Reevaluation of the Role of Gangliosides as Receptors for Tetanus Toxin

Binding of tetanus toxin to rat brain membranes was of lower affinity and capacity when binding was determined in 150 mM NaCl, 50 mM Tris-HCl (pH 7.4) than in 25 mM Tris-acetate (pH 6.0). Binding under both conditions was reduced by treating the membranes with neuraminidase. Pronase treatment, however, reduced toxin binding only in the Tris-saline buffer (pH 7.4). In addition, the concentration of gangliosides required to inhibit toxin binding was 100-fold higher in Tris-saline compared to Tris-acetate buffer. The toxin receptors in the membranes were analyzed by ligand blotting techniques. Membrane components were dissolved in sodium dodecyl sulfate, separated by polyacrylamide gel electrophoresis, and transferred to nitrocellulose sheets, which were overlaid with 125I-labeled toxin. Tetanus toxin bound only to material that migrated in the region of the dye front and was extracted with lipid solvents. Gangliosides isolated from the lipid extracts or other sources were separated by TLC on silica gel and the chromatograms were overlaid with labeled tetanus toxin. The toxin bound to areas where the major rat brain gangliosides migrated. When equimolar amounts of different purified gangliosides were applied to the chromatogram, binding of the toxin was in the order GD1b approximately equal to GT1b approximately equal to GQ1b greater than GD2 greater than GD3 much greater than GD1a approximately equal to GM1. Thus, the toxin appears to have the highest affinity for gangliosides with a disialyl group linked to the inner galactosyl residue. When binding of tetanus toxin to transfers and chromatograms was determined in the Tris-saline buffer (pH 7.4), the toxin bound to the same components but the extent of binding was markedly reduced compared with the low-salt and -pH conditions. Our results indicate that the interaction of tetanus toxin with rat brain membranes and gangliosides is greatly reduced under more physiological conditions of salt and pH and raise the possibility that other membrane components such as sialoglycoproteins may be receptors for the toxin under these conditions.     

Flow cytometric analysis of tetanus toxin binding to neuroblastoma cells

A neuroblastoma cell line was assessed for its capacity to bind tetanus toxin (TT) by using immunofluorescence and flow cytometry to analyze cells on a single cell basis. A clone of Neuro 2a, N2AB-1, was shown to bind variable amounts of TT per cell and this binding could be saturated by increasing doses of the toxin. Toxin binding was specific for neuronal cells, as the non-neuronal cell line, C6 glioma, bound negligible amounts of toxin. Variability of immunofluorescence staining was due in part to the increase in size of N2AB-1 cells as they progress through the cell cycle as measured by cell surface densities of toxin binding and DNA levels by propidium iodide (PI) staining. When N2AB-1 cells were treated with exogenous gangliosides for 24 h, cells were induced to sprout neurites and cell growth was inhibited. Analysis of DNA histograms indicated that ganglioside treatment caused more cells to appear in G0G1 of the cell cycle than that seen for untreated controls. Upon cytometric analysis of TT binding to ganglioside treated cells, it was apparent that treatment stimulated all cells to bind TT in larger amounts per cell than that seen with untreated N2AB-1 cells. These data suggest that TT binding and, therefore, toxin receptors are constant in density throughout the cell cycle of these neuroblastoma cells and that exogenous gangliosides can cause differentiation followed by increased toxin binding.     

Periodate-Modified Gangliosides Enhance Surface Binding of Tetanus Toxin to PC 12 Pheochromocytoma Cells

The interaction of 125I-labeled tetanus toxin with PC12 pheochromocytoma cells in monolayer cultures has been examined. Under regular growth conditions, the PC12 cells bind 125I-tetanus toxin to a limited degree compared with dissociated cerebral neuron cultures. After exposure to nerve growth factor for 2 days in low serum-containing media with growth factor supplements, binding of toxin increases over twofold compared with untreated PC12 cells. Binding can also be enhanced (greater than 2.5-fold) after treatment of cells with 2 mM sodium metaperiodate for 20 min. Dissociated cerebral neurons but not fibroblasts in cell culture bind more toxin after periodate treatment. The effect of periodate can be abolished by 5 mM sodium borohydride. A ganglioside isolated from periodate-treated PC12 cells and tentatively identified as GT1b [(N-acetylneuraminyl)galactosyl-N-acetylgalactosaminyl(N- acetylneuraminyl-N-acetylneuraminyl)-galactosyl-glucosylceramide] binds 125I-tetanus toxin on silica gel chromatoplates and on nitrocellulose paper. There are no indications to suggest binding to a polypeptide from treated cells after polyacrylamide gel electrophoresis. Cells artificially supplemented with GT1b and subsequently treated with periodate effectively bind the toxin. The data suggest that modified sialyl groups linked to gangliosides, and not to proteins, are preferential targets for tetanus toxin.     

GANGLIOSIDES IN NERVOUS TISSUE CULTURES AND BINDING OF 125I-LABELLED TETANUS TOXIN, A NEURONAL MARKER

Abstract— —Continuous cell lines, primary cell cultures derived from embryonic CNS, and homogenates made from adult and embryonic CNS were compared with respect to their lipid pattern and their ability to bind ¹²⁵I-labelled tetanus toxin. In parallel experiments de novo synthesis of gangliosides in the cell lines was studied, using [¹⁴C]glucosamine as precursor. Of the total lipid only gangliosides were specifically labelled by [¹⁴C]glucosamine. The patterns of the de novo synthesized gangliosides corresponded to those present in the respective cells.
Pronounced binding of ¹²⁵I-labelled toxin was only detectable in tissues containing long-chain gangliosides (ganglioside C which represents GDIb and GTI).
Accordingly, hybrid (neuroblastoma x glioma) cells, due to their lack of long-chain gangliosides, bound just-discernible amounts of labelled toxin. When previously exposed to gangliosides, their binding of tetanus toxin tremendously increased.
It was concluded that only the long-chain gangliosides in the neuronal cells are functionally involved in the binding of the tetanus toxin and that these acceptors of tetanus toxin can be transplanted.     

Characterization of Curaremimetic Neurotoxin Binding Sites on Cellular Membrane Fragments Derived from the Rat Pheochromocytoma PC 12

Studies were conducted on the properties of 125I-labeled alpha-bungarotoxin binding sites on cellular membrane fragments derived from the PC12 rat pheochromocytoma. Two classes of specific toxin binding sites are present at approximately equal densities (50 fmol/mg of membrane protein) and are characterized by apparent dissociation constants of 3 and 60 nM. Nicotine and d-tubocurarine are among the most potent inhibitors of high-affinity toxin binding. The affinity of high-affinity toxin binding sites for nicotinic cholinergic agonists is reversibly or irreversibly decreased, respectively, on treatment with dithiothreitol or dithiothreitol and N-ethylmaleimide. The nicotinic receptor affinity reagent bromoacetylcholine irreversibly blocks high-affinity toxin binding to PC12 cell membranes that have been treated with dithiothreitol. Two polyclonal antisera raised against the nicotinic acetylcholine receptor from Electrophorus electricus inhibit high-affinity toxin binding. These detailed studies confirm that curaremimetic neurotoxin binding sites on the PC12 cell line are comparable to toxin binding sites from neural tissues and to nicotinic acetylcholine receptors from the periphery. Because toxin binding sites are recognized by anti-nicotinic receptor antibodies, the possibility remains that they are functionally analogous to nicotinic receptors.     

Interaction Between Tetanus Toxin and Rabbit Kidney: A Comparison with Rat Brain Preparations

125I-Tetanus toxin is bound by basolateral membranes from rabbit kidneys. Fixation is specific, as it is minimally inhibited by the nonbinding (fragment B) moiety of tetanus toxin, whereas the binding moiety (fragment C) is equivalent to the native toxin in inhibiting fixation. Competition is also pronounced with mildly toxoided toxin. Association and dissociation of 125I-toxin are delayed in kidney when compared to brain membranes. The binding sites in kidney membranes are partially sensitive to neuraminidase and resist heating to 56 degrees C, in contrast to those in brain membranes which are very sensitive to both treatments. The binding sites of the two preparations can be discriminated further by variation of the ionic environment. Sodium dodecyl sulfate-disc gel electrophoresis followed by transfer to nitrocellulose, and TLC with consecutive overlay indicate that tetanus toxin exclusively binds to long-chain gangliosides from rat brain. Binding sites in kidney membranes from rabbits and rats can be made visible by the overlay technique. They are apparently heterogeneous and more hydrophobic. We conclude that rabbit kidney contains binding sites for tetanus toxin which resemble gangliosides but differ from the major gangliosides in brain both chemically and with respect to their interaction with tetanus toxin.     

Molecular basis for tetanus toxin coreceptor interactions

Tetanus toxin (TeNT) elicits spastic paralysis through the cleavage of vesicle-associated membrane protein-2 (VAMP-2) in neurons at the interneuronal junction of the central nervous system. While TeNT retrograde traffics from peripheral nerve endings to the interneuronal junction, there is limited understanding of the neuronal receptors utilized by tetanus toxin for the initial entry into nerve cells. Earlier studies implicated a coreceptor for tetanus toxin entry into neurons: a ganglioside binding pocket and a sialic acid binding pocket and that GT1b bound to each pocket. In this study, a solid phase assay characterized the ganglioside binding specificity and functional properties of both carbohydrate binding pockets of TeNT. The ganglioside binding pocket recognized the ganglioside sugar backbone, Gal-GalNAc, independent of sialic acid-(5) and sialic acid-(7) and GM1a was an optimal substrate for this pocket, while the sialic acid binding pocket recognized sialic acid-(5) and sialic acid-(7) with "b"series of gangliosides preferred relative to "a" series gangliosides. The high-affinity binding of gangliosides to TeNT HCR required functional ganglioside and sialic acid binding pockets, supporting synergistic binding to coreceptors. This analysis provides a model for how tetanus toxin utilizes coreceptors for high-affinity binding to neurons.     

Neuronal sensitivity to tetanus toxin requires gangliosides.

Tetanus toxin produces spastic paralysis in situ by blocking inhibitory neurotransmitter release in the spinal cord. Although di- and trisialogangliosides bind tetanus toxin, their role as productive toxin receptors remains unclear. We examined toxin binding and action in spinal cord cell cultures grown in the presence of fumonisin B(1), an inhibitor of ganglioside synthesis. Mouse spinal cord neurons grown for 3 weeks in culture in 20 microM fumonisin B(1) develop dendrites, axons, and synaptic terminals similar to untreated neurons, even though thin layer chromatography shows a greater than 90% inhibition of ganglioside synthesis. Absence of tetanus and cholera toxin binding by toxin-horseradish peroxidase conjugates or immunofluorescence further indicates loss of mono- and polysialogangliosides. In contrast to control cultures, tetanus toxin added to fumonisin B(1)-treated cultures does not block potassium-stimulated glycine release, inhibit activity-dependent uptake of FM1-43, or abolish immunoreactivity for vesicle-associated membrane protein, the toxin substrate. Supplementing fumonisin B(1)-treated cultures with mixed brain gangliosides completely restores the ability of tetanus toxin to bind to the neuronal surface and to block neurotransmitter release. These data demonstrate that fumonisin B(1) protects against toxin-induced synaptic blockade and that gangliosides are a necessary component of the receptor mechanism for tetanus toxin.     

The interaction of tetanus toxin with intact bovine adrenal chromaffin cells: binding of toxin and subsequent inhibition of catecholamine release.

Tetanus toxin (about 1 nM) inhibits 70% of the nicotine-evoked release of catecholamines from intact adrenal medullary chromaffin cells after 20 h of incubation and 30% of the K(+)-evoked release. Inhibition of Ca(2+)-evoked release from detergent-permeabilized cells requires higher concentrations of toxin (about 1 microM) toxin, but is maximal after 12 min. Preincubation of the intact cells with ganglioside GT1 in the absence of toxin also inhibits evoked secretion. 125I-labelled toxin bound specifically to these cells; the binding capacity was greater at pH 6 (about 1 pmol toxin/mg cell protein) than at pH 7.4 (about 0.25 pmol). In both cases there were at least two binding components: one of high affinity (Kd about 1 nM) accounting for about 20% of total binding and one of lower affinity (Kd 10-20 nM). Preincubation of the cells with ganglioside increased the binding capacity, but did not affect the Kd of the lower affinity component. Similar observations could be made when binding was measured immunocytochemically. Extraction of gangliosides from chromaffin cells and overlay experiments with radiolabelled toxin showed that, as well as GM3, the major ganglioside component of chromaffin cell membranes, a ganglioside having the chromatographic mobility of GT1 was a major ligand for toxin.     

Characterization of tetanus toxin binding to rat brain membranes. Evidence for a high-affinity proteinase-sensitive receptor.

Binding of 125I-labelled tetanus toxin to rat brain membranes in 25 mM-Tris/acetate, pH 6.0, was saturable and there was a single class of high-affinity site (KD 0.26-1.14 nM) present in high abundance (Bmax. 0.9-1.89 nmol/mg). The sites were largely resistant to proteolysis and heating but were markedly sensitive to neuraminidase. Trisialogangliosides were effective inhibitors of toxin binding (IC50 10 nM) and trisialogangliosides inserted into membranes lacking a toxin receptor were able to bind toxin with high affinity (KD 2.6 nM). The results are consistent with previous studies and the hypothesis that di- and trisialogangliosides act as the primary receptor for tetanus toxin under these conditions. In contrast, when toxin binding was assayed in Krebs-Ringer buffer, pH 7.4, binding was greatly reduced, was non-saturable and competition binding studies showed evidence for a small number of high-affinity sites (KD 0.42 nM, Bmax. 0.90 pmol/mg) and a larger number of low-affinity sites (KD 146 nM, Bmax. 179 pmol/mg). Treatment of membranes with proteinases, heat, and neuraminidase markedly reduced binding. Trisialogangliosides were poor inhibitors of toxin binding (IC50 11.0 microM), and trisialogangliosides inserted into membranes bound toxin with low affinity. The results suggest that in physiological buffers tetanus toxin binds with high affinity to a protein receptor, and that gangliosides represent only a low-affinity site.     

Role of membrane gangliosides in the binding and action of bacterial toxins

Summary Gangliosides are complex glycosphingolipids that contain from one to several residues of sialic acid. They are present in the plasma membrane of vertebrate cells with their oligosaccharide chains exposed to the external environment. They have been implicated as cell surface receptors and several bacterial toxins have been shown to interact with them. Cholera toxin, which mediates its effects on cells by activating adenylate cyclase, bind with high affinity and specificity to ganglioside G_M1. Toxin-resistant cells which lack G_M1 can be sensitized to cholera toxin by treating them with G_M1. Cholera toxin specifically protects G_M1 from cell surface labeling procedures and only G_M1 is recovered when toxin-receptor complexes are isolated by immunoadsorption. These results clearly demonstrate that G_M1 is the specific and only receptor for cholera toxin. Although cholera toxin binds to G_M1 on the external side of the plasma membrane, it activates adenylate cyclase on the cytoplasmic side of the membrane by ADP-ribosylation of the regulatory component of the cyclase. G_M1 in addition to functioning as a binding site for the toxin appears to facilitate its transmembrane movement. The heat-labile enterotoxin ofE. coli is very similar to cholera toxin in both form and function and can also use G_M1 as a cell surface receptor. The potent neurotoxin, tetanus toxin, has a high affinity for gangliosides G_D1b and G_T1b and binds to neurons which contain these gangliosides. It is not yet clear whether these gangliosides are the physiological receptors for tetanus toxin. By applying the techniques that established G_M1 as the receptor for cholera toxin, the role of gangliosides as receptors for tetanus toxin as well as physiological effectors may be elucidated.     

Gangliosides of Active and Inactive Neuroblastoma Clones

It is possible to divide neuroblastoma cells into clones able to synthesize neurotransmitters (active clones) or not (inactive clones).
The analysis of gangliosides of active and inactive clones shows that their total lipid sialic acids is markedly lower than that of neuron-enriched fractions prepared from brain. The ganglioside pattern of the cultured cells also differs notably from those obtained with neuronal fractions from brain. The absence of tri- and tetrasialogangliosides and the presence of appreciable amounts of the simplest monosialogangliosides are particularly noticeable in the neuroblastoma. Morphological differentiation obtained by serum deprivation, dibutyryl cyclic AMP or bromodeoxyuridine does not restore a true neuronal pattern. Gangliosides could not therefore be used as a marker of neuronal differentiation in this type of cell. No correlations can be found between the ganglioside pattern and the ability of cells to synthesize neurotransmitters.     

Gangliosides of active and inactive neuroblastoma clones.

It is possible to divide neuroblastoma cells into clones able to synthesize neurotransmitters (active clones) or not (inactive clones). The analysis of gangliosides of active and inactive clones shows that their total lipid sialic acids is markedly lower than that of neuron-enriched fractions prepared from brain. The ganglioside pattern of the cultured cells also differs notably from those obtained with neuronal fractions from brain. The absence of tri- and tetrasialogangliosides and the presence of appreciable amounts of the simplest monosialogangliosides are particularly noticeable in the neuroblastoma. Morphological differentiation obtained by serum deprivation, dibutyryl cyclic AMP or bromodeoxyuridine does not restore a true neuronal pattern. Gangliosides could not therefore be used as a marker of neuronal differentiation in this type of cell. No correlations can be found between the ganglioside pattern and the ability of cells to synthesize neurotransmitters.     

Two carbohydrate binding sites in the H(CC)-domain of tetanus neurotoxin are required for toxicity

Tetanus neurotoxin binds via its carboxyl-terminal H(C)-fragment selectively to neurons mediated by complex gangliosides. We investigated the lactose and sialic acid binding pockets of four recently discovered potential binding sites employing site-directed mutagenesis. Substitution of residues in the lactose binding pocket drastically decreased the binding of the H(C)-fragment to immobilized gangliosides and to rat brain synaptosomes as well as the inhibitory action of recombinant full length tetanus neurotoxin on exocytosis at peripheral nerves. The conserved motif of S(1287)XWY(1290) em leader G(1300) assisted by N1219, D1222, and H1271 within the lactose binding site comprises a typical sugar binding pocket, as also present, for example, in cholera toxin. Replacement of the main residue of the sialic acid binding site, R1226, again caused a dramatic decline in binding affinity and neurotoxicity. Since the structural integrity of the H(C)-fragment mutants was verified by circular dichroism and fluorescence spectroscopy, these data provide the first biochemical evidence that two carbohydrate interaction sites participate in the binding and uptake process of tetanus neurotoxin. The simultaneous binding of one ganglioside molecule to each of the two binding sites was demonstrated by mass spectroscopy studies, whereas ganglioside-mediated linkage of native tetanus neurotoxin molecules was ruled out by size exclusion chromatography. Hence, a subsequent displacement of one ganglioside by a glycoprotein receptor is discussed.     

Studies on the intoxication pathway of tetanus toxin in the rat pheochromocytoma (PC12) cell line. Binding, internalization, and inhibition of acetylcholine release

Tetanus toxin was found to be a potent inhibitor of neurosecretion in the rat pheochromocytoma cell line PC12, a system in which biochemical and functional studies could be performed in parallel. Incubation of the cells with 10 nM tetanus toxin (3 h) led to an inhibition of acetylcholine release by 75-80% when evoked by 200 microM veratridine, 1 mM carbachol, or 2 mM Ba2+. The main characteristics of the inhibition process are: 1) the toxin is very potent, with threshold doses of 10 pM; 2) the action of toxin is blocked at low temperature (0 degrees C) and by antitoxin; 3) the effects are dose- and time-dependent; 4) a concentration-dependent lag phase precedes the onset of the inhibitory effects. Thus the PC12 cultures are a valid system for studies on the underlying molecular process in tetanus action. This system was exploited by the use of long term incubation studies to examine the processes responsible for the lag phase. When cells were incubated with 0.1 nM 125I-tetanus toxin, cell-associated toxin reached a plateau of 16 fmol of toxin/mg of protein, yet the toxic effects did not appear until 12 h. Further, PC12 cells were found to rapidly internalize tetanus toxin, with a half-life of 1-2 min, once it was bound to the surface of the cells. Thus, the lag phase results from steps that occur in the intracellular compartment after internalization. An important discovery was that the differentiation state of the PC12 cells was a critical factor in determining sensitivity to tetanus toxin. Cells that were cultured with nerve growth factor for 8-12 days were very sensitive to toxin. In contrast, acetylcholine release from nondifferentiated, autodifferentiated, or dexamethasone-treated cultures was insensitive to tetanus toxin. Since differential expression of high affinity tetanus toxin receptors cannot explain these results, it is concluded that PC12 cells are capable of expressing different forms of excitation-secretion coupling mechanisms. Tetanus toxin should prove a valuable probe to further distinguish these processes.     

Botulinum Neurotoxin Serotype C Associates with Dual Ganglioside Receptors to Facilitate Cell Entry

Botulinum neurotoxins (BoNTs) cleave SNARE proteins in motor neurons that inhibits synaptic vesicle (SV) exocytosis, resulting in flaccid paralysis. There are seven BoNT serotypes (A–G). In current models, BoNTs initially bind gangliosides on resting neurons and upon SV exocytosis associate with the luminal domains of SV-associated proteins as a second receptor. The entry of BoNT/C is less clear. Characterizing the heavy chain receptor binding domain (HCR), BoNT/C was shown to utilize gangliosides as dual host receptors. Crystallographic and biochemical studies showed that the two ganglioside binding sites, termed GBP2 and Sia-1, were independent and utilized unique mechanisms to bind complex gangliosides. The GBP2 binding site recognized gangliosides that contained a sia5 sialic acid, whereas the Sia-1 binding site recognized gangliosides that contained a sia7 sialic acid and sugars within the backbone of the ganglioside. Utilizing gangliosides that uniquely recognized the GBP2 and Sia-1 binding sites, HCR/C entry into Neuro-2A cells required both functional ganglioside binding sites. HCR/C entered cells differently than the HCR of tetanus toxin, which also utilizes dual gangliosides as host receptors. A point-mutated HCR/C that lacked GBP2 binding potential retained the ability to bind and enter Neuro-2A cells. This showed that ganglioside binding at the Sia-1 site was accessible on the plasma membrane, suggesting that SV exocytosis may not be required to expose BoNT/C receptors. These studies highlight the utility of BoNT HCRs as probes to study the role of gangliosides in neurotransmission.     

Ganglioside GM1 Causes Expression of Type B Monoamine Oxidase in a Rat Clonal Pheochromocytoma Cell Line, PC12h

The effects of ganglioside supplementation of culture medium on monoamine oxidase (MAO) type A and B activities in a rat clonal pheochromocytoma cell line, PC12h, were examined. The MAO activity in PC12h cells proved to be mainly due to type A MAO, and type B MAO activity was negligible. After supplementation of the culture medium with ganglioside GM1, the PC12 cells were found to express type B MAO activity after 4 days of culture, and the amount of type B activity increased with the number of days of culture. After 3 weeks of culture in the presence of GM1, type B activity was about 10% of the total, whereas in control cells type B MAO activity was only about 0.6% of the total. By kinetic analyses of type A and B MAO in PC12h cells after 3 weeks of culture, the increase of type B MAO activity was found to be due to the increase in amount of type B MAO; the Km values were almost the same and only the Vmax values were increased in the cells supplemented with GM1. Among gangliosides tested GM1 was the most effective in causing expression of type B MAO activity, whereas nerve growth factor was not effective. These results suggest that GM1 and other gangliosides may be involved in the expression of type B MAO in nerve cells and in the regulation of levels of the biogenic amines in the brain.     

Identification of a binding site for ganglioside on the receptor binding domain of tetanus toxin

The carboxyl-terminal region of the tetanus toxin heavy chain (H(C) fragment) binds to di- and trisialylgangliosides on neuronal cell membranes. To determine which amino acids in tetanus toxin are involved in ganglioside binding, homology modeling was performed using recently resolved X-ray crystallographic structures of the tetanus toxin H(C) fragment. On the basis of these analyses, two regions in tetanus toxin that are structurally homologous with the binding domains of other sialic acid and galactose-binding proteins were targeted for mutagenesis. Specific amino acids within these regions were altered using site-directed mutagenesis. The amino acid residue tryptophan 1288 was found to be critical for binding of the H(C) fragment to ganglioside GT1b. Docking of GD1b within this region of the toxin suggested that histidine 1270 and aspartate 1221 were within hydrogen bonding distance of the ganglioside. These two residues were mutagenized and found also to be important for the binding of the tetanus toxin H(C) fragment to ganglioside GT1b. In addition, the H(C) fragments mutagenized at these residues have reduced levels of binding to neurites of differentiated PC-12 cells. These studies indicate that the amino acids tryptophan 1288, histidine 1270, and aspartate 1221 are components of the GT1b binding site on the tetanus toxin H(C) fragment.     

The structures of the H(C) fragment of tetanus toxin with carbohydrate subunit complexes provide insight into ganglioside binding

The entry of tetanus neurotoxin into neuronal cells proceeds through the initial binding of the toxin to gangliosides on the cell surface. The carboxyl-terminal fragment of the heavy chain of tetanus neurotoxin contains the ganglioside-binding site, which has not yet been fully characterized. The crystal structures of native H(C) and of H(C) soaked with carbohydrates reveal a number of binding sites and provide insight into the possible mode of ganglioside binding.     

Ganglioside modulation of neural cell adhesion molecule and N-cadherin- dependent neurite outgrowth

We have used monolayers of control 3T3 cells and 3T3 cells expressing transfected human neural cell adhesion molecule (NCAM) or chick N-cadherin as a culture substrate for PC12 cells. NCAM and N-cadherin in the monolayer directly promote neurite outgrowth from PC12 cells via a G-protein-dependent activation of neuronal calcium channels. In the present study we show that ganglioside GM1 does not directly activate this pathway in PC12 cells. However, the presence of GM1 (12.5-100 micrograms/ml) in the co-culture was associated with a potentiation of NCAM and N-cadherin-dependent neurite outgrowth. Treatment of PC12 cells with GM1 (100 micrograms/ml) for 90 min led to trypsin-stable increases in both beta-cholera toxin binding to PC12 cells and an enhanced neurite outgrowth response to N-cadherin. The ganglioside response could be fully inhibited by treatment with pertussis toxin. These data are consistent with exogenous gangliosides enhancing neuritic growth by promoting cell adhesion molecule-induced calcium influx into neurons.