Proteolytic Cleavage of Tetanus Toxin Increases Activity

Tetanus toxin is initially synthesized in the form of a single polypeptide chain and then proteolytically "nicked" by the bacteria to produce a two-chain structure joined by a disulfide bond. This two-chain form of the toxin is the form known to be biologically active. Whether such nicking is necessary for activity, as it is for certain other bacterial toxins, has not been demonstrated previously. Single-chain toxin preparations produced by salt extraction from the bacteria are characterized and compared with pure two-chain toxin obtained from extracellular filtrates. The ability of these various toxin preparations to produce paroxysmal activity in mouse spinal cord neurons grown in dissociated cell culture is described. The pure two-chain toxin is demonstrated to have greater activity than the single-chain toxin preparations. Indeed the activity of the single-chain toxin preparations can be explained by the small amounts of residual two-chain toxin present in these extracts. Using a protease from a toxin-minus strain of Clostridium tetani to convert a single-chain toxin preparation to two-chain toxin increases toxin activity. In vivo the single-chain toxin preparation is also less toxic. These findings indicate that proteolytic nicking of tetanus toxin increases activity. The unnicked, single-chain form of tetanus toxin may be a relatively nontoxic protoxin form of the toxin; this is a structure-function relationship similar to that of other bacterial protein toxins.     

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)     

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).     

Activation of Clostridium botulinum type B and E derivative toxins with lysine-specific proteases

Abstract Clostridium botulinum type B and E derivative toxins were activated with lysyl endopeptidase or endoproteinase Lys-C, which splits only the bond involving the carboxyl group of a lysine residue. Type B toxin was more efficiently activated with lysyl endopeptidase; type E toxin was more efficiently activated with trypsin. Type B toxin was split by the lysine-specific protease into 2 fragments of molecular sizes indistinguishable from those induced with trypsin. Type E toxin was split by the same protease into 3 fragments, 2 of which had M _r identical to those obtained with trypsin, the other having an M _r less than that of the heavy chain but greater than that of the light chain. These results attest that both activation and nicking of type B and E derivative toxins are ascribable to cleavage, not of an arginyl, but of a lysyl bond.     

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.     

Activation and maturation mechanisms of boar acrosin zymogen based on the deduced primary structure

We have isolated cDNA clones encoding boar acrosin, a serine protease participating in the initial stage of fertilization, from boar testis lambda gt11 cDNA libraries. Nucleotide sequencing of the overlapping clones indicates that the composite cDNA inserts contain 1,391 base pairs coding for a 5'-untranslated region, an open reading frame, a stop codon, a 3'-untranslated region, and a poly(A)+ tail. A polyadenylation signal, AATAAA, is located 33 bases upstream from the start of the poly(A)+ tail. The amino acid sequence deduced from the cDNAs shows that boar acrosin is initially synthesized as a prepro-protein with a 16-residue signal peptide at the NH2 terminus. This signal sequence is followed by a 399-residue sequence corresponding to the acrosin zymogen. COOH-terminal sequence analysis of boar sperm 55-kDa proacrosin and its processed forms indicates that the mature acrosin molecule contains 322 amino acid residues in two polypeptide chains, a 23-residue light chain and a 299-residue heavy chain, with a combined molecular mass of 35,735 Da, and that the 55-kDa proacrosin molecule has 14-, 18-, and 43-residue segments as COOH-terminal extensions that are removed during proacrosin maturation. The COOH-terminal 43-residue segment is rich in proline residues, including an unusual repeat of 23 consecutive prolines. The deduced amino acid sequence of boar acrosin shows a high degree of identity with major portions of other serine proteases, including the active site region and the location of cysteine residues. We conclude that boar acrosin is synthesized as a single-chain polypeptide with the regions corresponding to the light and heavy chains covalently connected by two disulfide bonds, and that the single-chain molecule is autoactivated by cleavage of the Arg23-Val24 bond after removal of the COOH-terminal 14-residue segment, resulting in the formation of the light and heavy chains. This two-chain molecule is then converted to the mature enzyme by removal of the COOH-terminal 18- and 43-residue segments.     

Characterization of nicking of the nontoxic-nonhemagglutinin components of Clostridium botulinum types C and D progenitor toxin

Clostridium botulinum C and D strains produce two types of progenitor toxins, M and L. Previously we reported that a 130-kDa nontoxic-nonhemagglutinin (NTNHA) component of the M toxin produced by type D strain CB16 was nicked at a unique site, leading to a 15-kDa N-terminal fragment and a 115-kDa C-terminal fragment. In this study, we identified the amino acid sequences around the nicking sites in the NTNHAs of the M toxins produced by C. botulinum type C and D strains by analysis of their C-terminal and N-terminal sequences and mass spectrometry. The C-terminus of the 15-kDa fragments was identified as Lys127 from these strains, indicating that a bacterial trypsin-like protease is responsible for the nicking. The 115-kDa fragment had mixtures of three different N-terminal amino acid sequences beginning with Leu135, Val139, and Ser141, indicating that 7–13 amino acid residues were deleted from the nicking site. The sequence beginning with Leu135 would also suggest cleavage by a trypsin-like protease, while the other two N-terminal amino acid sequences beginning with Val139 and Ser141 would imply proteolysis by an unknown protease. The nicked NTNHA forms a binary complex of two fragments that could not be separated without sodium dodecyl sulfate.     

Covalent Structure of Botulinum Neurotoxin Type B; Location of Sulfhydryl Groups and Disulfide Bridge and Identification of C-Termini of Light and Heavy Chains

Botulinum neurotoxin (NT) serotype B, produced by Clostridium botulinum (proteolytic strain), is a 150-kDa single-chain polypeptide of 1291 amino acids, of which 10 are Cys residues [Whelan et al. (1992), Appl. Environ. Microbiol. 58, 2345–2354] The posttranslational modifications of the gene product were found to consist of excision of only the initiating Met residue, limited proteolysis (nicking) of the 1290-residue-long protein between Lys 440 and Ala 441, and formation of at least one disulflde bridge. The dichain (nicked) protein, in a mixture with the precursor single-chain (unnicked) molecules, was found to have a 50-kDa light chain (Pro 1 through Lys 440) and a 100-kDa heavy chain (Ala 441 through Glu 1290). The limited in vivo nicking of the single-chain NT to the dichain form, by protease endogenous to the bacteria, and the nonfacile in vitro cleavage by trypsin of the Lys 440–Ala 441 bond appear to be due to the adjacent Ala 441–Pro 442 imide bond's probable cis configuration in a mixed population of molecules with cis and trans configurations. The two chains were found connected by an interchain disulfide formed by Cys 436 and Cys 445. Six other Cys residues, at positions 70, 195, 308, 777, 954, and 1277, were found in sulfhydryl form. In addition, a Cys at position 1220 or 1257 appeared to be in sulfhydryl form, hence our experimental results could not unambiguously identify presence of an intrachain disulfide bridge near the C-terminus of the NT. A total of 384 amino acid residues, including the 6 Cys residues at positions 70, 195, 308, 436, 445, and 1277, were identified by direct protein-chemical analysis; thus 29.7% of the protein's entire amino acid sequence predicted from the nucleotide sequence was confirmed. The 6 amino acids, residues 945–950, did not match with the sequence predicted in 1992, but did match with a later report of 1995. The above determinations were made by a combination of chemical (CNBr and acidic cleavage at Asp–Pro) and enzymatic (trypsin, clostripain, and pepsin) cleavages of the NT, and NT carboxymethylated with iodoacetamide (with or without ¹⁴C label), separation and isolation of the fragments by SDS–PAGE (followed by electroblotting onto PVDF membrane), and/or reversed-phase HPLC, and analyses of the fragments for the N-terminal amino acid sequences by Edman degradation and amino acid compositions.     

Structure of tetanus toxin. I. Breakdown of the toxin molecule and discrimination between polypeptide fragments.

Tetanus toxin was digested with papain, yielding one major polypeptide (Fragment C) with a molecular weight corresponding to 47,000 +/- 5%, thus comprising about one-third of the toxin molecule. Fragment C was antigenically active, atoxic, and stimulated the formation of antibodies neutralizing the lethal action of tetanus toxin in vivo. Furthermore, a second split product (Fragment B) was isolated from the papain digest, containing two polypeptide chains linked together via a disulfide bond. Fragment B (Mr = 95,000 +/- 5%) was atoxic and showed a reaction of nonidentity with Fragment C on immunodiffusion analysis against tetanus antitoxin. The basic two-chain structure (heavy and light chain polypeptide, cf. Matsuda, M., and Yoneda, M. (1975) Infect. Immun. 12, 1147-1153) of tetanus toxin has been confirmed and the relationship between Fragments B and C within this framework has been established. Fragment C was distinguished from the light chain by electrophoresis in sodium dodecyl sulfate and by immunodiffusion analysis, indicating that this fragment constitutes a portion of the heavy chain polypeptide. Fragment B showed a reaction of partial identity with the light as well as the heavy chain from tetanus toxin. Reduction of Fragment B with dithiothreitol followed by gel chromatography yielded a fraction which was indistinguishable from the light chain portion of the toxin molecule. It is concluded that Fragment B comprises the complementary portion of the heavy chain (remaining after scission of the polypeptide bond(s) releasing Fragment C) linked to the light chain by a disulfide bond.     

Conformational changes associated with the nicking and activation of botulinum neurotoxin type E

Secondary and tertiary structural parameters of type E botulinum neurotoxin in the unactivated single-chain and activated two-chain (i.e., after proteolytic cleavage) forms were analyzed using circular dichroism, derivative absorption and fluorescence spectroscopy. The estimated secondary structures (22 and 20% alpha-helix, 44 and 44% beta-pleated sheets, and 34 and 36% random coils for the single- and two-chain neurotoxins, respectively) indicated that virtually no change occurred upon nicking of the single-chain neurotoxin. About 57% of the 70 Tyr residues were exposed in the single-chain form, which increased to 62% in the two-chain form. Fluorescence quenching experiments with neutral, anionic and cationic quenchers indicated that about 40% of the maximum accessible fluorescent Trp residues were exposed on the surface of the single-chain neurotoxin as compared to only 20% in the case of the two-chain neurotoxin. Acrylamide was the most effective quencher with a fraction accessibility of 0.56 and 0.48 of maximum accessible Trp fluorescence residues in the single and two-chain forms of the neurotoxin, respectively. Native polyacrylamide gel electrophoresis of the two forms of the neurotoxin revealed greater mobility for the two chain form. This indicates that the surface charges in the single-chain neurotoxin were altered upon nicking. These observations suggest that nicking of the single-chain type E neurotoxin results in refolding and redistribution of the surface charges of the neurotoxin.     

Proteolytic processing sites producing the mature form of human cathepsin D.

1. The proteolytic processing sites of human lysosomal aspartic protease cathepsin D at which the intermediate single-chain form was converted into the mature two-chain form were determined. 2. The two chains were isolated by reversed-phase HPLC in order to investigate the cleavage sites of the enzyme. 3. Protein sequencing of the heavy chain, which was presumed to be derived from the C-terminal side in the single-chain enzyme, gave an N-terminal Leu 105. In addition, it revealed that there were also minor sequences, which commenced with Gly 106 and Gly 107. 4. A small C-terminal peptide was isolated from the light chain, which had been digested with two kinds of exogenous proteases. Sequence determination of this peptide, which was characterized as a nonapeptide by mass spectrometry, suggested that the C-terminus of the light chain was Ser 98. 5. These results indicate that a Ser 98-Ala 99 bond and an Ala 104-Leu 105 bond are cleaved to release 6 amino acid residues between the two chains.     

Botulinum Neurotoxin Type A: Limited Proteolysis by Endoproteinase Glu-C and α-Chymotrypsin Enhanced Following Reduction; Identification of the Cleaved Sites and Fragments

Botulinum neurotoxin (NT) serotype A is a ～150-kDa dichain protein. Posttranslational nicking of the single-chain NT (residues Pro 1–Leu 1295) by the protease(s) endogenous to Clostridium botulinum excises 10 residues, leaving Pro 1–Lys 437 and Ala 448–Leu 1295 in the ～50-kDa light (L) and ～100-kDa heavy (H) chains, respectively, connected by a Cys 429–Cys 453 disulfide and noncovalent bonds [Krieglstein et al. (1994), J. Protein Chem. 13, 49–57]. The L chain is a metalloprotease, while the amino- and carboxy-terminal halves of the H chain have channel-forming and receptor-binding activities, respectively [Montecucco and Schiavo (1995), Q. Rev. Biophys. 28, 423–472]. Endoproteinase Glu-C and α-chymotrypsin were used for controlled digestion at pH 7.4 of the ～150-kDa dichain NT and the isolated ～100-kDa H chain (i.e., freed from the L chain) in order to map the cleavage sites and isolate the proteolytic fragments. The dichain NT appeared more resistant to cleavage by endoproteinase Glu-C than the isolated H chain. In contrast, the NT with its disulfide(s) reduced showed rapid digestion of both chains, including a cleavage between Glu 251 and Met 252 (resulting in ～30- and ～20-kDa fragments of the L chain) which was not noted unless the NT was reduced. Interestingly, an adjacent bond, Tyr 249–Tyr 250, was noted earlier [DasGupta and Foley (1989), Biochimie 71, 1193–1200] to undergo “self-cleavage” following reductive separation of the L chain from the H chain. The site Tyr–Tyr–Glu–Met (residues 249–252) appears to become exposed following reduction of Cys 429–Cys 453 disulfide. Identification of Glu 669–Ile 670 and Tyr 683–Ile 684 as protease-susceptible sites demonstrated for the first time that at least two peptide bonds in the segment of the H chain (residues 659–684), part of which (residues 659–681) is thought to interact with the endosomal membranes and forms channels [Oblatt-Montal et al., (1995), Protein Sci. 4, 1490–1497], are exposed on the surface of the NT. Two of the fragments of the H chain we generated and purified by chromatography are suitable for structure–function studies; the ～85- and ～45-kDa fragments beginning at residue Leu 544 and Ser 884, respectively (both extend presumably to Leu 1295) contain the channel-forming segment and receptor-binding segments, respectively. In determining partial amino acid sequences of 10 fragments, a total of 149 amino acids in the 1275-residue NT were chemically identified.     

The tetanus toxin light chain inhibits exocytosis

The intracellular action on exocytosis of various forms of tetanus toxin was studied using adrenal medullary chromaffin cells, the membrane barrier of which has been removed by permeabilization with streptolysin O. Such cells still release catecholamines on stimulation with calcium. The two-chain form of tetanus toxin (67 nmol/l) strongly inhibited exocytosis, but only if dithiothreitol was present as a reducing agent. Purified light chain completely prevented [3H]noradrenaline release with a half-maximal effect at about 5 nmol/l. Heavy chain (up to 11 nmol/l) and unprocessed single-chain toxin (up to 133 nmol/l) were without effect. It is concluded that the original single-chain form of tetanus toxin has to be processed by proteolysis and reduction to yield a light chain which inhibits transmitter release.     

Comparison of Clostridium botulinum toxins type D and C1 in molecular property, antigenicity and binding ability to rat-brain synaptosomes

Botulinum type D neurotoxin was purified 950-fold from the culture supernatant with an overall yield of 32%. The purified toxin had a specific toxicity of 5.8 X 10(7) mouse minimal lethal dose per mg of protein and a relative molecular mass of 140000. The purified toxin had a di-chain structure consisting of heavy and light chains with relative molecular masses of 85000 and 55000, respectively, linked by one disulfide bond. These subunits had different amino acid compositions and antigenicities. A similarity in molecular constructions and amino acid compositions was observed between type D and type C1 toxins as well as between their subunits. Among the seven kinds of monoclonal antibodies against type D toxin, six reacted with the heavy chain of type D toxin, while one of the six also reacted with the heavy chain of type C1 toxin and neutralized the toxicities of the two toxins. The other one of monoclonal antibodies reacted with the light chains of both toxins. This evidence indicates that both toxins have common antigenic sites on their heavy and light chains and that the antigenic site on the heavy chain may contribute to the neutralization of both toxins by antibody. The binding of type D toxin to rat brain synaptosomes was examined by use of 125I-labelled type D toxin. The binding was competitively inhibited not only by unlabelled type D and C1 toxins, but also by the heavy chains of both toxins, however, it was not inhibited by the light chain of type D toxin. These results suggest that the toxin receptors on synaptosomal membrane are common for type D and C1 toxins, and that the heavy chain contributes to the binding of toxin to synaptosomes and the structure of the binding sites on the heavy chains of both toxins is quite similar.     

Effect of Nicking the C-terminal Region of the <Emphasis Type="Italic">Clostridium botulinum</Emphasis> Serotype D Neurotoxin Heavy Chain on its Toxicity and Molecular Properties

A unique strain of Clostridium botulinum serotype D 4947 produces toxin complexes that are composed of un-nicked components, including a neurotoxin (BoNT) and auxiliary proteins. This BoNT showed aberrant elution upon Superdex gel filtration, indicating a much lower molecular weight, due to hydrophobic interaction with the column. Limited trypsin proteolysis of BoNT produces two nicks; first nick yielded a BoNT 50 kDa light chain disulfide linked to a 100 kDa heavy chain (Hc), and a second nick arose in Hc C-terminal 10 kDa. The second nick occurred in the putative binding domain of the BoNT molecule and induced alterations in its secondary structure, leading to a significant reduction of mouse toxicity in comparison with that of the fully-activated singly nicked BoNT. These results help to clarify the role of the C-terminal half of the Hc in the oral toxicity of single-chain and more complex forms of BoNT.     

Proteolytic processing by matrix metalloproteinases and phosphorylation by protein kinase CK2 of fetuin-A, the major globulin of fetal calf serum

Bovine fetuin-A is a member of a glycoprotein family with a wide spectrum of functions. Until now the bovine protein has been thought to be a single-chain protein. Recently we have shown that native bovine plasma fetuin-A partially exists as a disulfide-bridged two-chain protein with a heavy N-terminal and a lighter C-terminal chain similar to the structure of human fetuin-A homologue (alpha2HS glycoprotein), and also is partially phosphorylated at residues Ser120, Ser302, Ser305 and Ser306 (Wind et al., Anal. Biochem. 317 (2003) 26-33). Both fetuin-A modifications, the phosphorylation at the four sites as well as the proteolysis which causes longer or shorter light chains (termed lc-1 and lc-2, respectively), are probably brought about by targeted enzymatic activities which still need to be defined. In this study we show that authentic bovine fetuin-A disulfide-bridged two-chain forms, which include the original C-terminus, were liberated from the single-chain precursor by metalloproteinases MMP-3 (stromelysin-1) and MMP-7 (matrilysin), but not by elastase, cathepsin E and cathepsin G. Peptide sequencing suggested cleavage sites chiefly at the Pro277-Ser278 or Arg294-His295 peptide bonds. Fetuin-A radioactive phosphorylation in vitro by protein kinase CK2 caused (32)P incorporation into the fetuin-A light chain lc-1 but not lc-2 or the fetuin-A heavy chain, as revealed by MMP assisted proteolysis. Analysis by nanoESI-MS pinpointed phosphorylation at the native phospho-residues Ser302, Ser305 and Ser306 by increased relative abundance following in vitro phosphorylation. Moreover, CK2 phosphorylation of synthetic C-terminal fetuin-A peptides, used as effective controls to the native protein, strongly implies that CK2 is involved in the in vivo phosphorylation of fetuin-A. The phosphorylation of N-terminally truncated peptide homologs seemed highly dependent on the sequence context N-terminal of the phosphorylation sites, thus providing a likely explanation for the non-phosphorylation of the light chain lc-2 in native fetuin-A.     

Unusual proteolysis of the protoxin and toxin from Bacillus thuringiensis. Structural implications

Trypsin is shown to generate an insecticidal toxin from the 130-kDa protoxin of Bacillus thuringiensis subsp. kurstaki HD-73 by an unusual proteolytic process. Seven specific cleavages are shown to occur in an ordered sequence starting at the C-terminus of the protoxin and proceeding toward the N-terminal region. At each step, C-terminal fragments of approximately 10 kDa are produced and rapidly proteolyzed to small peptides. The sequential proteolysis ends with a 67-kDa toxin which is resistant to further proteolysis. However, the toxin could be specifically split into two fragments by proteinases as it unfolded under denaturing conditions. Papain cleaved the toxin at glycine 327 to give a 34.5-kDa N-terminal fragment and a 32.3-kDa C-terminal fragment. Similar fragments could be generated by elastase and trypsin. The N-terminal fragment corresponds to the conserved N-terminal domain predicted from the gene-deduced sequence analysis of toxins from various subspecies of B. thuringiensis, and the C-terminal fragment is the predicted hypervariable sequence domain. A double-peaked transition was observed for the toxin by differential scanning calorimetry, consistent with two or more independent folding domains. It is concluded that the N- and C-terminal regions of the protoxin are two multidomain regions which give unique structural and biological properties to the molecule.     

Human complement component C1s. Partial sequence determination of the heavy chain and identification of the peptide bond cleaved during activation

Human C1s proenzyme (Mr 83 000) was isolated by a rapid two-stage method involving affinity chromatography of C1 on IgG-Sepharose and isolation of subcomponent C1s by ion-exchange chromatography on DEAE-Sephacel. Single-chain C1s proenzyme was activated to two-chain C1s with self-activated C1r. After reduction and S-carboxamidomethylation the heavy chain of C1s (Mr 57 000) was isolated by ion exchange chromatography on DEAE-Sephacel. Cleavage of C1s heavy chain with CNBr yielded five fragments whose N-terminal sequences were determined. The alignment of the fragments within the heavy chain was established by tryptic peptides containing methionine. C1s heavy chain comprises about 470 amino acid residues and 42% of its sequence was determined. An intrachain sequence homology and a homology to the alpha 2 chain of human haptoglobin were identified. The C-terminal CNBr fragment comprising 44 amino acid residues was completely sequenced. From BNPS-skatole cleavage of reduced and alkylated C1s proenzyme a fragment was isolated which overlaps the C1s heavy and light chain parts and which contains the peptide bond cleaved during activation. The results show that this is an Arg-Ile bond and that under standard conditions of activation no peptide material is liberated from this portion of the molecule. The sequence data and homology to two-chain serine proteases indicate a single interchain disulfide bond in C1s.     

Botulinum neurotoxin type A: cleavage of the heavy chain into two halves and their partial sequences

The 145-kDa type A botulinum neurotoxin (NT) is produced by the bacteria Clostridium botulinum (strain, Hall). The heavy (H) and light (L) chains (97- and 53-kDa, respectively) of this protein are linked by at least one disulfide bond. The N- and C-terminal halves of the H chain appear to have different functions in the mechanism of action of the NT [1987) FEBS Lett. 226, 115-120). Well-characterized and highly purified preparations of the two halves of the H chain are needed for such studies. Two different approaches were taken to cut the H chain with trypsin and isolate the fragments. In one method the cleavage products were: (i) 94-kDa fragment made of the L chain linked to the N-terminal half of the H chain (49 kDa) by a disulfide bond(s), and (ii) the C-terminal 44-kDa fragment. The N-terminal half of H chain was separated from the L chain by reducing the disulfide bond(s) linking them and then purified by ion-exchange chromatography. The 1-27 residues of 49-kDa N-terminal half of the H chain were Ala-Leu-Asn-Asp-Leu-Cys-Ile-Lys-Val-Asn-Asn-Trp-Asp-Leu-Phe-Phe-Ser-Pro- Ser-Glu - Asp-Asn-Phe-Thr-Asn-Asp-Leu-. The sequence of the other half of the H chain (44 kDa) was X-Ile-Ile-Asn-Leu-X-Ile-Leu-Asn-Leu-Arg-Tyr-Glu-X-Asn-His-Leu-Ile-Asp-Le u-Lys- X-Tyr-Ala-Ser-. In the second method, the H chain was first separated from the L chain, purified, and then cleaved. One product of cleavage, the 44-kDa fragment, was partially sequenced; the first 25 residues were identical to the sequence of the 44-kDa fragment generated by the first method. The present work also demonstrated that (i) The cysteine residue(s) located on the N-terminal half of the H chain form the -S-S- link(s) with the L chain. (ii) The other half of the H chain (44-kDa fragment, apparently the C-terminal half) is not linked via -S-S- to the L-chain or to the N-terminal half (49-kDa fragment) of the H chain.(ABSTRACT TRUNCATED AT 400 WORDS)     

Covalent structure of botulinum neurotoxin type A: Location of sulfhydryl groups, and disulfide bridges and identification of C-termini of light and heavy chains

Botulinum neurotoxin Type A is synthesized byClostridium botulinum as a 150 kD single chain polypeptide. The posttranslational processing of the 1296 amino acid residue long gene product involves removal of the initiating methionine, formation of disulfide bridges, and limited proteolysis (nicking) by the bacterial protease(s). The mature dichain neurotoxin is made of a 50-kD light chain and a 100-kD heavy chain connected by a disulfide bridge. DNA derived amino acid sequencepredicted a total of 9 Cys residues (Binzet al., 1990,J. Biol. Chem. 265, 9153–9158; Thompsonet al., 1990,Eur. J. Biochem. 189, 73–81). Treatment of the dichain neurotoxin, dissolved in 6 M guanidine. HCl, with 4-vinylpyridine converted 5 Cys residues into S-pyridylethyl cysteine residues; but alkylation after mercaptolysis converted all 9 Cys residues in the S-pyridylethylated form. After confirming the predicted number of Cys residues by amino acid analysis, the positions of the 5 Cys residues carrying sulfhydryl groups and the 4 involved in disulfide bridges were determined by comparing the elution patterns in reversed-phase HPLC of the cyanogen bromide mixtures of the exclusively alkylated and the mercaptolyzed-alkylated neurotoxin. The chromatographically isolated components were identified by N-terminal amino acid sequence analysis. The HPLC patterns showed characteristic differences. The Cys residuespredicted in positions 133, 164, 790, 966, and 1059 were found in the sulfhydryl form; Cys 429 and 453 were found disulfide-bridged connecting the light and heavy chains, and Cys 1234 and 1279 were found in an intrachain disulfide-bridge near the C-terminus in the heavy chain. Ten amino acid residues, Thr 438-Lys 447,predicted to be present in the single chain neurotoxin were not found in the dichain neurotoxin. Nicking of single-chain neurotoxin by the protease(s) endogenous to the bacteria therefore appears to excise these 10 amino acid residues from the nicking region which leaves Lys 437 as the C-terminus of the light chain and Ala 448 as the N-terminus of the heavy chain. The N-terminal Pro 1 and C-terminal Leu 1295,predicted from the nucleotide sequence, remain conserved after nicking. Residues Pro 1-Lys 437 and Ala 448-Leu 1295 constitute the light and heavy chains, respectively. The C-termini were determined by isolation of short C-terminal peptide fragments and subsequent sequence analysis by Edman degradation. About 20% of the amino acid sequence predicted from DNA analysis was confirmed in these studies by protein-chemical methods.