Binding of tetanus toxin to somatic neural hybrid cells with varying ganglioside composition

Chronic epileptic foci in neocortex: in vivo and in vitro effects of tetanus toxin

Injection of 0.2 - 3.0 ng of tetanus toxin into rat parietal neocortex resulted in permanent (> 7 months) changes in the local circuit properties of this tissue. It caused excessive synchronization of neuronal activity. This was seen as spontaneous paroxysmal field potentials and/or evoked all-or-none population burst discharges. Such activity was recorded widely over the parietal and temporal areas of both the injected and the contralateral hemispheres from as little as 16 h after injection up to the maximum survival time of 7 months. Several observations suggest that the speed with which the hypersynchronous activity spread to the opposite hemisphere reflects transport of the toxin through corticocortical axons, and consequent blockade of synaptic inhibition. However, from what is known of the half life of the peptide in brain, it is unlikely that the persistent, widespread distribution of epileptiform discharge several months after injection was due to the continued presence of toxin. Thus, intracortical application of tetanus toxin provides a good experimental model of chronic focal epilepsies, and raises fundamental questions regarding the long term regulation of local circuit properties in the neocortex.

Neurotoxins affecting neuroexocytosis

Nerve terminals are specific sites of action of a very large number of toxins produced by many different organisms. The mechanism of action of three groups of presynaptic neurotoxins that interfere directly with the process of neurotransmitter release is reviewed, whereas presynaptic neurotoxins acting on ion channels are not dealt with here. These neurotoxins can be grouped in three large families: 1) the clostridial neurotoxins that act inside nerves and block neurotransmitter release via their metalloproteolytic activity directed specifically on SNARE proteins; 2) the snake presynaptic neurotoxins with phospholipase A(2) activity, whose site of action is still undefined and which induce the release of acethylcholine followed by impairment of synaptic functions; and 3) the excitatory latrotoxin-like neurotoxins that induce a massive release of neurotransmitter at peripheral and central synapses. Their modes of binding, sites of action, and biochemical activities are discussed in relation to the symptoms of the diseases they cause. The use of these toxins in cell biology and neuroscience is considered as well as the therapeutic utilization of the botulinum neurotoxins in human diseases characterized by hyperfunction of cholinergic terminals.

Successive isolation and separation of the major lipid fractions including gangliosides from single biological samples

Currently available techniques concerning extraction and characterization of the different lipids from biological specimens are designed for particular families and do not address consecutive isolation of lipid constituents in their globality. We describe here a simple, nondestructive chromatographic procedure that allows efficient elution and further analysis of the major lipid classes (neutral lipids, phospholipids, nonsialylated sphingolipids, and gangliosides) in their natural states from the same starting material. The procedure describes the use of solvent mixtures adapted to silicic acid column chromatography and permits 90-97% recovery of each of the above lipid groups. We have particularly concentrated on optimizing the efficient recovery of the diverse minor forms of gangliosides, free of other contaminants, from relatively small amounts of neural tissue. As model systems we have used in vivo and in vitro preparations of mammalian retina for which only fragmentary data are available on lipid composition. We show that relative to brain, retina contains, for example, twofold more sphingomyelin and sixfold more GD3 ganglioside. In turn, cultured retinal glial cells contain twofold higher levels of globoside and eightfold higher amounts of GM3 ganglioside with respect to intact retina. Compared to previously published techniques, we obtain improved total ganglioside recovery, with enrichment of poly-sialogangliosides. The technique presented here should be widely applicable to analyze global lipid composition of diverse biological samples.

Acidification of the cytosol inhibits the uptake of tetanus toxin in NG108-15 and NBr-10A neurohybridoma cells

The influence of cytosol acidification on the uptake of two-chain tetanus toxin (TeTX)1 by neurohybridoma cells NG 108-15 and NBr-10A was investigated with two established techniques, the NH4Cl pulse method and the pH-clamp method. With the former, the extracellular pH is maintained at its physiological value, but is set to different values with the latter. Acidification of the cytoplasm with an NH4Cl pulse retarded the uptake of TeTX by both NG 108-15 and NBr-10A cells. This result provides further evidence for a vesicular endocytotic uptake of TeTX. In contrast, acidification of both the external medium and the cytoplasm (pH-clamp method) resulted in a net increase of toxin uptake. This result is explained as follows: Acidification of the extracellular environment has been shown to facilitate the uptake of tetanus toxin, and under pH clamp conditions, this effect is stronger than the simultaneous retardation of the toxin uptake by acidification also of the cytosol.

Structure and function of tetanus and botulinum neurotoxins

Tetanus and botulinum neurotoxins are produced by Clostridia and cause the neuroparalytic syndromes of tetanus and botulism. Tetanus neurotoxin acts mainly at the CNS synapse, while the seven botulinum neurotoxins act peripherally. Clostridial neurotoxins share a similar mechanism of cell intoxication: they block the release of neurotransmitters. They are composed of two disulfide-linked polypeptide chains. The larger subunit is responsible for neurospecific binding and cell penetration. Reduction releases the smaller chain in the neuronal cytosol, where it displays its zinc-endopeptidase activity specific for protein components of the neuroexocytosis apparatus. Tetanus neurotoxin and botulinum neurotoxins B, D, F and G recognize specifically VAMP/ synaptobrevin. This integral protein of the synaptic vesicle membrane is cleaved at single peptide bonds, which differ for each neurotoxin. Botulinum A, and E neurotoxins recognize and cleave specifically SNAP-25, a protein of the presynaptic membrane, at two different sites within the carboxyl-terminus. Botulinum neurotoxin type C cleaves syntaxin, another protein of the nerve plasmalemma. These results indicate that VAMP, SNAP-25 and syntaxin play a central role in neuroexocytosis. These three proteins are conserved from yeast to humans and are essential in a variety of docking and fusion events in every cell. Tetanus and botulinum neurotoxins form a new group of zinc-endopeptidases with characteristic sequence, mode of zinc coordination, mechanism of activation and target recognition. They will be of great value in the unravelling of the mechanisms of exocytosis and endocytosis, as they are in the clinical treatment of dystonias.

Injection of tetanus toxin into the neocortex elicits persistent epileptiform activity but only transient impairment of GABA release

Focal injection of a minute quantity of tetanus toxin into the rat neocortex induces chronic epileptogenesis. Within a day, spontaneous and stimulus-evoked paroxysmal discharges appear in widespread regions of both hemispheres and this lasts for at least nine months. Tetanus toxin blocks transmitter release, apparently by catalysing the breakdown of synaptobrevin, a synaptic protein. It specifically binds to neuronal membranes but its potent epileptogenic properties have been ascribed to a higher affinity for inhibitory neurons. Following focal injection of tetanus toxin into the hippocampus a long-lasting epileptic syndrome also develops. During the early part of the syndrome GABA release is depressed in slices from the injected side, but not in slices from the contralateral, secondary focus. In the present experiments on neocortex, release of radiolabelled GABA was measured from primary and secondary epileptic foci induced by unilateral focal injection of tetanus toxin into the parietal cortex. By four weeks after the injection, no differences were detected in GABA release from any neocortical site in control or toxin-injected animals, despite the persistence of profound epileptic activity in slices from the latter. At earlier times (1.5 days) after the toxin injection, however, release was significantly depressed in both hemispheres. The results indicate that at first, the toxin induces focal neocortical epileptogenesis by directly impeding GABAergic synaptic transmission but that with time there is a recovery from this initial effect. We propose, as has also been suggested for other models, that the initial epileptogenesis leaves in its wake a long-lasting change in the local functional connectivity, such that the neocortex is rendered permanently epileptic.

Development of glutamate neurotoxicity in cortical cultures: induction of vulnerability by insulin

The effect of insulin on the development of excitotoxic vulnerability in primary cultures of the rat cerebral cortex was examined. Cells were maintained for two weeks in serum-supplemented culture media, in the presence or absence of increasing insulin concentrations. Excitotoxic cell death was induced by 1 mM glutamate. The vulnerability of cells was evaluated by phase contrast microscopy and by the measurement of lactate dehydrogenase (LDH) release due to cytotoxic injury. In addition to a moderate (less than 50%) stimulation of protein and DNA synthesis, insulin produced more than a twofold increase in the excitotoxic vulnerability of cells. The effect of insulin was specific, concentration-dependent and required an intact molecular structure of insulin. Our findings indicate that insulin induces significant changes in cerebral neurons by increasing the lethal vulnerability of cortical cells to excitatory amino acids (EAAs).

Gangliosides: the relevance of current research to neurosurgery

Gangliosides are complex glycolipids found on the outer surface of most cell membranes: they are particularly concentrated in tissues of the nervous system. Gangliosides form part of the immunological identity of mammalian cells and are involved in a variety of cell-surface phenomena such as cell-substrate binding and receptor functions. In tumorous tissue, the ganglioside composition is altered, sometimes in direct proportion to the degree of malignancy. The literature on the glycosphingolipid composition and immunology of intracranial tumors is reviewed. Some gangliosides induce neuritogenesis and exhibit a trophic effect on nerve cells grown in vitro. In vivo, a particular ganglioside, GM1, reduces cerebral edema and accelerates recovery from injury (traumatic and ischemic) to the peripheral and central nervous systems of laboratory animals. Preliminary clinical studies have shown that treatment with gangliosides may have corresponding effects on lesions of the human peripheral nervous system. Gangliosides have not been tested in human subjects with brain injury.

Plasticity of presynaptic and postsynaptic elements of neuromuscular junctions repeatedly observed in living adult mice

In order to assay the extent of ongoing synaptic remodelling in adult mouse neuromuscular junctions, dynamic structural changes of identified neuromuscular junctions were monitored in vivo over periods up to three months. Nerve terminal outgrowths as small as 1 micron were detectable with a new fluorescent tetanus toxin C-fragment stain combined with fluoresceinated alpha-bungarotoxin to stain postsynaptic acetylcholine receptors. With limited illumination, the new stain did not affect miniature endplate potential frequency, nor morphometric parameters of repeatedly observed neuromuscular junctions. At each observation, areas of presynaptic nerve terminal extending beyond underlying acetylcholine receptor ('preprojections'), and areas of acetylcholine receptor without overlying nerve terminal ('postprojections') were measured. Regions of the neuromuscular junction in which nerve terminal-postsynaptic acetylcholine receptor complexes either 'lengthened' or 'shortened' between observations were also measured. The total area of pre- and postprojections (relative to total junctional area) remained the same over three months but most had been replaced; only 20% of preprojections gave rise to lengthenings, the rest retracted or were unchanged. Lengthening and shortening of branches were about 1-2% of junctional area per month. These more permanent changes occurred against a background of ongoing transient nerve terminal outgrowth and retraction (which constituted 80% of all neuromuscular junction shape changes from one observation to the next, compared with 20% for the postsynaptic component). Breaks in the continuity of the underlying acetylcholine receptor were also observed between observations as were instances where acetylcholine receptor continuity was re-established. A newly observed form of plasticity was a shift in position and angle of pre-existing branches. Establishment of new acetylcholine receptor-positive synaptic regions was mostly preceded by nerve terminal outgrowth on the previous observation. In animals in which spontaneous wheel-running increased locomotor activity approximately tenfold over a period of 35 days, the findings were identical to those in unexercised mice. In summary, in the adult neuromuscular junction, the nerve terminal, not the postsynaptic component, is the dynamic entity, continually changing shape on the scale of micrometers, with relatively small permanent changes. These ongoing exploratory excursions may supply the substrate for synaptic plasticity, which would involve regulation of the dynamics or stability of nerve outgrowth.

Preparation of affinity-purified, biotinylated tetanus toxin, and characterization and localization of cell surface binding sites on nerve growth factor-treated PC12 cells

Biotinylated derivatives of tetanus toxin were prepared and isolated by chromatofocusing and ganglioside-affinity chromatography. Biotinylation was monitored by the appearance of a 210,00 dalton complex upon SDS-polyacrylamide gel electrophoresis in the presence of avidin, and by selective binding to an avidin-Sepharose gel. At molar biotin:toxin ratios from 1:1 to 20:1 only biotinylated derivatives with low toxicity were obtained; these derivatives, however, retained 60-80% of their specific binding affinity for brain synaptosomes. A biotinylated tetanus toxin derivative purified by ganglioside-affinity chromatography was used to identify and localize tetanus toxin binding sites on PC12 cells. Electron microscopic analysis with streptavidin-gold revealed very low levels of tetanus toxin binding sites on the surface of untreated cells, and the appearance of such binding sites during the second week of nerve growth factor-induced differentiation. Examination of micrographs of the differentiated cells indicated that the tetanus toxin binding sites sites are concentrated on the neurites, with relatively few appearing on the cell bodies. Cognate studies using 125I-labeled, affinity-purified tetanus toxin revealed an increase in PC12 binding capacity from about 0.07 nmol/mg protein in untreated cells to 0.8 nmoles/mg protein in cells treated for 14 days with nerve growth factor. Cells treated in suspension for 2-3 weeks with nerve growth factor do not express tetanus toxin binding sites; upon plating, these cells required one week for the appearance of binding sites, although neurites grew much more rapidly from these "primed" cells. The high binding capacity of these tetanus toxin sites, as well as their sensitivity to neuraminidase, is indicative of a polysialoganglioside structure. The advantages of biotinylated tetanus toxin derivatives are discussed and the significance of nerve growth factor-differentiated PC12 cells grown as monolayers as a model for the study of the development, localization, and function of neuraminidase-sensitive tetanus toxin binding sites is presented.

Tetanus toxin attenuates the ability of phorbol myristate acetate to mobilize cytosolic protein kinase C in NG-108 cells

Although the pathology of tetanus toxin poisoning has been linked to an inhibition of neurotransmitter release, the mechanism of this inhibition is unknown. The neuroblastoma x glioma hybrid cell NG-108 is an emerging model in which to study the biochemical effect of tetanus toxin on acetylcholine secretion. In differentiated as well as undifferentiated NG-108 cells, a 4 hr tetanus toxin (10(-8) M) pretreatment had no effect on basal levels of cyclic AMP or cyclic GMP. In addition, toxin pretreatment did not affect agonist induced increases in either cyclic nucleotide. Treatment of NG-108 cells for 4 hr with 10(-10) M tetanus toxin had no effect on the subsequently measured activity of cytosolic protein kinase C. However, a 4 hr pretreatment of undifferentiated or differentiated cells with tetanus toxin (10(-8) or 10(-10) M respectively) significantly attenuated the ability of phorbol myristate acetate to mobilize cytosolic protein kinase C. Direct addition of tetanus toxin (10(-7)-10(-10) M) to isolated protein kinase C did not alter the ability of the enzyme to phosphorylate histone protein. These results suggest that one manifestation of tetanus toxin poisoning may be a disruption in protein kinase C metabolism.

Involvement of GABA receptors in the regulation of neurite growth in cultured embryonic chick tectum

Modulation of neurite growth by gamma-aminobutyric acid (GABA) and several agonists and antagonists to its receptors was analysed in neuronal cultures of embryonic chick tectum and rat cerebellum, respectively, using morphometric methods. In each case, modulation of growth by GABA was similar in both types of neurons. However, data on neurite elongation suggest differential effects depending on the culture medium used. In serum-containing medium GABA stimulated neurite growth. In serum-free, defined medium the opposite effect was observed, i.e. GABA inhibited neurite elongation in tectal as well as in cerebellar cultures. When agonists of the GABAA-receptor were employed stimulation of neurite outgrowth was observed in serum-supplemented medium but not in serum-free medium. These ligands could not influence the inhibition of neurite growth caused by GABA. In contrast, the GABAB-receptor agonist (-)baclofen inhibited neurite elongation in serum-free medium without affecting cells in the presence of serum. Phaclofen, a GABAB-receptor antagonist, induced quite the opposite effect. It stimulated neurite elongation in serum-free culture conditions and prevented the inhibition induced by GABA in a concentration-dependent manner. In serum-supplemented medium it had no effect. The data suggest that GABAA-receptors may be involved in the GABA-induced neurite elongation in serum-supplemented medium only, although this subtype of receptors is present in serum-free conditions as well as revealed in binding studies using [3H]muscimol. Whether GABAB-receptors and/or as yet undefined mechanisms are responsible for the different action of GABA in serum-free medium is subject of further investigations.

Periodate-modified gangliosides enhance surface binding of tetanus toxin to PC12 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.

Coordinate regulation of ganglioside glycosyltransferases in differentiating NG108-15 neuroblastoma x glioma cells

The enzymatic basis for ganglioside regulation during differentiation of NG108-15 mouse neuroblastoma x rat glioma hybrid cells was studied. This cell line contains four gangliosides that lie along the same biosynthetic pathway: GM3, GM2, GM1, and GD1a. Chemically induced neuronal differentiation of NG108-15 cells led to an 80% drop in the steady-state level of their major ganglioside, GM3, a sixfold increase in the level of a minor ganglioside, GM2 (which became the predominant ganglioside of differentiated cells); and relatively little change in the levels of GM1 and GD1a, which lie further along the same biosynthetic pathway. The enzymatic basis for this selective change in ganglioside expression was investigated by measuring the activity of two glycosyltransferases involved in ganglioside biosynthesis. UDP-N-acetylgalactosamine: GM3 N-acetylgalactosaminyltransferase (GM2-synthetase) activity increased fivefold during butyrate-induced differentiation, whereas UDP-galactose: GM2 galactosyltransferase (GM1-synthetase) activity decreased to 10% of its control level. Coordinate regulation of these two glycosyltransferases appears to be primarily responsible for the selective increase of GM2 expression during NG108-15 differentiation.

Filopodia, lamellipodia and retractions at mouse neuromuscular junctions

In order to determine if mature motor nerve terminals retain structures associated with development such as filopodia and lamellipodia, we studied whole mounts of mature mouse neuromuscular junctions stained with both fluorescent-labelled tetanus toxin C-fragment and alpha-bungarotoxin, and employed electron microscopy in parallel. The rapid fluorescent stain may be of general usefulness. Both filopodia and lamellipodia were found, extending beyond the border of the established postsynaptic receptors. Filopodia often appeared in clusters, were devoid of a synaptic vesicle antigen, and many withdrew in response to cytochalasin D. Control experiments demonstrated that filopodia were not induced by the toxin treatment. The mean number of filopodia per endplate varied from about one in phasic muscle to three in tonic muscle, and was twice as great in immature mouse muscle. Postsynaptic receptor-rich regions without overlying terminals were less numerous than filopodial and lamellipodial projections without underlying receptors. Electron microscopy showed that lamellipodia contained actin-like filaments and immunoreactivity to actin, but no neurofilaments, microtubules, mitochondria or vesicles. Therefore, these structures would not be visualized by in vivo mitochondrial stains. The lamellipodia protruded into the gap between muscle and a closely overlying Schwann cell process. Lamellipodia occupied about 5% of the linear extent of the terminal arbor in whole mounts, but appeared in 16% of random electron micrographic fields. Thus, the lamellipodia and filopodia typical of developing terminals are present in adulthood and represent a distinctive specialization of the nerve terminal, which may interact with the adjacent Schwann and muscle cell. The frequency of filopodia is a function of age and of muscle or motoneuron type. We suggest that some of the factors known to regulate growth of filopodia and lamellipodia in vitro or in development may continue to act at adult presynaptic nerve terminals.

Tetanus toxin in dissociated spinal cord cultures: long-term characterization of form and action

The clinical course of tetanus is notable, in addition to its often dramatic clinical presentation, by the long duration of the neuromuscular symptoms. Survivors may have tetanic manifestations for several weeks after the onset of the disease. In this article we correlate the duration of specific electrophysiologic effects produced by tetanus toxin with the degradation of cell-associated toxin in primary cultures of mouse spinal cord neurons. From these studies we can conclude that the toxin has a half-life of 5-6 days. Both the heavy and the light chains of tetanus toxin degrade at similar rates. Labeled toxin, visualized by radioautography, is associated with neuronal cell bodies and neurites, and its distribution is not altered during a 1-week period following toxin exposure. Blockade of synaptic activity persists for weeks at the concentration of radiolabeled toxin used in these studies. This blockade of transmission is reversed as the toxin is degraded, suggesting that degradation of toxin may be a sufficient mechanism for recovery from tetanus.

Attenuation of inhibitory processes in the central nervous system by tetanus toxin: an in vitro study on rat hippocampal slices

The influence of tetanus toxin on the efficiency of recurrent inhibition in the rat hippocampal slice was tested. The efficiency of the recurrent inhibition diminished in a dose-dependent manner following incubation of the slices with tetanus toxin. The effect was not observed in the slices preincubated for 3 hours with neuraminidase from Vibrio cholerae. This treatment reduces markedly the level of polysialogangliosides (receptor for tetanus toxin). It is concluded that tetanus toxin influences the efficiency of some inhibitory synapses in the central nervous system and that a certain level of polysialogangliosides is necessary for tetanus toxin to exert its action.

Possible role of gangliosides in regulating an adenylate cyclase-linked 5-hydroxytryptamine (5-HT1) receptor

Cultured NCB-20 hybrid cells express adenylate cyclase-coupled receptors for 5-hydroxytryptamine (5-HT) that correspond biochemically and pharmacologically to 5-HT1 receptors in rodent brain membrane preparations, apart from a much-reduced affinity for 5-HT (160 nM compared to less than 5 nM in brain). Since NCB-20 cells also differ from rodent brain both qualitatively and quantitatively in their ganglioside composition, the effects of exogenously added gangliosides on the affinity of the 5-HT1 receptor for 5-HT were tested. Both GM1 ganglioside (the cholera toxin receptor) and tetrasialoganglioside GQ1b produced a 10-fold increase in receptor affinity for [3H]5-HT, measured by binding studies. All gangliosides, at submicromolar concentrations, resulted in significantly reduced EC50 values for 5-HT-mediated elevation of intracellular cyclic AMP levels. GQ1b had the capacity to most dramatically enhance the potency of 5-HT in mediating increases in cyclic AMP levels. Gangliosides had no effect on the potency of DADLE or 3,4-dihydroxyphenylethylamine (dopamine)-mediated depression of cyclic AMP levels, suggesting some specificity for 5-HT. Our data are interpreted as implying a specific role for polysialogangliosides in modulating the affinity of the 5-HT1 receptor and the coupling of the 5-HT1 receptor-guanine nucleotide binding protein adenylate cyclase complex.

Fate of tetanus toxin bound to the surface of primary neurons in culture: evidence for rapid internalization

We examined the nature of the tetanus toxin receptor in primary cultures of mouse spinal cord by ligand blotting techniques. Membrane components were separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and transferred to nitrocellulose sheets, which were overlaid with 125I-labeled tetanus toxin. The toxin bound only to material at or near the dye front, which was lost when the cells were delipidated before electrophoresis. Gangliosides purified from the lipid extract were separated by thin-layer chromatography and the chromatogram was overlaid with 125I-toxin. The toxin bound to gangliosides corresponding to GD1b and GT1b. Similar results were obtained with brain membranes; thus, gangliosides rather than glycoproteins appear to be the toxin receptors both in vivo and in neuronal cell cultures. To follow the fate of tetanus toxin bound to cultured neurons, we developed an assay to measure cell-surface and internalized toxin. Cells were incubated with tetanus toxin at 0 degree C, washed, and sequentially exposed to antitoxin and 125I-labeled protein A. Using this assay, we found that much of the toxin initially bound to cell surface disappeared rapidly when the temperature was raised to 37 degrees C but not when the cells were kept at 0 degree C. Some of the toxin was internalized and could only be detected by our treating the cells with Triton X-100 before adding anti-toxin. Experiments with 125I-tetanus toxin showed that a substantial amount of the toxin bound at 0 degree C dissociated into the medium upon warming of the cells. Using immunofluorescence, we confirmed that some of the bound toxin was internalized within 15 min and accumulated in discrete structures. These structures did not appear to be lysosomes, as the cell-associated toxin had a long half-life and 90% of the radioactivity released into the medium was precipitated by trichloroacetic acid. The rapid internalization of tetanus toxin into a subcellular compartment where it escapes degradation may be important for its mechanism of action.

Tunicamycin blocks neuritogenesis and glucosamine labeling of gangliosides in developing cerebral neuron cultures

Fetal cerebral neurons at the initiation of active neurite outgrowth in culture incorporate 4-fold more [3H]glucosamine into glycoproteins than into the cellular lipid fraction. After 8 days or longer, when a well-developed fiber network is apparent, lipids are labeled more extensively than the glycoproteins. Labeling of the latter is inhibited 95% and 89% by 0.5 microgram of tunicamycin per ml added to 1-day-old and 8-day-old cultures, respectively. Labeling of glycolipids is inhibited 30% in 1-day-old and 86% in 8-day-old cultures. Tunicamycin blocks incorporation of glucosamine label into practically all ganglioside species except for a resorcinol-positive, sialidase-sensitive band tentatively identified as GQ1b tetrasialoganglioside (Svennerholm ganglioside nomenclature). It also substantially reduces binding of 125I-labeled tetanus toxin to intact cells. There is 14% and 27% reduction in the total ganglioside sialic acid content in 1-day-old and 8-day-old cells treated for 24 hr with 0.5 microgram of tunicamycin per ml, but no substantial compositional changes are encountered. Tunicamycin blocks neurite outgrowth when added to cells soon after plating but causes no retraction or losses of fibers once the fiber network is established. Therefore, inhibition of neurite outgrowth by tunicamycin is not due to an effect on cellular gangliosides but can be correlated to an inhibition of protein glycosylation.

Increasing membrane polyunsaturated fatty-acid content augments cyclic AMP formation and prostaglandin production in NIE-115 neuroblastoma

Addition of linoleic acid (50 microM) to culture medium significantly increases levels of polyunsaturated fatty acids (PUFA) in membrane phospholipids of NIE-115 neuroblastoma. Basal levels of cyclic AMP are elevated significantly in supplemented cells. Exogenous prostaglandins (PG) PGE1 and PGD2 stimulate cAMP formation in NIE-115 neuroblastoma. Supplemented cells produce higher levels of PGE and PGD than do control cultures. Inclusion of cyclooxygenase inhibitors in culture medium does not block elevation of cyclic nucleotide in supplemented cells. Endogenous PG production and receptor activation cannot account for increased cAMP in EFA-supplemented neuroblastoma.