Ricin B chain-containing immunotoxins prepared with heat-denatured B chain lacking galactose-binding ability potentiate the cytotoxicity of a cell-reactive ricin A chain immunotoxin

Ricin B chain incubated at 37 degrees C in the absence of lactose loses its ability to bind the galactose-containing protein, asialofetuin. Circular dichroism analysis of the B chain during thermal denaturation indicates that the loss of galactose-binding ability by the B chain correlates with limited unfolding of the molecule. As a result of this conformational change, disulfide bonds that are shielded from the solvent by the compact folded structure of the B chain become exposed and the chitobiosyl cores of both N-linked oligomannose chains become susceptible to cleavage by endoglycosidases. The heat-denatured B chain does not enhance the toxicity of a ricin A chain-containing rabbit anti-human immunoglobulin (RAHIg-A) to Daudi cells. However, when heat-denatured B chain is coupled to goat anti-rabbit immunoglobulin (GARIg), the resulting immunotoxin, GARIg-hdB, potentiates the killing of RAHIg-A-treated Daudi cells to an extent similar to that of an immunotoxin prepared with GARIg and native B chain. These results indicate that the native, galactose-binding structure of the B chain is not necessary to enhance the cytotoxicity of the cell-reactive A chain immunotoxin (IT-A) and suggests that regions of the B chain exposed by unfolding the molecule may mediate potentiation of cytotoxicity.     

Purification of ricin A1, A2, and B chains and characterization of their toxicity

This paper describes a protocol for the preparation of highly purified A (A1 and A2) and B chains of the plant toxin, ricin, and biochemical and biological characterization of these proteins. Intact ricin was bound to acid-treated Sepharose 4B and was split on the column into A and B chains with 2-mercaptoethanol. The A chains were eluted with borate buffer containing 2-mercaptoethanol. A1 and A2 were then partially separated by cation exchange chromatography and the contaminating B chain was removed by affinity chromatography on Sepharose-asialofetuin and Sepharose-monoclonal anti-B chain. The B chain was eluted from the Sepharose 4B column by treatment with galactose and was further purified by cation and anion exchange chromatography; contaminating A chains were removed by affinity chromatography on Sepharose-monoclonal anti-A chain. The purified A and B chains were active as determined by their ability to inhibit protein synthesis in a cell-free assay and their binding to asialofetuin, respectively. Furthermore, by polyacrylamide gel electrophoresis, toxicity in mice, and toxicity on several different cell types, both A and B chains were shown to be minimally cross-contaminated. Finally, it was shown that ammonium chloride significantly enhanced the nonspecific toxicity of B chains for cells in vitro. In contrast, ammonium chloride did not enhance either the nonspecific toxicity of A chains in vitro or the specific toxicity of A chain-containing immunotoxins prepared with the highly purified A1, A2 chains.     

Identification and characterization of a monoclonal antibody recognizing a galactose-binding domain of the toxin ricin

A monoclonal antibody raised against purified ricin B chain, 75/3B12, blocked ricin toxicity 30- to 100-fold in vitro. The 75/3B12 IgG and F(ab')2 blocked ricin binding to cell surface galactose-containing receptors. The 75/3B12 Fab bound ricin D with a Ka of 10(7) M-1, and this binding was blocked by asialofetuin, lactose, and N-acetylgalactosamine--molecules which interact with the ricin galactose-binding site--but not by fetuin, sucrose, or glucose. The 75/3B12 Fab contained no detectable carbohydrate and, according to several lines of evidence, did not bind ricin via Ig carbohydrate determinants. The monoclonal antibody appears to recognize a galactose-binding site on ricin D via the variable region of the antibody. The 75/3B12 Fab bound ricin E only 1/50 as well as ricin D and bound the Ricinus agglutinin only 1/80 as well as ricin D. The antibody specificity indicates that structural differences exist in the galactose-binding sites of the Ricinus communis lectins. Abrin and other lectins which bind galactose or N-acetylgalactosamine were not significantly bound by the monoclonal antibody. In vitro, the antibody blocked the nontarget toxicity of immunotoxins similarly to lactose. However, in vivo, unlike lactose, the 75/3B12 antibody protected mice from ricin toxicity.     

The effect of antibody valency and lysosomotropic amines on the synergy between ricin A chain- and ricin B chain-containing immunotoxins

The cytotoxicity of A chain immunotoxins containing IgG or Fab fragments specific for the surface immunoglobulin of the Daudi cell line was assessed in the presence of B chain immunotoxins (IgG or Fab) or lysosomotropic amines, or both. The concentration required for 50% inhibition of protein synthesis (IC50) in Daudi cells was 1.3 X 10(-8) M for IgG-A and 5 X 10(-8) M for Fab-A. The toxicity of both A chain immunotoxins was enhanced twofold by ammonium chloride. In the presence of A chain immunotoxins and ammonium chloride, a maximum of 99 and 90% reduction of clonal precursors was obtained with IgG and Fab-A chain immunotoxins respectively. Immunotoxins containing ricin B chain and IgG or Fab fragments specific for the antibody portion of A chain immunotoxins were used as secondary "piggyback" immunotoxins to treat cells that were pretreated with A chain immunotoxins. Both B chain immunotoxins were nontoxic at 1 X 10(-6) M. When added to target cells pretreated with specific A chain immunotoxins, the IC50 of the A chain immunotoxins was decreased up to 16-fold in the absence of ammonium chloride. In contrast to the results obtained with A chain immunotoxins alone, ammonium chloride significantly increased the toxicity of the complete piggyback system, resulting in the killing of 99.999% or five logs of target cells in the clonal assay. This decreased the IC50 of A chain immunotoxins up to 116-fold when compared with A chain immunotoxin alone. This enhanced toxicity was independent of the valency of either immunotoxin.     

Conformation-dependent antigenic determinants in the toxic lectin ricin.

The major part of the ricin-precipitable antibodies in sera produced by immunizing rabbits with formaldehyde-treated ricin is precipitated also by the isolated ricin A and B chains. In contrast, in antisera produced by immunizing with formaldehyde-treated ricinus agglutinin only a small part of the antibodies cross-reacting with ricin can be precipitated by the isolated A and B chains, or bound to immunoabsorbents containing the isolated ricin chains. In immunodiffusion studies with anti-ricinus agglutinin sera, a star-shaped precipitate was formed when isolated A and B chains recombined to form intact ricin. Both anti-ricin and anti-ricinus agglutinin sera neutralized effectively the ability of ricin to inhibit protein synthesis in HeLa cells. Anti-ricin serum also neutralized the inhibitory effect of the isolated A chain on protein synthesis in a cell-free system and the ability of the isolated B chain to induce indirect hemagglutination. In contrast, antiricinus agglutinin serum did not neutralize the biologic activities of the isolated ricin A and B chains. Anti-ricinus agglutinin serum formed a precipitate with the hybrid ricin A chain/abrin B chain, and protected against the toxic effect on HeLa cells of this hybrid, indicating conformational changes of ricin A chain upon binding to the B chain. It is concluded that the anti-ricinus agglutinin serum contains antibodies directed against conformational determinants present on intact ricin, but not present or exposed in the isolated A and B chains. At least part of these conformational determinants appears to be carried by the A chain.     

The preparation of deglycosylated ricin by recombination of glycosidase-treated A- and B-chains: effects of deglycosylation on toxicity and in vivo distribution

Deglycosylation of ricin may be necessary to prevent the entrapment of antibody-ricin conjugates in vivo by cells of the reticuloendothelial system which have receptors that recognise the oligosaccharide side chains on the A- and B-chains of the toxin. Carbohydrate-deficient ricin was therefore prepared by recombining the A-chain, which had been treated with alpha-mannosidase, with the B-chain, which had been treated with endoglycosidase H or alpha-mannosidase or both. By recombining treated and untreated chains, a series of ricin preparations was made having different carbohydrate moieties. The removal of carbohydrate from the B-chain did not affect the ability of the toxin to agglutinate erythrocytes, and alpha-mannosidase treatment of the A-chain did not affect its ability to inactivate ribosomes. The toxicity of ricin to cells in culture was only reduced in those preparations containing B-chain that had been treated with alpha-mannosidase, when a 75% decrease in toxicity was observed. The toxicity of the combined ricin preparation to mice varied from double to half that of native ricin, depending on the chain(s) treated and the enzymes used. Removal of carbohydrate greatly reduced the hepatic clearance of the toxin and the levels of toxin in the blood were correspondingly higher. These results suggest that antibody-ricin conjugates prepared from deglycosylated ricin would be cleared more slowly by the liver, inflict less liver damage, and have greater opportunity to reach their target.     

Whole ricin and recombinant ricin A chain idiotype-specific immunotoxins for therapy of the guinea pig L2C B cell leukemia

The therapeutic efficacy of whole ricin, or recombinant ricin A chain, coupled to a monoclonal antibody that reacts with the idiotype of the surface IgM expressed on guinea pig L2C lymphoblasts, was assessed. In vitro studies were done to characterize the immunotoxins (IT) and to demonstrate their specificity before use in vivo. The concentration of whole ricin IT (M6-Ricin) that inhibited protein synthesis by 50% (IC50) in L2C cells was 1.4 X 10(-9) M, in a 5-hr assay, in the presence of lactose to block non-antibody-directed toxicity. M6-Ricin did not inhibit protein synthesis in two control guinea pig cell lines that did not express the idiotype, nor did a whole ricin IT prepared with an isotype-matched monoclonal antibody of irrelevant specificity inhibit protein synthesis in L2C cells. Two recombinant ricin A chain IT, which differed from one another by a factor of 2 to 3 in the number of A chains conjugated per antibody molecule, were less effective in vitro than M6-Ricin (IC50 of greater than 5 X 10(-8) M). For in vivo experiments, the IT were given by the i.p. route 24 hr after the i.p. inoculation of 1 X 10(5) L2C cells. The highest doses of M6-Ricin and M6-Ricin A chain IT tested, 30 micrograms/kg and 3000 micrograms/kg, respectively, were within fourfold to fivefold of their maximum tolerated doses; no deaths or ill effects due to ricin toxicity were noted. These doses increased the median survival time of L2C-bearing guinea pigs to 31 to 34 days, compared with 15 days for untreated animals. This magnitude of increase in survival indicates that 99.999% (5 logs) of injected tumor cells were eliminated, thus accounting for the 12% long-term survival rate obtained. Median survival times for guinea pigs treated with 30 micrograms/kg of the A chain IT were 18 and 21 days for the two conjugates tested, and the median survival for guinea pigs treated with 3000 micrograms/kg of unconjugated antibody was 18 days. Our data demonstrate that recombinant A chain IT are active in vivo and that the B chain of ricin can potentiate IT activity in vivo. Although the potency differs by 100-fold, the therapeutic index of the intact ricin IT is similar to that of the ricin A chain IT.     

Homology between ricin and Ricinus communie agglutinin: Amino terminal sequence analysis and protein synthesis inhibition studies

The existence of three forms of ricin and two forms of the Ricinus communis agglutinin (RCA) was established using cation exchange chromatography, isoelectric focusing, and polyacrylamide gel electrophoresis. The preparation of the RCA we obtained was 60–75 times more potent than ricin in the agglutination of erythrocytes, but was about 4% as effective as an inhibitor of cell-free protein synthesis. When reduced with 2-mercaptoethanol, the RCA was activated 3000-fold as an inhibitor of cell-free protein synthesis, whereas ricin was activated about 600-fold by the same treatment. A mixture of the RCA A chains was about one-fifth as effective as the ricin A chain in the inhibition of cell-free protein synthesis. The purified polypeptide subunits of the castor bean lectins were subjected to automated Edman degradation. The sequence for 17 of the first 19 residues of the agglutinin A chain was determined. The first seven residues of the ricin A chain were determined and they are identical with those of the RCA A chain. Nineteen turns of Edman degradation on the RCA B chain resulted in the identification of 18 amino acids. The sequence determined for the first 17 residues of the ricin B chain was identical with that of the RCA B chain. It is likely that the identity of the ricin/RCA A and B chain sequences extends further along the polypeptide chains than the sequences we have determined. The similar structural and catalytic potentials of the RCA and ricin suggest that they bear a precursor-product relationship.     

Blocked and non-blocked ricin immunotoxins against the CD4 antigen exhibit higher cytotoxic potency than a ricin A chain immunotoxin potentiated with ricin B chain or with a ricin B chain immunotoxin

Summary An immunotoxin consisting of ricin A chain linked to the monoclonal antibody M-T151, recognising the CD4 antigen, was weakly toxic to the human T-lymphoblastoid cell line CEM in tissue culture. The incorporation of [³H]leucine by CEM cells was inhibited by 50% at an M-T151-ricin-A-chain concentration (IC₅₀) of 4.6 nM compared with an IC₅₀ of 1.0 pM for ricin. In contrast, immunotoxins made by linking intact ricin to M-T151 in such a way that the galactose-binding sites of the B chain subunit were either blocked sterically by the antibody component or were left unblocked, were both powerfully cytotoxic with IC₅₀ values of 20–30 pM. The addition of ricin B chain to CEM cells treated with M-T151—ricin-A-chain enhanced cytotoxicity by only eight-fold indicating that isolated B chain potentiated the action of the A chain less effectively than it did as an integral component of an intact ricin immunotoxin. Ricin B chain linked to goat anti-(mouse immunoglobulin) also potentiated weakly.Lactose completely inhibited the ability of isolated ricin B chain to potentiate the cytotoxicity of M-T151—ricin-A-chain and partially (3- to 4-fold) inhibited the cytotoxicity of the blocked and non-blocked ricin immunotoxins. Thus, in this system, the galactose-binding sites of the B chain contributed to cell killing regardless of whether isolated B chain was associated with the A chain immunotoxin or was present in blocked or non-blocked form as part of an intact ricin immunotoxin. The findings suggest that the blocked ricin immunotoxin may become unblocked after binding to the target antigen to re-expose the cryptic galactose-binding sites. However, the unblocking cannot be complete because the maximal inhibition of [³H]leucine incorporation by the blocked immunotoxin was only 80% compared with greater than 99% inhibition by the non-blocked immunotoxin.     

Specific killing of lymphocytes that cause experimental autoimmune myasthenia gravis by ricin toxin-acetylcholine receptor conjugates

Experimental autoimmune myasthenia gravis (EAMG) is an autoimmune disease in which antibodies to acetylcholine receptor (AChR) cause loss of AChR from muscle, thereby impairing neuromuscular transmission. Here we report the use of a hybrid molecule that contains ricin toxin, irreversibly coupled to AChR to specifically suppress the immune response to AChR in vitro. Lymph node cell cultures from rats with EAMG pretreated with ricin toxin-AChR conjugates exhibited suppressed T helper cell proliferation and B cell antibody synthesis in response to the subsequent addition of AChR. Nonspecific toxicity of the conjugates was measured by suppression of the T cell proliferative response to the mitogen concanavalin A and the antigen keyhole limpet hemocyanin (KLH), and B cell antibody production to KLH. We have evaluated different pretreatment conditions and ricin toxin covalently coupled to AChR in different molar ratios to optimize specific immunosuppression. By varying the number of ricin molecules covalently bound to AChR in the immunotoxin, we were able to minimize the nonspecific toxicity while still maintaining specific killing of AChR-reactive lymphocytes. Furthermore, B cells were more susceptible to specific killing than were the T cells. The specific immunosuppression was potentiated by performing the pretreatment with immunotoxin in the presence of chloroquine. Chloroquine raises lysosomal pH and probably delays the degradation of immunotoxin in the cell. It should be noted that ricin toxin was covalently coupled to AChR by using a novel, non-reducible reaction. These in vitro results suggest that it may be feasible to use immunotoxin molecules to specifically suppress this autoimmune response in vivo.     

Immunological characteristics associated with the protective efficacy of antibodies to ricin

A/B toxins, produced by bacteria and plants, are among the deadliest molecules known. The B chain binds the cell, whereas the A chain exerts the toxic effect. Both anti-A chain and anti-B chain Abs can neutralize toxins in vivo and in vitro. B chain Abs block binding of the toxin to the cell. It is not known how anti-A chain Abs function. Working with ricin toxin, we demonstrate that immunization with A chain induces greater protection than immunization with B chain. A panel of mAbs, binding to A chain, B chain, or both chains, has been produced and characterized. Immunologic characteristics evaluated include isotype, relative avidity, and epitope specificity. The ability to inhibit ricin enzymatic or cell binding activity was studied, as was the ability to block ricin-mediated cellular cytotoxicity on human and murine cell lines. Finally, the in vivo protective efficacy of the Abs in mice was studied. The Ab providing the greatest in vivo protective efficacy was directed against the A chain. It had the greatest relative avidity and the greatest ability to block enzymatic function and neutralize cytotoxicity. Interestingly, we also obtained an anti-A chain Ab that bound with high avidity, blocked enzymatic activity, did not neutralize cytotoxicity, and actually enhanced the in vivo toxicity of ricin. Anti-A chain Abs with moderate avidity had no in vivo effect, nor did any anti-B chain Abs.     

Milk inhibits the biological activity of ricin

Ricin is a highly toxic protein produced by the castor plant Ricinus communis. The toxin is relatively easy to isolate and can be used as a biological weapon. There is great interest in identifying effective inhibitors for ricin. In this study, we demonstrated by three independent assays that a component of reconstituted powdered milk has a high binding affinity to ricin. We discovered that milk can competitively bind to and reduce the amount of toxin available to asialofetuin type II, which is used as a model to study the binding of ricin to galactose cell-surface receptors. Milk also removes ricin bound to the microtiter plate. In parallel experiments, we demonstrated by activity assay and by immuno-PCR that milk can bind competitively to 1 ng/ml ricin, reducing the amount of toxin uptake by the cells, and thus inhibit the biological activity of ricin. The inhibitory effect of milk on ricin activity in Vero cells was at the same level as by anti-ricin antibodies. We also found that (a) milk did not inhibit ricin at concentrations of 10 or 100 ng/ml; (b) autoclaving 10 and 100 ng/ml ricin in DMEM at 121 °C for 30 min completely abolished activity; and (c) milk did not affect the activity of another ribosome inactivating protein, Shiga toxin type 2 (Stx2), produced by pathogenic Escherichia coli O157:H7. Unlike ricin, which is internalized into the cells via a galactose-binding site, Stx2 is internalized through the cell surface receptor glycolipid globotriasylceramides Gb3 and Gb4. These observations suggest that ricin toxicity may possibly be reduced at room temperature by a widely consumed natural liquid food.     

Mannose receptor-mediated uptake of ricin toxin and ricin A chain by macrophages. Multiple intracellular pathways for a chain translocation

The role of the high mannose carbohydrate chains in the mechanism of action of ricin toxin was investigated. Ricin is taken up by two routes in macrophages, by binding to cell surface mannose receptors, or by binding of the ricin galactose receptor to cell surface glycoproteins. Removal of carbohydrate from ricin by periodate oxidation led to a large loss in toxicity via both routes of uptake by an effect on the B chain not due to a loss of galactose binding affinity. These data suggest that the carbohydrate chains of ricin B chain may be required for full toxicity. The pathway of uptake of ricin by the macrophage mannose receptor was found to differ in several respects from uptake via the galactose-specific pathway. Analysis of intoxication of macrophages by ricin in the presence of ammonium chloride suggested that mannose receptor bound ligand passes through acidic vesicles prior to translocation, unlike galactose bound ligand. Intoxication by ricin via galactose-specific uptake was potentiated by swainsonine but not by castanospermine, suggesting that ricin may be attacked by an endogenous mannosidase within the cell, and that ricin passes through either a lysosomal or a Golgi compartment prior to translocation.     

Cell surface and intracellular functions for ricin galactose binding.

The role of the two galactose binding sites of ricin B chain in ricin toxicity was evaluated by studying a series of ricin point mutants. Wild-type (WT) ricin and three ricin B chain point mutants having mutations in either 1) the first galactose binding domain (site 1 mutant, Met in place of Lys-40 and Gly in place of Asn-46), 2) the second galactose binding domain (site 2 mutant, Gly in place of Asn-255), or 3) both galactose binding domains (double site mutant containing all three amino acid replacements formerly stated) were expressed in Xenopus oocytes and then reassociated with recombinant ricin A chain. The different ricin B chains were mannosylated to the same extent. Cytotoxicity of these toxins was evaluated when cell entry was mediated either by galactose-containing receptors or through an alternate receptor, the mannose receptor of macrophages. WT ricin and each of the single domain mutants was able to kill Vero cells following uptake by galactose containing receptors. Lactose blocked the toxicity of each of these ricins. Site 1 and 2 mutants were 20-40 times less potent than WT ricin, and the double site mutant had no detectable cytotoxicity. WT ricin, the site 1 mutant, and the site 2 mutant also inhibited protein synthesis of mannose receptor-containing cells. Ricin can enter these cells through either a cell-surface galactose-containing receptor or through the mannose receptor. By including lactose in the cell medium, galactose-containing receptor-mediated uptake is blocked and cytotoxicity occurs solely via the mannose receptor. WT ricin, site 1, and site 2 mutants were cytotoxic to macrophages in the presence of lactose with the relative potency, WT greater than site 2 mutant greater than site 1 mutant. The double site mutant lacked cytotoxicity either in the absence or presence of lactose. Thus, even for mannose receptor-mediated toxicity of ricin, at least one galactose binding site remains necessary for cytotoxicity and two galactose binding sites further increases potency. These results are consistent with the model that the ricin B chain galactose binding activity plays a role not only in cell surface binding but also intracellularly for ricin cytotoxicity.     

Killing of cultured hepatocytes by conjugates of asialofetuin and EGF linked to the A chains of ricin or diphtheria toxin

A disulfide-linked conjugate between asialofetuin (ASF) and the toxic A chain (RTA) of ricin is as potent a toxin for cultured rat hepatocytes as our previously described conjugate between ASF and fragment A of diphtheria toxin (DTA). An RTA conjugate of epidermal growth factor (EGF) was a potent toxin for 3T3 cells. In contrast, EGF-DTA was essentially nontoxic for 3T3 cells. We have now examined the toxicity of EGF-RTA and EGF-DTA on cultured hepatocytes. The EGF-DTA conjugate, nontoxic to 3T3 cells, is also a potent toxin for hepatocytes. We also observed a decrease with time of culture in the sensitivity of hepatocytes to the ASF and EGF conjugates. This decrease is not a result of a decrease in EGF or asialoglycoprotein receptors.     

Toxic ligand conjugates as tools in the study of receptor-ligand interactions

We have constructed hybrid proteins in which the toxic A chains of ricin or diptheria toxin have been linked to either asialofetuin, fetuin, or epidermal growth factor (EGF). Both ASF-RTA and ASF-DTA are potent toxins on cultured rat hepatocytes, cells that display the asialoglycoprotein receptor. Toxicity of these two compounds is restricted to hepatocytes and can be blocked by asialoglycoproteins but not the native glycoproteins or asialoagalactoglycoprotein derivatives, indicating that the toxicity of the conjugates is mediated by the hepatic asialoglycoprotein receptor. The EGF-RTA conjugate is an extremely potent toxin on cells that can bind the hormone, but is only poorly effective on cells that are unable to bind EGF. The EGF-DTA conjugate, in contrast, is unable to kill 3T3 cells and is at least two orders of magnitude less effective than EGF-RTA on A431 cells, a cell line with 1-2 X 10(6) EGF receptors per cell. However, when EGF-RTA and EGF-DTA were tested on primary liver hepatocyte cultures, which were susceptible to both ASF-RTA and ASF-DTA, both EGF conjugates were potent toxins. Sensitivity of the hepatocyte cultures to ricin toxicity increases slightly during a 52-hr culture period. In contrast, sensitivity to EGF-RTA and ASF-RTA decline dramatically during this period. Receptors for both ligands remain plentiful on the cell surface during this time.     

Dislocation of ricin toxin A chains in human cells utilizes selective cellular factors

Ricin is a potent A-B toxin that is transported from the cell surface to the cytosol, where it inactivates ribosomes, leading to cell death. Ricin enters cells via endocytosis, where only a minute number of ricin molecules reach the endoplasmic reticulum (ER) lumen. Subsequently, the ricin A chain traverses the ER bilayer by a process referred to as dislocation or retrograde translocation to gain access to the cytosol. To study the molecular processes of ricin A chain dislocation, we have established, for the first time, a human cell system in which enzymatically attenuated ricin toxin A chains (RTA(E177D) and RTA(Δ177-181)) are expressed in the cell and directed to the ER. Using this human cell-based system, we found that ricin A chains underwent a rapid dislocation event that was quite distinct from the dislocation of a canonical ER soluble misfolded protein, null Hong Kong variant of α(1)-antitrypsin. Remarkably, ricin A chain dislocation occurred via a membrane-integrated intermediate and utilized the ER protein SEL1L for transport across the ER bilayer to inhibit protein synthesis. The data support a model in which ricin A chain dislocation occurs via a novel strategy of utilizing the hydrophobic nature of the ER membrane and selective ER components to gain access to the cytosol.     

Cholera toxin B-subunit protects mammalian cells from ricin and abrin toxicity

The glycoproteins ricin and abrin intoxicate cells by inhibiting protein synthesis. Pretreatment of HeLa cells with cholera toxin partially protects them from ricin and abrin activity. The involvement in this phenomenon of the various effects of cholera toxin, namely, redistribution of membrane receptors elicited from protomer B and increasing cyclic AMP concentrations induced by protomer A, were studied. Substances able to enhance cyclic AMP concentrations do not affect ricin and abrin activity, while protomer B alone protects cells. In addition, the effects of several lectins on ricin or abrin toxicity were examined. Almost complete prevention of ricin or abrin activity was obtained using concanavalin A (Con A) and wheat germ agglutinin (WGA). Conversely, neither succinyl Con A nor Ulex europeus agglutinin (UEA) affected the cellular response. Both protomer B of cholera toxin and Con A did not alter the binding of ricin or abrin; they seem to protect cells by altering membrane structure.     

Fate and action of ricin in rat liver in vivo: translocation of endocytosed ricin into cytosol and induction of intrinsic apoptosis by ricin B‐chain

Cytotoxicity of many plant and bacterial toxins requires their endocytosis and retrograde transport from endosomes to the endoplasmic reticulum. Using cell fractionation and immunoblotting procedures, we have assessed the fate and action of the plant toxin ricin in rat liver in vivo, focusing on endosome‐associated events and induction of apoptosis. Injected ricin rapidly accumulated in endosomes as an intact A/B heterodimer (5–90 min) and was later (15–90 min) partially translocated to cytosol as A‐ and B‐chains. Unlike cholera and diphtheria toxins, which also undergo endocytosis in liver, neither in cell‐free endosomes loaded by ricin in vivo nor upon incubation with endosomal lysates did ricin undergo degradation in vitro. A time‐dependent translocation of ricin across the endosomal membrane occurred in cell‐free endosomes. Endosome‐located thioredoxin reductase‐1 was required for translocation as shown by its physical association with ricin chains and effects of its removal and inhibition. Ricin induced in vivo intrinsic apoptosis as judged by increased cytochrome c content, activation of caspase‐9 and caspase‐3, and enrichment of DNA fragments in cytosol. Furthermore, reduced ricin and ricin B‐chain caused cytochrome c release from mitochondria in vivo and in vitro, suggesting that the interaction of ricin B‐chain with mitochondria is involved in ricin‐induced apoptosis.