Structure of tetanus toxin. II. Toxin binding to ganglioside.

The interaction between tetanus toxin and ganglioside containing 2 N-acetylneuraminic acid residues linked in sequence to one another has been investigated using a new method involving radioactively labeled ganglioside and tetanus toxin adsorbed to Sephadex matrix. Binding between the two components was demonstrated, and it was calculated that in the nanomolar concentration range, tetanus toxin becomes half-saturated at about 5 X 10(-8) M concentration of ganglioside. Removal of the ceramide portion from the ganglioside resulted in the complete loss of binding activity, whereas removal of the terminal N-acetylneuraminic acid residue from the intact ganglioside had no effect. Among the fragments derived from tetanus toxin (Helting, T. B., and Zwisler, O. (1977) J. Biol. Chem. 252, 187-193), only the heavy chain polypeptide exhibited a binding activity of the same order of magnitude as that observed for the native toxin. The light chain polypeptide showed no interaction with ganglioside and among the fragments derived from the toxin by digestion with papain, only Fragment C, at a high protein concentration, displayed marginal binding activity. Using monovalent antibodies directed against specific regions of the tetanus toxin molecule, it was demonstrated that antibodies directed against Fragment C uniquely interfere with the binding process. Anti-light chain serum was ineffective, as well as antitetanus toxoid serum previously absorbed with Fragment C. It is concluded that the binding site for ganglioside is located on the heavy chain portion of tetanus toxin, possibly in or near the region comprised by Fragment C.     

Characterization of tetanus toxins and toxin components by amino terminal analyses

Extract tetanus toxin, filtrate tetanus toxin, and the heavy and light chains of filtrate toxin were analyzed for their amino termini with 4-N,N-dimethylaminoazobenzene-4′isothiocyanate and phenylisothiocyanate. Extract toxin (intracellular toxin) is a single-chain polypeptide with proline as the amino terminus. Filtrate toxin (extracellular toxin) is a mixture of species produced by endogenous proteases, and showed three major amino terminal residues, proline, asparagine, and serine. Cleavage points in the filtrate toxin molecule appear to be on either side of a disulfide bond. Reductive and nonreductive preparative electrophoresis of filtrate toxin produce different species of light and heavy chains. The light chains have a single amino terminus of proline, indicating that the light chain is the amino terminal portion of the toxin molecule. The heavy chains showed no proline but rather asparagine and serine as the major amino termini. Small amounts of other amino terminal residues were present, indicating microheterogenity at the cleavage sites in the toxin. The results permit the construction of a model of tetanus toxin which is consistent with the fragments obtained from either reductive or nonreductive preparative electrophoresis of filtrate toxin.     

Tetanus toxin: primary structure, expression in E. coli, and homology with botulinum toxins.

A pool of synthetic oligonucleotides was used to identify the gene encoding tetanus toxin on a 75-kbp plasmid from a toxigenic non-sporulating strain of Clostridium tetani. The nucleotide sequence contained a single open reading frame coding for 1315 amino acids corresponding to a polypeptide with a mol. wt of 150,700. In the mature toxin molecule, proline (2) and serine (458) formed the N termini of the 52,288 mol. wt light chain and the 98,300 mol. wt heavy chain, respectively. Cysteine (467) was involved in the disulfide linkage between the two subchains. The amino acid sequences of the tetanus toxin revealed striking homologies with the partial amino acid sequences of botulinum toxins A, B, and E, indicating that the neurotoxins from C. tetani and C. botulinum are derived from a common ancestral gene. Overlapping peptides together covering the entire tetanus toxin molecule were synthesized in Escherichia coli and identified by monoclonal antibodies. The promoter of the toxin gene was localized in a region extending 322 bp upstream from the ATG codon and was shown to be functional in E. coli.     

Enzymatic breakdown of tetanus toxin

Treatment of tetanus toxin with papain at 55°C resulted in breakdown of the molecule to yield an atoxic fraction with a molecular weight of approximately 40 000. The highly purified material exhibited partial immunological identity with the parent toxin, showed no toxicity and elicited the formation of neutralizing antibodies against tetanus.     

Limited proteolysis of tetanus toxin. Relation to activity and identification of cleavage sites

Tetanus toxin is synthesized by Clostridium tetani as a 151-kDa peptide chain. The primary gene product is processed post-translationally by removal of the initiating methionine residue, formation of disulfide bridges and limited proteolysis by bacterial or exogenous proteinases. The mature toxins consist of a 52-kDa light chain and a 98-kDa heavy chain, linked together by a disulfide bond. Proteolytic nicking is accompanied by increased pharmacological potency. To identify the structural alterations involved, single-chain toxin has been subjected to limited proteolysis with various enzymes. The new N-termini have been determined by Edman degradation and the C-termini by isolation of short C-terminal peptide fragments and subsequent analysis of the sequence and composition. All two-chain toxins result from proteolytic nicking within the 17-residue segment of residues 445-461. Thus, the protease(s) of the culture broth cleave on the C-terminal side of Glu449 and partially Ala456, giving rise to two heavy chain N-termini. Trypsin and clostripain first attack the C-terminal of Arg454 and later Arg448, whereas endoproteinase Arg-C cleaves the former bond only. Chymotrypsin and endoproteinase Glu-C each split a single peptide bond, i.e. that located after Tyr452 and Glu449, respectively. Papain gives rise to a large number of cleavages within the 17-residue segment, the new C-terminus being Thr445 or Asn446 and the new N-terminus being Asp460 or Leu461. Further papain digestion leads to an additional cleavage within the heavy chain between Ser863 and Lys864. The original N-terminal Pro1 and C-terminal Asp1314, predicted from the nucleotide sequence, are conserved in all proteolytic digests. The pharmacological activity of the various two-chain toxins was 5-11 times that of the single-chain toxin, as estimated from the inhibition of [3H]noradrenaline release from rat-brain homogenate. The present data on the processing and activation by limited proteolysis prove the existence of several active tetanus isotoxins. These data, together with our previous data on the localization of disulfide bridges and sulfhydryl groups (Krieglstein, K., Henschen, A., Weller, U. & Habermann, E. (1990) Eur. J. Biochem. 188, 39-45), provide the detailed protein chemical characterization of the tetanus isotoxins.     

Tetanus toxin action: inhibition of neurotransmitter release linked to synaptobrevin proteolysis.

Tetanus toxin is a potent neurotoxin that inhibits the release of neurotransmitters from presynaptic nerve endings. The mature toxin is composed of a heavy and a light chain that are linked via a disulfide bridge. After entry of tetanus toxin into the cytoplasm, the released light chain causes block of neurotransmitter release. Recent evidence suggests that the L-chain may act as a metalloendoprotease. Here we demonstrate that blockade of neurotransmission by tetanus toxin in isolated nerve terminals is associated with a selective proteolysis of synaptobrevin, an integral membrane protein of synaptic vesicles. No other proteins appear to be affected by tetanus toxin. In addition, recombinant light chain selectively cleaves synaptobrevin when incubated with purified synaptic vesicles. Our data suggest that cleavage of synaptobrevin is the molecular mechanism of tetanus toxin action.     

Isolation and molecular size of Clostridium botulinum type C toxin.

A procedure is described for the purification of hemagglutinin-free Clostridium botulinum type C toxin. The toxin was purified approximately 1,000-fold from the original culture supernatant in an overall yield of 60% to a final specific toxicity of 4.4 x 10(7) minimal lethal doses/mg of protein. The toxin had a molecular weight of 141,000 and consisted of a heavy and a light chain. The molecular weights of the subunits were approximately 98,000 and 53,000. When comparing the molecular size and composition of type C toxin to that of botulinum toxins of different types, some common features may be suggested; i.e., the toxin has a molecular weight between 141,000 to 160,000 and is comprised of a heavy and a light chain linked by disulfide bonds (or bond).     

Isolation and molecular size of Clostridium botulinum type C toxin.

A procedure is described for the purification of hemagglutinin-free Clostridium botulinum type C toxin. The toxin was purified approximately 1,000-fold from the original culture supernatant in an overall yield of 60% to a final specific toxicity of 4.4 x 10(7) minimal lethal doses/mg of protein. The toxin had a molecular weight of 141,000 and consisted of a heavy and a light chain. The molecular weights of the subunits were approximately 98,000 and 53,000. When comparing the molecular size and composition of type C toxin to that of botulinum toxins of different types, some common features may be suggested; i.e., the toxin has a molecular weight between 141,000 to 160,000 and is comprised of a heavy and a light chain linked by disulfide bonds (or bond).     

The heavy chain of tetanus toxin can mediate the entry of cytotoxic gelonin into intact cells

An artificial conjugate of the heavy chain of tetanus toxin linked by a disulphide bond to the impermeant ribosome-inactivating protein gelonin is cytotoxic to intact HT29 cells by inhibiting intracellular protein synthesis. Neither toxin nor gelonin alone has any significant effect. This shows that the heavy chain has the ability to mediate internalization of a protein to which it is bound by a disulphide bond. Thus the normal role of the tetanus toxin heavy chain may be to allow entry of the light chain into a cell.     

Reductive chain separation of botulinum A toxin--a prerequisite to its inhibitory action on exocytosis in chromaffin cells

Cleavage of the disulfide bond linking the heavy and the light chains of tetanus toxin is necessary for its inhibitory action on exocytotic release of catecholamines from permeabilized chromaffin cells [(1989) FEBS Lett. 242, 245-248; (1989) J. Neurochem., in press]. The related botulinum A toxin also consists of a heavy and a light chain linked by a disulfide bond. The actions of both neurotoxins on exocytosis were presently compared using streptolysin O-permeabilized bovine adrenal chromaffin cells. Botulinum A toxin inhibited Ca2+-stimulated catecholamine release from these cells. Addition of dithiothreitol lowered the effective doses to values below 5 nM. Under the same conditions, the effective doses of tetanus toxin were decreased by a factor of five. This indicates that the interchain S-S bond of botulinum A toxin must also be split before the neurotoxin can exert its effect on exocytosis.     

Structure of tetanus toxin. N-Terminal amino acid analysis of the two molecular forms of tetanus toxin and its composite chains.

N-Terminal amino acid analysis of the intracellular form of tetanus toxin revealed proline as the single terminal residue present in significant quantities. In agreement with new concepts on the structure of tetanus toxin, a second N-terminal amino acid (leucine) was exposed upon conversion to the extracellular form of the toxin molecule. These results were corroborated by analysis of the separate polypeptide chains of the extracellular toxin, and it is concluded that the light chain polypeptide constitutes the N-terminal region of the single chain toxin molecule originally synthesized by the bacterial cell. Treatment of the intracellular tetanus toxin with trypsin $\text{in vitro}$ resulted in the exposure of amino acids in addition to those found after conversion to the extracellular form effected by the bacterial protease during fermentation.     

Isolated Light Chain of Tetanus Toxin Inhibits Exocytosis: Studies in Digitonin-Permeabilized Cells

Previous work indicates that the heavy chain of tetanus toxin is responsible for the binding of the toxin to the neuronal membrane and its subsequent internalization. In the present study, the light chain of tetanus toxin mimicked the holotoxin in inhibiting Ca2+-dependent secretion of [3H]norepinephrine from digitonin-permeabilized adrenal chromaffin cells. Preincubation of tetanus toxin with monoclonal antibodies to the light chain prevented the inhibition by tetanus toxin. Preincubation of tetanus toxin with nonimmune ascites fluid or with monoclonal antibodies directed against the C fragment (the C-terminal of the heavy chain) or the heavy-chain portion of the B fragment did not prevent inhibition by tetanus toxin. The data indicate that the light chain is responsible for the intracellular blockade of exocytosis.     

Identification and partial characterization of a low affinity metal-binding site in the light chain of tetanus toxin.

Tetanus toxin was shown to contain a metal-binding site for zinc and copper. Equilibrium dialysis binding experiments using 65Zn indicated an association constant of 9-15 microM, with one zinc-binding site/toxin molecule. The zinc-binding site was localized to the toxin light chain as determined by binding of 65Zn to the light chain but not to the heavy chain after separation by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and transfer to Immobilon membranes. Copper was an efficient inhibitor of 65Zn binding to tetanus toxin and caused two peptide bond cleavages in the toxin light chain in the presence of ascorbate. These metal-catalyzed oxidative cleavages were inhibited by the presence of zinc. Partial characterization of metal-catalyzed oxidative modifications of a peptide based on a putative metal-binding site (HELIH) in the toxin light chain was used to map the metal-binding site in the protein.     

Enzymatic fragmentation of tetanus toxin. Identification and characterization of an atoxic,immunogenic fragment

Summary Purified filtrate tetanus toxin was subjected to limited digestion with papain and the resulting fragments were separated by gel exclusion chromatography and characterized. One atoxic fragment was shown to react with antiserum against tetanus toxoid and was capable of inducing antibodies in rabbits that neutralized native tetanus toxin. The fragment had an estimated molecular weight of 56,000 by SDS polyacrylamide gel electrophoresis and 62,000 by sedimentation equilibrium. In the presence of a reducing agent, the fragment yielded two components with approximatec molecular weights of 23,000 and 32,000. Thus, it appears that the atoxic, immunogenic fragment is composed of two peptides joined by at least one disulfide bond. The fragment was examined by circular dichroism and data analysis indicated the presence of considerable -structure, but little, if any, -helicity. This is significantly different from the estimates for filtrate toxin, 29% -helicity and 23% -structure. Above 250 nm, the circular dichroic spectrum of the fragment was also distinct from that of intact toxin.Portions of this workwere presented at the 1977 Federation Meeting, Chicago, April 4, 1977 (Fed. Proc. 36, 2099, 1977).Recipient of a Research Career Development Award AM-00055.     

Purification of tetanus toxin and its peptide components by preparative polyacrylamide gel electrophoresis

A discontinuous preparative gel electrophoresis system has been devised and used successfully to separate the different tetanus toxin forms and fragments into highly purified preparations. A major feature of the system is the interaction of toxin, a suitable reducing agent and a critical concentration of denaturant during electrophoresis. With this procedure, filtrate (nicked) toxin has been separated into two distinct, but closely related molecular species. They appear to be nicked close to but on either side of an interchain disulfide bond, yielding heavy and light chains. The heavy- and light-chain components of each form of nicked toxin have been prepared and characterized. The system was also used to prepare extract (unnicked) toxin to a degree of purity not previously achieved in this laboratory. Nicked and unnicked toxin as well as the two forms of both heavy and light chain can consistently be prepared in sufficient purity and quantity to allow extensive biological, chemical, and physical characterization of each.     

Chains and fragments of tetanus toxin, and their contribution to toxicity

1. Single-chain toxin is enzymatically converted into two-chain isotoxins which differ from the precursor by their higher pharmacological activity, acidity and hydrophilicity. The interchain disulfide bridge and the disulfide loop within fragment C have been located at the amino acid level. 2. Independent of the enzymes used, the nicking sites are positioned within a region spanning no more than 17 amino acids. The N- and C-termini of the primary gene product are preserved in the two-chain toxin. The chains have been separated by isoelectric focussing and can be reconstituted to functionally intact toxin. 3. Light chain inhibits neurotransmitter release on different systems. First, permeabilized bovine adrenal chromaffin cells and rat pheochromocytoma (PC 12) cells release catecholamines when exposed to micromolar [Ca2+]. Inhibition is achieved with light chain or reduced two-chain toxin, but not with single-chain toxin or heavy chain. Washing away the light chain does not restitute the Ca2(+)-evoked release. The light chains of tetanus and botulinum A toxin act in a apparently similar, however not identical manner. Second, light but not heavy chain inhibits the release of acetylcholine when injected into Aplysia neurones. 4. The pharmacology of heavy chain is quite different. Ganglioside binding is mediated by its fragment C moiety, and modulated by the adjoining beta 2 piece and by light chain. Heavy chain and to a lesser degree its N-terminal beta 2-fragment promote the loss of calcein from liposomes indicating pore formation. Its C-terminal fragment C is inactive in this respect.(ABSTRACT TRUNCATED AT 250 WORDS)     

Separation and characterization of heavy and light chains from Clostridium botulinum type C toxin and their reconstitution

Clostridium botulinum type C toxin consists of a heavy and a light chain with molecular weights of 98,000 and 53,000, respectively, which are linked by one disulfide bond. The two components were separated from each other by quaternary aminoethyl Sephadex A-50 column chromatography by stepwise elution with NaCl in 27.5 mM borax-45 mM sodium dihydrogen phosphate buffer, pH 8.0, containing 5% 2-mercaptoethanol at 0 degrees C. The purified components had different amino acid compositions and antigenicities, and the toxicity of the toxin was neutralized completely by either anti-heavy chain Fab or anti-light chain Fab. the two components could be reconstituted to form an active molecule with recovered toxicity which varied according to the method used. Maximum recovery was obtained in a system in which the intersubunit S--S bond was first formed in the presence of high concentration of neutral salts, after which the concentration of salt was gradually decreased. The reconstituted preparation was highly toxic and had the same properties as the parental toxin on chromatography, sodium dodecyl sulfate-polyacrylamide gel electrophoresis, and immunodiffusion. By the use of three perturbants, the fractions of exposed tryptophans and tyrosines of the preparation were found to be almost the same as that of the parental toxin.     

Recombinant forms of tetanus toxin engineered for examining and exploiting neuronal trafficking pathways

Tetanus toxin is a fascinating, multifunctional protein that binds to peripheral neurons, undergoes retrograde transport and trans-synaptic transfer to central inhibitory neurons where it blocks transmitter release, thereby, causing spastic paralysis. As a pre-requisite for exploiting its unique trafficking properties, a novel recombinant single chain was expressed at a high level in Escherichia coli as a soluble, easily purifiable protein. It could be activated with enterokinase to produce a dichain that matched native toxin in terms of proteolytic and neuroinhibitory activities, as well as induction of spastic paralysis in mice. Importantly, nicking was not essential for protease activity. Substitution of Glu(234) by Ala created a protease-deficient atoxic form, which blocked the neuroparalytic action of tetanus toxin in vitro, with equal potency to its heavy chain; but, the mutant proved >30-fold more potent in preventing tetanus in mice. This observation unveils differences between the intoxication processes resulting from retrograde transport of toxin in vivo and its local uptake into peripheral or central nerves in vitro, dispelling a popularly held belief that the heavy chain is the sole determinant for efficient trafficking. Thus, this innocuous mutant may be a useful vehicle, superior to the heavy chain, for drug delivery to central neurons.     

Minimal essential domains specifying toxicity of the light chains of tetanus toxin and botulinum neurotoxin type A.

To define conserved domains within the light (L) chains of clostridial neurotoxins, we determined the sequence of botulinum neurotoxin type B (BoNT/B) and aligned it with those of tetanus toxin (TeTx) and BoNT/A, BoNT/C1, BoNT/D, and BoNT/E. The L chains of BoNT/B and TeTx share 51.6% identical amino acid residues whereas the degree of identity to other clostridial neurotoxins does not exceed 36.5%. Each of the L chains contains a conserved motif, HExxHxxH, characteristic for metalloproteases. We then generated specific 5'- and 3'-deletion mutants of the L chain genes of TeTx and BoNT/A and tested the biological properties of the gene products by microinjection of the corresponding mRNAs into identified presynaptic cholinergic neurons of the buccal ganglia of Aplysia californica. Toxicity was determined by measurement of neurotransmitter release, as detected by depression of postsynaptic responses to presynaptic stimuli (Mochida, S., Poulain, B., Eisel, U., Binz, T., Kurazono, H., Niemann, H., and Tauc, L. (1990) Proc. Natl. Acad. Sci. U. S. A. 87, 7844-7848). Our studies allow the following conclusions. 1) Residues Cys439 of TeTx and Cys430 of BoNT/A, both of which participate in the interchain disulfide bond, play no role in the toxification reaction. 2) Derivatives of TeTx that lacked either 8 amino- or 65 carboxyl-terminal residues are still toxic, whereas those lacking 10 amino- or 68 carboxyl-terminal residues are nontoxic. 3) For BoNT/A, toxicity could be demonstrated only in the presence of added nontoxic heavy (H) chain. A deletion of 8 amino-terminal or 32 carboxyl-terminal residues from the L chain had no effect on toxicity, whereas a removal of 10 amino-terminal or 57 carboxyl-terminal amino acids abolished toxicity. 4) The synergistic effect mediated by the H chain is linked to the carboxyl-terminal portion of the H chain, as demonstrated by injection of HC-specific mRNA into neurons containing the L chain. This finding suggests that the HC domain of the H chain becomes exposed to the cytosol during or after the putative translocation step of the L chain.     

构象稳定的破伤风毒素Hc 片段突变体 (HcM) 的制备及其免疫原性分析

破伤风是由破伤风杆菌侵入人体伤口、生长繁殖、产生毒素而引起的一种急性特异性感染,其死亡率高,严重危害人民生命健康。研究证实破伤风毒素重链C端 (Hc) 具有与毒素受体结合的活性,完全保留了全分子的免疫原性,有望开发成为新的基因工程破伤风亚单位疫苗以替换传统的甲醛灭活类毒素疫苗。由于野生型Hc蛋白 (HcW) 易形成分子间及分子内二硫键,且各构象分子之间易发生不稳定的转换,为疫苗的生产工艺带来困难,因此,通过将破伤风HcW蛋白的869位半胱氨酸突变为丙氨酸,构建构象稳定的破伤风亚单位疫苗突变体HcM,对Hc