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

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

The HCC-domain of botulinum neurotoxins A and B exhibits a singular ganglioside binding site displaying serotype specific carbohydrate interaction

Tetanus and botulinum neurotoxins selectively invade neurons following binding to complex gangliosides. Recent biochemical experiments demonstrate that two ganglioside binding sites within the tetanus neurotoxin HC-fragment, originally identified in crystallographic studies to bind lactose or sialic acid, are required for productive binding to target cells. Here, we determine by mass spectroscopy studies that the HC-fragment of botulinum neurotoxins A and B bind only one molecule of ganglioside GT1b. Mutations made in the presumed ganglioside binding site of botulinum neurotoxin A and B abolished the formation of these HC-fragment/ganglioside complexes, and drastically diminished binding to neuronal membranes and isolated GT1b. Furthermore, correspondingly mutated full-length neurotoxins exhibit significantly reduced neurotoxicity, thus identifying a single ganglioside binding site within the carboxyl-terminal half of the HC-fragment of botulinum neurotoxins A and B. These binding cavities are defined by the conserved peptide motif H...SXWY...G. The roles of tyrosine and histidine in botulinum neurotoxins A and B in ganglioside binding differ from those in the analogous tetanus neurotoxin lactose site. Hence, these findings provide valuable information for the rational design of potent botulinum neurotoxin binding inhibitors.     

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

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

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.     

SV2 mediates entry of tetanus neurotoxin into central neurons

Tetanus neurotoxin causes the disease tetanus, which is characterized by rigid paralysis. The toxin acts by inhibiting the release of neurotransmitters from inhibitory neurons in the spinal cord that innervate motor neurons and is unique among the clostridial neurotoxins due to its ability to shuttle from the periphery to the central nervous system. Tetanus neurotoxin is thought to interact with a high affinity receptor complex that is composed of lipid and protein components; however, the identity of the protein receptor remains elusive. In the current study, we demonstrate that toxin binding, to dissociated hippocampal and spinal cord neurons, is greatly enhanced by driving synaptic vesicle exocytosis. Moreover, tetanus neurotoxin entry and subsequent cleavage of synaptobrevin II, the substrate for this toxin, was also dependent on synaptic vesicle recycling. Next, we identified the potential synaptic vesicle binding protein for the toxin and found that it corresponded to SV2; tetanus neurotoxin was unable to cleave synaptobrevin II in SV2 knockout neurons. Toxin entry into knockout neurons was rescued by infecting with viruses that express SV2A or SV2B. Tetanus toxin elicited the hyper excitability in dissociated spinal cord neurons - due to preferential loss of inhibitory transmission - that is characteristic of the disease. Surprisingly, in dissociated cortical cultures, low concentrations of the toxin preferentially acted on excitatory neurons. Further examination of the distribution of SV2A and SV2B in both spinal cord and cortical neurons revealed that SV2B is to a large extent localized to excitatory terminals, while SV2A is localized to inhibitory terminals. Therefore, the distinct effects of tetanus toxin on cortical and spinal cord neurons are not due to differential expression of SV2 isoforms. In summary, the findings reported here indicate that SV2A and SV2B mediate binding and entry of tetanus neurotoxin into central neurons.     

Botulinum neurotoxins C, E and F bind gangliosides via a conserved binding site prior to stimulation-dependent uptake with botulinum neurotoxin F utilising the three isoforms of SV2 as second receptor

The high toxicity of clostridial neurotoxins primarily results from their specific binding and uptake into neurons. At motor neurons, the seven botulinum neurotoxin serotypes A–G (BoNT/A–G) inhibit acetylcholine release, leading to flaccid paralysis, while tetanus neurotoxin blocks neurotransmitter release in inhibitory neurons, resulting in spastic paralysis. Uptake of BoNT/A, B, E and G requires a dual interaction with gangliosides and the synaptic vesicle (SV) proteins synaptotagmin or SV2, whereas little is known about the entry mechanisms of the remaining serotypes. Here, we demonstrate that BoNT/F as wells depends on the presence of gangliosides, by employing phrenic nerve hemidiaphragm preparations derived from mice expressing GM3, GM2, GM1 and GD1a or only GM3. Subsequent site-directed mutagenesis based on homology models identified the ganglioside binding site at a conserved location in BoNT/E and F. Using the mice phrenic nerve hemidiaphragm assay as a physiological model system, cross-competition of full-length neurotoxin binding by recombinant binding fragments, plus accelerated neurotoxin uptake upon increased electrical stimulation, indicate that BoNT/F employs SV2 as protein receptor, whereas BoNT/C and D utilise different SV receptor structures. The co-precipitation of SV2A, B and C from Triton-solubilised SVs by BoNT/F underlines this conclusion.     

Neuronal binding of tetanus toxin compared to its ganglioside binding fragment (H(c))

The non-toxin 50 kD C-terminus peptide of the heavy chain of tetanus H(c) contains the ganglioside binding domain of tetanus toxin (TTX). H(c) retains much of the capacity of tetanus toxin for binding internalization and transport by neurons. For this reason tetanus H(c) has been studied as a vector for delivery of therapeutic proteins to neurons. We directly compared H(c) and TTX in the capacity to bind and be internalized by neurons by ELISA. Primary cultures of dissociated fetal cortical neurons were incubated with equimolar amounts of TTX or H(c). Neuronal associated tetanus protein was 4-8 fold greater on a molar basis with tetanus toxin compared to H(c) (1 h incubation). This increase in neuronal tetanus protein was evident with incubation in concentrations from 0.1 microM to 2 microM. There were greater amounts of TTX delivered to the cultured cells at both 0 degrees C (representing membrane bound tetanus protein) and 37 degrees C (bound and internalized tetanus protein). Unlike H(c), TTX showed significant continued accumulation of protein with increasing incubation durations. Neuronal associated TTX increased 2-3 fold over incubation times ranging from 1 to 8 h. Tetanus toxin appears to be clearly superior to the ganglioside binding fragment (H(c)) in the capacity for neuronal binding and internalization. Atoxic tetanus proteins containing additional molecular domains as well as H(c) may be more suitable vectors for linkage with therapeutic proteins and delivery to 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.     

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     

Evidence for a vesicle-mediated maintenance of store-operated calcium channels in a human embryonic kidney cell line

Direct microinjection of the clostridial neurotoxins botulinum neurotoxin A light chain or tetanus neurotoxin into cells of a human embryonic kidney cell line significantly reduced calcium entry after depletion of internal calcium stores by cyclopiazonic acid, a reversible inhibitor of the sarcoplasmic-endoplasmic reticular calcium-ATPases. Botulinum neurotoxin A light chain specifically hydrolyzes a synaptosomal-associated protein of 25 kilodaltons (SNAP-25), and tetanus neurotoxin specifically hydrolyzes synaptobrevin-2 (vesicle-associated membrane protein 2, VAMP-2) and cellubrevin (vesicle-associated membrane protein 3, VAMP-3). Since these substrate proteins are required for vesicle docking and fusion, inhibition of store-operated calcium entry by botulinum neurotoxin A light chain and tetanus neurotoxin supports a model in which vesicle fusion is a prerequisite for activation of store-operated calcium entry. Brefeldin A, a fungal metabolite that interferes with vesicle traffic, partially reduced calcium entry following store depletion. The size of the reserve pool of vesicles or parallel vesicle recycling pathways employing brefeldin A-sensitive and brefeldin A-insensitive ADP-ribosylation factors may explain the failure of brefeldin A to completely inhibit store-operated calcium entry.     

Sequence of the gene for Clostridium botulinum type B neurotoxin associated with infant botulism,expression of the C-terminal half of heavy chain and its binding activity

Previously, we demonstrated that the neurotoxin of strain 111 (111/NT) associated with type B infant botulism showed antigenic and biological properties different from that (Okra/NT) produced by a foodborne botulism-related strain, Okra. In this study, the neurotoxin genes of 111/NT and Okra/NT were amplified and the sequences determined. The nucleotide sequences of the genes for both neurotoxins possessed an open reading frame of 3873 bp that encoded 1291 amino acids. The identities of nucleotide sequences and amino acid sequences were 97.6% and 95.7%, respectively. The ratio of nonsynonymous to synonymous substitutions was 0.47. The amino acid substitutions between 111/NT and Okra/NT occurred mainly in the domain of the C-terminal half of heavy chain (H(C)) responsible for binding to its receptor complex of protein and ganglioside. To characterize the binding capability of the H(C), recombinant genes for the H(C) and two hybrid H(C) in which one half of Okra/NT was replaced by the homologous half of 111/NT were constructed and expressed in Escherichia coli. The binding activity of the recombinant H(C) of 111/NT to the protein receptor synaptotagmin II, in the presence of ganglioside GT1b, was 4.2-fold less than Okra/NT, consistent with the corresponding two NTs. The use of hybrid H(C) revealed that mutation of 23 residues in carboxy terminal half of H(C) (1029-1291) of Okra/NT could be attributed to the lower binding activity of 111/NT and thus the differences in binding affinity between the two BoNT/B.     

N-terminal helix reorients in recombinant C-fragment of Clostridium botulinum type B

Botulinum neurotoxins comprise seven distinct serotypes (A-G) produced by Clostridium botulinum. The crystal structure of the binding domain of the botulinum neurotoxin type B (BBHc) has been determined to 2A resolution. The overall structure of BBHc is well ordered and similar to that of the binding domain of the holotoxin. However, significant structural changes occur at what would be the interface of translocation and binding domains of the holotoxin. The loop 911-924 shows a maximum displacement of 14.8A at the farthest point. The N-terminal helix reorients and moves by 19.5A from its original position. BBHc is compared with the binding domain of the holotoxin of botulinum type A and B, and the tetanus C-fragment to characterize the heavy chain-carbohydrate interactions. The probable reasons for different binding affinity of botulinum and tetanus toxins are discussed.     

Results of an international transferability study of the BINACLE (binding and cleavage) assay for in vitro detection of tetanus toxicity

Tetanus vaccines contain detoxified tetanus neurotoxin. In order to check for residual toxicity, the detoxified material (toxoid) has to be tested in guinea pigs. These tests are time-consuming and raise animal welfare issues. In line with the “3R” principles of replacing, reducing and refining animal tests, the “binding and cleavage” (BINACLE) assay for detection of active tetanus neurotoxin has been developed as a potential alternative to toxicity testing in animals. This in vitro test system can discriminate well between toxic and detoxified toxin molecules based on their receptor-binding and proteolytic characteristics.Here we describe an international study to assess the transferability of the BINACLE assay. We show that all participating laboratories were able to successfully perform the assay. Generally, assay variability was within an acceptable range. A toxin concentration-dependent increase of assay signals was observed in all tests. Furthermore, participants were able to detect low tetanus neurotoxin concentrations close to the estimated in vivo detection limit.In conclusion, the data from this study indicate that the methodology of the BINACLE assay seems to be robust, reproducible and easily transferable between laboratories. These findings substantiate our notion that the method can be suitable for the routine testing of tetanus toxoids.     

Organization and regulation of the neurotoxin genes in Clostridium botulinum and Clostridium tetani

Botulinum and tetanus neurotoxins are structurally and functionally related 150 kDa proteins that are potent inhibitors of neuroexocytosis. Botulinum neurotoxin associates with non-toxic proteins to form complexes of various sizes. The botulinum neurotoxin and non-toxic protein genes are clustered in a DNA segment called the botulinum locus. This locus is probably located on a mobile or degenerate mobile element, which accounts for the various genomic localizations (chromosome, plasmid, phage) in different Clostridium botulinum types. The botulinum neurotoxin and non-toxic protein genes are organized in two polycistronic operons (ntnh-bont and ha operons) transcribed in opposite orientations. The gene that separates the two operons of the botulinum locus in C. botulinum A encodes a 21 kDa protein BotR/A, which is a positive regulator of the expression of the botulinum locus genes. Similarly, in Clostridium tetani, the gene located immediately upstream of the tetanus toxin gene, encodes a positive regulatory protein, TetR. BotR and TetR are possibly alternative sigma factors related to TxeR and UviA, which regulate C. difficile toxin and C. perfringens bacteriocin production, respectively. TxeR and UviA define a new sub-group of the sigma(70) family of RNA polymerase initiation factors. In addition, the C. botulinum genome contains predicted two-component system genes, some of which are possibly involved in regulation of toxinogenesis.     

Synaptotagmins I and II act as nerve cell receptors for botulinum neurotoxin G

Botulinum neurotoxins (BoNTs) induce muscle paralysis by selectively entering cholinergic motoneurons and subsequent specific cleavage of core components of the vesicular fusion machinery. Complex gangliosides are requisite for efficient binding to neuronal cells, but protein receptors are critical for internalization. Recent work evidenced that synaptotagmins I and II can function as protein receptors for BoNT/B (Dong, M., Richards, D. A., Goodnough, M. C., Tepp, W. H., Johnson, E. A., and Chapman, E. R. (2003) J. Cell Biol. 162, 1293-1303). Here, we report the protein receptor for a second BoNT serotype. Like BoNT/B, BoNT/G employs synaptotagmins I and II to enter phrenic nerve cells. Using pull-down assays we show that only BoNT/G, but neither the five remaining BoNTs nor tetanus neurotoxin, interacts with synaptotagmins I and II. In contrast to BoNT/B, interactions with both isoforms are independent of the presence of gangliosides. Peptides derived from the luminal domain of synaptotagmin I and II are capable of blocking the neurotoxicity of BoNT/G in phrenic nerve preparations. Pull-down and neutralization assays further established the membrane-juxtaposed 10 luminal amino acids of synaptotagmins I and II as the critical segment for neurotoxin binding. In addition, we show that the carboxyl-terminal domain of the cell binding fragment of BoNT/B and BoNT/G mediates the interaction with their protein receptor.     

Vaccines against botulism

The clostridial neurotoxins (CNTs) are the most toxic proteins for humans and include botulinum neurotoxins (BoNT) and tetanus neurotoxin (TeNT). CNT neurotropism is based upon the preferred binding and entry into neurons and specific cleavage of neuronal SNARE proteins. While chemically inactive TeNT toxoid remains an effect vaccine, the current pentavalent vaccine against botulism is in limited supply. Recent advances have facilitated the development of the next generation of BoNT vaccines, utilizing non-catalytic full-length BoNT or a subunit vaccine composed of the receptor binding domain of BoNT as immunogens. This review describes the issues and progress towards the production of a vaccine against botulism that will be effective against natural BoNT variants.     

The structure of the tetanus toxin reveals pH‐mediated domain dynamics

The tetanus neurotoxin (TeNT) is a highly potent toxin produced by Clostridium tetani that inhibits neurotransmission of inhibitory interneurons, causing spastic paralysis in the tetanus disease. TeNT differs from the other clostridial neurotoxins by its unique ability to target the central nervous system by retrograde axonal transport. The crystal structure of the tetanus toxin reveals a “closed” domain arrangement stabilised by two disulphide bridges, and the molecular details of the toxin's interaction with its polysaccharide receptor. An integrative analysis combining X‐ray crystallography, solution scattering and single particle electron cryo‐microscopy reveals pH‐mediated domain rearrangements that may give TeNT the ability to adapt to the multiple environments encountered during intoxication, and facilitate binding to distinct receptors.     

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.     

Sequence homology and structural analysis of the clostridial neurotoxins.

The clostridial neurotoxins (CNTs), comprised of tetanus neurotoxin (TeNT) and the seven serotypes of botulinum neurotoxin (BoNT A-G), specifically bind to neuronal cells and disrupt neurotransmitter release by cleaving proteins involved in synaptic vesicle membrane fusion. In this study, multiple CNT sequences were analyzed within the context of the 1277 residue BoNT/A crystal structure to gain insight into the events of binding, pore formation, translocation, and catalysis that are required for toxicity. A comparison of the TeNT-binding domain structure to that of BoNT/A reveals striking differences in their surface properties. Further, the solvent accessibility of a key tryptophan in the C terminus of the BoNT/A-binding domain refines the location of the ganglioside-binding site. Data collected from a single frozen crystal of BoNT/A are included in this study, revealing slight differences in the binding domain orientation as well as density for a previously unobserved translocation domain loop. This loop and the conservation of charged residues with structural proximity to putative pore-forming sequences lend insight into the CNT mechanism of pore formation and translocation. The sequence analysis of the catalytic domain revealed an area near the active-site likely to account for specificity differences between the CNTs. It revealed also a tertiary structure, highly conserved in primary sequence, which seems critical to catalysis but is 30 A from the active-site zinc ion. This observation, along with an analysis of the 54 residue "belt" from the translocation domain are discussed with respect to the mechanism of catalysis.