A single pulse of nerve growth factor triggers long-term neuronal excitability through sodium channel gene induction

The continuous presence of nerve growth factor (NGF) is thought to be required for the elaboration of neuronal-like traits in PC12 cells. Surprisingly, we find that a 1 min exposure to NGF is sufficient to engage a longer-term genetic program leading to the acquisition of membrane excitability. Whereas continuous exposure to NGF causes the induction of a family of sodium channels, the effect of a brief exposure is to induce selectively expression of the peripheral nerve-type sodium channel gene PN1, through a distinct signaling pathway requiring immediate-early genes. A 1 min exposure of PC12 cells to interferon-gamma also causes PN1 gene induction, suggesting that the "triggered" NGF and interferon-gamma signaling pathways share common molecular intermediates.     

Distribution of the tetrodotoxin-resistant sodium channel PN3 in rat sensory neurons in normal and neuropathic conditions

The novel sodium channel PN3/alpha-SNS, which was cloned from a rat dorsal root ganglion (DRG) cDNA library, is expressed predominantly in small sensory neurons and may contribute to the tetrodotoxin-resistant (TTXR) sodium current that is believed to be associated with central sensitization in chronic neuropathic pain states. To assess further the role of PN3, we have used electrophysiological, in situ hybridization and immunohistochemical methods to monitor changes in TTXR sodium current and the distribution of PN3 in normal and peripheral nerve-injured rats. (1) Whole-cell patch-clamp recordings showed that there were no significant changes in the TTXR and TTX-sensitive sodium current densities of small DRG neurons after chronic constriction injury (CCI) of the sciatic nerve. (2) Additionally, in situ hybridization showed that there was no change in the expression of PN3 mRNA in the DRG up to 14 d after CCI. PN3 mRNA was not detected in sections of brain and spinal cord taken from either normal or nerve-injured rats. (3) In contrast, immunohistochemical studies showed that major changes in the subcellular distribution of PN3 protein were caused by either CCI or complete transection of the sciatic nerve. The intensity of PN3 immunolabeling decreased in small DRG neurons and increased in sciatic nerve axons at the site of injury. The alteration in immunolabeling was attributed to translocation of presynthesized, intracellularly located PN3 protein from neuronal somata to peripheral axons, with subsequent accumulation at the site of injury. The specific subcellular redistribution of PN3 after peripheral nerve injury may be an important factor in establishing peripheral nerve hyperexcitability and resultant neuropathic pain.     

Excitability changes of terminal arborizations of single Ia and Ib afferent fibers produced by muscle and cutaneous conditioning volleys

1. In cats anesthetized with sodium pentobarbital, recordings were made from dorsal root ganglion (DRG) cells having a peripheral process in the gastrocnemius-soleus (GS) nerve. The GS nerve was left in continuity with the muscle to allow identification of group Ia and Ib fibers by responses of the receptors to muscle stretch and contraction. The central processes of the DRG cells were activated antidromically by stimulation within the spinal cord so that changes in the excitability of the fibers could be examined following conditioning volleys in muscle and cutaneous nerves. 2. Recordings were made from 44 DRG cells. Of these, 15 were group Ia and 9 group Ib afferents of the GS nerve. 3. Of 15 Ia fibers, 12 were activated antidromically by stimulation in the motor nucleus, but no Ib fibers were discharged by such stimulation. Ib fibers could be antidromically activated by stimulation in the intermediate nucleus. 4. The central processes of the Ia DRG cells had slower conduction velocities than did the peripheral processes. 5. The thresholds to electrical stimulation of the peripheral processes of Ia and Ib fibers of the GS nerve showed considerable overlap. 6. All of the Ia DRG cells tested showed an increased excitability following conditioning volleys in the biceps-semitendinosus (BST) nerve. The increase in excitability was produced by the largest fibers of the BST nerve. 7. Stimulation of the sural (SU) or superficial peroneal (SP) cutaneous nerves also increased the excitability of some Ia fibers. However, other Ia fibers were unaffected, and in two cases the excitability was reduced. 8. The excitability of group Ib fibers was increased by conditioning volleys in the BST, SU, or SP nerves. 9. It is concluded that cutaneous volleys produce a mixture of primary afferent depolarization and primary afferent hyperpolarization in Ia fibers of anesthetized cats. Such converse actions probably cancel in excitability tests using population responses. 10. The excitability of single Ia fibers is not stationary in excitability presumably reflect slow alterations within the central nervous system, perhaps related to spontaneous alterations in the level of tonically maintained primary afferent depolarization.     

Sodium channels accumulate at the tips of injured axons

The axolemmal distribution of voltage-gated sodium channels largely determines the regions of axonal electrical excitability. Using a well-characterized anti-sodium channel antibody, we examined peripheral nerve fibers focally injured by exposure to the neurotoxic agent, potassium tellurite (K2TeO3). Immunocytochemical and radioimmunoassay data showed a focal accumulation of sodium channels within the tips of injured axons. The major increase in sodium channel concentration occurred between 7 and 11 days after toxin exposure; however, immunocytochemically, excess sodium channels persisted in several axonal endings for a much longer time. The accumulation of sodium channels at injured axonal tips may be responsible, in part, for ectopic axonal excitability and the resulting abnormal sensory phenomena (especially pain and paresthesias) which frequently complicate peripheral nerve injury in humans.     

Neural-immune interactions--an evolutionary perspective

Efforts to understand how the immune system can influence nervous system function are hampered by the complexity of mammalian nervous and immune systems. The marine mollusc Aplysia californica has recently emerged as a useful model system to investigate cellular mechanisms underlying neural-immune interactions. Aplysia has a relatively simple, well-characterized nervous system that is accessible for intracellular recording. Moreover, it shares with mammals basic cellular defensive responses to non-self or wounded-self, i.e. the accumulation of numerous defense cells (hemocytes) around foreign objects or at injured sites. We have shown that the excitability of a population of nociceptive sensory neurons in Aplysia can be influenced by the presence of hemocytes close to their axons. These sensory neurons also show profound, long-lasting increases in their excitability following axonal injury. Hemocytes are attracted to injured sites on peripheral nerves, and we have developed an in vitro nervous system-hemocyte coculture system to demonstrate that hemocytes can also influence the expression of this injury-induced sensory hyperexcitability. Immunoreactive interleukin-1 (IL-1) and tumor necrosis factor have been identified in Aplysia. Preliminary in vitro studies showing that IL-1 can modulate the expression of injury-induced sensory hyperexcitability raise the interesting possibility that hemocyte-derived cytokine-like factors can modulate sensory neuron functioning. The relevance of this work to more phylogenetically advanced organisms is also discussed.     

Differential actions of pacific ciguatoxin-1 on sodium channel subtypes in mammalian sensory neurons

Pacific ciguatoxin-1 (P-CTX-1), is a highly lipophilic cyclic polyether molecule originating from the marine dinoflagellate Gambierdiscus toxicus. Its effects were investigated on sodium channel subtypes present in acutely dissociated rat dorsal root ganglion neurons, using whole-cell patch clamp techniques. Concentrations of P-CTX-1 ranging from 0.2 to 20 nM had no effect on the kinetics of tetrodotoxin-sensitive (TTX-S) or tetrodotoxin-resistant (TTX-R) sodium channel activation and inactivation, however, a concentration-dependent reduction in peak current amplitude occurred in both channel types. The main actions of 5 nM P-CTX-1 on TTX-S sodium channels were a 13-mV hyperpolarizing shift in the voltage dependence of sodium channel activation and a 22-mV hyperpolarizing shift in steady-state inactivation (hinfinity). In addition, P-CTX-1 caused a rapid rise in the membrane leakage current in cells expressing TTX-S sodium channels. This effect was blocked by 200 nM TTX, indicating an action mediated through TTX-S sodium channels. In contrast, the main action of P-CTX-1 (5 nM) on TTX-R sodium channels was a significant increase in the rate of recovery from sodium channel inactivation. These results indicate that P-CTX-1 acts to modify voltage-gated sodium channels present in peripheral sensory neurons consistent with its action to increase nerve excitability. This provides an explanation for the sensory neurological disturbances associated with ciguatera fish poisoning.     

Neuregulin expression in PNS neurons: isoforms and regulation by target interactions

Neuregulins have several important functions in the development of the peripheral nervous system, acting on both developing Schwann cells and muscle fibers. To determine whether these factors are also important for peripheral nerve regeneration, we have analyzed neuregulin expression in motor and sensory neurons by Northern blots and in situ hybridization. The results of this analysis show that the predominant neuregulin isoform expressed in these neurons is a novel transmembrane splice variant. After axotomy, there is a rapid decline in neuregulin expression in both motor and sensory neurons, but following reinnervation of target tissues, neuregulin expression returns to near normal levels. These results indicate that the normal expression of neuregulins in these neurons is maintained by the interactions with target tissues.     

Expression of chloride channel 1 mRNA in cultured myogenic cells: a marker of myotube maturation

The chloride channel CIC-1 is required to maintain a normal excitability of mature muscle fibers; its blockade leads to hyperexcitability, the hallmark of the disease myotonia. In mouse and rat myotubes, representing the embryonic stage of muscle, CIC-1 mRNA is not detectable by Northern blotting. From neonatal to adult, CIC-1 expression increases at least fourfold. Using RT-PCR and hybridization on cultured myotubes we found CIC-1 mRNA at a level of 0.4-1.1% of that in mature mouse muscle, and < or = 0.01% in myoblasts, at stages when desmin mRNA levels are already high. The level of CIC-1 mRNA is thus a sensitive and specific indicator of the maturation of skeletal muscle cells.     

Expression of Kv1.1, a Shaker-like potassium channel, is temporally regulated in embryonic neurons and glia

Kv1.1, a Shaker-like voltage-gated potassium channel, is strongly expressed in a variety of neurons in adult rodents, in which it appears to be involved in regulating neuronal excitability. Here we show that Kv1.1 is also expressed during embryonic development in the mouse, exhibiting two transient peaks of expression around embryonic day 9.5 (E9.5) and E14.5. Using both in situ hybridization and immunocytochemistry, we have identified several cell types and tissues that express Kv1.1 RNA and protein. At E9.5, Kv1.1 RNA and protein are detected transiently in non-neuronal cells in several regions of the early CNS, including rhombomeres 3 and 5 and ventricular zones in the mesencephalon and diencephalon. At E14.5, several cell types in both the CNS and peripheral nervous system express Kv1.1, including neuronal cells (sensory ganglia and outer aspect of cerebral hemispheres) and glial cells (radial glia, satellite cells, and Schwann cell precursors). These data show that Kv1.1 is expressed transiently in a variety of neuronal and non-neuronal cells during restricted periods of embryonic development. Although the functional roles of Kv1.1 in development are not understood, the cell-specific localization and timing of expression suggest this channel may play a role in several developmental processes, including proliferation, migration, or cell-cell adhesion.     

Age-induced decrease of glycoprotein Po and myelin basic protein gene expression in the rat sciatic nerve. Repair by steroid derivatives

The data here reported show that the gene expression of the glycoprotein Po and of the myelin basic protein, the major components of myelin in the peripheral nervous system, dramatically decreases with ageing in the sciatic nerve of normal male rats. A one-month treatment with dihydroprogesterone, the 5alpha-reduced derivative of progesterone, is able to partially restore the fall in Po gene expression occurring in the sciatic nerve of aged male rats, without significantly modifying the gene expression of the myelin basic protein. In cultures of neonatal Schwann cells (the peripheral nervous system elements involved in the synthesis of myelin), the addition of progesterone and of dihydroprogesterone significantly increases Po gene expression; the 3alpha-reduced metabolite of dihydroprogesterone, tetrahydroprogesterone proved to be even more effective. These data suggest that the effect of progesterone is linked to its conversion into dihydroprogesterone and especially into tetrahydroprogesterone, since Schwann cells possess the 5alpha-reductase-3alpha-hydroxysteroid dehydrogenase system. The data provide the first demonstration that ageing decreases the gene expression of two major components of the peripheral myelin in the sciatic nerve; they also show that this phenomenon may be partially reversed by progesterone derivatives, which might act by stimulating Po gene expression in the Schwann cells.     

Impairment of peripheral nerve excitability

Functional abnormalities, especially the excitability changes of axon in the peripheral nerve involvement, were reviewed. In GBS and CIDP, the correlation between conduction block and anti-ganglioside antibodies have been discussed. Using anti GM1 antibody positive sera, the suppression of voltage-gated sodium channels (VGSC) has been reported. Although this findings have not been confirmed, the involvement of VGSC may be an important mechanism for eliciting conduction block. In Isaacs' syndrome, voltage-gated potassium channels (VGKC) were suppressed by autoantibodies to VGKC. Furthermore, in generalized myokymia syndrome which shows only myokymia and muscle cramp without grip myotonia, VGKCs are also suppressed in some cases. These findings suggest that some patients with myokymia and neuromyotonia are induced by anti-VGKC antibodies. For evaluating the axonal excitability in vivo, the threshold electrotonus method have been developed and applied for the involvement of peripheral nerves. In ALS, impairment of potassium conductance was shown and was speculated to have the possible rrelation with fasciculation. Thus threshold electrotonus method will be an important method for evaluating axonal excitability in human. The accumulated knowledge about the involvement of axonal ion channels will expand and will be categorized as axonal channelopathies.     

Expression of two neuronal markers, growth-associated protein 43 and neuron-specific enolase, in rat glial cells

Recent studies have revealed that proteins such as growth-associated protein 43 (GAP-43) and neuron-specific enolase (NSE), believed for many years to be expressed exclusively in neurons, are also present in glial cells under some circumstances. Here we present an overview of these observations. GAP-43 is expressed both in vitro and in vivo transiently in immature rat oligodendroglial cells of the central nervous system, in Schwann cell precursors, and in non-myelin-forming Schwann cells of the peripheral nervous system. GAP-43 mRNA is also present in oligodendroglial cells and Schwann cells, indicating that GAP-43 is synthesized in these cells. GAP-43 is also expressed in type 2 astrocytes (stellate-shaped astrocytes) and in some reactive astrocytes but not in type 1 astrocytes (flat protoplasmic astrocytes). These results suggest that GAP-43 plays a more general role in neural plasticity during development of the central and peripheral nervous systems. NSE enzymatic activity and protein and mRNA have been detected in rat cultured oligodendrocytes at levels comparable to those of cultured neurons. NSE expression increases during the differentiation of oligodendrocyte precursors into oligodendrocytes. In vivo, NSE protein is expressed in differentiating oligodendrocytes and is repressed in fully mature adult cells. The upregulation of NSE in differentiating oligodendrocytes coincides with the formation of large amounts of membrane structures and of protoplasmic processes. Similarly, NSE becomes detectable in glial neoplasms and reactive glial cells at the time when these cells undergo morphological changes. The expression of the glycolytic isozyme NSE in these cells, which do not normally contain it, could reflect a response to higher energy demands. This expression may also be related to the neurotrophic and neuroprotective properties demonstrated for this enolase isoform. NSE activity and protein and mRNA have also been found in cultured rat type 1-like astrocytes but at much lower levels than in neurons and oligodendrocytes. Thus GAP-43 and NSE should be used with caution as neuron-specific markers in studies of normal and pathological neural development.     

Slow closed-state inactivation: a novel mechanism underlying ramp currents in cells expressing the hNE/PN1 sodium channel

To better understand why sensory neurons express voltage-gated Na+ channel isoforms that are different from those expressed in other types of excitable cells, we compared the properties of the hNE sodium channel [a human homolog of PN1, which is selectively expressed in dorsal root ganglion (DRG) neurons] with that of the skeletal muscle Na+ channel (hSkM1) [both expressed in human embryonic kidney (HEK293) cells]. Although the voltage dependence of activation was similar, the inactivation properties were different. The V1/2 for steady-state inactivation was slightly more negative, and the rate of open-state inactivation was approximately 50% slower for hNE. However, the greatest difference was that closed-state inactivation and recovery from inactivation were up to fivefold slower for hNE than for hSkM1 channels. TTX-sensitive (TTX-S) currents in small DRG neurons also have slow closed-state inactivation, suggesting that hNE/PN1 contributes to this TTX-S current. Slow ramp depolarizations (0.25 mV/msec) elicited TTX-S persistent currents in cells expressing hNE channels, and in DRG neurons, but not in cells expressing hSkM1 channels. We propose that slow closed-state inactivation underlies these ramp currents. This conclusion is supported by data showing that divalent cations such as Cd2+ and Zn2+ (50-200 microM) slowed closed-state inactivation and also dramatically increased the ramp currents for DRG TTX-S currents and hNE channels but not for hSkM1 channels. The hNE and DRG TTX-S ramp currents activated near -65 mV and therefore could play an important role in boosting stimulus depolarizations in sensory neurons. These results suggest that differences in the kinetics of closed-state inactivation may confer distinct integrative properties on different Na+ channel isoforms.