Functional analysis of the Shiga toxin and Shiga-like toxin type II variant binding subunits by using site-directed mutagenesis.

The B subunit of Shiga toxin and the Shiga-like toxins (SLTs) mediates receptor binding, cytotoxic specificity, and extracellular localization of the holotoxin. While the functional receptor for Shiga toxin, SLT type I (SLT-I), and SLT-II is the glycolipid designated Gb3, SLT-II variant (SLT-IIv) may use a different glycolipid receptor. To identify the domains responsible for receptor binding, localization in Escherichia coli, and recognition by neutralizing monoclonal antibodies, oligonucleotide-directed site-specific mutagenesis was used to alter amino acid residues in the B subunits of Shiga toxin and SLT-IIv. Mutagenesis of a well-conserved hydrophilic region near the amino terminus of the Shiga toxin B subunit rendered the molecule nontoxic but did not affect immunoreactivity or holotoxin assembly. In addition, elimination of one cysteine residue, as well as truncation of the B polypeptide by 5 amino acids, caused a total loss of activity. Changing a glutamate to a glutamine at the carboxyl terminus of the Shiga toxin B subunit resulted in the loss of receptor binding and immunoreactivity. However, the corresponding mutation in the SLT-IIv B subunit (glutamine to glutamate) did not reduce the levels of cytotoxicity but did affect extracellular localization of the holotoxin in E. coli.     

Analysis of Shiga toxin subunit association by using hybrid A polypeptides and site-specific mutagenesis.

Shiga toxin (STX), a bacterial toxin produced by Shigella dysenteriae type 1, is a hexamer composed of five receptor-binding B subunits which encircle an alpha-helix at the carboxyl terminus of the enzymatic A polypeptide. Hybrid toxins constructed by fusing the A polypeptide sequences of STX and Shiga-like toxin type II were used to confirm that the carboxyl terminus of the A subunits governs association with the B pentamers. The alpha-helix of the 293-amino-acid STX A subunit contains nine residues (serine 279 to methionine 287) which penetrate the nonpolar pore of the B-subunit pentamer. Site-directed mutagenesis was used to establish the involvement of two residues bordering this alpha-helix, aspartic acid 278 and arginine 288, in coupling the C terminus of StxA to the B pentamer. Amino acid substitutions at StxB residues arginine 33 and tryptophan 34, which are on the membrane-contacting surface of the pentamer, reduced cytotoxicity without affecting holotoxin formation. Although these B-subunit mutations did not involve receptor-binding residues, they may have induced an electrostatic repulsion between the holotoxin and the mammalian cell membrane or disrupted cytoplasmic translocation.     

Identification of the Shiga toxin A-subunit residues required for holotoxin assembly.

Recent X-ray crystallographic analyses have demonstrated that the receptor-binding (B) subunits of Shiga toxin (STX) are arranged as a doughnut-shaped pentamer. The C terminus of the enzymatic (A) subunit presumably penetrates the nonpolar pore of the STX B pentamer, and the holotoxin is stabilized by noncovalent interactions between the polypeptides. We identified a stretch of nine nonpolar amino acids near the C terminus of StxA which were required for subunit association by using site-directed mutagenesis to introduce progressive C-terminal deletions in the polypeptide and assessing holotoxin formation by a receptor analog enzyme-linked immunosorbent assay, immunoprecipitation, and a cytotoxicity assay. Tryptophan and aspartic acid residues which form the N-terminal boundary, as well as two arginine residues which form the C-terminal boundary of the nine-amino-acid sequence, were implicated as the stabilizers of subunit association. Our model proposes that residues 279 to 287 of the 293-amino-acid STX A subunit penetrate the pore while the tryptophan, aspartic acid, and 2 arginine residues interact with other charged or aromatic amino acids outside the pore on the planar surfaces of the STX B pentamer.     

Mutational analysis of the Shiga toxin and Shiga-like toxin II enzymatic subunits.

The A-subunit polypeptides of Shiga toxin, the Shiga-like toxins (SLTs), and the plant lectin ricin inactivate eucaryotic ribosomes by enzymatically depurinating 28S rRNA. Comparison of the amino acid sequences of the members of the Shiga toxin family and ricin revealed two regions of significant homology that lie within a proposed active-site cleft of the ricin A chain. In previous studies, these conserved sequences of the SLT-I and ricin A subunits have been implicated as active sites. To establish the importance of these regions of homology, we used site-directed mutagenesis to alter the A-subunit sequences of two members of the Shiga toxin family. Substitution of an aspartic acid for glutamic acid 166 of the Slt-IIA subunit decreased the capacity of the polypeptides to inhibit protein synthesis at least 100-fold in a cell-free translation system. However, this mutation did not prevent the expression of immunoreactive, full-length Slt-IIA. In addition, SLT-II holotoxin containing the mutated A subunit was 1,000-fold less toxic to Vero cells. Finally, site-directed mutagenesis was used to delete sequences encoding amino acids 202 through 213 of the Shiga toxin A subunit. Although this deletion did not prevent holotoxin assembly, it abolished cytotoxic activity.     

Isolation and characterization of functional Shiga toxin subunits and renatured holotoxin

Shiga toxin is a protein toxin produced by Shigella dysenteriae type I strains. In this report we present a procedure for the separation of functionally intact toxin A and B chains and for their reconstitution to form biologically active molecules. In agreement with the findings of others, the isolated A chain was shown to be a potent in vitro inhibitor of eukaryotic protein synthesis. The isolated B chain bound to HeLa cells and competitively inhibited the binding and cytotoxic activity of holotoxin. These findings show that the functional role of the B chain is to recognize cell surface functional receptors. By labelling the B subunit alone, prior to renaturation of holotoxin, the polypeptide chains were shown to associate noncovalently with a stoichiometry of one A chain and five B chains.     

Cloning and sequencing of a Shiga-like toxin type II variant from Escherichia coli strain responsible for edema disease of swine.

A Shiga-like toxin type II variant (SLT-IIv) is produced by strains of Escherichia coli responsible for edema disease of swine and is antigenically related to Shiga-like toxin type II (SLT-II) of enterohemorrhagic E. coli. However, SLT-IIv is only active against Vero cells, whereas SLT-II is active against both Vero and HeLa cells. The structural genes for SLT-IIv were cloned from E. coli S1191, and the nucleotide sequence was determined and compared with those of other members of the Shiga toxin family. The A subunit genes for SLT-IIv and SLT-II were highly homologous (94%), whereas the B subunit genes were less homologous (79%). The SLT-IIv genes were more distantly related (55 to 60% overall homology) to the genes for Shiga toxin of Shigella dysenteriae type 1 and the nearly identical Shiga-like toxin type I (SLT-I) of enterohemorrhagic E. coli. (These toxins are referred to together as Shiga toxin/SLT-I.) The A subunit of SLT-IIv, like those of other members of this toxin family, had regions of homology with the plant lectin ricin. SLT-IIv did not bind to galactose-alpha 1-4-galactose conjugated to bovine serum albumin, which is an analog of the eucaryotic cell receptor for Shiga toxin/SLT-I and SLT-II. These findings support the hypothesis that SLT-IIv binds to a different cellular receptor than do other members of the Shiga toxin family but has a similar mode of intracellular action. The organization of the SLT-IIv operon was similar to that of other members of the Shiga toxin family. Iron did not suppress SLT-IIv or SLT-II production, in contrast with its effect on Shiga toxin/SLT-I. Therefore, the regulation of synthesis of SLT-IIv and SLT-II differs from that of Shiga toxin/SLT-I.     

Physicochemical characterization of A and B subunits of Shiga toxin and reconstitution of holotoxin from isolated subunits

The A and B subunits of Shiga toxin were isolated by high performance liquid chromatography and their physicochemical properties were examined. The A subunit of Shiga toxin purified from culture supernatant was not nicked, but it could be nicked in vitro by trypsin. The isoelectric points of the A and B subunits were determined to be 8.2 and 5.8, respectively. Amino acid compositions of the two subunits were also determined. The isolated A and B subunits were reconstituted to form active holotoxin which showed lethal activity to mice which was similar to that of native Shiga toxin.     

Minimum domain of the Shiga toxin A subunit required for enzymatic activity.

The minimum sequence of the enzymatic (A) subunit of Shiga toxin (STX) required for activity was investigated by introducing N-terminal and C-terminal deletions in the molecule. Enzymatic activity was assessed by using an in vitro translation system. A 253-amino-acid STX A polypeptide, which is recognized as the enzymatically active portion of the 293-amino-acid A subunit, expressed less than wild-type levels of activity. In addition, alteration of the proposed nicking site between Ala-253 and Ser-254 by site-directed mutagenesis apparently prevented proteolytic processing but had no effect on the enzymatic activity of the molecule. Therefore, deletion analysis was used to identify amino acid residue 271 as the C terminus of the enzymatically active portion of the STX A subunit. STX A polypeptides with N-terminal and C-terminal deletions were released into the periplasmic space of Escherichia coli by fusion to the signal peptide and the first 22 amino acids of Shiga-like toxin type II, a member of the STX family. Although these fusion proteins expressed less than wild-type levels of enzymatic activity, they confirmed the previous finding that Tyr-77 is an active-site residue. Therefore, the minimum domain of the A polypeptide which was required for the expression of enzymatic activity was defined as StxA residues 75 to 268.     

Characterization of point mutations in the cdtA gene of the cytolethal distending toxin of Actinobacillus actinomycetemcomitans

The Cdt is a family of gram-negative bacterial toxins that typically arrest eukaryotic cells in the G0/G1 or G2/M phase of the cell cycle. The toxin is a heterotrimer composed of the cdtA, cdtB and cdtC gene products. Although it has been shown that the CdtA protein subunit binds to cells in culture and in an enzyme-linked immunosorbent assay (CELISA) the precise mechanisms by which CdtA interacts with CdtB and CdtC has not yet been clarified. In this study we employed a random mutagenesis strategy to construct a library of point mutations in cdtA to assess the contribution of individual amino acids to binding activity and to the ability of the subunit to form biologically active holotoxin. Single unique amino acid substitutions in seven CdtA mutants resulted in reduced binding of the purified recombinant protein to Chinese hamster ovary cells and loss of binding to the fucose-containing glycoprotein, thyroglobulin. These mutations clustered at the 5'- and 3'-ends of the cdtA gene resulting in amino acid substitutions that resided outside of the aromatic patch region and a conserved region in CdtA homologues. Three of the amino acid substitutions, at positions S165N (mutA81), T41A (mutA121) and C178W (mutA221) resulted in gene products that formed holotoxin complexes that exhibited a 60% reduction (mutA81) or loss (mutA121, mutA221) of proliferation inhibition. A similar pattern was observed when these mutant holotoxins were tested for their ability to induce cell cycle arrest and to convert supercoiled DNA to relaxed and linear forms in vitro. The mutations in mutA81 and mutA221 disrupted holotoxin formation. The positions of the amino acid substitutions were mapped in the Haemophilus ducreyi Cdt crystal structure providing some insight into structure and function.     

Stimulation of adenylate cyclase in washed pigeon erythrocyte membrane with cholera toxin and its subunits.

Cholera toxin was found to stimulate adenylate cyclase activity in washed membrane of pigeon erythrocytes in the presence of dithiothreitol and NAD. When tested with isolated cholera toxin components, the stimulatory activity was found with subunit A or polypeptide A1 derived from this subunit, but not with A2 or subunit B. On a molar basis, polypeptide A1 was approximately four times more active than cholera toxin. Dithiothreitol was not required in the action of polypeptide A1, suggesting that the reagent was needed only to release A1 from subunit A or the holotoxin for their action on adenylate cyclase. The single SH group in polypeptide A1 was not involved in the activity of the peptide, since chemical modification of the thiol group did not alter the stimulatory activity of the peptide. The presence of NAD was, however, essential for the activation of adenylate cyclase with cholera toxin, subunit A, or polypeptide A1. Elevation of the adenylate cyclase activity was also observed when the intact pigeon erythrocytes were incubated with polypeptide A1, although a 30-fold molar excess of A1 over that of holotoxin was required for the same level of activation.     

Analysis of structure and function of the B subunit of cholera toxin by the use of site-directed mutagenesis

Oligonucleotide-directed mutagenesis of ctxB was used to produce mutants of cholera toxin B subunit (CT-B) altered at residues Cys-9, Gly-33, Lys-34, Arg-35, Cys-86 and Trp-88. Mutants were identified phenotypically by radial passive immune haemolysis assays and genotypically by colony hybridization with specific oligonucleotide probes. Mutant CT-B polypeptides were characterized for immunoreactivity, binding to ganglioside GM1, ability to associate with the A subunit, ability to form holotoxin, and biological activity. Amino acid substitutions that caused decreased binding of mutant CT-B to ganglioside GM1 and abolished toxicity included negatively charged or large hydrophobic residues for Gly-33 and negatively or positively charged residues for Trp-88. Substitution of lysine or arginine for Gly-33 did not affect immunoreactivity or GM1-binding activity of CT-B but abolished or reduced toxicity of the mutant holotoxins, respectively. Substitutions of Glu or Asp for Arg-35 interfered with formation of holotoxin, but none of the observed substitutions for Lys-34 or Arg-35 affected binding of CT-B to GM1. The Cys-9, Cys-86 and Trp-88 residues were important for establishing or maintaining the native conformation of CT-B or protecting the CT-B polypeptide from rapid degradation in vivo.     

Shiga toxin, Shiga-like toxin II variant, and ricin are all single-site RNA N-glycosidases of 28 S RNA when microinjected into Xenopus oocytes

Ricin, Shiga toxin, and Shiga-like toxin II (SLT-II, Vero toxin 2) exhibit an RNA N-glycosidase activity which specifically removes a single base near the 3' end of 28 S rRNA in isolated rat liver ribosomes and deproteinized 28 S rRNA (Endo Y., Mitsui, K., Motizuki, M., & Tsurugi, K. (1987) J. Biol. Chem. 262, 5908-5912; Endo Y. & Tsurugi, K. (1987) J. Biol. Chem. 262, 8128-8130, Endo, Y., Tsurugi, K., Yutsudo, T., Takeda, Y., Ogasawara, K. & Igarashi, K. (1988) Eur. J. Biochem. 171, 45-50). These workers identified the single base removed, A-4324, by examining a 28 S rRNA degradation product which was generated by contaminating ribonucleases associated with the ribosomes. To determine whether this N-glycosidase activity applies in living cells, we microinjected ricin into Xenopus oocytes. We also microinjected Shiga toxin and a variant of Shiga-like toxin II (SLT-IIv). All three toxins specifically removed A-3732, located 378 nucleotides from the 3' end of 28 S rRNA. This base is analogous to the site observed in rat 28 S rRNA for ricin, Shiga toxin, and SLT-II. Purified, glycosylated, ricin A chain contains this RNA N-glycosidase activity in oocytes. We also demonstrated that the nonglycosylated A subunit of recombinant ricin exhibits this RNA N-glycosidase activity when injected into Xenopus oocytes. Ricin, Shiga toxin, and SLT-IIv also caused a rapid decline in oocyte protein synthesis for nonsecretory proteins.     

Effects of human intravenous immune globulin on diarrhea caused by Shiga-like toxin I and Shiga-like toxin II in infant rabbits.

Shiga toxin and the related Shiga-like toxins (SLT), produced by Escherichia coli, can cause hemorrhagic colitis and hemolytic uremic syndrome (HUS). Human intravenous immune globulin (HIVIg) blocks the cytotoxicity of some SLTs in vitro. To examine the ability of HIVIg to modify disease caused by Shiga-like toxin I or Shiga-like toxin II (SLT-I or SLT-II), we injected 3-day-old rabbits intraperitoneally with SLT-containing cell-free supernatants from Escherichia coli O157: H7. A subset of rabbits was treated with subcutaneous HIVIg. All rabbits given 10(4) CD50 of SLT-I developed severe diarrhea, and 5 died. When HIVIg 500 mg/kg was given in addition to SLT-I, only 6 of 18 rabbits (33.3%) developed diarrhea (P < 0.0001), and 1 died. HIVIg 500 mg/kg or 1,000 mg/kg protected against diarrhea when given one hour prior to toxin. HIVIg 1,000 mg/kg was protective when administered one hour after toxin, but not at 6 or 24 hr. Seventeen of 18 rabbits given 10(6) CD50 of SLT-II developed severe diarrhea, and 4 died. In contrast to SLT-I-associated disease, HIVIg had no effect on diarrhea in rabbits given SLT-II. We conclude that HIVIg protects infant rabbits from diarrhea and death caused by intraperitoneally administered SLT-I, but does not affect the course of SLT-II-associated illness.     

Cytotoxic effect of Shiga toxin-2 holotoxin and its B subunit on human renal tubular epithelial cells

Shiga toxin-producing Escherichia coli produces watery diarrhea, hemorrhagic colitis and hemolytic-uremic syndrome (HUS). In Argentina, HUS is the most common cause of acute renal failure in children. The purpose of the present study was to examine the cytotoxicity of Stx type 2 (Stx2 holotoxin) and its B subunit (Stx2 B subunit) on human renal tubular epithelial cells (HRTEC), in the presence and absence of inflammatory factors. Cell morphology, cell viability, protein synthesis and apoptosis were measured. HRTEC are sensitive to both Stx2 holotoxin and Stx2 B subunit in a dose- and time-dependent manner. IL-1, LPS and butyrate but not TNF, IL-6 and IL-8, increased the Stx mediated cytotoxicity. The effects of Stx2 B subunit appear at doses higher than those used for Stx2 holotoxin. Although the physiological importance of these effects is not clear, it is important to be aware of any potentially toxic activity in the B subunit, given that it has been proposed for use in a vaccine.     

Differences in crystal and solution structures of the cytolethal distending toxin B subunit: Relevance to nuclear translocation and functional activation

Cytolethal distending toxin (CDT) induces cell cycle arrest and apoptosis in eukaryotic cells, which are mediated by the DNA-damaging CdtB subunit. Here we report the first x-ray structure of an isolated CdtB subunit (Escherichia coli-II CdtB, EcCdtB). In conjunction with previous structural and biochemical observations, active site structural comparisons between free and holotoxin-assembled CdtBs suggested that CDT intoxication is contingent upon holotoxin disassembly. Solution NMR structural and 15N relaxation studies of free EcCdtB revealed disorder in the interface with the CdtA and CdtC subunits (residues Gly233-Asp242). Residues Leu186-Thr209 of EcCdtB, which encompasses tandem arginine residues essential for nuclear translocation and intoxication, were also disordered in solution. In stark contrast, nearly identical well defined alpha-helix and beta-strand secondary structures were observed in this region of the free and holotoxin CdtB crystallographic models, suggesting that distinct changes in structural ordering characterize subunit disassembly and nuclear localization factor binding functions.     

Adenine nucleotides promote dissociation of pertussis toxin subunits

Pertussis toxin is composed of an enzymatically active A subunit and a binding component (B oligomer). Both the holotoxin and the isolated A subunit have previously been shown to exhibit NAD glycohydrolase activity although the A subunit is more active on a molar basis than the holotoxin. We have investigated the mechanism by which ATP stimulates the activity of this toxin. Since dissociation of pertussis toxin subunits would result in increased NAD glycohydrolase activity, the ability of ATP to promote release of the A subunit from the B oligomer was examined. In the presence of the zwitterionic detergent 3-(3-cholamidopropyldimethyl)-1-ammonio)-propanesulfonate, concentrations of ATP as low as 1 microM promoted subunit dissociation. The concentration of ATP required for release of the A subunit was similar to that required for stimulation of NAD glycohydrolase activity. Both ATP and ADP promoted subunit dissociation and stimulated NAD glycohydrolase activity. In contrast, AMP and adenosine did not alter NAD glycohydrolase activity or affect subunit structure. The ability of ATP to decrease the affinity of the A subunit for the B oligomer may play a role in nucleotide stimulation of pertussis toxin activity.     

Effect of Substitution for Arginine Residues near Position 146 of the A Subunit of Escherichia coli Heat-Labile Enterotoxin on the Holotoxin Assembly

Escherichia coli heat-labile enterotoxin (LT) is a holotoxin which consists of one A and five B subunits. Although B subunit monomers released into periplasm can associate into pentameric structures in the absence of the A subunit, the A subunit accelerates the assembly. To express the function, A subunit constructs the proper spatial structure. However, the regions involved in the construction are unknown. To identify the regions, we substituted arginine residues near position 146 of the A subunit with glycine by oligonucleotide-directed site-specific mutagenesis and obtained the mutants expressing LT(R141G), LT(R143G), LT(R146G), LT(R143G, R146G), LT(R141G, R143G, R146G) and LT(R143G, R146G, R148G). We purified these mutant LTs by using an immobilized d -galactose column and analyzed the purified mutant LTs by SDS-PAGE to examine the amount of A subunit associated with B-subunit oligomer. The substitution of an arginine residue at any position did not induce a significant alteration in the amount of A subunit associated with B-subunit oligomer. However, the substitution of more than two arginine residues induced a significant decrease in the amount of A subunits associated with the B-subunit oligomer. Subsequently, we measured the level of the intracellular B-subunit oligomer of these mutant strains. The measurement revealed that the amount of B-subunit oligomer in cells decreased as the number of substituted arginine residues increased. These results show that all arginine residues near position 146 are important for the construction of the functional A subunit, and thus for holotoxin formation, although each individual arginine residue is not an absolute requirement.     

Adenylate cyclase toxin from Bordetella pertussis. Identification and purification of the holotoxin molecule

Bordetella pertussis adenylate cyclase (AC) toxin is a calmodulin-activated adenylate cyclase enzyme which has the capacity to enter eukaryotic target cells and catalyze the conversion of endogenous ATP into cyclic AMP. In this work, the AC holotoxin molecule is identified and isolated. It is a single polypeptide of apparent 216 kDa as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Monoclonal antibodies which immunoprecipitate AC activity from extracts of wild type B. pertussis (BP338) react with this 216-kDa band on Western blots, and it is absent from a transposon Tn5 mutant (BP348) specifically lacking AC toxin. Isolation of the 216-kDa protein to greater than 85% purity by hydrophobic chromatography, preparative sucrose gradient centrifugation, and affinity chromatography using either calmodulin-Sepharose or monoclonal antibody coupled to Sepharose 4B yields stepwise increases in AC toxin potency, to a maximum of 88.3 mumol of cAMP/mg of target cell protein/mg of toxin. Electroelution of the 216-kDa band following sodium dodecyl sulfate-polyacrylamide gel electrophoresis yields a preparation with both AC enzyme and toxin activities. These data indicate that this protein represents the AC holotoxin molecule.