In the absence of TTX, mean peak Na+ current density was 126 +/- 19 pA/pF, corresponding to a channel density of 2.7 +/- 0.4/micron 2 (mean +/- SE). Time-to-peak (t-peak), activation (tau m), and inactivation time constants (tau h) for Na+ currents in B104 cells were 1.0 +/- 0.04, 0.4 +/- 0.06, and 0.9 +/- 0.04 ms at -10 mV. The peak conductance-voltage relationship had a V 1/2 of -39.8 +/- 1.5 mV. V 1/2 for steady-state inactivation was -81.6 +/- 1.5 mV. TTX-sensitive and -resistant components of the Na current had half-maximal inhibitions (IC50), respectively, of 1.2 nM and, minimally, 575.5 nM. The TTX-sensitive and -resistant Na+ currents were kinetically distinct; time-to-peak, tau m, and tau h for TTX-sensitive currents were shorter than for TTX-resistant currents. Steady-state voltage dependence of the two currents was indistinguishable. The presence of TTX-sensitive and -resistant Na+ currents, which are pharmacologically and kinetically distinct, led us to search for mRNAs known to be associated with TTX-resistant channels, in addition to the alpha subunit mRNAs, which have previously been shown to be expressed in these cells. Using RT-PCR and restriction enzyme mapping, we were unable to detect alpha SNS, but detected mRNA for rH1, which is known to encode a TTX-resistant channel, in B104 cells. B104 neuroblastoma cells thus express TTX-sensitive and -resistant Na+ currents. These appear to be encoded by neuronal-type and cardiac Na+ channel mRNAs including the RH1 transcript. This cell line may be useful for studies on the rH1 channel, which is known to be mutated in the long-QT syndrome.

Potassium currents in acutely isolated neurons from superficial and deep layers of the juvenile rat entorhinal cortex

Using the whole-cell configuration of the patch-clamp technique, outward K+ currents were recorded from acutely isolated stellate cells from superficial layers, and pyramidal cells from deep layers, of the entorhinal cortex of juvenile rats. In both cell types a fast transient and a slowly inactivating outward K+ current were obtained. Whereas the fast transient current (IA) activated at potentials beyond -50 mV, the activation threshold of the slowly inactivating current (IK) was measured at -40 mV in stellate and pyramidal cells. In stellate cells a half-maximal inactivation was estimated for IA at -80.4 mV and for IK at -74.6 mV, and in pyramidal cells at -81.1 mV and -71.8 mV, respectively. IK of both cell types were reduced by tetraethylammonium (TEA) in a concentration-dependent manner. IC50 values were 0.8 mM TEA for stellate cells and 1.1 mM TEA for pyramidal cells. Superfusion of 4-aminopyridine resulted in a reduction of the amplitudes of IA and IK as well as in an acceleration of the inactivation time constants of IA. Extracellularly applied dendrotoxin did not have any effect on entorhinal cortex K+ currents. In summary, kinetic and pharmacological properties of IA as well as of IK are rather similar in superficial-layer stellate and deep-layer pyramidal cells acutely isolated from the entorhinal cortex of juvenile rats.

Structure and function of a novel voltage-gated, tetrodotoxin-resistant sodium channel specific to sensory neurons

Small neurons of the dorsal root ganglia (DRG) are known to play an important role in nociceptive mechanisms. These neurons express two types of sodium current, which differ in their inactivation kinetics and sensitivity to tetrodotoxin. Here, we report the cloning of the alpha-subunit of a novel, voltage-gated sodium channel (PN3) from rat DRG. Functional expression in Xenopus oocytes showed that PN3 is a voltage-gated sodium channel with a depolarized activation potential, slow inactivation kinetics, and resistance to high concentrations of tetrodotoxin. In situ hybridization to rat DRG indicated that PN3 is expressed primarily in small sensory neurons of the peripheral nervous system.

A novel tetrodotoxin-resistant sodium current from an immortalized neuroepithelial cell line

1. Voltage-gated ionic currents were recorded from cells of an immortalized neuroepithelial cell line named V1. The cell line was produced by insertion of the temperature-sensitive tsA58 allele of the SV40 large T-antigen into embryonic day 14 mouse hypothalamic cells. V1 cells display a mixed immature neural-glial phenotype and have two phenotypes, round and flat. 2. Recordings from round V1 cells demonstrate voltage-gated Na+ and K+ currents (n = 297), while no voltage-gated currents were observed in flat V1 cells (n = 45). Voltage-gated currents were recorded from cells cultured at both permissive and restrictive temperatures. 3. Internal Cs+ and external tetraethylammonium (TEA) were used to suppress outward currents. The remaining inward current has rapid activation and inactivation time constants which decreased as the test potential increased. In different cells, the amplitude of the peak inward current varied from about 50 pA to as large as 4500 pA (in 120 mM external Na+). The reversal potential for the inward current was close to the predicted Nernst equilibrium potential for Na+. Both the magnitude and reversal potential of the inward current were dependent on the external Na+ concentration. It is therefore considered to be a Na+ current, INa. 4. INa was found to be TTX resistant. About 5% of the INa was blocked by 200 nM TTX and 20 microM TTX fully suppressed the Na+ current. The apparent Kd for TTX blockade was estimated to be 1.49 microM. 5. The activation kinetics of INa could be described by a Hodgkin-Huxley model with an m3 variable. The time constants of activation and inactivation of INa are fast, similar to those of the TTX-resistant and TTX-sensitive Na+ currents in central nervous system neurons and glial cells. 6. The divalent and trivalent cations Cd2+, Co2+, Ni2+, Zn2+ and La3+ shifted the activation of INa to more positive potentials and decreased the maximal conductance in a dose-dependent manner. The apparent Kd values for blockade of the INa by Cd2+, Co2+, Ni2+, Zn2+ and La3+ were 430, 3500, 1900, 83 and 202 microM, respectively. 7. The addition of phorbol myristate acetate, an activator of protein kinase C, consistently produced a reduction in the amplitudeof INa without affecting the time course of activation or inactivation. 8. INa in V1 cells expresses a unique combination of voltage and time kinetics and sensitivity to blockade by TTX and cations. We hypothesize that this Na+ current may be expressed transiently during development of the central nervous system at the stage of development represented by the V1 cell line.

Single-channel analysis of two types of Na+ currents in rat dorsal root ganglia

The properties of voltage-gated Na+ channels were studied in neurones isolated from rat dorsal root ganglia using the outside-out configuration of the patch-clamp technique. Two types of single-channel currents were identified from the difference in unit amplitudes. Neither type was evoked in the medium in which extracellular Na+ ions were replaced by an equimolar amount of tetramethylammonium ions. The two types of single-channel currents differed in their sensitivity to tetrodotoxin (TTX). The smaller channel current was insensitive to 1 microM TTX (referred to as TTX-I), while the larger channel current was blocked by 1 nM TTX (TTX-S). The unit amplitudes measured during a step depolarization to -30 mV (1.4 mM internal and 250 mM external Na+ concentrations) were 1.16 pA for TTX-S and 0.57 pA for TTX-I, respectively. The slope conductance measured at -30 mV was 16.3 pS for TTX-S and 8.5 pS for TTX-I. TTX-S could be activated by step depolarizations positive to -60 mV, while TTX-I could be activated at potentials positive to -40 mV. When the test pulse was preceded by a depolarizing prepulse, the prepulse positive to -50 mV preferentially inactivated TTX-S with a minimal effect on TTX-I. Activation and inactivation time courses of the averaged ensemble currents computed from TTX-S showed remarkable resemblances to the time courses of the macroscopic TTX-sensitive Na+ current. Similarly, the ensemble currents of TTX-I mimicked the macroscopic TTX-insensitive Na+ current. It was concluded that the two types of Na+ channels in rat dorsal root ganglia differ not only in their sensitivity to TTX, but also in their single-channel conductances.

A bifurcation analysis of neuronal subthreshold oscillations

The conditions under which a noninactivating sodium current and either a potassium current or an inwardly rectifying cation current can generate subthreshold oscillations were analyzed using nonlinear dynamical techniques applied to a neuronal model consisting of two differential equations. Mathematical descriptions of the membrane currents were derived using voltage-clamp data collected from entorhinal cortical neurons. A bifurcation analysis was performed using applied current as the control parameter to map the range of magnitudes of the sodium, potassium/cation, and leakage conductances over which subthreshold oscillations exist. The threshold of the potassium/cation current was an important determinant of the robustness of oscillatory behavior. The activation time constant of the potassium/cation current largely determined the frequency range of emergent oscillations. This result implicates the slow inward rectifier or an as yet undescribed slow outward current in entorhinal cortical oscillations; the latter explanation, while more speculative, is more consistent with the pharmacological properties of subthreshold oscillations and gives oscillations over a larger current range. The shallowness of the sodium activation curve confined emergent oscillations to rise gradually rather than abruptly and extended the current range over which the model oscillated.

The tetrodotoxin-insensitive sodium current in rat dorsal root ganglia is unlikely to involve the expression of the tetrodotoxin-resistant sodium channel, SkM2

Tetrodotoxin-insensitive (TTX-I) sodium currents have been recorded from newborn and adult rat sensory neurons, but the sodium channel gene(s) responsible for the TTX-I current are unknown. Because SkM2, one of six voltage-sensitive sodium channel genes cloned from rat, encodes the only cloned channel that is relatively resistant to tetrodotoxin, we sought to test whether the TTX-I current in rat sensory neurons is due to the SkM2 channel. We hypothesized that the TTX-I current might be generated from (1) an RNA splicing variant of SkM2, (2) post-translational modification of the SkM2 protein, or (3) interaction with alternate additional channel subunits. SkM2 mRNA expression was examined in newborn rat dorsal root ganglia (DRG) by RNase protection assay. No SkM2 expression was detected. Therefore, we conclude that the TTX-I sodium current in DRG is unlikely to result from the expression of the SkM2 gene.

Differential effects of sulfhydryl reagents on saxitoxin and tetrodotoxin block of voltage-dependent Na channels

We have probed a cysteine residue that confers resistance to tetrodotoxin (TTX) block in heart Na channels, with membrane-impermeant, cysteine-specific, methanethiosulfonate (MTS) analogs. Covalent addition of a positively charged group to the cysteinyl sulfhydryl reduced pore conductance by 87%. The effect was selectively prevented by treatment with TTX, but not saxitoxin (STX). Addition of a negatively charged group selectively inhibited STX block without affecting TTX block. These results agree with models that place an exposed cysteinyl sulfhydryl in the TTX site adjacent to the mouth of the pore, but do not support the contention that STX and TTX are interchangeable. The surprising differences between the two toxins are consistent with the hypothesis that the toxin-receptor complex can assume different conformations when STX or TTX bound.

Tetrodotoxin-resistant sodium channels

1. Tetrodotoxin (TTX) has been widely used as a chemical tool for blocking Na+ channels. However, reports are accumulating that some Na+ channels are resistant to TTX in various tissues and in different animal species. Studying the sensitivity of Na+ channels to TTX may provide us with an insight into the evolution of Na+ channels. 2. Na+ channels present in TTX-carrying animals such as pufferfish and some types of shellfish, frogs, salamanders, octopuses, etc., are resistant to TTX. 3. Denervation converts TTX-sensitive Na+ channels to TTX-resistant ones in skeletal muscle cells, i.e., reverting-back phenomenon. Also, undifferentiated skeletal muscle cells contain TTX-resistant Na+ channels. Cardiac muscle cells and some types of smooth muscle cells are considerably insensitive to TTX. 4. TTX-resistant Na+ channels have been found in cell bodies of many peripheral nervous system (PNS) neurons in both immature and mature animals. However, TTX-resistant Na+ channels have been reported in only a few types of central nervous system (CNS). Axons of PNS and CNS neurons are sensitive to TTX. However, some glial cells have TTX-resistant Na+ channels. 5. Properties of TTX-sensitive and TTX-resistant Na+ channels are different. Like Ca2+ channels, TTX-resistant Na+ channels can be blocked by inorganic (Co2+, Mn2+, Ni2+, Cd2+, Zn2+, La3+) and organic (D-600) Ca2+ channel blockers. Usually, TTX-resistant Na+ channels show smaller single-channel conductance, slower kinetics, and a more positive current-voltage relation than TTX-sensitive ones. 6. Molecular aspects of the TTX-resistant Na+ channel have been described. The structure of the channel has been revealed, and changing its amino acid(s) alters the sensitivity of the Na+ channel to TTX. 7. TTX-sensitive Na+ channels seem to be used preferentially in differentiated cells and in higher animals instead of TTX-resistant Na+ channels for rapid and effective processing of information. 8. Possible evolution courses for Na+ and Ca2+ channels are discussed with regard to ontogenesis and phylogenesis.