Isolated light chains of botulinum neurotoxins inhibit exocytosis. Studies in digitonin-permeabilized chromaffin cells

The effects of botulinum neurotoxins or their light and heavy chain subunits were investigated in digitonin-permeabilized adrenal chromaffin cells. Because these cells are permeable to proteins, the toxin had direct access to the cell interior. Botulinum type A neurotoxin and its light chain subunit inhibited Ca2+-dependent catecholamine secretion in a dose-dependent manner. The heavy chain subunit had no effect. Inhibition required introduction of the neurotoxin or light chain into the cell and was not seen when intact cells were incubated with these proteins. The inhibition of secretion by type A neurotoxin and light chain was incomplete, the maximal response being 65%. The inhibition was not overcome by increasing Ca2+ concentrations. The action of the light chain was irreversible and rapid. Botulinum type E neurotoxin also inhibited secretion in a dose-dependent manner. Its potency was increased 30-fold following mild trypsinization, which nicked the single chain protein to the dichain form. In contrast to the results seen with types A and E, botulinum type B neurotoxin did not inhibit secretion, while its light chain totally abolished secretion. Trypsinization of the neurotoxin produced the dichain form, which did not inhibit secretion. Reduction of the trypsinized neurotoxin with dithiothreitol produced inhibition equivalent to that seen with the purified light chain subunit. Isolated type A heavy chain had no effect on the inhibitory action of type A or B light chains. The data demonstrate that the ability of botulinum neurotoxins to inhibit secretion is confined to the light chain region of these proteins. Furthermore, while the botulinum neurotoxin types A, B, and E have similar macrostructures, they are not identical with respect to their biological activities.     

Partial amino acid sequences of botulinum neurotoxins types B and E

Clostridium botulinum type E neurotoxin, a single-chain protein of Mr 147,000, was purified and subjected to amino acid sequencing. The same was done for single-chain botulinum type B neurotoxin (Mr 152,000), and for the heavy and light chains (Mr 104,000 and 51,000 respectively) derived from type B by limited trypsin digestion. Twelve to eighteen residues were identified and the following conclusions were drawn: The light chain of the nicked (dichain) type B is derived from the N-terminal one-third of the single-chain (unnicked) parent neurotoxin; sequence homologies are present between single-chain types B and E and the light chain of the nicked type A [J. J. Schmidt, V. Sathyamoorthy, and B. R. DasGupta (1984) Biochem. Biophys. Res. Commun. 119, 900-904]; the N-terminal regions of the heavy chains of types A and B have some structural similarity; and activation of type B neurotoxin cannot involve removal of amino acids or peptides from the N terminus.     

Botulinum neurotoxin type B (strain 657): partial sequence and similarity with tetanus toxin

The type B neurotoxin (NT) isolated from Clostridium botulinum (strain 657) behaved as a mixture of single (unnicked) and dichain (nicked) proteins, both of Mr approximately 150 kDa. When the dichain NT was reduced by mercaptoethanol, the two chains migrated in sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) as separate polypeptides of Mr approximately 100 and 50 kDa that appeared similar to the heavy and light chains of other serotypes of botulinum NT. The N-terminal amino acid sequences of the two chains were determined. They were as follows: light chain: Pro-Val-Thr-Ile-Asn-Asn-Phe-Asn-Tyr-Asn-Asp-Pro-Ile-Asp-Asn-Asn-Asn-Ile- Ile-Met - Met-Glu-Pro-Pro-Phe-Ala-Arg-Gly-Met-Gly-Arg-Tyr-Tyr-Lys-Ala-Phe-Lys-Ile- Thr-Asp - Arg-Ile-Trp-Ile-; and heavy chain: Ala-Pro-Gly-Ile-X-Ile-Asp-Val-Asp-Asn-Glu-Asp-Leu-Phe-Phe-Ile-Ala-Asp-Ly s-Asn- Ser-Phe-Arg-Asp-Asp-Leu-. These two sequences matched exactly with those of the light and heavy chains of type B NT (strain Okra) of which only 16 and 18 residues were known (J. Biol. Chem. (1985) 260, 10461). The above sequences were different from those of type A NT. Immunoprecipitation reactions of type B NT isolated from strains 657 and Okra were indistinguishable against polyclonal anti-type B NT serum. These two preparations did not produce precipitin reactions with polyclonal anti-type A NT serum.(ABSTRACT TRUNCATED AT 250 WORDS)     

Botulinum neurotoxin type E fragmented with endoproteinase Lys-C reveals the site trypsin nicks and homology with tetanus neurotoxin

Botulinum neurotoxin type E, a 150 kDa single chain protein, cleaved with endoproteinase Lys-C yielded 113, 73, and 50 kDa fragments. The N-terminal sequence of the 113 kDa fragment, Gly-Ile-Arg-Lys-Ser-Ile-Cys-Ile, overlaps the N-terminal sequence, Lys-Ser-Ile-Cys-Ile, of the 103 kDa heavy chain produced by nicking the neurotoxin with trypsin. The -Arg-Lys- bond is therefore the site on the single chain type E NT where trypsin nicks generating the 50 kDa light and 103 kDa heavy chains of the dichain NT. The sequence of the first 50 N-terminal residues of the 73 kDa fragment were determined. This fragment is a segment of the heavy chain; 50% of the 50 residues are present in identical positions in a similar segment of the heavy chain of tetanus neurotoxin.     

Immuno-crossreactivity between botulinum neurotoxin type C1 or D and exoenzyme C3

Botulinum neurotoxin type D and exoenzyme C3 have been separately purified from Clostridium botulinum strain D-1873 to apparent homogeneity. Both ADP-ribosylated a rat liver cytosolic protein of 24 kDa. The N-terminal amino acid sequence of C3 was determined and showed a low degree of homology with those of the light and heavy chains of neurotoxins of various types which have been reported previously. However, a polyclonal antibody raised against C3 cross-reacted with the light chains, but not with the heavy chains, of type C1 and D neurotoxins. Furthermore, a monoclonal antibody recognizing the light chains of type C1 and D neurotoxins interacted with C3. These results suggest that the light chain of type C1 or D neurotoxin and exoenzyme C3 share at least one epitope in common with each other.     

Nicking of single chain Clostridium botulinum type A neurotoxin by an endogenous protease

Botulinum neurotoxin (NT) serotype A isolated from cells from young cultures (approximately 8 h) of Clostridium botulinum type A is a approximately 150 kDa single chain protein. Supernatant from older cultures (96 h) yields approximately 150 kDa dichain NT composed approximately 50 and approximately 100 kDa subunits, that remain associated by disulfide and noncovalent bonds. This had led to the assumption that an endogenous protease cleaves a peptide bond at 1/3rd the distance from the N- or C-terminals of the single chain protein. An endogenous protease that causes such a cleavage (nicking) has now been purified greater than 1,000-fold from C. botulinum type A (Hall strain) culture; this culture also produces the single chain NT and eventually yields the dichain NT. The purified protease nicked the pure preparation of single chain type A NT, in vitro at pH 5.6, into a dichain form that was indistinguishable from the dichain NT normally isolated from 96 h cultures. The protease appears specific for nicking serotype A NT because it did not nick single chain serotype B and E NT nor did it enhance toxicity of serotype A, B and E NT.     

Botulinum neurotoxin type A: sequence of amino acids at the N-terminus and around the nicking site

Clostridium botulinum synthesizes the type A botulinum neurotoxin (NT) as a approximately 150 kDa single chain protein. Post-translational proteolytic processing yields a approximately 150 kDa dichain protein composed of a approximately 50 kDa light and approximately 100 kDa heavy chain, which has higher toxicity. Trypsin's action mimics the endogenous proteolytic processing. The proteolytic cleavages could occur at 4 sites. We have examined 2 such sites and defined the peptide sequences before and after proteolytic processing. The N-terminal residues of the newly synthesized approximately 150 kDa single chain NT, Pro-Phe-Val-Asn-Lys-, remain intact at the N-terminus of the approximately 50 kDa light chain generated either in the clostridial culture or in vitro with trypsin or with a protease purified from the homologous bacterial culture. The clostridial protease cleaves the single chain NT in vitro, at 1/3 the distance from its N-terminus, on the amino side of Gly of the sequence -Gly-Tyr-Asn-Lys-Ala-Leu-Asn-Asp-Leu- before cleaving the bond Lys-Ala at a slower rate. The data indicate that the dichain NT is formed in the bacterial culture in at least 2 steps. Cleavage at X-Gly produces a approximately 100 kDa heavy chain-like fragment which is then truncated; cleavage 4 residues downstream at Lys-Ala, and excision of the tetrapeptide Gly-Tyr-Asn-Lys, generates the mature heavy chain with Ala as its N-terminal residue. The approximately 100 kDa heavy chain generated in vitro, by nicking the single chain NT with trypsin, also has Ala-Leu-Asn- as the N-terminal residues.     

Presumptive identification of common adenovirus serotypes by the development of differential cytopathic effects in the human lung carcinoma (A549) cell culture

Abstract The neurotoxin gene from Clostridium barati ATCC43756 was cloned as a series of overlapping polymerase chain reaction (PCR) generated fragments using primers designed to conserve toxin sequences previously published. The toxin gene has an open reading frame (ORF) of 1268 amino acids giving a calculated molecular mass of 141049 Da. The sequence identity between the C. barati ATCC43756 and non-proteolytic C. botulinum 202F neurotoxins is 64.2% for the light chain and 73.6% for the heavy chain. This is much lower than reported identities for the type E neurotoxins from C. botulinum and C. butyricum (96% identity between light chains and 98.8% between the heavy chains). Previously identified conserved regions in other botulinal neurotoxins were also conserved in that of C. barati . An ORF upstream of the toxin coding region was revealed. This shows strong homology to the 3' end of the gene coding for the nontoxic-nonhemagglutinin (NTNH) component of the progenitor toxin from C. botulinum type C neurotoxin.     

Partial amino acid sequence of the heavy and light chains of botulinum neurotoxin type A

The dichain (nicked) type A botulinum neurotoxin is a protein (mol. wt. 145,000) composed of a heavy and a light chain (mol. wt. 97,000 and 53,000, respectively) that are held together by disulfide bond(s). We report here the sequence of the first 17 amino acid residues of the light chain, and the first 10 residues of the heavy chain. The heavy chain was isolated from the neurotoxin by two different methods, while the light chain was isolated by the only available method. The identical amino acid sequence was found in both preparations of heavy chain. Two samples of the light chain isolated from two separately prepared batches of the neurotoxin also had identical sequences.     

Circular dichroic and fluroescence spectroscopic study of the conformation of botulinum neurotoxin types A and E

Summary Botulinum neurotoxin (NT) is synthesized byClostridium botulinum in any of seven antigenically distinct forms, called types A through G. Protease(s) endogenous to the bacteria, or trypsin, nicks the single chain protein to a dichain molecule which generally is more toxic. The conformation of dichain type A (nicked by endogenous protease), single chain type E, and dichain type E NT (nicked by trypsin) have been determined using circular dichroism (CD) and fluorescence spectroscopy. The high degree of ordered secondary structure (α helix 28%, β sheet 42%, total 70%) found in type A NT at pH 6.0 was similar to that found at pH 9.0 (α 22%, β 47%, total 69%). The secondary structure of the single chain type E NT at pH 6.0 (α 18%, β 37%, total 55%) differed somewhat from these values at pH 9.0 (α 22%, β 43%, total 65%). The dichain type E NT at pH 6.0 assumed a secondary structure (α 20%, β 47%, total 67%) more similar to that of dichain type A than the single chain type E NT. Examination with the fluorogenic probe toluidine napthalene sulfonate revealed that the hydrophobicity of the type A and E NTs were higher at pH 9.0 than at pH 6.0. Also, the hydrophobicity of the dichain type E NT was higher than its precursor the single chain protein and appeared similar to that of the dichain type A NT. The CD and fluorescence studies indicate that conversion of the single chain type E NT to the dichain form (i.e. nicking by trypsin) induced changes in conformation. The ordered secondary structure (a + β contents) of botulinum NT, 70% for type A and 67% for dichain type E, agree well with 65% of α + β contents of tetanus toxin [21] that is produced byClostridium tetani.     

Characterization of the subunits of botulinum neurotoxin type A

A comparative amino acid analysis of botulinum neurotoxin type A and its subunits has been carried out. The heavy and light chains of neurotoxin have the same ratios of polar and non-polar amino acids (1.3:1), the amount of tryptophan residues in the heavy chain is 4 times as much as that in the light chain, and the number of SH-groups exceeds that in the light chains 2-fold. In neurotoxin, two N-terminal amino acid residues--alanine and leucine--were identified. Alanine was found to be the N-terminus of the heavy chain. The fluorescence spectra of neurotoxin subunits indicate differences in the conformational state of the polypeptide chains. The antigenic non-identity of botulinum neurotoxin A subunits suggests the presence in the neurotoxin molecule of at least two antigenic determinants, corresponding to the heavy and light chains.     

Effect of diethylpyrocarbonate on the biological activities of botulinum neurotoxin types A and E

The single chain (unnicked) type-E and the dichain (nicked) type-A botulinum neurotoxins were modified with diethylpyrocarbonate (ethoxyformic anhydride), a reagent highly specific for histidine residues. The type-E neurotoxin could be completely detoxified without causing detectable damage to its serological reactivity. Under identical modification reaction conditions, the type A was incompletely detoxified with some alteration in its serological reactivity. Modification of histidine residues was evident from the increase in absorbance at 240 nm, and reactivation of the detoxified proteins by reversing the modification with hydroxylamine. The completely detoxified type-E neurotoxin, used as toxoid, elicited antibodies in rabbits. The antiserum precipitated and neutralized the neurotoxin. This toxoid is homogeneous as tested by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, whereas the traditional toxoid produced with formaldehyde is heterogeneous.     

Cloning, high level expression, purification, and crystallization of the full length Clostridium botulinum neurotoxin type E light chain

The catalytic activity of the highly potent botulinum neurotoxins are confined to their N-terminal light chains ( approximately 50kDa). A full-length light chain for the type E neurotoxin with a C-terminal 6x His-tag, BoNT/E-LC, has been cloned in a pET-9c vector and over-expressed in BL21 (DE3) cells. BoNT/E-LC was purified to homogeneity by affinity chromatography on Ni-NTA agarose followed by exclusion chromatography using a Superdex-75 sizing column. The purified protein has very good solubility and can be stored stably at -20 degrees C; however, it seems to undergo auto-proteolysis when stored at temperature #10878;4-10 degrees C. BoNT/E-LC is active on its natural substrate, the synaptosomal associated 25kDa protein, SNAP-25, indicating that it retains a native-like conformation and therefore can be considered as a useful tool in studying the structure/function of the catalytic light chain. Recombinant BoNT/E-LC has been crystallized under five different conditions and at various pHs. Crystals diffract to better than 2.1A.     

Is formation of visible channels in a phospholipid bilayer by botulinum neurotoxin type B sensitive to its disulfide?

Botulinum neurotoxin, produced by Clostridium botulinum as a approximately 150-kDa single-chain protein, is nicked proteolytically either endogenously or exogenously. The approximately 50- and approximately 100-kDa chains of the dichain molecule remain held together by an interchain disulfide bridge and noncovalent interactions. The neurotoxin binds to receptors of the target cell and is internalized by endocytosis. Thereafter, a portion of the neurotoxin, the approximately 50-kDa chain, escapes to the cytosol, where it blocks neurotransmitter release. Botulinum neurotoxin serotype B is released by the bacteria primarily as an unnicked single chain. We reduced this unnicked protein and used its binding to ganglioside in a lipid layer to produce helical tubular crystals of unnicked botulinum neurotoxin type B in its disulfide-reduced state. The helical arrangement of the neurotoxin allowed determination of the structure of the molecule using cryo-electron microscopy and image processing. The resulting model reveals that neurotoxin molecules formed loops extending out from the surface of the bilayer and bending toward a neighboring loop. Although channels have been seen with disulfide-linked neurotoxin (Schmid, Robinson, and DasGupta (1993) Direct visualization of botulinum neurotoxin-induced channels in phospholipid vesicles, Nature 364, 827-830), no channels were seen here, a finding which suggests that the reduced, unnicked neurotoxin is incapable of forming a visible channel.     

Dichain structure of botulinum neurotoxin: identification of cleavage sites in types C, D, and F neurotoxin molecules

Botulinum neurotoxin (NT) is synthesized by Clostridium botulinum as about a 150-kDa single-chain polypeptide. Posttranslational modification by bacterial or exogenous proteases yielded dichain structure which formed a disulfide loop connecting a 50-kDa light chain (Lc) and 100-kDa heavy chain (Hc). We determined amino acid sequences around cleavage sites in the loop region of botulinum NTs produced by type C strain Stockholm, type D strain CB16, and type F strain Oslo by analysis of the C-terminal sequence of Lc and the N-terminal sequence of Hc. Cleavage was found at one or two sites at Arg444/Ser445 and Lys449/Thr450 for type C, and Lys442/Asn443 and Arg445/Asp446 for type D, respectively. In culture fluid of mildly proteolytic strains of type C and D, therefore, NT exists as a mixture of at least three forms of nicked dichain molecules. The NT of type F proteolytic strain Oslo showed the Arg435 as a C-terminal residue of Lc and Ala440 as an N-terminal residue of Hc, indicating that the bacterial protease cuts twice (Arg435/Lys436 and Lys439/Ala440), with excision of four amino acid residues. The location of cleavage and number of amino acid residue excisions in the loop region could be explained by the degree of exposure of amino acid residues on the surface of the molecule, which was predicted as surface probability from the amino acid sequence. In addition, the observed correlation may also be adapted to the cleavage sites of the other botulinum toxin types, A, B, E, and G.     

Role of the heavy and light chains of botulinum neurotoxin in neuromuscular paralysis

Botulinum neurotoxin (NT) is synthesized by Clostridium botulinum in any of seven antigenically distinct forms called types A-G. NT, when fully active, is a dichain protein, composed of two polypeptides, a heavy (H) and a light (L) chain (approximately 100,000 and approximately 50,000 Da, respectively) that are held together by noncovalent bonds and at least one disulfide bond. Two types of dichain NT, A and B, and their respective H and L chains were applied to nerve-muscle (NM) preparations (phrenic nerve-hemidiaphragm of the mouse), in order to develop a broader, comparative understanding of the neuroparalytic actions of NT types. It was found that the paralysis induced by dichain NT was delayed or antagonized if NM preparations were incubated with isolated and purified H chain prior to, or during, incubation with the parent, dichain NT. NM preparations preincubated with H chain and then washed free of unbound H chain became paralyzed after subsequent incubation with L chain. Paralysis did not occur if NM preparations were incubated first with L chain, washed, and then incubated with H chain. These observations suggest that the H chain binds with specific sites on the nerve terminal. This binding appears to permit the L chain, or some combination of the L and H chain, to bring about neuroparalysis through a mechanism very similar to that of the parent, dichain NT.     

Molecular composition of progenitor toxin produced by Clostridium botulinum type C strain 6813

The molecular composition of the purified progenitor toxin produced by a Clostridium botulinum type C strain 6813 (C-6813) was analyzed. The strain produced two types of progenitor toxins (M and L). Purified L toxin is formed by conjugation of the M toxin (composed of a neurotoxin and a non-toxic nonhemagglutinin) with additional hemagglutinin (HA) components. The dual cleavage sites at loop region of the dichain structure neurotoxin were identified between Arg444-Ser445 and Lys449-Thr450 by the analyses of C-terminal of the light chain and N-terminal of the heavy chain. Analysis of partial amino acid sequences of fragments generated by limited proteolysis of the neurotoxin has shown to that the neurotoxin protein produced by C-6813 was a hybrid molecule composed of type C and D neurotoxins as previously reported. HA components consist of a mixture of several subcomponents with molecular weights of 70-, 55-, 33-, 26~21- and 17-kDa. The N-terminal amino acid sequences of 70-, 55-, and 26~21-kDa proteins indicated that the 70-kDa protein was intact HA-70 gene product, and other 55- and 26~21-kDa proteins were derived from the 70-kDa protein by modification with proteolysis after translation of HA-70 gene. Furthermore, several amino acid differences were exhibited in the amino acid sequence as compared with the deduced sequence from the nucleotide sequence of the HA-70 gene which was common among type C (strains C-St and C-468) and D progenitor toxins (strains D-CB16 and D-1873).     

C. botulinum neurotoxin types A and E: isolated light chain breaks down into two fragments. Comparison of their amino acid sequences with tetanus neurotoxin

The flaccid paralysis in the neuromuscular disease botulism appears to depend on the coordinated roles of the approximately 50 kDa light and approximately 100 kDa heavy chain subunits of the approximately 150 kDa neurotoxic protein produced by Clostridium botulinum (J. Biol. Chem. (1987) 262, 2660 and Eur. J. Biochem. (1988) 177, 683). We observed that the light chain after separation from its conjugate heavy chain, in the presence of dithiothreitol and 2 M urea, begins to split into approximately 28 and approximately 18 kDa fragments. The other subunit-the approximately 100 kDa heavy chain following its isolation-and the parent approximately 150 kDa dichain neurotoxin do not break down under comparable conditions. This cleavage was examined in the neurotoxin serotypes A and E. The cleavage does not appear to be due to a protease. Partial amino acid sequences established that: i) the approximately 28-kDa and approximately 18-kDa fragments comprise the N- and C-terminal regions of the light chain, respectively; ii) the light chain of the neurotoxin serotypes A and E break down at precise peptide bonds; iii) the peptide bonds cleaved in serotypes A and E are five residues apart; and iv) the portions of the approximately 18 kDa fragments of serotype A and E neurotoxin sequenced so far are highly homologous to the corresponding region of tetanus neurotoxin produced by Clostridium tetani. The partial N-terminal sequence of the approximately 28 kDa fragment matches with the N-terminal sequence of the intact L chain. The 47 residues of the approximately 18-kDa fragment of type A sequenced from its N-terminal are: -Y.E.M.S.G.L.E.V.S.F.E.E.L.R.T.F.G.G.H.D.A.K.F.I.D.S.L.Q.E.N.E.F.R.L.Y.Y .Y. N.K.F.K. D.I.A.S.T.L.-. These align with those of tetanus neurotoxin beginning at its residue #259 (Tyr); the 18 underlined residues of the above 47 residues (i.e. 38%) are identical in positions between the two proteins. The 41 residues sequenced from the approximately 18 kDa fragment of type E botulinum neurotoxin are: -K.G.I.N.I.E.E.F.L. T.F.G.N.N.D.L.N.I.I.T.V.A.Q.Y.N.D.I.Y.T.N.L.L.N.D.Y.R. K.I.A.X.K. L.-.(ABSTRACT TRUNCATED AT 250 WORDS)     

Role of arginine residues in the structure and biological activity of botulinum neurotoxin types A and E

When nicked types A and E as well as the unnicked (i.e., single chain) type E botulinum neurotoxins were treated with 1,2-cyclo-hexanedione, which specifically modifies the arginine residues in 0.2 M borate buffer, pH 8.0 i) both the nicked and unnicked neurotoxins were detoxified, ii) the unnicked single chain neurotoxin became resistant to nicking with trypsin, and iii) the serological reactivity of type A (type E was not tested) was altered. Reversal of the arginine modification partially restored toxicity. In the electroimmunodiffusion test the modified type A neurotoxin appeared as 2 cones; the height of one cone increased and the other decreased as the modification reaction progressed. These results indicate that i) at least one arginine residue is involved in maintaining the toxigenic structure of types A and E neurotoxins; ii) the site of nicking in type E is an arginyl bond; and iii) arginine residue is critical for at least one antigenic determinant of type A neurotoxin.     

Effect of pH on the interaction of botulinum neurotoxins A, B and E with liposomes.

The interaction of botulinum neurotoxin serotypes A, B and E with membranes of different lipid compositions was examined by photolabelling with two photoreactive phosphatidylcholine analogues that monitor the polar region and the hydrophobic core of the lipid bilayer. At neutral pH the neurotoxins interacted both with the polar head groups and with fatty acid chains of phospholipids. At acidic pHs the neurotoxins underwent structural changes characterized by a more extensive interaction with lipids. Both the heavy and light chain subunits of the neurotoxins were involved in the process. The change in the nature and extent of toxin-lipid interaction occurred in the pH range 4-6 and was not influenced by the presence of polysialogangliosides. The present data are in agreement with the idea that botulinum neurotoxins enter into nerve cells from a low pH intracellular compartment.