Slow inactivation of tetrodotoxin-insensitive Na+ channels in neurons of rat dorsal root ganglia

Summary Whole-cell patch-clamp experiments were performed with neurons cultured from rat dorsal root ganglia (DRG). Two types of Na⁺ currents were identified on the basis of sensitivity to tetrodotoxin. One type was blocked by 0.1 nm tetrodotoxin, while the other type was insensitive to 10 m tetrodotoxin. The peak amplitude of the tetrodotoxin-insensitive Na⁺ current gradually decreased after depolarization of the membrane. The steady-state value of the peak amplitude was attained several minutes after the change of holding potential. Such a slow inactivation was not observed in tetrodotoxin-sensitive Na⁺ current. The slow inactivation of the tetrodotoxin-insensitive Na⁺ current was kinetically distinct from the ordinary short-time steady-state inactivation. The voltage dependence of the slow inactivation could be described by a sigmoidal function, and its time course had a double-exponential process. A decrease of external pH partially antagonized the slow inactivation, probably through an increased diffusion potential across the membrane. However, the slow inactivation was not due to change in surface negative charges, since a shift of the kinetic parameters along the voltage axis was not observed during the slow inactivation. Due to the slow inactivation, the inactivation curves for the tetrodotoxininsensitive Na⁺ current were shifted in the negative direction as the prepulse duration was increased. Consequently, the window current activated at potentials close to the resting membrane potential was markedly reduced. Thus, the slow inactivation may be involved in the long-term regulation of the excitability of sensory neurons.We thank Prof. Hirosi Kuriyama for his support and advice and Dr. M. Yoshii for helpful discussions. This study was supported by the Japanese Ministry of Education (Scientific Research 02670090).     

The regulation of presenilin-1 by nerve growth factor

Presenilin-1 (PS1) protein concentration is linked to neuronal development and to the pathogenesis of Alzheimer's disease, yet little is known about the biological factors and mechanisms that control cellular levels of PS1 protein. As PS1 levels are highest in the developing brain, we tested whether neurotrophin-induced differentiation influences PS1 expression using neuronotypic pheochromocytoma (PC12) cells. Treatment of PC12 cells with nerve growth factor (NGF) caused approximately 60-75% increases in the steady-state levels of endogenous PS1 N- and C-terminal fragments. PS1 protein accumulation was dose-responsive to NGF and required the presence of the TrkA NGF receptor tyrosine kinase. NGF also induced PS1 fragment accumulation in cultured explants of rat dorsal root ganglia. Quantitative northern blot analysis using PC12 cultures indicated that NGF did not increase steady-state PS1 mRNA levels. However, pulse-chase experiments indicated that NGF slowed the degradation rate of endogenous PS1 fragments, increasing the half-life from t(1/2) @22.5 to @25.0 h. This increase in half-life was insufficient to account for the approximately 60-75% increase in PS1 fragment levels measured in NGF-treated cells. Thus, NGF may regulate PS1 protein concentration in NGF-responsive cells by a complex mechanism that increases PS1 fragment production independent of holoprotein synthesis.     

Difference of sodium currents between pediatric and adult human atrial myocytes: evidence for developmental changes of sodium channels

Voltage-gated calcium currents and potassium currents were shown to undergo developmental changes in postnatal human and animal cardiomocytes. However, so far, there is no evidence whether sodium currents also presented the developmental changes in postnatal human atrial cells. The aim of this study was to observe age-related changes of sodium currents between pediatric and adult atrial myocytes. Human atrial myocytes were acutely isolated and the whole-cell patch clamp technique was used to record sodium currents isolated from pediatric and adult atrial cardiomocytes. The peak amplitude of sodium currents recorded in adult atrial cells was significantly larger than that in pediatric atrial myocytes. However, there was no significant difference of the activation voltage for peak sodium currents between two kinds of atrial myocytes. The time constants for the activation and inactivation of sodium currents were smaller in adult atria than pediatric atria. The further study revealed that the voltage-dependent inactivation of sodium currents were more slow in adult atrial cardiomyocytes than pediatric atrial cells. A significant difference was also observed in the recovery process of sodium channel from inactivation. In summary, a few significant differences were demonstrated in sodium currents characteristics between pediatric and adult atrial myocytes, which indicates that sodium currents in human atria also undergo developmental changes.     

Modulation of the neuronal binding of the beta subunit of nerve growth factor (NGF) by the alpha-NGF subunit

The effect of the alpha subunit of the 7S-NGF on the binding of beta-NGF to its two classes of sites on target cells has been studied. The presence of microM concentrations of alpha-NGF causes the displacement of 125I-beta-NGF from one class of sites on dissociated dorsal root ganglia neurons from stage E9 chicken embryos. At 0.1 nM 125I-beta-NGF, increasing alpha-NGF concentrations produce a monotonic displacement curve with half-maximal displacement occurring at 10 microM alpha-NGF. The affinity and number of sites of the 125I-beta-NGF displaced by alpha-NGF are similar to those of beta-NGF that binds to the higher affinity (site I) receptors. The binding to the lower affinity class of sites (site II) is not affected by concentrations of alpha-NGF up to 30 microM. This modulation of 125I-beta-NGF binding does not occur with equivalent concentrations of serum albumin. No detectable neuronal binding of 125I-alpha-NGF was found, suggesting that the mechanism does not involve direct competition for receptor sites. The dissociation constant for the alpha-beta complex is in the microM range, and formation of this complex in solution can thus compete with the process of 125I-beta-NGF binding to neurons. A model accounting for these observations includes binding of the alpha-beta complex to the lower affinity but not to the higher affinity sites. We conclude that there are differences in the specificity of the two classes of receptors.     

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 altenate additional channel subunits. SkM2 mRNA expression was examined in newborn rat dorsal root ganglia (DRG) by RNase arotection 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.     

低浓度神经生长因子存在下GPI-1046刺激鸡胚神经节突起生长

对GPI-1046是否具有神经营养作用目前有两种不同的认识。Steiner等认为GPI-1046能促进体外培养的感觉神经节神经元突起生长。但Harper等却没能证明GPI-1046有这样的作用。由于GPI-1046在临床上具有重要应用价值和前景,我们重新评价了GPI-1046对体外培养鸡胚神经节的神经营养作用,发现在低浓度神经生长因子（nerve growth factor,NGF）存在下,GPI-1046能明显促进鸡背根神经节神经突起的生长。     

神经病理痛大鼠DRG神经元GABAA受体激活电流的变化

目的：观察坐骨神经慢性压榨损伤（CCI）致神经病理痛后,大鼠背根节神经元GABAA受体（γ-氨基丁酸A受体）激活电流的变化。方法：运用全细胞膜片钳技术记录CCI模型手术侧、手术对侧及假手术组大鼠背根神经节细胞GABAx受体激活电流,比较坐骨神经慢性压榨损伤后GABAA受体激活电流的变化。结果：①CCI模型组大鼠手术侧DRG神经元在不同浓度（0．1-1000μmol／L）GABAA受体激活电流幅值均显著小于假手术组。②CCI模型组大鼠手术对侧DRG神经元在不同浓度（0．01-1000μmol／L）GABAA受体激活电流幅值均显著大于手术同侧及假手术组。结论：在坐骨神经慢性压榨损伤的过程中,不仅损伤侧的DRG神经元GABAA受体激活电流显著减小,这种损伤同时还引起了手术对侧的DRG神经元GABA激活电流代偿性的增强,GABAA受体功能的改变导致的突触前抑制作用的减弱可能是神经病理痛产生的根本原因之一。     

小剂量芬太尼联合咪达唑仑对大鼠皮质神经元钠离子通道电流的影响

目的：观察小剂量芬太尼联合咪达唑仑对大鼠大脑皮层神经元细胞膜电压门控性钠离子通道电流的影响。方法：用膜片钳全细胞记录方式观察小剂量芬太尼联合咪达唑仑对原代培养的新生SD大鼠大脑皮层神经元钠离子通道电流的影响。实验分为空白组,即未用药组;芬太尼5μg/L（F5）组和芬太尼5μg/L＋咪达唑仑200μg/L（F5＋M200）组。结果：F5＋M200组平均最大电流密度为（-213.98±91.68）pA/pF,明显低于空白组（-267±115.36）pA/pF（n=5,P〈0.05）和F5组（-231.90±97.16）pA/pF（n=5,P〈0.05）。结论：小剂量芬太尼联合咪达唑仑对皮质神经元钠离子通道电流的抑制作用较单一芬太尼组具有增强效应,这可能是临床两种药物合用后镇静镇痛作用增强原因之一。     

Tyrosine kinase activity of nerve growth factor and estrogen in embryonic septal neurons cultured from the rat

Alzheimer's disease (AD) is a neurodegenerative disease characterized by dementia, senile plaques, fibrillary tangles, and a reduction of cholinergic neurons in the septal nucleus of the brain. Nerve growth factor (NGF) and estrogen were studied to observe effects on tyrosine kinase activity in septal neurons. The time course of tyrosine kinase activation and number of cells in which tyrosine kinase was activated were measured. Tissue from embryonic day 16 rats was microdissected and the septal neurons obtained were treated with estrogen (10 M) or NGF (100 ng/mL) at intervals of 1, 2, 3, 4, 5, or 10 min. Immunostaining for phosphotyrosine revealed that cells treated with NGF showed an increase in phosphotyrosine activity within 2-4 min followed by a decline to control levels of enzyme activity. Treatment with estrogen led to an increase in phosphotyrosine immunostaining within 2-3 min followed by a decline to control levels. This time course suggests a mechanism for estrogen activity other than the traditional method involving binding to nuclear receptors followed by protein synthesis.     

NO-cGMP mediated galanin expression in NGF-deprived or axotomized sensory neurons

Leukaemia inhibitory factor (LIF) and nerve growth factor (NGF) are well characterized regulators of galanin expression. However, LIF knockout mice containing the rat galanin 5' proximal promoter fragment (- 2546 to + 15 bp) driving luciferase responded to axotomy in the same way as control mice. Also, LIF had no effect on reporter gene expression in vitro, neither in the presence or absence of NGF, suggesting that other factors mediate an axotomy response from the galanin promoter. We then addressed the role of nitric oxide (NO) using NGF-deprived rat dorsal root ganglion (DRG) neuron cultures infected with viral vectors containing the above-mentioned construct, and also studied endogenous galanin expression in axotomized DRG in vivo. Blocking endogenous NO in NGF-deprived DRG cultures suppressed galanin promoter activity. Consistent with this, axotomized/NGF-deprived DRG neurons expressed high levels of neuronal NO synthase (nNOS) and galanin. Further, using pharmacological NOS blockers, or adenoviral vectors expressing dominant-negative either for nNOS or soluble guanylate cyclase in vivo and in vitro, we show that the NO-cGMP pathway induces endogenous galanin in DRG neurons. We propose that both LIF and NO, acting at different promoter regions, are important for the up-regulation of galanin, and for DRG neuron survival and regeneration after axotomy.     

The history of the discovery of the nerve growth factor

The Nerve Growth Factor (NGF) is the progenitor of a family of growth factors which is still expanding. The history of its discovery is very colorful; it is a rare combination of scientific reasoning, intuition, fortuities, and good luck. In addition, I believe that the collaboration of three scientists with very different backgrounds contributed to the success: I had grown up in a laboratory of experimental embryology, Dr. Levi-Montalcini came from neurology, and Dr. Stanley Cohen was from biochemistry. The decision where to begin the history of a discovery is always arbitrary. I shall give my reasons why I begin this story with my wing bud extirpations on chick embryos and the analysis of the effects of the operation on the development of spinal nerve centers, published in 1934. Of course, I am aware of the fact that the analysis of neurogenesis had been pioneered by Dr. R. G. Harrison and his students at Yale University since the beginning of this century. It should be mentioned that their experiments had been done on amphibian embryos. My own interest in problems of neurogenesis dates back to my Ph.D. thesis in the Zoology Department of Professor H. Spemann at the University of Freiburg in (the Federal Republic of) Germany; it dealt with the influence of the nervous system on the development of limbs in frog embryos. After I had obtained some inconclusive results I did the crucial experiment of producing nerveless legs. I removed the lumbar part of the spinal cord and the spinal ganglia before the outgrowth of nerve fibers. The nerveless legs developed normally in every respect, but the muscles atrophied eventually.     

Voltage-gated currents and firing properties of embryonic Drosophila neurons grown in a chemically defined medium

This study reports the composition of a chemically defined medium (DDM1) that supports the survival and differentiation of neurons in dissociated cell cultures prepared from midgastrula stage Drosophila embryos. Cells with neuronal morphology that stain with a neural-specific marker are clearly differentiated by 1 day in vitro and can be maintained in culture for up to 2 weeks. Although the whole cell capacitance measurements from neurons grown in DDM1 were 5- to 10-fold larger than those of neurons grown in a conventional serum-supplemented medium, the potassium current densities were similar in the two growth conditions. A small but significant increase in the sodium current density was observed in the neurons grown in DDM1 compared with those in serum-supplemented medium. The majority of neurons grown in DDM1 fired either single or trains of action potentials in response to injection of depolarizing current. Contributing to the observed heterogeneity in the firing properties between individual neurons grown in DDM1 was heterogeneity in the levels of expression and gating properties of voltage-dependent sodium, calcium, and pottassium currents. The ability of embryonic Drosophila neurons to differentiate in a chemically defined medium and the fact that they are amenable to both voltage-clamp and current-clamp analysis makes this system well suited to studies aimed at understanding the mechanisms regulating expression of ion channels involved in electrical excitability. © 1995 John Wiley & Sons, Inc.     

Commercial recombinant human beta-nerve growth factor and adult rat dorsal root ganglia contain an identical molecular species of nerve growth factor prohormone

Examination of commercial recombinant human beta-nerve growth factor (rh-beta-NGF) preparations with polyclonal antibodies specific to 13-kDa NGF and pro-NGF-specific domains revealed the presence of high-molecular-mass immunoreactive proteins, including a 60-kDa NGF prohormone. On incubation with a mixture of N- and O-specific glycosidases, the 60-kDa NGF pro-hormone generated a 32-kDa protein corresponding to the molecular size of NGF precursor predicted by the cloned human NGF cDNA. Highly sensitive chemiluminescence immunoblot analysis of adult rat dorsal root ganglia, spinal cord, and colon tissues with NGF- and pro-NGF domain-specific antibodies also revealed the presence of high-molecular-mass proteins, including the 60-kDa NGF prohormone. Based on the presence of the 60-kDa NGF prohormone in dorsal root ganglia and its efferent tissues, we suggest that proteolytically unprocessed, glycosylated NGF prohormone may mediate interactions between neurons and the tissues they innervate.     

Localization of basic fibroblast growth factor in a subpopulation of rat sensory neurons

Summary The distribution of basic fibroblast growth factor (bFGF)-immunoreactivity (IR) was studied in rat sensory and autonomic ganglia. In postnatal and adult sympathetic superior cervical ganglia and in adult parasympathetic otic ganglia no bFGF-staining was found. Postnatal and adult neural crest-and placode-derived sensory ganglia displayed intensive bFGF-IR in a neuronal subpopulation. This subpopulation was characterized by use of consecutive sections of adult dorsal root ganglia stained with antibodies against substance P, somatostatin, bombesin, and bFGF. Basic FGF was colocalized with the somatostatin/bombesin subpopulation but not with substance P.     

Target specificity and size of avian sensory neurons supported in vitro by nerve growth factor,brain-derived neurotrophic factor,and neurotrophin-3

To obtain insight into which subpopulations of sensory neurons in dorsal root ganglia are supported by different neurotrophins, we retrogradely labeled cutaneous and muscle afferents in embryonic day 9 chick embryos and followed their survival in neuron-enriched cultures supplemented with either nerve growth factor (NGF), brain-derived neurotrophic factor (BDNF), or neurotrophin-3 (NT-3). We found that NGF is a wide survival factor for subpopulations of both cutaneous and muscle afferents, whereas the survival effects of BDNF and NT-3 are restricted primarily to muscle afferents. We also measured soma size in each neurotrophic factor. These new data show that BDNF- and NT-3–dependent cells appear to be a mixture of two populations of neurons: one small diameter and the other large diameter. In contrast, based on size alone, NGF-dependent cells appear to be a single population of only small-diameter neurons. Thus, BDNF and NT-3 may have some new, previously unreported effects on small-diameter afferent neurons. © 1994 John Wiley & Sons, Inc. 1994 John Wiley & Sons, Inc.     

Different roles for aspartates and glutamates for cation permeation in bacterial sodium channels

A key driving force for ion channel selectivity is represented by the negative charge of the Selectivity Filter carried by aspartate (D) and glutamate (E) residues. However, the structural effects and specific properties of D and E residues have not been extensively studied. In order to investigate this issue we studied the mutants of NaChBac channel with all possible combinations of D and E in the charged rings in position 191 and 192. Electrophysiological measurements showed significant Ca²⁺ currents only when position 191 was occupied by E. Equilibrium Molecular Dynamics simulations revealed the existence of two binding sites, corresponding to the charged rings and another one, more internal, at the level of L190. The simulations showed that the ion in the innermost site can interact with the residue in position 191 only when this is glutamate. Based on the MD simulations, we suggest that a D in position 191 leads to a high affinity Ca²⁺ block site resulting from a significant drop in the free energy of binding for an ion moving between the binding sites; in contrast, the free energy change is more gradual when an E residue occupies position 191, resulting in Ca²⁺ permeability. This scenario is consistent with the model of ion channel selectivity through stepwise changes in binding affinity proposed by Dang and McCleskey. Our study also highlights the importance of the structure of the selectivity filter which should contribute to the development of more detailed physical models for ion channel selectivity.     

尿素对小鼠体表心电图和心室肌细胞钠离子通道电流的影响

目的：观察尿素对小鼠体表心电图和心室肌细胞钠离子通道电流的影响。方法：使用常规的心电图记录方法和膜片钳实验技术,分别记录小鼠体表心电图和心室肌细胞钠离子通道电流。结果：尿素可以使小鼠心率明显减慢（P〈0．01）,呈浓度依赖性,低、中、高三个剂量组的心率分别由给药前的（612±27、615±23、619±26）b·min^-1下降到给药后的（556±29、469±37、378±48）b·min^-1,并且中、高剂量组发生了不同程度的传导阻滞性心律失常;尿素对小鼠心室肌细胞钠电流有明显的抑制作用（P〈0．05）,钠电流分别由给药前的（8．76±0．91、8．87±1．01、8．77±0．96）nA降低到给药后的（7．32±0．68、5．69±0．64、4．58±0．57）nA,呈浓度依赖性。结论：尿素可以通过抑制心室肌细胞钠电流使小鼠发生传导阻滞性心律失常。     

Induction of tyrosine hydroxlase synthesis in rat superior cervical ganglia in vitro by nerve growth factor and dexamethasone.

The addition of dexamethasone and nerve growth factor to organ cultures of superior cervical ganglia from young rats induces the synthesis of tyrosine hydroxylase. The combination of nerve growth factor and dexamethasone $\text{in vitro}$ produces a differential rate of tyrosine hydroxylase synthesis which approaches that obtained by the $\text{in vivo}$ administration of nerve growth factor.     

Activation of M3 muscarinic receptors inhibits T-type Ca(2+) channel currents via pertussis toxin-sensitive novel protein kinase C pathway in small dorsal root ganglion neurons

Cobrotoxin (CbT), a short-chain postsynaptic α-neurotoxin, has been reported to play a role in analgesia. However, to date, the detailed mechanisms still remain unknown. In the present study, we identify a novel functional role of CbT in modulating T-type Ca²⁺ channel currents (T-currents) in small dorsal root ganglia (DRG) neurons as well as pain behaviors in mice. We found that CbT inhibited T-currents in a dose-dependent manner. CbT at 1 μM reversibly inhibited T-currents by ~ 26.3%. This inhibitory effect was abolished by the non-selective muscarinic acetylcholine receptor (mAChR) antagonist atropine, or the selective M3 mAChR antagonist 4-DAMP, while naloxone, an opioid receptor antagonist had no effect. Intracellular infusion of GDP-β-S or pretreatment of the cells with pertussis toxin (PTX) completely blocked the inhibitory effects of CbT. Using depolarizing prepulse, we found the absence of direct binding between G-protein βγ subunits and T-type Ca²⁺ channels in CbT-induced T-current inhibition. CbT responses were abolished by the phospholipase C inhibitor U73122 (but not the inactive analog U73343). The classical and novel protein kinase C (nPKC) antagonist chelerythrine chlorid or GF109203X abolished CbT responses, whereas the classical PKC antagonist Ro31-8820 or inhibition of PKA elicited no such effects. Intrathecal administration of CbT (5 μg/kg) produced antinociceptive effects in mechanical, thermal, and inflammatory pain models. Moreover, CbT-induced antinociception could be abrogated by 4-DAMP. Taken together, these results suggest that CbT acting through M3 mAChR inhibits T-currents via a PTX-sensitive nPKC pathway in small DRG neurons, which could contribute to its analgesic effects in mice.