The removal of carbohydrates from ricin with endoglycosidases H, F and D and alpha-mannosidase

Recently, several investigators have explored the possibility of targeting ricin to designated cell types in animals by its linkage to specific antibodies. There is evidence, however, that the mannose-containing oligosaccharide chains on ricin are recognised by reticuloendothelial cells in the liver and spleen and so cause the immunotoxins to be removed rapidly from the blood stream. In the present study we analysed the carbohydrate composition of ricin and examined enzymic methods for removing the carbohydrate. The carbohydrate analysis ricin A-chain revealed the presence of one residue of xylose and one of fucose in addition to mannose and N-acetylglucosamine which had been detected previously. The B-chain contained only mannose and N-acetylglycosamine. Ricin A-chain is heterogeneous containing two components of molecular weight 30 000 and 32 000. Strong evidence was found that the heavier form of the A-chain contains an extra carbohydrate unit which is heterogeneous with respect to concanavalin A binding and sensitivity to endoglycosidase H. The lower molecular weight form of A-chain did not bind concanavalin A and was insusceptible to endoglycosidases. Only one of the two high mannose oligosaccharide units on the isolated B-chain could be removed by endoglycosidases H or F, whereas both were removable after denaturation of the polypeptide by SDS. Both the isolated A- and B-chains were sensitive to alpha-mannosidase. Intact ricin was resistant to endoglycosidase treatment and was only slightly sensitive to alpha-mannosidase. The addition of SDS allowed endoglycosidase H to remove both of the B-chain oligosaccharides from intact ricin and increased the toxin's sensitivity to alpha-mannosidase. In conclusion, extensive enzymic deglycosylation of ricin may only be possible if the A- and B-chains are first separated, treated with enzymes and then recombined to form the toxin.     

Modification of the carbohydrate in ricin with metaperiodate-cyanoborohydride mixtures. Effects on toxicity and in vivo distribution

Attempts to target antibody-ricin conjugates (immunotoxins) to designated cell types in vivo may be thwarted by their rapid clearance by hepatic reticuloendothelial cells which have receptors that recognise oligosaccharide side chains on the toxin. The B-chain of ricin contains high mannose type oligosaccharides and the A-chain contains a complex unit (GlcNAc)2-Fuc-Xyl-(Man)4-6, all of which potentially could be recognised by the reticuloendothelial system. Treatment of ricin with a mixture of sodium metaperiodate and sodium cyanoborohydride at pH 3.5 resulted in oxidative cleavage of the carbohydrates and reduction of the aldehyde groups thus formed to primary alcohols. By conducting the modification procedure at acidic pH, both the possibility of Schiff's base formation between the aldehyde groups and amino groups in the protein and the possibility of non-specific oxidation of amino acids were minimised. The extent of the carbohydrate modification depended on the duration of treatment, resulting maximally in the destruction of 13 of the 18 mannose residues and of all xylose and fucose. The toxicity of the modified toxin to cells in culture declined by up to 90% as the carbohydrate was destroyed. This was not due to a reduced ability of the B-chain to bind to cells or of the A-chain to inactivate ribosomes. In contrast to the in vitro results, the toxicity of the modified toxin to mice and rats was elevated by up to fourfold. The modification greatly reduced the clearance of the toxin by non-parenchymal cells in the liver and prevented the damage to hepatic Kupffer and sinusoidal cells and to the red pulp of the spleen that is inflicted by the native toxin. The elevated toxicity to animals appears to be because the modified toxin evades the reticuloendothelial system and persists in the bloodstream for longer periods, thus resulting in lethal damage to vital tissues in the animal at lower dosage. The results suggest that immunotoxins prepared from modified ricin would not be readily cleared by the reticuloendothelial system and so be more effective at killing their target cells.     

The removal of carbohydrates from ricin with endoglycosidases H,F and D and α-mannosidase

Recently, several investigators have explored the possibility of targetting ricin to designated cell types in animals by its linkage to specific antibodies. There is evidence, however, that the mannose-containing oligosaccharide chains on ricin are recognised by reticuloendothelial cells in the liver and spleen and so cause the immunotoxins to be removed rapidly from the blood stream. In the present study we analysed the carbohydrate composition of ricin and examined enzymic methods for removing the carbohydrate. The carbohydrate analysis ricin A-chain revealed the presence of one residue of xylose and one of fucose in addition to mannose and N-acetylglucosamine which had been detected previously. The B-chain contained only mannose and N-acetylglycosamine. Ricin A-chain is heterogeneous containing two components of molecular weight 30 000 and 32 000. Strong evidence was found that the heavier form of the A-chain contains an extra carbohydrate unit which is heterogeneous with respect to concanavalin A binding and sensitivity to endoglycosidase H. The lower molecular weight form of A-chain did not bind concanavalin A and was insusceptible to endoglycosidases. Only one of the two high mannose oligosaccharide units on the isolated B-chain could be removed by endoglycosidases H or F, whereas both were removable after denaturation of the polypeptide by SDS. Both the isolated A- and B-chains were sensitive to α-mannosidase. Intact ricin was resistant to endoglycosidase treatment and was only slightly sensitive to α-mannosidase. The addition of SDS allowed endoglycosidase H to remove both of the B-chain oligosaccharides from intact ricin and increased the toxin's sensitivity to α-mannosidase. In conclusion, extensive enzymic deglycosylation of ricin may only be possible if the A- and B-chains are first separated, treated with enzymes and then recombined to form the toxin.     

Somatic cell mutants resistant to ricin, diphtheria toxin, and to immunotoxins

The human B-cell line Namalwa expresses the common acute lymphoblastic leukemia antigen (CALLA). Frame-shift mutants in Namalwa cell cultures were generated with ICR-191, and mutants were then selected for resistance to ricin or resistance to a conjugate of ricin with the anti-CALLA antibody J5 in the presence of lactose. Three mutants were found that were resistant to ricin and were in addition shown to be resistant to diphtheria toxin, to a J5-ricin conjugate, and to a conjugate between ricin B-chain and gelonin. The mutants, however, were sensitive to a J5-gelonin conjugate. These mutants expressed high levels of CALLA and/or receptors for ricin, and their cell-free translation systems appeared to be as sensitive to the inhibitory action of ricin A-chain and of gelonin as the translation system of wild-type Namalwa cells. The behavior of these mutants was consistent with the hypothesis that these cells possess an alteration of their surface that impedes the passage of ricin and diphtheria toxin across the plasma membrane. A fourth mutant was found to bind reduced quantities of ricin and was resistant to ricin but was sensitive to J5-ricin. The properties of this cell line provide evidence that the binding of antibody-ricin conjugates to cells via the ricin moiety may be prevented without impeding the cytotoxicity of the conjugates.     

The role of binding ligand in toxic hybrid proteins: a comparison of EGF-ricin, EGF-ricin A-chain, and ricin

To analyze the influence of ricin B-chain on the toxicity of hybrid-protein conjugates, the rate of cellular uptake of conjugates, and the rate at which ricin A-chain (RTA) is delivered to the cytoplasm, we have constructed toxic hybrid proteins consisting of epidermal growth factor (EGF) coupled in disulfide linkage either to ricin or to RTA. EGF-ricin is no more toxic on A431 cells than EGF-RTA. The two conjugates demonstrate similar kinetics of cellular uptake (defined as antibody irreversible toxicity). EGF-RTA and EGF-ricin, like ricin, required a 2-2 1/2 hour period at 37 degrees before the onset of protein synthesis inhibition occurred. Our results suggest that RTA determines the processes which carry it, either in conjugate or toxin, from the plasma membrane binding site to the cytoplasm following endocytosis, and the ricin B chain is not required for these processes.     

Features of the structure of catalytic subunits of toxins, inhibiting protein synthesis. I. The effect of pH and interaction with the B-chain of ricin

A comparative study of gelonin and A-chains of ricin, mistletoe lectin I and diphtheria toxin was undertaken. The effect of pH was studied on: a) the conformation of the proteins under study using intrinsic fluorescence; b) interaction of these proteins with ricin B-chain using gel-filtration. Structural stability of the proteins was assessed according to denaturing action of guanidine hydrochloride and temperature, and localization of tryptophan residues was determined using fluorescence quenching by I-, Cs+ and acrylamide. All investigated proteins were shown to undergo the conformational changes when a environment became acidic. In comparison with an intact protein--gelonin, the A-chains of ricin, a mistletoe lectin and a diphtheria toxin are less stable. At pH less than 5.0 tryptophan residues became more accessible to quencher and a positive charge of the surrounding area increases (in the case of gelonin it is negatively charged). No reliable interaction of a ricin B-chain with both gelonin and A-chain of diphtheria toxin was observed. The interaction of a ricin B-chain with a A-chain of mistletoe lectin I is weaker than that with ricin A-chain and is practically pH-independent.     

Blockade of the galactose-binding sites of ricin by its linkage to antibody. Specific cytotoxic effects of the conjugates

A method is described for preparing specific cytotoxic agents by linking intact ricin to antibodies in a manner that produces obstruction of the galactose-binding sites on the B chain of the toxin and so diminishes the capacity of the conjugate to bind non-specifically to cells. The conjugates were synthesised by reacting iodoacetylated ricin with thiolated immunoglobulin and the components of conjugate with reduced galactose-binding capacity were separated by affinity chromatography on Sepharose (a beta-galactosyl matrix) and asialofetuin-Sepharose. Fluorescence-activated cell sorter (FACS) analyses revealed that the fraction of a monoclonal anti-Thy1.1-ricin conjugate that passed through a Sepharose column had markedly diminished capacity to bind non-specifically to Thy1.2-expressing CBA thymocytes and EL4 lymphoma cells. The fraction of conjugate that passed through an asialofetuin-Sepharose column displayed no detectable non-specific binding. Both fractions of conjugate were potent cytotoxic agents for Thy1.1-expressing AKR-A lymphoma cells in tissue culture. They reduced the [3H]leucine incorporation of the cells by 50% at a concentration of 2-5 pM. Comparable inhibition of EL4 cells was only achieved with 3000-7500-fold greater concentrations of conjugate. By contrast, the fraction of anti-Thy1.1-ricin that retained Sepharose-binding capacity showed marked non-specific binding and toxicity to EL4 cells. A conjugate with diminished galactose-binding capacity was also prepared from the W3/25 monoclonal antibody which recognises an antigen upon helper T-lymphocytes in the rat. It elicited powerful and specific toxic effects upon W3/25 antigen-expressing rat T-leukaemia cells. This finding is of particular importance because isolated ricin A-chain disulphide-linked to W3/25 antibody is not cytotoxic. The property of the B-chain in intact ricin conjugates that facilitates delivery of the A-chain to the cytosol thus appears to be independent of galactose recognition. It is concluded that the 'blocked' ricin conjugates combine the advantages of high potency, which is often lacking in antibody-A-chain conjugates, with high specificity, which previously was lacking in intact ricin conjugates.     

Identification of the ricin lipase site and implication in cytotoxicity

Ricin is a heterodimeric plant toxin and the prototype of type II ribosome-inactivating proteins. Its B-chain is a lectin that enables cell binding. After endocytosis, the A-chain translocates through the membrane of intracellular compartments to reach the cytosol where its N-glycosidase activity inactivates ribosomes, thereby arresting protein synthesis. We here show that ricin possesses a functional lipase active site at the interface between the two subunits. It involves residues from both chains. Mutation to alanine of catalytic serine 221 on the A-chain abolished ricin lipase activity. Moreover, this mutation slowed down the A-chain translocation rate and inhibited toxicity by 35%. Lipase activity is therefore required for efficient ricin A-chain translocation and cytotoxicity. This conclusion was further supported by structural examination of type II ribosome-inactivating proteins that showed that this lipase site is present in toxic (ricin and abrin) but is altered in nontoxic (ebulin 1 and mistletoe lectin I) members of this family.     

The effect of pH on the conformation and stability of the structure of plant toxin-ricin

The effect of pH on the conformation of ricin and its A- and B-chains has been studied by measuring their intrinsic fluorescence. At pH 5.0 and 7.5, the structural stability of toxin and subunits was estimated according to the denaturing action of guanidine hydrochloride. It was demonstrated that the fluorescence of native toxin and catalytic A-subunit does not depend significantly on pH in the range pH 3-8, whereas ricin B-chain undergoes a structural transition at pH less than 5.0. The structural stability of ricin and isolated chains differs significantly at pH 7.5 and 5.0; the structural stability of ricin and the A-chain increases, whereas that of the B-chain decreases.     

Effect of pH on the conformation and stability of the plant toxin ricin

Intrinsic protein fluorescence of native plant toxin and its isolated subunits were studied. The effect of pH was studied on: conformation of ricin and its A- and R-chains; affinity to galactose of ricin and its binding B-subunit. At two pH 5.0 and 7.0, the structural stability of toxin and subunits was estimated according to denaturational action of guanidine chloride. It was demonstrated that position of maximum and the spectrum shape of fluorescence of native toxin and catalytical A-subunit insignificantly depends on pH in the range of 3-8, whereas sufficient changes of the separameters for the ricin B-chain reveal structural transition at pH 4-5. The affinity of galactose of ricin and its isolated B-chain depends on pH, the maximal binding is observed at pH 7. The structural stability of ricin and isolated chains significantly differs at pH 7.5 and 5.0, thus the structure stability of ricin and A-chain increases, and that of B-chain decreases at pH 5.0.     

The specific cytotoxicity of immunoconjugates containing blocked ricin is dependent on the residual binding capacity of blocked ricin: evidence that the membrane binding and A-chain translocation activities of ricin cannot be separated.

Recently we have developed blocked ricin, a derivative of native ricin in which the galactose-binding sites of the B-chain are blocked by covalent modification with affinity ligands. This modification impedes the binding function of the B-chain, while sparing its ability to facilitate the entry of the toxic subunit of ricin, the A-chain, into the cytoplasm. Immunotoxins prepared with blocked ricin approach the cytotoxic potency of native ricin with antibody-dependent specificity. Here we report that the high cytotoxic potency of these immunoconjugates, which is attributed to the preserved translocation function of the ricin B-chain, is dependent on the minimal residual lectin activity of blocked ricin. Our findings support the notion that two functions of ricin, membrane binding and translocation, cannot be separated.     

The tRNA N2,N2-dimethylguanosine-26 methyltransferase encoded by gene trm1 increases efficiency of suppression of an ochre codon in Schizosaccharomyces pombe

The plant toxin ricin has proven valuable as a membrane marker in studies of endocytosis as well as studies of different intracellular transport steps. The toxin, which consists of two polypeptide chains, binds by one chain (the B-chain) to both glycolipids and glycoproteins with terminal galactose at the cell surface. The other chain (the A-chain) enters the cytosol and inhibits protein synthesis enzymatically. After binding the toxin is endocytosed by different mechanisms, and it is transported via endosomes to the Golgi apparatus and the endoplasmic reticulum before translocation of the A-chain to the cytosol. The different transport steps have been analyzed by studying trafficking of ricin as well as modified ricin molecules.     

Carbohydrate-specifically polyethylene glycol-modified ricin A-chain with improved therapeutic potential

Ricin A-chain, which exhibits excellent cytotoxicity to tumor cells, has been widely used as an immunotoxin source. However, it has the fatal shortcoming of poor pharmacokinetics due to the tremendous liver uptake via carbohydrate-mediated recognition. Modification of proteins with polyethylene glycol, PEGylation, has the advantages of shielding the specific sites and prolonging the biological half-life. In this study, the carbohydrate-specific PEGylation of ricin A-chain was considered to be a novel approach to overcome this limitation. The carbohydrate group of ricin A-chain was oxidized by sodium m-periodate and further specifically conjugated with hydrazide-derivatized PEG. For a comparative study, the PEGylated ricin A-chain at amino groups was prepared using the hydroxysuccinimide ester-derivatized PEG. The carbohydrate-specifically PEGylated ricin A-chain showed a markedly lower liver uptake and systemic clearance compared with the amine-directly PEGylated ricin A-chain as well as the unmodified ricin A-chain. Furthermore, carbohydrate-specifically PEGylated ricin A-chain showed a significantly higher in vitro ribosome-inactivating activity than the amine-directly PEGylated ricin A-chain. These findings clearly demonstrate that the carbohydrate-specificity as well as PEGylation plays an important role in improving the in vivo pharmacokinetic properties and in vitro bioactivity. Therefore, these results suggest that the therapeutic use of immunotoxins constructed using this carbohydrate-specifically PEGylated ricin A-chain has potential as a cancer therapy.     

Dependence of ricin toxicity on translocation of the toxin A-chain from the endoplasmic reticulum to the cytosol

Ricin acts by translocating to the cytosol the enzymatically active toxin A-chain, which inactivates ribosomes. Retrograde intracellular transport and translocation of ricin was studied under conditions that alter the sensitivity of cells to the toxin. For this purpose tyrosine sulfation of mutant A-chain in the Golgi apparatus, glycosylation in the endoplasmic reticulum (ER) and appearance of A-chain in the cytosolic fraction was monitored. Introduction of an ER retrieval signal, a C-terminal KDEL sequence, into the A-chain increased the toxicity and resulted in more efficient glycosylation, indicating enhanced transport from Golgi to ER. Calcium depletion inhibited neither sulfation nor glycosylation but inhibited translocation and toxicity, suggesting that the toxin is translocated to the cytosol by the pathway used by misfolded proteins that are targeted to the proteasomes for degradation. Slightly acidified medium had a similar effect. The proteasome inhibitor, lactacystin, sensitized cells to ricin and increased the amount of ricin A-chain in the cytosol. Anti-Sec61alpha precipitated sulfated and glycosylated ricin A-chain, suggesting that retrograde toxin translocation involves Sec61p. The data indicate that retrograde translocation across the ER membrane is required for intoxication.     

The lower cytotoxicity of cinnamomin (a type II RIP) is due to its B-chain

The cytotoxicity of intact cinnamomin (a type II ribosome-inactivating protein, RIP) and the RNA N-glycosidase activity of cinnamomin A-chain have been studied and compared with those of ricin. Cinnamomin A-chain exhibits a similar RNA N-glycosidase activity in inhibiting in vitro protein synthesis compared with that of ricin, whereas the cytotoxicity to BA/F3beta cells of intact cinnamomin is markedly lower than intact ricin. In order to demonstrate that it is the B-chains of the two RIPs that bear the difference in cytotoxicity, two hybrid RIPs are prepared from the purified A-/B-chains of cinnamomin and ricin by the disulfide exchange reaction. It has been found that hybrid RIP constructed from cinnamomin A-chain and ricin B-chain is more toxic to BA/F3beta cells than the native cinnamomin, and equivalent to the native ricin. However, the cytotoxicity to BA/F3beta cells of the hybrid RIP constructed from the ricin A-chain and cinnamomin B-chain is lower than ricin, equivalent to the native cinnamomin. Furthermore, the bound amounts of two B-chains on the cell surface are determined by the method of direct cellular ELISA and Scatchard analysis of the binding of the two B-chains indicates that cinnamomin and ricin share similar binding sites with different affinity.     

The mechanism of action of barley toxin: a type 1 ribosome-inactivating protein with RNA N-glycosidase activity

In a previous report (Endo, Y. and Tsurugi, K. (1987) J. Biol. Chem. 262, 8128-8130) it was shown that the RNA N-glycosidase activity of ricin A-chain was responsible for the ability of this protein to inactivate eukaryotic ribosomes. The objective of the present study was to determine whether a similar mechanism was used by a ribosome-inactivating protein from pearled barley (barley toxin). Rat liver ribosomes were incubated either with ricin A-chain or barley toxin, and the rRNA was extracted and treated with acidic aniline to hydrolyze phosphodiester bonds rendered susceptible by removal of a purine or pyrimidine base. Evaluation of the rRNA by polyacrylamide/agarose electrophoresis disclosed two 28 S rRNA-derived fragments which differed in size from those generated by untreated (control) ribosomes. Sequencing of the smaller of these fragments confirmed that - as is the case for ricin A-chain - the aniline-sensitive site in barley toxin-treated ribosomes was between A and G in 28 S rRNA. We conclude that barley toxin inactivates ribosomes via a mechanism identical to that of ricin A-chain: enzymatic hydrolysis of the N-glycosidic bond at A of 28 S rRNA.     

Preparation and properties of a hybrid toxin of modeccin A-chain and ricin B-chain

Hybrid molecules were prepared from the A- and B-chains of the two toxic lectins ricin and modeccin by dialyzing mixtures of isolated chains to allow a disulfide bridge to be formed between them. Whereas the hybrid consisting of ricin A-chain and modeccin B-chain was non-toxic, the converse hybrid, modeccin A-chain/ricin B-chain, was even more toxic to Vero cells than were the parent toxins, native ricin and modeccin. A number of drugs (NH₄Cl, monensin, trifluoperazine, verapamil, ionophore A23187) which protect cells against modeccin, but not against ricin, protected to some extent against the toxic hybrid, but less so than against native modeccin. The possibility is discussed that the modeccin A-chain of the hybrid may enter the cytosol by two routes, one which is highly efficient and identical to that used by native modeccin and another less efficient one which cannot be used by native modeccin.     

Interaction of ricin and its constituent polypeptides with dipalmitoylphosphatidylcholine vesicles

The interaction of ricin and of its constituent polypeptides, the A- and B-chain, with dipalmitoylphosphatidylcholine (DPPC) vesicles was investigated. The A- and B-chain were individually associated with DPPC vesicles, although the intact ricin was not associated. The maximum binding and association constants were evaluated to be 154 micrograms per mg of DPPC and Ka = 2.30 X 10(5) M-1 for the A-chain, and 87 micrograms per mg of DPPC and Ka = 14.5 X 10(5) M-1 for the B-chain, respectively. The A-chain could induce the phase transition release of carboxyfluorescein from DPPC vesicles to a greater extent than the B-chain, whereas the release induced by the intact ricin was negligible. The evidence indicated that the hydrophobic regions on the A-chain and on the B-chain were buried inside when the two chains constituted the intact ricin molecule through one interchain disulfide bond, and that the A-chain caused perturbation of the DPPC bilayer at the phase transition temperature with consequent leakage of carboxyfluorescein.     

Radioimmunoassay of ricin A- and B-chains applied to samples of ricin A-chain prepared by chromatofocusing and by DEAE Bio-Gel A

A radioimmunoassay for ricin and ricin A- and B-chains was developed. Amounts as low as 100 pg of A-chain and 500 pg of B-chain could easily be quantitated. We showed, however, that the free chains were more reactive in the radioimmunoassay than the equivalent quantity of the individual chains when combined in intact ricin. The usefulness of the assay was demonstrated by determining the concentration of contaminating A- or B-chains in preparations of the separate polypeptides purified by DEAE Bio-Gel A chromatography and by chromatofocusing.     

Brefeldin-A enhancement of ricin A-chain immunotoxins and blockade of intact ricin, modeccin, and abrin

After binding, the protein toxins ricin, abrin, and modeccin are endocytosed and processed through the cell's vesicular system in a poorly understood fashion, prior to translocation to the cytosol. The role of the Golgi apparatus in toxin processing was studied using brefeldin-A (BFA), a fungal metabolite which blocks Golgi function. At concentrations that inhibit secretion of interleukin-2 (IL-2), BFA blocks ricin, modeccin, and abrin intoxication of a lymphocyte derived cell line (Jurkat). Paradoxically, BFA enhances the toxicity of two ricin A-chain immunotoxins targeted against distinct cell surface determinants. BFA concentrations which are optimal for immunotoxin enhancement are below those needed to affect ricin intoxication or IL-2 secretion. BFA blockade of ricin does not involve effects on ricin endocytosis, toxin translocation to the cytosol, or the enzymatic activity of toxin A-chain. In contrast, BFA has no effect on immunotoxin processing but does enhance the immunotoxin translocation step. It is concluded that: 1) intact Golgi function is required for holotoxin processing. 2) Intact Golgi function is not required for holotoxin translocation. 3) Golgi function is tightly linked to immunotoxin translocation. 4) BFA has effects on vesicular routing in addition to the block of Golgi function in secretion which has been reported.