Evidence for involvement of tryptophan residue in the low-affinity saccharide binding site of ricin D

Polymer antidotes for toxin sequestration

Toxins delivered by envenomation, secreted by microorganisms, or unintentionally ingested can pose an immediate threat to life. Rapid intervention coupled with the appropriate antidote is required to mitigate the threat. Many antidotes are biological products and their cost, methods of production, potential for eliciting immunogenic responses, the time needed to generate them, and stability issues contribute to their limited availability and effectiveness. These factors exacerbate a world-wide challenge for providing treatment. In this review we evaluate a number of polymer constructs that may serve as alternative antidotes. The range of toxins investigated includes those from sources such as plants, animals and bacteria. The development of polymeric heavy metal sequestrants for use as antidotes to heavy metal poisoning faces similar challenges, thus recent findings in this area have also been included. Two general strategies have emerged for the development of polymeric antidotes. In one, the polymer acts as a scaffold for the presentation of ligands with a known affinity for the toxin. A second strategy is to generate polymers with an intrinsic affinity, and in some cases selectivity, to a range of toxins. Importantly, in vivo efficacy has been demonstrated for each of these strategies, which suggests that these approaches hold promise as an alternative to biological or small molecule based treatments.

Equilibrium dialysis using chromophoric sugar derivatives

Equilibrium dialysis has been used to examine the binding affinity of ligands to proteins. It is a simple and reliable method, which requires only inexpensive equipment. For analysis of lectin-sugar interactions, the lectin and sugar are placed in the individual chambers separated by the membrane to allow the sugar to diffuse into the lectin chamber. After equilibrium has been reached, the concentrations of the sugar in both chambers are determined to evaluate the sugar-binding affinity of lectin. In this chapter, an example of the equilibrium dialysis experiment using the chromophoric derivatives of galactose and N-acetylgalactosamine is demonstrated, which reveals the difference in the affinity as well as specificities of two different carbohydrate-binding sites present in the B-chains of the plant lectin ricin.

Protective immunity to ricin toxin conferred by antibodies against the toxin's binding subunit (RTB)

The B subunit (RTB) of ricin toxin is a galactose-/N-acetyl galactosamine-specific lectin that promotes attachment and entry of ricin into host cells. RTB is also the archetype of the so-called R-type lectin family, whose members include haemagglutinins of botulinum neurotoxin (BoNT) progenitor toxins, as well as the binding subunits of cytolethal distending toxins. Although RTB is an appealing subunit vaccine candidate, as well as a potential target for immunotherapeutics, the degree to which RTB immunization elicits protective antibodies against ricin toxin remains unresolved. To address this issue, groups of mice were immunized with RTB and then challenged with 5×LD(50)s of ricin administered intraperitoneally. Despite high RTB-specific serum antibody titers, groups of RTB immunized mice were only partially immune to ricin challenge. Analysis of a collection of RTB-specific B cell hybridomas suggested that only a small fraction of antibodies against RTB have demonstrable neutralizing activity. Two RTB-specific neutralizing monoclonal IgG(1) antibodies, 24B11 and SylH3, when passively administered to mice, were sufficient to protect the animals against a 5×LD(50) dose of ricin. Both 24B11 and SylH3 blocked ricin attachment to terminal galactose residues and prevented toxin binding to the surfaces of bone marrow-derived macrophages (BMM), suggesting that they function by steric hindrance and recognize epitopes located on RTB's carbohydrate recognition sub-domains (1α or 2γ). These data raise the possibility of using specific RTB sub-domains, rather than RTB itself, as antigens to more efficiently elicit neutralizing antibodies and protective immunity against ricin.

Crystal structure at 3 A of mistletoe lectin I, a dimeric type-II ribosome-inactivating protein, complexed with galactose

The X-ray structure of mistletoe lectin I (MLI), a type-II ribosome-inactivating protein (RIP), cocrystallized with galactose is described. The model was refined at 3.0 A resolution to an R-factor of 19.9% using 21 899 reflections, with Rfree 24.0%. MLI forms a homodimer (A-B)2 in the crystal, as it does in solution at high concentration. The dimer is formed through contacts between the N-terminal domains of two B-chains involving weak polar and non-polar interactions. Consequently, the overall arrangement of sugar-binding sites in MLI differs from those in monomeric type-II RIPs: two N-terminal sugar-binding sites are 15 A apart on one side of the dimer, and two C-terminal sugar-binding sites are 87 A apart on the other side. Galactose binding is achieved by common hydrogen bonds for the two binding sites via hydroxy groups 3-OH and 4-OH and hydrophobic contact by an aromatic ring. In addition, at the N-terminal site 2-OH forms hydrogen bonds with Asp27 and Lys41, and at the C-terminal site 3-OH and 6-OH undergo water-mediated interactions and C5 has a hydrophobic contact. MLI is a galactose-specific lectin and shows little affinity for N-acetylgalactosamine. The reason for this is discussed. Structural differences among the RIPs investigated in this study (their quaternary structures, location of sugar-binding sites, and fine sugar specificities of their B-chains, which could have diverged through evolution from a two-domain protein) may affect the binding sites, and consequently the cellular transport processes and biological responses of these toxins.

Primary structure of hemolytic lectin CEL-III from marine invertebrate Cucumaria echinata and its cDNA: structural similarity to the B-chain from plant lectin, ricin

CEL-III, a galactose/N-acetylgalactosamine (Gal/GalNAc) specific lectin purified from a marine invertebrate Cucumaria echinata has a strong hemolytic activity especially toward human and rabbit erythrocytes. We determined the primary structure of the CEL-III by examining the amino acid sequences of the protein and the nucleotide sequence of the cDNA. The cDNA encoding CEL-III has 1823 nucleotides and an open reading frame of 1296 nucleotides. CEL-III is composed of 432 amino acid residues with a M(r) of 47¿ omitted¿457 and has six internal tandem repeats, each with of 40-50 amino acids, comprising the N-terminal two-thirds of the molecule. Similar repeats are found in the B-chains of cytotoxic plant lectins, such as ricin and abrin, where six repetitive sequences extend throughout the molecules. A hydropathy plot predicts hydrophobic segments in the C-terminal region of CEL-III. These findings suggest that the N-terminal region of CEL-III plays an important role in binding to carbohydrate receptors on the target cell membranes, an event which triggers an intermolecular hydrophobic interaction of the C-terminal region, the result being oligomerization of CEL-III to lead to pore-formation in erythrocyte membrane.

Characterization of the Asialofetuin microtitre plate-binding assay for evaluating inhibitors of ricin lectin activity

Optimum conditions for the binding of ricin to the glycoprotein asialofetuin immobilized on microtitre plates were investigated for the purpose of evaluating inhibitors of ricin B-chain lectin activity. Such inhibitors are of potential value in the use of immunotoxins based on ricin. This assay was first reported in 1986, but has not been characterized fully. Maximum binding of asialofetuin to the plate was observed at a concentration of ca. 4 microg ml(-1). Binding increased with time of incubation (1-24 h), pH (7.4-9.9) and temperature (2-37 degrees C). The pH effects were more marked at lower temperatures. Saturable binding of ricin to immobilized asialofetuin was observed, and at least 80% of maximum binding was observed by 10 min of incubation time. The binding was found to be very tight, such that an appreciable proportion of ricin added to the wells was bound at low concentrations, and binding was only partially reversible by addition of free galactose. Consequently, only estimates of the ricin-asialofetuin and ricin-galactose dissociation constants could be determined: 1.9 nM and 83 microM, respectively. Binding of ricin A- and B-chains was found to be 47% (at a 200-fold higher concentration) and 26% (at a twofold higher concentration) of that of the whole ricin molecule, respectively. The assay permits qualitative comparison of inhibitors of ricin B-chain lectin activity.

Restoration of lectin activity to an inactive abrin B chain by substitution and mutation of the 2 gamma subdomain

Abrin is a heterodimeric plant protein that occurs in several isoforms (abrin-a, abrin-b, abrin-c and abrin-d), whose B chains are believed to either have (abrin-a and abrin-d) or lack (abrin-b and abrin-c) the ability to bind galactose. The 5' signal sequence and toxin B chain (ATB)-coding region were excised from a preproabrin cDNA [K. A. Wood, J. M. Lord, E. J. Wawrzynczak, and M. Piatak (1991) Eur. J. Biochem. 198, 723-732], tentatively identified as abrin-c, which was predicted to lack lectin activity, and fused in-frame to generate pre-ATB cDNA. Transcripts, synthesized in vitro from pre-ATB cloned into the transcription vector pSP64T, were expressed after microinjection into Xenopus oocytes. The recombinant ATB was shown, using a qualitative sugar-binding assay, to be devoid of lectin activity. Lectin activity could not be restored to this nonbinding ATB by replacing the 2 gamma subdomain with the corresponding galactose-binding 2 gamma subdomain from ricin B chain, but it was restored by replacement with the active galactose-binding 2 gamma subdomain from a different abrin isoform (abrin-a). The putative galactose-binding pocket of the nonbinding ATB 2 gamma subdomain contained a His residue at the position occupied by a residue with an aromatic side chain (Tyr or Trp) in functional 2 gamma subdomains. Mutationally converting this His to either Tyr or Trp restored lectin activity to the nonbinding ATB, emphasizing the contribution of an aromatic side chain in a functional 2 gamma subdomain galactose-binding site for members of this lectin family.

Mutational analysis of the Ricinus lectin B-chains. Galactose-binding ability of the 2 gamma subdomain of Ricinus communis agglutinin B-chain

Ricin B-chain (RTB) is a galactose-specific lectin that folds into two globular domains, each of which binds a single galactoside. The two binding sites are structurally similar and both contain a conserved tripeptide kink and an aromatic residue that comprises a sugar-binding platform. Whereas the critical RTB residues implicated in lectin activity are conserved in domain 1 of Ricinus communis agglutinin (RCA) B-chain, the sugar platform aromatic residue Tyr-248 present in domain 2 of RTB is replaced by His in RCA B-chain. In this study, key residues in the vicinity of the binding sites of the Ricinus lectin B-chains were altered by site-directed mutagenesis. The recombinant B-chains were produced in Xenopus oocytes in soluble, stable, and core-glycosylated forms. Both sites of RCA B-chain must be simultaneously modified in order to abolish lectin activity, indicating the presence of two independent, functional binding sites/molecule. Activity associated with the domain 2 site of RCA B-chain is abrogated by the conversion of Trp-258 to Ser. Moreover, the domain 2 site appears responsible for a weak binding interaction recombinant RCA B-chain with GalNAc, not observed with native tetrameric RCA. Finally, the introduction of His at position 248 of RTB severely disrupts but does not abolish GalNAc binding.

Hydrogen-bonding pattern of methyl beta-lactoside binding to the Ricinus communis lectins

The binding of O-methyl and fluorodeoxy derivatives of methyl beta-lactoside to the Ricinus communis toxin (RCA60) and agglutinin (RCA120) was studied in order to determine the donor/acceptor relationships of the hydrogen bonds between the hydroxyl groups of methyl beta-lactoside and the binding sites of the lectins. Free energy contributions of the hydrogen bonds at each position have been estimated from these data and from those previously reported for the monodeoxy derivatives [Rivera-Sagredo, A., Solís, D., Díaz-Mauriño, T., Jiménez-Barbero, J. & Martín-Lomas, M. (1991) Eur. J. Biochem. 197, 217-228; Rivera-Sagredo, A., Jiménez-Barbero, J., Martín-Lomas, M., Solís, D. & Díaz-Mauriño, T. (1992) Carbohydr. Res. 232, 207-226]. The nature of the groups of the lectins involved in hydrogen bonding has been predicted on the basis of the free energy data. Analysis of the results indicates that both the C-3' and C-4' hydroxyl groups act as hydrogen-bond donors to charged groups of both RCA60 and RCA120. The C-6' and probably also the C-2' hydroxyl groups participate both as donors and as acceptors of two hydrogen bonds with neutral groups of the lectins. And finally, the C-6 hydroxyl group possibly acts as a donor of a weak hydrogen bond to a neutral group in RCA60, but not in RCA120. The results provide a molecular basis to explain some features of the binding specificity of the lectins. Comparison of RCA60 binding data with the recently refined X-ray crystal structure of the RCA60-lactose complex shows similarities but also some discrepancies that can be attributed to the marked influence of the pH on the carbohydrate-lectin interaction.

Conformation of methyl beta-lactoside bound to the ricin B-chain: interpretation of transferred nuclear Overhauser effects facilitated by spin simulation and selective deuteration

Spin simulation and selective deuteration have been used to aid in the interpretation of 1D transferred nuclear Overhauser effect (TRNOE) NMR experiments on ricin B-chain/ligand systems. Application of these methods has revealed a change in the conformation of deuterated methyl beta-lactoside upon binding to the ricin B-chain which results in a slight change in glycosidic torsional angels which appear to dominate in the solution conformation. The combination of simulation and experiment also shows an important sensitivity of TRNOE magnitudes to dissociation rate constants and available spin-diffusion pathways for the ricin B-chain/ligand systems under study. The sensitivity to dissociation rates allows determination of rate constants for methyl beta-lactoside and methyl beta-galactoside of 50 and 300 s-1, respectively.

Fluorescence spectroscopic studies on tryptophan at the saccharide-binding site of castor bean hemagglutinin

The environment of tryptophan in castor bean hemagglutinin (CBH) was analyzed by fluorescence spectroscopy with regard to saccharide binding. Upon binding of specific saccharides, the fluorescence maximum of 333 nm of CBH shifted to a wavelength 2 nm shorter, owing to the change in the environment of tryptophan at the saccharide-binding site. By analyzing the change in the fluorescence intensity at 320 nm as a function of concentration of saccharides, the association constants for binding of saccharides to CBH were determined. The results suggest that the saccharide-binding site on each B-chain is actually composed of a subsite with which the saccharide residue linked to galactopyranoside at the non-reducing end can interact, and another site which recognizes the galactopyranoside moiety. Quenching data indicated that five out of 22 tryptophans in CBH are surface-localized and are available for quenching with both KI and acrylamide, and three other tryptophans are buried and are available only to acrylamide. Binding of raffinose to CBH decreased by 2 the number of tryptophan residues accessible to quenchers in the CBH molecule. We speculate that raffinose binds to CBH in such a manner as to shield the tryptophan located at the subsite from quenching by KI and acrylamide. The results also suggest that the tryptophan residue at the saccharide-binding site on each B-chain is localized near the surface, and present in the positively charged environment.

Clearance of certain modified haptoglobins from the rabbit circulation

1. Human haptoglobin (Hp) type 2-1 was subjected to the sulfanilazo-modification of tyrosine and histidine residues, the removal of sialic acid, and the reduction of disulfide bonds (isolation of alpha 2, alpha 1, beta subunits), respectively. Radioactively labeled preparations were administered intravenously to rabbits. 2. Human Hp and isolated beta (heavy) chain disappeared from the circulation somewhat faster (half-lives = 72 and 67 h, respectively), than homologous rabbit Hp (half-life = 96 h). Hp light chains (alpha 2, alpha 1), devoid of oligosaccharide showed shorter half-lives of 27-19 h. 3. Treatment of Hp with diazotized sulfanilic acid resulted in an appreciable reduction of half-life to 21-11 h, as dependent on the number of modified residues. 4. Asialo-Hp, asialo-beta chain, and asialo-sulfanilazo-Hp were cleared rapidly from the circulation with half-lives of 5.5, 5.0, and 4.2 h, respectively. 5. These results suggest that in different pathways of Hp catabolism in vivo, polypeptide recognition markers in addition to carbohydrate ones, are involved.

Structure and evolution of ricin B chain

Ricin is a dimeric toxin from the castor bean Ricinus communis, which is composed of a sugar-binding subunit (B) that attaches to receptors on the surfaces of target cells and a subunit (A) with enzymatic activity that attacks and inactivates ribosomes. We report here that comparison of amino-acid sequence data with high-resolution structure analysis of the ricin B subunit shows it to be the product of a series of gene duplications. The modern protein has two sugar-binding domains, each of which is composed of three copies of a more ancient galactose-binding peptide of about 40 residues.