Activity-induced internalization and rapid degradation of sodium channels in cultured fetal neurons.

A regulatory mechanism for neuronal excitability consists in controlling sodium channel density at the plasma membrane. In cultured fetal neurons, activation of sodium channels by neurotoxins, e.g., veratridine and alpha-scorpion toxin (alpha-ScTx) that enhance the channel open state probability induced a rapid down-regulation of surface channels. Evidence that the initial step of activity-induced sodium channel down-regulation is mediated by internalization was provided by using 125I-alpha-ScTx as both a channel probe and activator. After its binding to surface channels, the distribution of 125I-alpha-ScTx into five subcellular compartments was quantitatively analyzed by EM autoradiography. 125I-alpha-ScTx was found to accumulate in tubulovesicular endosomes and disappear from the cell surface in a time-dependent manner. This specific distribution was prevented by addition of tetrodotoxin (TTX), a channel blocker. By using a photoreactive derivative to covalently label sodium channels at the surface of cultured neurons, we further demonstrated that they are degraded after veratridine-induced internalization. A time-dependent decrease in the amount of labeled sodium channel alpha subunit was observed after veratridine treatment. After 120 min of incubation, half of the alpha subunits were cleaved. This degradation was prevented totally by TTX addition and was accompanied by the appearance of an increasing amount of a 90-kD major proteolytic fragment that was already detected after 45-60 min of veratridine treatment. Exposure of the photoaffinity-labeled cells to amphotericin B, a sodium ionophore, gave similar results. In this case, degradation was prevented when Na+ ions were substituted by choline ions and not blocked by TTX. After veratridine- or amphotericin B-induced internalization of sodium channels, breakdown of the labeled alpha subunit was inhibited by leupeptin, while internalization was almost unaffected. Thus, cultured fetal neurons are capable of adjusting sodium channel density by an activity-dependent endocytotic process that is triggered by Na+ influx.

Sodium channel internalization in developing neurons.

Neurotoxin-induced activation of voltage-dependent Na+ channels provoked rapid (t1/2 = 15-20 min) channel down-regulation in cultured rat brain neurons, resulting in a 50%-70% decrease in [3H]saxitoxin and 125I-alpha-scorpion toxin binding capacities as well as a decrease in Na+ peak current. Experiments using 125I-alpha-scorpion toxin as both a Na+ channel activator and a surface channel probe showed that a fraction of the bound toxin was internalized, since it was not releasable by acidic washing. Internalization was inhibited by tetrodotoxin, abolished in Na(+)-free medium, and induced by amphotericin B, a Na+ ionophore. Moreover, down-regulation occurred only in immature neuronal tissue, either cultured fetal neurons or postnatal hippocampal slices, but was absent in adult brain. These observations indicate that Na+ channel internalization is triggered by Na+ influx into neurons and may be involved in the control of electrical activity during development.

Effect of point mutations on the in-vitro pore properties of maltoporin, a protein of Escherichia coli outer membrane.

Maltoporin (LamB protein), a protein of Escherichia coli outer membrane forms ionic channels with a selectivity for maltose and maltodextrins (Dargent et al., 1987). The effect of different point mutations on maltoporin pore properties was investigated in vitro with planar bilayers. The mutations belong to three classes in terms of selective maltose transport in vivo: class A (substitution at positions 259 and 382) does not affect maltose transport, class B (position 163 and 245) decreases maltose transport down to 20 to 30%, and class C (position 18) almost completely abolishes selective maltose transport. This in-vitro study reveals that class A does not affect the pore properties in contrast to class B substitutions. The class B maltoporins are still able to form channels but display some specific features and altered specificity for maltose and maltodextrins. The substitution (Gly18----Val) alters trimer stability and impedes pore function (class C mutant). Thus, there is a good correlation between the specific transport properties of the mutated maltoporins in vivo and their behavior in vitro. These data, in combination with the asymmetric orientation of the protein within the bilayer and topological considerations, indicate that residues 245 and 163 do not belong to the selectivity filter. Mutations at these sites cause hindrance at the mouth of the pore on the outer domain of maltoporin.

Selectivity for maltose and maltodextrins of maltoporin, a pore-forming protein of E. coli outer membrane.

Homogenous maltoporin (lamB protein), an Escherichia coli outer membrane spanning protein, was incorporated in phospholipid planar bilayers. It generates aqueous channels distinct from those formed by the non-specific porin (OmpF) or by phosphoporin (phoE protein). The single conductance, 150 pS in 1 M NaCl, is much smaller than that of the porins. The channels, which are poorly selective for cations and voltage independent, are specifically inhibited by maltose and maltodextrins. This inhibition, observed in the absence of maltose binding protein, demonstrates that the selectivity of maltoporin for maltose and maltodextrins is an intrinsic property of the protein.

Activation of voltage-dependent sodium channels in cultured cerebellar poffule cells induces neurotoxicity that is not mediated by glutamate release.

Exposure of rat cerebellar granule cell cultures to neurotoxins that specifically enhance the open state probability of voltage-dependent Na+ channels, resulted in neuronal death as estimated by a cell viability assay based on fluorescent staining and 51Cr-uptake. Toxicity was detected within 1 h after addition of 100 microM veratridine and was complete within 10-18 h; it was dose-dependent and was found to be completely abolished by tetrodotoxin, an Na+ channel blocker. When veratridine was replaced by an alpha-scorpion toxin, similar observations were done. In contrast, when cultured neurons prepared ffom the cerebral hemisphere of fetal rat brain were exposed to either veratridine or alpha-scorpion toxin for 18 h or even for a longer time of incubation, no neuronal death was observed. DNA fragmentation analysis showed that the toxicity was not mediated by apoptosis. Neuronal death was neither prevented by glutamate receptor antagonists, nor by depletion of endogenous glutamate, nor by voltage sensitive calcium channel antagonists such as omega-Conotoxin-GVIA (N-type channels), omega-Agatoxin-IVA (P-type channels), nimodipine and nitrendipine (L-type channels). Our study indicates that prolonged opening of Na+ channels induced neuronal death of cerebellar granule cells which is not mediated by glutamate and reveals novel neurotoxic mechanism in addition to the well-established excitatory amino acid receptor pathway.

Down-regulation of voltage-dependent sodium channels coincides with a low expression of alphabeta1 subunit complexes.

The association between the beta1 subunit and the alpha subunit of the sodium channel from rat brain was studied in hippocampus during postnatal development and in cultures of fetal rat forebrain neurons and cerebellar granule cells, using an anti-beta1 antipeptide antibody to specifically immunoprecipitate alphabeta1 complexes labeled with [3H]saxitoxin. In the hippocampus, the increase in beta1 RNA expression during development was accompanied by an increase in immunoprecipitated alphabeta1 complexes. Most of the alphabeta1 complexes were constituted during the first 3 postnatal weeks, with the steepest rise between postnatal days 5 and 12. In cultured fetal neurons, the amount of beta1 RNA and of alphabeta1 complexes was approximately 3-4% of that found in the adult, whereas it reached 60-70% in cultured cerebellar granule cells. We had previously described a neurotoxin-induced internalization of sodium channels which occurred in immature neurons but not in adult tissue. Internalization decreased during development in neurotoxin-treated hippocampal slices, and resistance of plasma membrane sodium channels to internalization followed the same time course than the appearance of alphabeta1 complexes. Similarly, neurotoxin activation resulted in sodium channel internalization in fetal neurons, while cerebellar granule cells, which express high levels of beta1 RNA and of alphabeta1 complexes, did not internalize their [3H]saxitoxin receptors in that same conditions. These data suggested that the association of the beta1 subunit with the alpha subunit could provide a suitable marker for the stabilization and anchoring of sodium channels in discrete membrane domains which occur during neuronal development.

Multiple pathways regulate the expression of genes encoding sodium channel subunits in developing neurons.

In primary cultures of fetal neurons, activation of sodium channels with either alpha-scorpion toxin or veratridine caused a rapid and persistent decrease of mRNAs encoding beta2 and different sodium channel alpha mRNAs. In contrast, beta1 subunit mRNA was up-regulated by sodium channel activation. This phenomenon was calcium-independent. The effects of activating toxins on mRNAs of different sodium channel subunits were mimicked by membrane depolarization. An important aspect of this study was the demonstration that cAMP also caused rapid reduction of alphaI, alphaII and alphaIII mRNA levels whereas beta1 subunit mRNA was up regulated and beta2 subunit mRNA was not affected. Sodium channel activation by veratridine was shown to increase cAMP immunoreactivity in cultured neurons, but alphaII mRNA down-regulation induced by activating toxins was not reversed by protein kinase A antagonists, indicating that this phenomenon is not protein kinase A dependent. The effects of cAMP and membrane depolarisation were antagonized by the PKA inhibitor H89. These results are indicative of the existence of multiple and independent regulatory pathways modulating the expression of sodium channel genes in the developing central nervous system.

Channel activators reduce the expression of sodium channel alpha-subunit mRNA in developing neurons.

The expression of rat brain sodium channel alpha-subunit (Na+I, Na+II and Na+III) and beta 1-subunit mRNAs was examined in rat fetal brain neurons in culture. A combined technique of reverse transcription and polymerase chain reaction (RT-PCR) was used. Two different PCR primer sets were designed to obtain simultaneous amplification of the three alpha-subunit mRNAs. All three molecules were detected in fetal neurons but the expression pattern (Na+III > Na+II > > Na+I) was different than that observed in adult tissue (Na+II > Na+I > Na+III). Expression of the beta 1-subunit mRNA was detected using a specific PCR primer set. Doublet bands were amplified, from fetal cells and adult brain mRNA. To get further insight into the molecular mechanism that underlie activity dependent plasticity of sodium channels, we studied the effect on the expression of sodium channel subunits mRNA of a 60 h incubation of cells in the presence of a scorpion neurotoxin that blocks channel inactivation. An overall decrease in the expression of all three alpha-subunit mRNAs was observed whereas the beta 1-subunit mRNA was unaffected by the same treatment. When cells were incubated with the scorpion neurotoxin together with tetrodotoxin, to block Na+ influx through channels, the decrease in mRNA expression was not observed. Finally, a 60 h continuous depolarization of cells induced by application of a high concentration KC1 solution did not mimic the effect of the scorpion toxin. These observations suggest that a persistent activation of the sodium channels is able to down-regulate mRNA expression for alpha-subunits but not for the beta 1-subunit.

CK2 accumulation at the axon initial segment depends on sodium channel Nav1.

Accumulation of voltage-gated sodium channel Nav1 at the axon initial segment (AIS), results from a direct interaction with ankyrin G. This interaction is regulated in vitro by the protein kinase CK2, which is also highly enriched at the AIS. Here, using phosphospecific antibodies and inhibition/depletion approaches, we showed that Nav1 channels are phosphorylated in vivo in their ankyrin-binding motif. Moreover, we observed that CK2 accumulation at the AIS depends on expression of Nav1 channels, with which CK2 forms tight complexes. Thus, the CK2-Nav1 interaction is likely to initiate an important regulatory mechanism to finely control Nav1 phosphorylation and, consequently, neuronal excitability.

Down-regulation of voltage-dependent sodium channels initiated by sodium influx in developing neurons.

To address the issue of whether regulatory feedback exists between the electrical activity of a neuron and ion-channel density, we investigated the effect of Na(+)-channel activators (scorpion alpha toxin, batrachotoxin, and veratridine) on the density of Na+ channels in fetal rat brain neurons in vitro. A partial but rapid (t1/2, 15 min) disappearance of surface Na+ channels was observed as measured by a decrease in the specific binding of [3H]saxitoxin and 125I-labeled scorpion beta toxin and a decrease in specific 22Na+ uptake. Moreover, the increase in the number of Na+ channels that normally occurs during neuronal maturation in vitro was inhibited by chronic channel activator treatment. The induced disappearance of Na+ channels was abolished by tetrodotoxin, was found to be dependent on the external Na+ concentration, and was prevented when either choline (a nonpermeant ion) or Li+ (a permeant ion) was substituted for Na+. Amphotericin B, a Na+ ionophore, and monensin were able to mimick the effect of Na(+)-channel activators, while a KCl depolarization failed to do this. This feedback regulation seems to be a neuronal property since Na(+)-channel density in cultured astrocytes was not affected by channel activator treatment or by amphotericin B. The present evidence suggests that an increase in intracellular Na+ concentration, whether elicited by Na(+)-channel activators or mediated by a Na+ ionophore, can induce a decrease in surface Na+ channels and therefore is involved in down-regulation of Na(+)-channel density in fetal rat brain neurons in vitro.

Internalization of voltage-dependent sodium channels in fetal rat brain neurons: a study of the regulation of endocytosis.

In fetal rat brain neurons, activation of voltage-dependent Na+ channels induced their own internalization, probably triggered by an increase in intracellular Na+ level. To investigate the role of phosphorylation in internalization, neurons were exposed to either activators or inhibitors of cyclic AMP- and cyclic GMP-dependent protein kinases, protein kinase C, and tyrosine kinase. None of the tested compounds mimicked or inhibited the effect of Na+ channel activation. An increase in intracellular Ca2+ concentration induced either by thapsigargin, a Ca(2+)-ATPase blocker, or by A23187, a Ca2+ ionophore, was unable to provoke Na+ channel internalization. However, Ca2+ seems to be necessary because both neurotoxin- and amphotericin B-induced Na+ channel internalizations were partially inhibited by BAPTA-AM. The selective inhibitor of Ca2+/calmodulin-dependent protein kinase II, KN-62, caused a dose-dependent inhibition of neurotoxin-induced internalization due to a blockade of channel activity but did not prevent amphotericin B-induced internalization. The rate of increase in Na+ channel density at the neuronal cell surface was similar before and after channel internalization, suggesting that recycling of internalized Na+ channels back to the cell surface was almost negligible. Pretreatment of the cells with an acidotropic agent such as chloroquine prevented Na+ channel internalization, indicating that an acidic endosomal/lysosomal compartment is involved in Na+ channel internalization in neurons.

The selectivity filter of voltage-dependent channels formed by phosphoporin (PhoE protein) from E. coli.

Phosphoporin, an Escherichia coli outer membrane-spanning protein re-incorporated in phospholipid planar bilayers generates aqueous channels similar to those of matrix porin. One phosphoporin trimer contains three pores which are induced simultaneously but fluctuate separately between open and closed states. Membrane potential shifts this two-state equilibrium in favour of closed channels. This negative resistance occurs at lower potentials than with matrix porin channels. The phosphoporin channel is poorly anion selective for small solutes. Polyphosphates and other phosphorylated molecules specifically inhibit phosphoporin pore conductance to small ions, a property which is specific to phosphoporin. There is an excellent correlation between the effect of such solutes measured in planar bilayers and their inhibitory effect on beta-lactam antibiotic uptake in vivo by phosphoporin. It is concluded that the phosphoporin channel contains a selectivity filter which is only efficient for larger molecules, most probably through basic residues.

Na(+) channel regulation by calmodulin kinase II in rat cerebellar granule cells.

The effects of specific CaM kinase II inhibitors were investigated on Na(+) channels from rat cerebellar granule cells. A maximal effect of KN-62 was observed at 20 microM and consisted of an 80% reduction of the peak Na(+) current after only a 10-min application. A hyperpolarizing shift of 8 mV in the steady-state inactivation was also observed. KN-04 (20 microM), an inactive analog, had no detectable effect. KN-62 was however inactive on Na(+) currents recorded from Chinese hamster ovary cells expressing the type II A alpha subunit. We have also analyzed the inhibitory effects of CaM kinase II 296-311 and CaM kinase II 281-309 peptides. Both peptides (75 microM) induced a maximum peak Na(+) current reduction within 30 min. Under similar conditions, a truncated peptide CaM kinase II 284-302 was ineffective. These results demonstrate that CaM kinase II acts as a modulator of Na(+) channel activity in cerebellar granule cells.

Direct interaction between synaptotagmin and the intracellular loop I-II of neuronal voltage-sensitive sodium channels.

Synaptotagmin, a synaptic vesicle protein involved in Ca(2+)-regulated exocytosis, displayed direct high affinity interaction with neuronal sodium channels. Monoclonal antibodies directed against synaptotagmins I and II adsorbed in a concentration-dependent and -specific manner [(3)H]saxitoxin prelabeled sodium channels extracted with detergent from nerve endings. Conversely, co-immunoprecipitation of synaptotagmin was achieved by antibodies against sodium channel subunits. Consistent with the co-immunoprecipitation assays, solubilized [(3)H]saxitoxin-prelabeled sodium channels were trapped on immobilized maltose binding protein (MBP)-synaptotagmin I. In vitro recombinant protein assays were employed to identify the interaction site of synaptotagmin I, which was located on the cytoplasmic loop between domains I and II of the sodium channel alphaIIA subunit. The co-immunoprecipitated synaptotagmin-sodium channel complexes were found to be Ca(2+)-dependent; this effect was mimicked by Ba(2+) and Sr(2+) but not Mg(2+). Finally the complex was shown to be distinct from the synaptotagmin-SNARE protein complex that can selectively interact with presynaptic calcium channels (N and P/Q types). Thus, our findings demonstrate an unexpected and direct interaction between sodium channels and synaptotagmin. The Ca(2+)-regulated association between sodium channels and a protein implicated in vesicular fusion may have intriguing consequences for the establishment and regulation of neuronal excitability.

Direct block of voltage-sensitive sodium channels by genistein, a tyrosine kinase inhibitor.

Genistein, an isoflavone inhibitor of tyrosine-specific protein kinases, was shown to specifically block the 22Na+ influx through voltage-sensitive Na+ channels in cultured rat brain neurons, whereas other tyrosine kinase antagonists such as lavendustin A, compound 5, tyrphostin A47 and an erbstatin analog were inactive at concentrations known to block kinase activity in other neuronal systems. Dose-response curves for genistein indicated a half-maximum effect at 60 microM. Daidzein, an inactive analog of genistein, had a similar inhibitory effect on the 22Na+ influx with a half-maximum effect at 195 microM. The time course of genistein action was rapid, because maximum effect on 22Na+ influx was obtained in less than 20 s at 100 microM. Analysis of Na+ currents by the whole-cell recording technique showed that 20 microM genistein reduced the sodium current and shifted the voltage dependence of both activation and inactivation curves. No competition with [3H]saxitoxin binding was observed, whereas the binding of [3H]batrachotoxinin A 20-alpha-benzoate to rat brain synaptosomal membranes was partially inhibited, which suggested a direct or allosteric interaction with neurotoxin binding site 2. These data taken together clearly indicate that the inhibition of voltage-sensitive sodium channels by genistein is not mediated by tyrosine kinase inhibition.

Three-dimensional reconstruction of maltoporin from electron microscopy and image processing.

Two dimensional crystals of maltoporin (or phage lambda receptor) were obtained by reconstitution of purified maltoporin trimers and Escherichia coli phospholipids by detergent dialysis. Two different trimer packing forms were observed. One was hexagonal (a = 7.8 nm) and one rectangular (a = 7.8 nm, b = 13.6 nm). In this paper we describe the three-dimensional structure of maltoporin, deduced from the study of the rectangular form by electron microscopy and image processing. At a resolution of approximately 2.5 nm, maltoporin trimers form aqueous channel triplets which appear to merge into a single outlet at the periplasmic surface of the outer membrane. The pore defined by maltoporin has a similar structure to that outlined by the matrix protein. From the results of functional studies by conductance measurement, it is concluded that the three channels defined by maltoporin act, contrary to those formed by the porin (OmpF protein), as a single conducting unit. A tentative outline of the maltoporin promoter is given. Maltoporin appears to be constituted by three different domains: a major rod-like domain spanning the membrane, a minor domain located near the periplasmic surface of the membrane and finally a central domain responsible for the splitting of the channel.

Identification of an axonal determinant in the C-terminus of the sodium channel Na(v)1.2.

To obtain a better understanding of how hippocampal neurons selectively target proteins to axons, we assessed whether any of the large cytoplasmic regions of neuronal sodium channel Na(v)1.2 contain sufficient information for axonal compartmentalization. We show that addition of the cytoplasmic C-terminal region of Na(v)1.2 restricted the distribution of a dendritic-axonal reporter protein to axons. The analysis of mutants revealed that a critical segment of nine amino acids encompassing a di-leucine-based motif mediates axonal compartmentalization of chimera. In addition, the Na(v)1.2 C-terminus is recognized by the clathrin endocytic pathway both in non-neuronal cells and the somatodendritic domain of hippocampal neurons. The mutation of the di-leucine motif located within the nine amino acid sequence to alanines resulted in the loss of chimera compartmentalization in axons and of internalization. These data suggest that selective elimination by endocytosis in dendrites may account for the compartmentalized distribution of some proteins in axons.

Immunoassays fail to detect antibodies against neuronal calcium channels in amyotrophic lateral sclerosis serum.

Recent studies suggested that autoantibodies that bind to voltage-dependent calcium channels and activate calcium entry may play a role in the progressive degeneration of motoneurons in sporadic amyotrophic lateral sclerosis. Immunoassays were performed to assess autoantibody titer in patients with amyotrophic lateral sclerosis or Lambert-Eaton myasthenic syndrome, a disease in which the presence of anti-calcium channel antibodies is well documented. Based on immunoprecipitation assays for antibodies against N-type calcium channels, only 8% (2/25) of amyotrophic lateral sclerosis patients had marginally positive titers, whereas 58% (18/31) of patients with Lambert-Eaton myasthenic syndrome had positive titers. Enzyme-linked immunosorbent assays with purified neuronal N-type calcium channels revealed immunoreactivity in 2 of 25 amyotrophic lateral sclerosis sera and 12 of 31 Lambert-Eaton myasthenic syndrome sera, which is not compatible with suggestions that enzyme-linked immunosorbent assay is a more sensitive technique for the detection of autoantibodies in amyotrophic lateral sclerosis. Furthermore, based on immunoprecipitation assays, amyotrophic lateral sclerosis sera were totally negative for antibodies against L-type calcium channels from skeletal muscle or brain. These data do not support the hypothesis that an autoimmune response against calcium channels plays a primary role in amyotrophic lateral sclerosis.

Synaptotagmin I and IV define distinct populations of neuronal transport vesicles.

Mammalian synaptotagmins constitute a multigene family of at least 11 membrane proteins. We have characterized synaptotagmin IV using antibodies directed against the C2A domain of the protein. Antibodies reacted specifically with a protein band that migrated as a 41-44 kDa doublet. Synaptotagmin IV expression was regulated throughout development. A strong decrease in the amount detected by Western blotting occurred between postnatal day 5 and adulthood, in agreement with studies on the expression of synaptotagmin IV transcripts. In subcellular fractionation, synaptotagmin IV was not detected in the synaptic vesicle-enriched fraction. Immunofluorescence microscopy was concordant with this finding. In 6-day-old rat cerebellum and cultured hippocampal neurons the subcellular distribution of synaptotagmin IV was clearly different from that of synaptotagmin I. Synaptotagmin IV displayed a punctate non-polarized distribution on neuronal extensions, whereas synaptotagmin I staining was essentially synaptic. Synaptotagmin IV staining was also observed in the soma in strong perinuclear fluorescent puncta superimposed on that of Golgi/TGN markers. Furthermore, synaptotagmin IV was seen in the proximal part of the growth cone domain and not in the microfilament-rich region which includes filopodia. Co-localizations with the adhesion molecules vinculin and zyxin at the proximal part of growth cones were observed. Synaptotagmin IV may thus be involved in the regulation of specific membrane-trafficking pathways during brain development.

Scorpion alpha-like toxins, toxic to both mammals and insects, differentially interact with receptor site 3 on voltage-gated sodium channels in mammals and insects.

alpha-Like toxins, a unique group designated among the scorpion alpha-toxin class that inhibit sodium channel inactivation, are highly toxic to mice but do not compete for alpha-toxin binding to receptor site 3 on rat brain sodium channels. We analysed the sequence of a new alpha-like toxin, which was also highly active on insects, and studied its action and binding on both mammalian and insect sodium channels. Action of the alpha-like toxin on isolated cockroach axon is similar to that of an alpha-toxin, and the radioactive toxin binds with a high affinity to insect sodium channels. Other sodium channel neurotoxins interact competitively or allosterically with the insect alpha-like toxin receptor site, similarly to alpha-toxins, suggesting that the alpha-like toxin receptor site is closely related to receptor site 3. Conversely, on rat brain sodium channels, specific binding of 125I-alpha-like toxin could not be detected, although at high concentration it inhibits sodium current inactivation on rat brain sodium channels. The difficulty in measuring binding to rat brain channels may be attributed to low-affinity binding due to the acidic properties of the alpha-like toxins that also impair the interaction with receptor site 3. The results suggest that alpha-like toxins bind to a distinct receptor site on sodium channels that is differentially related to receptor site 3 on mammalian and insect sodium channels.