Studies on the Intoxication Pathway of Tetanus Toxin in the Rat Pheochromocytoma (PC12) Cell Line

Dopamine, a key factor of mitochondrial damage and neuronal toxicity on rotenone exposure and also parkinsonic motor dysfunction-Impact of asiaticoside with a probable vesicular involvement

Persuasive evidence propose that the toxicity of dopamine in parkinsonism and the loss of dopaminergic neurons are the earliest events during the pathogenesis of Parkinson's disease (PD). In our earlier study, Asiaticoside (AS), a triterpenoid saponin isolated from Centella asiatica was shown to exert a neuroprotective effect against hemiparkinsonism, purportedly due to phosphoinositides (PI)-assisted cytodynamics and synaptic function. Here, we evaluate AS in the modulation of dopamine (DA), mitochondrial integrity and neurite variations in vitro and motor dysfunctions in vivo. PC12 cells challenged with rotenone-(ROT) (0.1 μM/mL) were exposed to AS and l-DOPA (10 mM and 20 μM/mL respectively). The protein expressions of Bax and Bcl-2 that regulate cell death were assessed following neurite length assays. Rats were distributed into 6 groups (6 rats/group): Sham, Vehicle controls, ROT-infused (6 μg/μl/kg), AS- treated (50 mg/kg/day), Drug control, and ROT + L-DOPA-treated (6 mg/kg/day) groups. At the end of the experimental period, the rats were sacrificed after performing motor behavioral analysis, and the striatum was dissected out. The contents of synaptic vesicular and cytosolic DA were analyzed. Further, the levels of striatal PI were also measured. ROT had caused significant reduction in the neurite outgrowth in the exposed PC12 cells while the tested concentrations of AS and l-DOPA can exert their protective effect on the stunted neurite growth. The levels of Bax, Bcl-2, and cytochrome c which were significantly disturbed by ROT, could also be affected by AS thereby suggesting its effect on neurons. AS treatment caused an improved motor performance, vesicular and cytosolic DA, and striatal PI. These pre-clinical findings force us to speculate that AS could be a potential drug candidate in combating ROT-induced variations that are possibly precipitated by varied vesicular trafficking of DA.

Botulinum toxin a inhibits acetylcholine release from cultured neurons in vitro

Clostridium botulinum type toxin A (BoTx) blocks stimulus-induced acetylcholine (ACh) release from presynaptic nerve terminals at peripheral neuromuscular junctions. However, the detailed mechanism of this effect remains elusive. One obstacle in solving this problem is the lack of a suitable in vitro homogenous cholinergic neuronal model system. We studied the clonal pheochromocytoma PC12 cell line to establish such a model. PC12 cells were differentiated in culture by treatment with 50 ng/ml nerve growth factor (NGF) for 4 days to enhance cellular ACh synthesis and release properties. Stimulation of these cells with high K(+) (80 mM) in the perfusion medium markedly increased calcium-dependent [(3)H]ACh release compared to undifferentiated cells. Stimulated [(3)H]ACh release was totally inhibited by pretreatment of cells with 2 nM BoTx for 2 h. BoTx inhibition of [(3)H]ACh release was time- and concentration-dependent. A 50% inhibition was obtained after 2 h incubation with a low (0.02 nM) toxin concentration. The time required for 2 nM BoTx to cause a measurable inhibition (18%) of stimulated [(3)H]ACh release was 30 min. Botulinum toxin inhibition of stimulated ACh release was prevented by toxin antiserum and heat treatment, suggesting the specificity of the toxin effect. Our results show that by differentiation with NGF, PC12 cells can be shifted from an insensitive to a sensitive state with respect to BoTx inhibition of stimulated ACh release. This cell line, therefore, may serve as a valuable in vitro cholinergic model system to study the mechanism of action of BoTx.

In vitro models for neurotoxicology research

The nervous system has a highly complex organization, including many cell types with multiple functions, with an intricate anatomy and unique structural and functional characteristics; the study of its (dys)functionality following exposure to xenobiotics, neurotoxicology, constitutes an important issue in neurosciences.

Double anchorage to the membrane and intact inter-chain disulfide bond are required for the low pH induced entry of tetanus and botulinum neurotoxins into neurons

Tetanus and botulinum neurotoxins are di-chain proteins that cause paralysis by inhibiting neuroexocytosis. These neurotoxins enter into nerve terminals via endocytosis inside synaptic vesicles, whose acidic pH induces a structural change of the neurotoxin molecule that becomes capable of translocating its L chain into the cytosol, via a transmembrane protein-conducting channel made by the H chain. This is the least understood step of the intoxication process primarily because it takes place inside vesicles within the cytosol. In the present study, we describe how this passage was made accessible to investigation by making it to occur at the surface of neurons. The neurotoxin, bound to the plasma membrane in the cold, was exposed to a warm low pH extracellular medium and the entry of the L chain was monitored by measuring its specific metalloprotease activity with a ratiometric method. We found that the neurotoxin has to be bound to the membrane via at least two anchorage sites in order for a productive low-pH induced structural change to take place. In addition, this process can only occur if the single inter-chain disulfide bond is intact. The pH dependence of the conformational change of tetanus neurotoxin and botulinum neurotoxin B, C and D is similar and take places in the same slightly acidic range, which comprises that present inside synaptic vesicles. Based on these and previous findings, we propose a stepwise sequence of molecular events that lead from toxin binding to membrane insertion.

Bacterial toxins and the nervous system: neurotoxins and multipotential toxins interacting with neuronal cells

Toxins are potent molecules used by various bacteria to interact with a host organism. Some of them specifically act on neuronal cells (clostridial neurotoxins) leading to characteristics neurological affections. But many other toxins are multifunctional and recognize a wider range of cell types including neuronal cells. Various enterotoxins interact with the enteric nervous system, for example by stimulating afferent neurons or inducing neurotransmitter release from enterochromaffin cells which result either in vomiting, in amplification of the diarrhea, or in intestinal inflammation process. Other toxins can pass the blood brain barrier and directly act on specific neurons.

Dynamics of intracellular oxygen in PC12 Cells upon stimulation of neurotransmission

Neurotransmission, synaptic plasticity, and maintenance of membrane excitability require high mitochondrial activity in neurosecretory cells. Using a fluorescence-based intracellular O2 sensing technique, we investigated the respiration of differentiated PC12 cells upon depolarization with 100 mm K+. Single cell confocal analysis identified a significant depolarization of the plasma membrane potential and a relatively minor depolarization of the mitochondrial membrane potential following K+ exposure. We observed a two-phase respiratory response: a first intense spike lasting approximately 10 min, during which average intracellular O2 was reduced from 85-90% of air saturation to 55-65%, followed by a second wave of smaller amplitude and longer duration. The fast rise in O2 consumption coincided with a transient increase in cellular ATP by approximately 60%, which was provided largely by oxidative phosphorylation and by glycolysis. The increase of respiration was orchestrated mainly by Ca2+ release from the endoplasmic reticulum, whereas the influx of extracellular Ca2+ contributed approximately 20%. Depletion of Ca2+ stores by ryanodine, thapsigargin, and 4-chloro-m-cresol reduced the amplitude of respiratory spike by 45, 63, and 71%, respectively, whereas chelation of intracellular Ca2+ abolished the response. Uncoupling of the mitochondria with the protonophore carbonyl cyanide p-trifluoromethoxyphenylhydrazone amplified the responses to K+; elevated respiration induced a profound deoxygenation without increasing the cellular ATP levels reduced by carbonyl cyanide p-trifluoromethoxyphenylhydrazone. Cleavage of synaptobrevin 2 by tetanus toxin, known to reduce neurotransmission, did not affect the respiratory response to K+, whereas the general excitability of d PC12 cells increased.

Differential Effects of Tetanus Toxin on Inhibitory and Excitatory Neurotransmitter Release from Mammalian Spinal Cord Cells in Culture

The effect of tetanus toxin on depolarization-evoked and spontaneous synaptic release of inhibitory and excitatory neurotransmitters was examined in murine spinal cord cell cultures. Toxin action on the release of radiolabeled glycine and glutamate was followed over time intervals corresponding to the early phase of convulsant activity through the later phase of electrical quiescence. Tetanus toxin inhibited potassium-evoked release of [3H]glycine and [3H]glutamate in a time- and dose-dependent manner. Ninety minutes after the application of toxin (6 x 10(-10) M), the stimulated release of [3H]glycine was blocked completely, whereas stimulated release of [3H]glutamate was not blocked completely until 150-210 min after toxin application. Fragment C, the binding portion of the tetanus toxin molecule, had no effect on stimulated release of either transmitter. The spontaneous synaptic release of [3H]glycine was blocked totally within 90 min of toxin exposure. In contrast, the spontaneous release of [3H]glutamate, in toxin-exposed cultures, was elevated to nearly twice that of control cultures at this time. Thus, toxin-induced convulsant activity is characterized by a reduction in the spontaneous synaptic release of inhibitory neurotransmitter with a concomitant increase in the release of excitatory neurotransmitter, as well as the more rapid onset of blockade of depolarization-evoked release of inhibitory versus excitatory neurotransmitter.

Repeated Amphetamine Couples Norepinephrine Transporter and Calcium Channel Activities in PC12 Cells

Repeated intermittent amphetamine enhances efflux of dopamine through the dopamine transporter in rat basal ganglia and through the norepinephrine transporter in rat pheochromocytoma PC12 cells. Extracellular Ca2+ is required for the detection of this enhancement in the rat. In this study, we examined the role of Ca2+ and Ca2+ channels in the enhanced amphetamine-induced dopamine efflux that develops in PC12 cells following repeated intermittent amphetamine. Repeated pretreatment of PC12 cells with 1 microM amphetamine followed by a drug-free period increased amphetamine-induced efflux of dopamine compared with controls. The enhancement in amphetamine-induced dopamine efflux depended upon the presence of extracellular Ca2+ and was inhibited by the blockade of N-type and L-type Ca2+ channels. The enhanced dopamine efflux was not altered by tetanus toxin or reserpine, treatments that abrogate synaptic vesicle-mediated, exocytotic dopamine efflux. Measurement of intracellular Ca2+ concentrations using fura-2/acetoxymethyl ester revealed that amphetamine increased intracellular Ca2+ by a transporter-dependent mechanism. In amphetamine-pretreated cells, amphetamine elicited a greater increase in intracellular Ca2+; this increase depended upon the presence of extracellular Ca2+ and N- and L-type Ca2+ channel activity. The enhanced amphetamine-induced dopamine efflux requires Ca2+/calmodulin kinase activity. In vehicle-treated cells, 1 microM amphetamine inhibited the calmodulin kinase activity although it did not in amphetamine-pretreated cells. This study suggests that repeated intermittent amphetamine couples norepinephrine transporter activity and Ca2+ signaling.

A survival motor neuron:tetanus toxin fragment C fusion protein for the targeted delivery of SMN protein to neurons

Spinal muscular atrophy (SMA) is a degenerative disorder of spinal motor neurons caused by homozygous mutations in the survival motor neuron (SMN1) gene. Because increased tissue levels of human SMN protein (hSMN) in transgenic mice reduce the motor neuron loss caused by murine SMN knockout, we engineered a recombinant SMN fusion protein to deliver exogenous hSMN to the cytosolic compartment of motor neurons. The fusion protein, SDT, is comprised of hSMN linked to the catalytic and transmembrane domains of diphtheria toxin (DTx) followed by fragment C of tetanus toxin (TTC). Following overexpression in Escherichia coli, SDT possessed a subunit molecular weight of approximately 130 kDa as revealed by both SDS-PAGE and immunoblot analyses with anti-SMN, anti-DTx, and anti-TTC antibodies. Like wild-type SMN, purified SDT showed specific binding in vitro to an RG peptide derived from Ewing's sarcoma protein. The fusion protein also bound to cultured primary neurons in amounts similar to those achieved by TTC. Unlike the case with TTC, however, immunolabeling of SDT-treated neurons with anti-TTC and anti-SMN antibodies showed staining restricted to the cell surface. Results from cytotoxicity studies in which the DTx catalytic domain of SDT was used as a reporter protein for internalization and membrane translocation activity suggest that the SMN moiety of the fusion protein is interfering with one or both of these processes. While these studies indicate that SDT may not be useful for SMA therapy, the use of the TTC:DTx fusion construct to deliver other passenger proteins to the neuronal cytosol should not be ruled out.

Enhancement of diphtheria toxin potency by replacement of the receptor binding domain with tetanus toxin C-fragment: a potential vector for delivering heterologous proteins to neurons

This study describes the expression, purification, and characterization of a recombinant fusion toxin, DAB(389)TTC, composed of the catalytic and membrane translocation domains of diphtheria toxin (DAB(389)) linked to the receptor binding fragment of tetanus toxin (C-fragment). As determined by its ability to inhibit cellular protein synthesis in primary neuron cultures, DAB(389)TTC was approximately 1,000-fold more cytotoxic than native diphtheria toxin or the previously described fusion toxin, DAB(389)MSH. The cytotoxic effect of DAB(389)TTC on cultured cells was specific toward neuronal-type cells and was blocked by coincubation of the chimeric toxin with tetanus antitoxin. The toxicity of DAB(389)TTC, like that of diphtheria toxin, was dependent on passage through an acidic compartment and ADP-ribosyltransferase activity of the DAB(389) catalytic fragment. These results suggest that a catalytically inactive form of DAB(389)TTC may be useful as a nonviral vehicle to deliver exogenous proteins to the cytosolic compartment of neurons.

Tetanus toxin fragment C binds to a protein present in neuronal cell lines and motoneurons

Tetanus Toxin Fragment C Binds to a Protein Present in Neuronal Cell Lines and Motoneurons Tetanus neurotoxin is one of the most powerful protein toxins known, acting in vivo at femtomolar doses. Two main factors determine its high potency: a protease activity restricted to a single intracellular substrate and its absolute neurospecificity. Whereas the enzymatic properties of tetanus toxin have been thoroughly defined, the nature of its neuronal receptor(s) and their involvement in the intracellular trafficking of tetanus toxin are poorly understood. Using binding and crosslinking experiments, we report here on the characterisation of an N-glycosylated 15-kDa interacting protein, which behaves as an integral membrane protein. This putative receptor specifically interacts with the binding domain (fragment C) of tetanus toxin and not with several related botulinum neurotoxins in spinal cord motoneurons and neuronal-like cell lines. Sialic acid-specific lectins antagonise the binding of tetanus toxin to the cell surface and to the 15-kDa protein, supporting the central role of sialic acid residues in the recognition process. Altogether, these results indicate the existence of a neuronal protein receptor for tetanus toxin whose identification is likely to constitute a key step in the analysis of the molecular machinery involved in the toxin internalisation and retrograde transport.

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.

In vitro techniques for the assessment of neurotoxicity

Risk assessment is a process often divided into the following steps: a) hazard identification, b) dose-response assessment, c) exposure assessment, and d) risk characterization. Regulatory toxicity studies usually are aimed at providing data for the first two steps. Human case reports, environmental research, and in vitro studies may also be used to identify or to further characterize a toxic hazard. In this report the strengths and limitations of in vitro techniques are discussed in light of their usefulness to identify neurotoxic hazards, as well as for the subsequent dose-response assessment. Because of the complexity of the nervous system, multiple functions of individual cells, and our limited knowledge of biochemical processes involved in neurotoxicity, it is not known how well any in vitro system would recapitulate the in vivo system. Thus, it would be difficult to design an in vitro test battery to replace in vivo test systems. In vitro systems are well suited to the study of biological processes in a more isolated context and have been most successfully used to elucidate mechanisms of toxicity, identify target cells of neurotoxicity, and delineate the development and intricate cellular changes induced by neurotoxicants. Both biochemical and morphological end points can be used, but many of the end points used can be altered by pharmacological actions as well as toxicity. Therefore, for many of these end points it is difficult or impossible to set a criterion that allows one to differentiate between a pharmacological and a neurotoxic effect. For the process of risk assessment such a discrimination is central. Therefore, end points used to determine potential neurotoxicity of a compound have to be carefully selected and evaluated with respect to their potential to discriminate between an adverse neurotoxic effect and a pharmacologic effect. It is obvious that for in vitro neurotoxicity studies the primary end points that can be used are those affected through specific mechanisms of neurotoxicity. For example, in vitro systems may be useful for certain structurally defined compounds and mechanisms of toxicity, such as organophosphorus compounds and delayed neuropathy, for which target cells and the biochemical processes involved in the neurotoxicity are well known. For other compounds and the different types of neurotoxicity, a mechanism of toxicity needs to be identified first. Once identified, by either in vivo or in vitro methods, a system can be developed to detect and to evaluate predictive ability for the type of in vivo neurotoxicity produced. Therefore, in vitro tests have their greatest potential in providing information on basic mechanistic processes in order to refine specific experimental questions to be addressed in the whole animal.

CuZn superoxide dismutase (SOD-1):tetanus toxin fragment C hybrid protein for targeted delivery of SOD-1 to neuronal cells

Increased levels of CuZn superoxide dismutase (SOD-1) are cytoprotective in experimental models of neurological disorders associated with free radical toxicity (e.g. stroke, trauma). Targeted delivery of SOD-1 to central nervous system neurons may therefore be therapeutic in such diseases. The nontoxic C-fragment of tetanus toxin (TTC) possesses the nerve cell binding/transport properties of tetanus holotoxin and has been used as a vector to enhance the neuronal uptake of proteins including enzymes. We have now produced a recombinant, hybrid protein in Escherichia coli tandemly joining human SOD-1 to TTC. The expressed hybrid protein (SOD:Tet450) has a subunit molecular mass of 68 kDa and is recognized by both anti-SOD-1 and anti-TTC antibodies. Calculated per mol, SOD:Tet450 has approximately 60% of the expected SOD-1 enzymatic activity. Analysis of the hybrid protein's interaction with the neuron-like cell line, N18-RE-105, and cultured hippocampal neurons by enzyme immunoassay for human SOD-1 revealed that SOD:Tet451 association with cells was neuron-specific and dose-dependent. The hybrid protein was also internalized, but there was substantial loss of internalized hybrid protein over the first 24 h. Hybrid protein associated with cells remained enzymatically active. These results suggest that human SOD-1 and TTC retain their respective functional properties when expressed together as a single peptide. SOD:Tet451 may prove to be a useful agent for the targeted delivery of SOD-1 to neurons.

Tetanus toxin selectively impairs anti-tumoral but not anti-microbial macrophage-mediated effector functions

The present study was designed to establish the susceptibility of macrophage-mediated effector functions to tetanus toxin (TT). Using the murine macrophage cell line, GG2EE, generated in vitro by v-raf/v-myc oncogenes, we have previously provided evidence that TT selectively inhibits interferon gamma (IFN-gamma), but not basal, lysozyme activity. Here we show that while neither phagocytic nor candidacidal activities are affected by TT treatment, antitumoral activity is significantly impaired after exposure to TT. This phenomenon, which is dose-dependent, is fully ascribed to the holotoxin, as heat inactivated TT, C or A-B fragments result ineffective. Furthermore, C but not A-B fragment competes with TT in abrogating its inhibitory effects. Overall, these data indicate that TT is not a broad-spectrum, down-regulating signal on macrophage-mediated functions, thus implying that its toxic action is exerted on specific molecular targets.

Neurotransmitter release regulated by nitric oxide in PC-12 cells and brain synaptosomes

BACKGROUND

Nitric oxide is a messenger molecule of the nervous system, which is produced by the enzyme nitric oxide synthase, which may regulate cyclic guanosine monophosphate levels and which has been implicated in the control of neurotransmitter release. PC-12 pheochromocytoma cells differentiate to form neuronal cells in culture when they are exposed to nerve growth factor. The levels of cyclic guanosine monophosphate in the cells and their ability to release acetylcholine in response to K(+)-depolarization are both maximal after eight days of treatment with nerve growth factor. We set out to assess a possible role for nitric oxide in the processes that occur in differentiating PC-12 cells.

RESULTS

Nitric oxide synthase is first evident in differentiating PC-12 cells eight days after beginning treatment with nerve growth factor, coinciding with the marked increase in K(+)-depolarization-induced release of acetylcholine. The release of both acetylcholine and dopamine in response to K(+)-depolarization is blocked by inhibitors of nitric oxide synthase and by hemoglobin, which binds nitric oxide. Providing l-arginine, a precursor required for nitric oxide synthesis, reverses the effects of the inhibitors. In synaptosomal preparations from the corpus striatum, inhibitors of nitric oxide synthase prevent the release of glutamate in response to the glutamate derivative N-methyl-d-aspartate but not in response to K(+)-depolarization.

CONCLUSION

Nitric oxide may mediate the release of acetylcholine and dopamine in response to K(+)-depolarization in PC-12 cells and the release of glutamate in response to N-methyl-d-aspartate in striatal synaptosomes. Nitric oxide synthase expression is induced after eight days of treating PC-12 cells with nerve growth factor, coinciding with a marked enhancement of the release of neurotransmitters in response to K(+)-depolarization.

Tetanus toxin inhibits depolarization-induced [3H]serotonin release from rat brain cortex synaptosomes

The effects of tetanus toxin on depolarization-induced [3H]serotonin release from superfused rat brain cortex synaptosomes was investigated. Two hours' preincubation of the synaptosomes with tetanus toxin resulted in a concentration-dependent decrease of K(+)-stimulated release, with an IC50 of about 30 nM (4.5 micrograms/ml); this inhibitory effect was blocked by a previous incubation of the tetanus toxin with antitoxin serum. Tetanus toxin had no effect on reserpine-induced release, a model of Ca(2+)-independent release. These results indicate that tetanus toxin is able to alter the exocytotic machinery of serotoninergic terminals, in agreement with results obtained with other neurotransmitters. They also indicate that serotoninergic terminals possess the receptor for tetanus toxin. These findings are in line with in vivo observations suggesting a role for serotoninergic system in tetanus intoxication.

Comparison of the intracellular effects of clostridial neurotoxins on exocytosis from streptolysin O-permeabilized rat pheochromocytoma (PC 12) and bovine adrenal chromaffin cells

The inhibitory effects of tetanus toxin, botulinum toxin A, their constituent light chains, and botulinum toxin B were compared using streptolysin O-permeabilized rat pheochromocytoma (PC 12) and bovine adrenal chromaffin cells in primary culture. In both types of chromaffin cells exocytosis can be triggered by micromolar amounts of free Ca2+, bovine adrenal chromaffin cells in addition require ATP. In PC 12 cells the isolated tetanus toxin light chain alone blocks exocytosis without any additive. The time-course of the inhibitory action of tetanus toxin light chain in permeabilized PC 12 cells in the absence of ATP is similar to the one obtained with permeabilized bovine adrenal chromaffin cells, in the presence of ATP. Thus, ATP does not seem to be crucial for tetanus toxin (two-chain form) poisoning. Botulinum toxin B (two-chain form), if preactivated by dithiothreitol, also inhibits exocytosis from permeabilized PC 12 cells up to 90% in the absence of ATP. By contrast, botulinum toxin A (two-chain form) or its isolated light chain, which are highly potent in permeabilized bovine adrenal chromaffin cells, causes only a weak inhibition in PC 12 cells. In streptolysin O-permeabilized bovine adrenal chromaffin cells omission of ATP during the incubation with the toxin increases the potency of botulinum toxin A light chain. Under the same conditions the effect of tetanus toxin light chain remains unchanged. Tetanus toxin and botulinum toxin B (two-chain forms) probably block a step which occurs during exocytosis from both PC 12 cells and adrenal chromaffin cells and which could be closely related to the final fusion event.(ABSTRACT TRUNCATED AT 250 WORDS)

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.

Inhibition of calcium-dependent release of noradrenaline from PC12 cells by botulinum type-A neurotoxin. Long-term effects of the neurotoxin on intact cells

(a) Clostridium botulinum type-A neurotoxin (BoNTA) inhibited the calcium-dependent release of noradrenaline from PC12 cells in a dose-dependent manner. Under conditions in which intact PC12 cells were incubated with BoNTA for 20 h at 37 degrees C, a neurotoxin concentration of approximately 0.12 +/- 0.03 microM was required to inhibit 50% of the calcium-dependent noradrenaline release. (b) PC12 cells, differentiated in the presence of nerve growth factor for 14 days, showed a similar dose-dependent inhibition of noradrenaline release by BoNTA with unchanged sensitivity. No specific saturable binding of 125I-labelled BoNTA was observed to either differentiated or undifferentiated PC12 cells, suggesting a lack of high-affinity acceptors on the cell surface for the neurotoxin. It is proposed that BoNTA enters PC12 cells either by non-specific binding to the cell membrane or via a low-concentration low-affinity acceptor molecule. (c) A study of the long-term effects of BoNTA on noradrenaline release from PC12 cells showed that the neurotoxin remains active within the growing cells for several days. Noradrenaline release from PC12 cells exposed to BoNTA (0.3 microM) for 24 h was reduced to less than 20% of control values over a subsequent 4-day period. After 8 days, release levels were significantly lower (60-65%) than control values, despite a more than 10-fold increase in the cell mass. (d) Investigation of the subcellular distribution of BoNTA after incubation with PC12 cells for 96 h revealed the bulk of the toxin (94-98%) to be associated with the cell membrane fraction. Of this, 50-80% of the BoNTA was associated with the nuclear and cell debris fraction and 11-25% was recovered in the large-granule-vesicle fraction; the specific binding of the neurotoxin to these membrane fractions was found to be similar. (e) Examination of the form of the cell-associated BoNTA after incubation for 96 h with PC12 cells revealed no evidence of any significant degradation of either neurotoxin subunit. This suggests that the neurotoxin adopts a relatively stable form within the cell. On SDS/PAGE under non-reducing conditions, no trace of protein bands corresponding to either of the BoNTA subunits were observed, suggesting that little or none of the neurotoxin subunits exists in a monomeric form within the cells.(ABSTRACT TRUNCATED AT 400 WORDS)

Tetanus toxin receptor. Specific cross-linking of tetanus toxin to a protein of NGF-differentiated PC 12 cells

A subclone of rat pheochromocytoma cells expresses high affinity receptors for tetanus toxin on differentiation with NGF [Walton, K.M., Sandberg, K., Rogers, T.B. and Schnaar, R.L. (1988) J. Biol. Chem. 263, 2055-2063]. In the presence of protein cross-linking agents, [125I]tetanus toxin, bound to these cells at 0 degree C, forms a cross-linked product with apparent molecular weight of 120 kDa. The formation of [125I]tetanus toxin conjugate involves the heavy chain of the toxin, is prevented by cold toxin and it is largely reduced by pretreating cells with proteases. The cross-linked product is formed only upon incubation of the toxin with NGF-differentiated cells. These results suggest that a protein with apparent molecular weight of 20 kDa is involved in the neurospecific binding of tetanus toxin.

Stereotaxic injection of tetanus toxin in rat central nervous system causes alteration in normal levels of monoamines

A single intraventricular injection of tetanus toxin produced a time-dependent elevation of serotonin levels in brain and spinal cord of adult rats. This tetanus toxin-induced increase was produced in areas of high density of serotonergic innervation, such as the hypothalamus, hippocampus, and spinal cord. Little or no effect was found in the thalamus, cerebellum, and frontal cortex, areas that are poorly innervated by serotonergic terminals. The responses of catecholamines (no change in dopamine level and generalized decrease in norepinephrine) pointed to a specific action of tetanus toxin on the serotonergic system. Stereotaxic injections of tetanus toxin in dorsal or magnus raphe nuclei did not have an evident effect on biogenic amine levels in the brain and spinal cord, respectively. Because direct stereotaxic injections of the toxin in the hypothalamus or hippocampus produced significant serotonin increases in both areas, it is proposed that tetanus toxin interacts with presynaptic targets to produce serotonin accumulation; this is probably due in part to an activation of tryptophan 5-hydroxylase.

Tetanus toxin inhibits neurotensin-induced mobilization of cytosolic protein kinase C activity in NG-108 cells

There is considerable literature on the pathogenesis of tetanus toxin poisoning; however, the mechanism of action and intracellular substrate of this toxin have not been defined. It was demonstrated that the NG-108 neuroblastoma x glioma cell line is a suitable model in which to study the mechanism of tetanus toxin action, from binding of the toxin to inhibition of transmitter release. Further, it has been shown that tetanus toxin pretreatment attenuates the ability of phorbol myristate acetate to mobilize cytosolic protein kinase C (PKC) in this cell line. In the present study a 4-hr tetanus toxin pretreatment (10(-10)-10(-13) M) completely inhibited the mobilization of cytosolic PKC induced by a 30-min exposure to 10 microM neurotensin. Pretreatment with 10(-10) M tetanus toxin for periods as short as 1 hr was sufficient to attenuate the ability of neurotensin to mobilize cytosolic PKC; however, a 30-min pretreatment had no significant effect. At a concentration of 10(-11) M, it was necessary to pretreat the cells for greater than 1 hr to significantly attenuate neurotensin-mobilized PKC activity. The exact role that PKC plays in the secretory process is not yet known; however, these findings suggest that the effect of tetanus toxin on neurotransmitter release is accompanied by an alteration in PKC metabolism in differentiated NG-108 cells.

Effect of tetanus toxin on oxytocin and vasopressin release from nerve endings of the neurohypophysis

The effect of tetanus toxin on neuropeptide hormone release from isolated nerve endings of the neural lobe of rat pituitaries (neurosecretosomes) was measured in a perfusion system. Tetanus toxin inhibited depolarization-evoked release of oxytocin and vasopressin in a time- and dose-dependent manner. At 1 microgram/ml, tetanus toxin blocked stimulated release by 85%. Tetanus toxin that was preincubated with a neutralizing monoclonal antibody or heated to 100 degrees C had no effect on hormone release. The ionophores A23187 and ionomycin were potent stimulators of hormone release in control nerve endings, but were not able to overcome the effect of tetanus toxin in intoxicated nerve endings. 8-Bromo-cyclic GMP, which has been reported to reverse the action of tetanus toxin in PC12 cells, had no effect on the action of tetanus toxin in neurosecretosomes. Neurosecretosomes are the first system in which tetanus toxin has been shown to block release from peptidergic nerve terminals. They appear to be a valuable in vitro system for studying the biochemical mechanism of tetanus toxin action.