POTENTIATION OF TNF-α TOXICITY BY CONJUGATION WITH RICIN A-CHAIN

Hybrid toxins containing a cytokine moiety have been used effectively to selectively kill cells expressing the complementary cytokine receptor both in vivo and in vitro. To date all cytokines incorporated into hybrid toxins, e.g. interleukin 2 are biologically active as monomers, so attachment of a toxin group causes minimal interference with the cytokine structure. By contrast, the pro-inflammatory and anti-cancer cytokine tumour necrosis factor α (TNF-α) is biologically active as a homotrimer in which the grooves created between the hydrophobically associated monomers form the receptor binding region, so maintenance of this structure is crucial for activity. In this report the authors show that TNF-α can be modified by reaction with a crosslinking agent and by subsequent attachment of the toxin ricin A-chain without loss of TNF-α cytotoxic activity in the WEHI assay. Structural association of the hybrid toxin composed of TNF-α and ricin A-chain was confirmed by Western blot analysis. The hybrid toxin was toxic to HeLa cells (IC₅₀=4 pM) not sensitive to native TNF-α, and sensitive WEHI cells with substantially increased lethality (LD₅₀=0.01 fM). This increased TNF-α cytotoxic activity suggests that hybrid toxins containing TNF-α may have therapeutic applications in the treatment of cancer.     

Ribosome-mediated folding of partially unfolded ricin A-chain

After endocytic uptake by mammalian cells, the cytotoxic protein ricin is transported to the endoplasmic reticulum, whereupon the A-chain must cross the lumenal membrane to reach its ribosomal substrates. It is assumed that membrane traversal is preceded by unfolding of ricin A-chain, followed by refolding in the cytosol to generate the native, biologically active toxin. Here we describe biochemical and biophysical analyses of the unfolding of ricin A-chain and its refolding in vitro. We show that native ricin A-chain is surprisingly unstable at pH 7.0, unfolding non-cooperatively above 37 degrees C to generate a partially unfolded state. This species has conformational properties typical of a molten globule, and cannot be refolded to the native state by manipulation of the buffer conditions or by the addition of a stem-loop dodecaribonucleotide or deproteinized Escherichia coli ribosomal RNA, both of which are substrates for ricin A-chain. By contrast, in the presence of salt-washed ribosomes, partially unfolded ricin A-chain regains full catalytic activity. The data suggest that the conformational stability of ricin A-chain is ideally poised for translocation from the endoplasmic reticulum. Within the cytosol, ricin A-chain molecules may then refold in the presence of ribosomes, resulting in ribosome depurination and cell death.     

Ribosome inactivation by the toxic lectins abrin and ricin. Kinetics of the enzymic activity of the toxin A-chains.

A sensitive test system for toxin-treated ribosomes was worked out by treating rabbit reticulocyte ribosomes with abrin A-chain, ricin A-chain or ricinus agglutinin A-chain, adding neutralizing amounts of specific antitoxins and testing for polyphenylalanine-synthesizing activity in a system where the concentration of elongation factors and ribosomes were varied. The strongest inhibition was obtained in the presence of low concentrations of elongation factor (EF-2). The activity of the ribosomes decreased with time of incubation with the toxin A-chains. Addition of anti-toxins stopped further inactivation. In systems containing untreated and toxin-treated ribosomes the ability to polymerize phenylalanine was proportional to the concentration of untreated ribosomes. There was a linear relationship between toxin A-chain concentration and the number of ribosomes inactivated per minute. The inactivation rate increased with temperature, and the estimated activation energy was 10.6 kcal (44.3 kJ). Linewaver-Burk plots of the data obtained by incubating various ribosome concentrations with toxins indicated a molecular activity of about 1500 ribosomes/minute for abrin and ricin A-chains and 100 ribosomes/minute for ricinus agglutinin A-chain. The apparent Michaelis constant was 0.1-0.2 muM for all three A-chains. The activity of the A-chains in the intact cell is discussed.     

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.     

The mechanism of action of ricin and related toxic lectins on eukaryotic ribosomes. The site and the characteristics of the modification in 28 S ribosomal RNA caused by the toxins

Ricin is a potent cytotoxic protein derived from the higher plant Ricinus communis that inactivates eukaryotic ribosomes. In this paper we have studied the mechanism of action of ricin A-chain on rat liver ribosomes in vitro. Our findings indicate that the toxin inactivates the ribosomes by modifying both or either of two nucleoside residues, G4323 and A4324, in 28 S rRNA. These nucleotides are located close to the alpha-sarcin cleavage site and become resistant to all ribonucleases tested. The examination of the lability of phosphodiester bonds of these nucleotides to both mild alkaline digestion and aniline treatment at acidic pH suggests that the base of A4324 is removed by the toxin. This unique activity of ricin A-chain was also observed when naked 28 S rRNA is used as a substrate, indicating that the toxin directly acts on the RNA. Similar activity on 28 S rRNA is also exhibited by abrin and modeccin, ricin-related toxins, suggesting a general mechanistic pathway for ribosome inactivation by lectin toxins.     

Real-time cytotoxicity assay for rapid and sensitive detection of ricin from complex matrices

Background

In the context of a potential bioterrorist attack sensitive and fast detection of functionally active toxins such as ricin from complex matrices is necessary to be able to start timely countermeasures. One of the functional detection methods currently available for ricin is the endpoint cytotoxicity assay, which suffers from a number of technical deficits.

Methodology/Findings

This work describes a novel online cytotoxicity assay for the detection of active ricin and Ricinus communis agglutinin, that is based on a real-time cell electronic sensing system and impedance measurement. Characteristic growth parameters of Vero cells were monitored online and used as standardized viability control. Upon incubation with toxin the cell status and the cytotoxic effect were visualized using a characteristic cell index–time profile. For ricin, tested in concentrations of 0.06 ng/mL or above, a concentration-dependent decrease of cell index correlating with cytotoxicity was recorded between 3.5 h and 60 h. For ricin, sensitive detection was determined after 24 h, with an IC50 of 0.4 ng/mL (for agglutinin, an IC50 of 30 ng/mL was observed). Using functionally blocking antibodies, the specificity for ricin and agglutinin was shown. For detection from complex matrices, ricin was spiked into several food matrices, and an IC50 ranging from 5.6 to 200 ng/mL was observed. Additionally, the assay proved to be useful in detecting active ricin in environmental sample materials, as shown for organic fertilizer containing R. communis material.

Conclusions/Significance

The cell-electrode impedance measurement provides a sensitive online detection method for biologically active cytotoxins such as ricin. As the cell status is monitored online, the assay can be standardized more efficiently than previous approaches based on endpoint measurement. More importantly, the real-time cytotoxicity assay provides a fast and easy tool to detect active ricin in complex sample matrices.     

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.     

Selective cytotoxicity of an antibody-ricin A chain conjugate for human tumor cells

The toxic subunit of a plant ricin has been conjugate by a disulfide bond to a polyclonal rabbit antibody specific for the L-chain of human IgG. Both the antibody and ricin A-chain retained their original biological activity after conjugation. This conjugate proved to be a potent cytotoxin for surface Ig positive Burkitt lymphoma EB-3 cells, growing in vitro and produced 50% inhibition of protein synthesis at level of 1.4 x 10(-9) M. When tested for cytotoxic action on target cells, the composite conjugate molecule was at least 100 times more effective than antibodies alone, ricin A-chain alone or a conjugate ricin A-chain--normal rabbit IgG.     

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.     

A superactive hormonotoxin prepared with truncated diphtheria toxin

A chemically truncated form of diphtheria toxin, DT51, which lacks the cell-binding site but retains the membrane-translocating function, was covalently linked to luteinizing hormone (LH) and compared to similar conjugates containing diphtheria toxin (DT) or diphtheria toxin A-chain (DTA). The DT51 hormonotoxin killed cells possessing an LH receptor at concentrations similar to that of DT hormonotoxin and orders of magnitude lower than DTA hormonotoxin. The DTA hormonotoxin exhibited an LD-50 similar to that of previously reported hormonotoxins which employed DTA, ricin A-chain, or gelonin as toxic moieties.     

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.     

Induction of cytokines by toxins that have an identical RNA N-glycosidase activity: Shiga toxin, ricin, and modeccin

Shiga toxin (Stx) has an A1-B5 subunit structure, and the A subunit is an RNA N-glycosidase that inhibits cellular protein synthesis. We previously reported that in Caco-2 cells Stx induced cytokines and that the RNA N-glycosidase activity was essential for the cytokine induction. It is known that the binding of the Stx-B subunit to its receptor glycolipid, Gb3, mediates an A subunit-independent signal in some types of cells, but the involvement of this signal in the cytokine induction is unclear. In this study, we investigated whether RNA N-glycosidase itself induces cytokines. IL-8 production was enhanced by Stx, ricin, and modeccin, three toxins that inhibit protein synthesis through an identical RNA N-glycosidase activity, but not by two other types of protein synthesis inhibitors, diphtheria toxin and cycloheximide. The RNA N-glycosidase-type toxins showed a similar induction pattern of cytokine mRNAs. Brefeldin A, a Golgi apparatus inhibitor, completely suppressed the cytokine induction by the toxins. Analysis by using inhibitors of toxin binding and also Stx-B subunit showed that the cytokine-inducing activity was independent of Gb3-mediated signaling. These results indicate that RNA N-glycosidase itself induces the cytokine production and that intracellular transport of toxins through the Golgi apparatus is essential for the activity.     

Oligosaccharide side chains on human secretory IgA serve as receptors for ricin

Secretory IgA (sIgA) Abs are polymeric Igs comprised of two or more IgA monomers joined together at their C termini and covalently associated with a 70-kDa glycoprotein called secretory component. As the predominant Ig type in gastrointestinal sections, sIgA Abs are centrally important in adaptive immunity to enteropathogenic bacteria, viruses, and toxins. In this study, we demonstrate that sIgA Abs may also function in innate defense against ricin, a naturally occurring, galactose-specific plant lectin with extremely potent shiga toxin-like enzymatic activity. In lectin blot overlay assays, we found that ricin bound to secretory component and the H chain of human IgA, and this binding was inhibited by the addition of excess galactose. The toxin also recognized IgM (albeit with less affinity than to IgA), but not IgG. Ricin bound to both human IgA1 and IgA2, primarily via N-linked oligosaccharide side chains. At 100-fold molar excess concentration, sIgA (but not IgG) Abs inhibited ricin attachment to the apical surfaces of polarized intestinal epithelial cells grown in culture. sIgA Abs also visibly reduced toxin binding to the luminal surfaces of human duodenum in tissue section overlay assays. We conclude that sIgA Abs in mucosal secretions may serve as receptor analogues for ricin, thereby reducing the effective dose of toxin capable of gaining access to glycolipid and glycoprotein receptors on epithelial cell surfaces.     

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.     

Uptake of native and deglycosylated ricin A-chain immunotoxins by mouse liver parenchymal and non-parenchymal cells in vitro and in vivo

The therapeutic activity of ricin A-chain immunotoxins is undermined by their rapid clearance from the bloodstream of animals by the liver. This uptake has generally been attributed to recognition of the mannose-terminating oligosaccharides present on ricin A-chain by receptors present on the non-parenchymal (Kupffer and sinusoidal) cells of the liver. However, we demonstrate here that, in the mouse, the liver uptake of a ricin A-chain immunotoxin occurs in both parenchymal and non-parenchymal cells in equal amounts. This is in contrast to the situation in the rat, where uptake of the immunotoxin is predominantly by the non-parenchymal cells. Recognition of sugar residues on the A-chain portion of the immunotoxin plays an important role in the liver uptake by both cell types in both species. However it is not the only mechanism since, firstly, an immunotoxin containing ricin A-chain which had been effectively deglycosylated with metaperiodate and cyanoborohydride was still trapped to a significant extent by hepatic non-parenchymal cells after it was injected into mice. Secondly, deglycosylation, while eliminating uptake of the free A-chain by parenchymal and non-parenchymal cells in vitro, only reduced the uptake of an immunotoxin by either cell type by about half. Thirdly, the addition of excess D-mannose or L-fucose inhibited the uptake of free A-chain by mouse liver cell cultures by more than 80% but only inhibited the uptake of the native A-chain immunotoxin by about half and had little effect on the uptake of the deglycosylated ricin A-chain immunotoxin. Recognition of the antibody portion of the immunotoxin by liver cells seems improbable, since antibody alone or an antibody-bovine serum albumin conjugate were not taken up in appreciable amounts by the cultures. Possibly attachment of the A-chain to the antibody exposes sites on the A-chain that are recognised by liver cells in vitro and in vivo.     

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.     

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.     

Studies on the galactose-binding site of ricin and the hybrid toxin man6P-ricin

N-acetylimidazole (NAI) was used to O-acetylate the plant seed toxin ricin. O-acetylation of one to two tyrosine residues per molecule of ricin inhibited ricin binding to Sepharose 4B and decreased toxicity by 90% in a protein synthesis inhibition assay in HeLa cells. Lactose, known to block the binding site on the ricin B subunit, protected ricin from NAI modification of binding or toxicity. Thus NAI, under these conditions, can be a lactose site-specific inhibitor. The lactose site-specific modification of the hybrid toxin, Man6P-ricin, performed under the same conditions, exhibited the same 90% inhibition of Man6P receptor-mediated toxicity as the galactose-containing receptor-mediated toxicity of either Man6P-ricin or ricin. Thus the ricin B chain lactose-binding site appears to be essential for the high potency of Man6P-ricin via the new cell type-specific Man6P receptor. Treatment of fibroblasts with neuraminidase exposes galactose residues, thus increasing the sensitivity to ricin eight fold. The Man6P receptor-mediated toxicity of Man6P-ricin is not affected by this treatment, although the galactose-inhibited route is potentiated eight fold. The Man6P-ricin hybrid appears to require the ricin B chain galactose-binding site to enter the cytosol after initially binding to the Man6P receptor. These data provide some insights into the proper design of hybrid toxins. We discuss a number of possible models for hybrid toxin entry.     

Specific killing of a human breast carcinoma cell line by a monoclonal antibody coupled to the A-chain of ricin

Summary We coupled monoclonal IgM_k antibodies directed against human breast carcinoma cells to the A-chain of the plant toxin ricin. These molecular hybrids maintain both their antibody-binding activity and the toxic activity of the A-chain. Thus, they specifically bind to and kill the breast carcinoma cells in vitro.     

Biologically active A-chain of the plant toxin ricin expressed from a synthetic gene in Escherichia coli

To assess the biological activity and pharmacokinetic properties of nonglycosylated ricin A-chain (RA), we have obtained the polypeptide following expression of a synthetic 842-bp RA gene in Escherichia coli. Expression of the gene was carried out using the phage T5 PN25 promoter fused to the E. coli lac operator. The RA polypeptide was synthesized in a completely soluble form and was purified in one step by immunoabsorption. It was shown to be as cytotoxic for a human cell line as both native RA and chemically deglycosylated native RA. Reconstituted whole ricin and an immunotoxin containing the recombinant RA were also biologically active. Immunotoxins made with recombinant and deglycosylated RA had similar clearance rates in vivo showing, after a short period of rapid elimination, stabilities far higher than that of an immunotoxin made with native RA. Our results show that the complete elimination of sugar side chains from the RA is not sufficient to entirely eradicate the rapid initial in vivo clearance of RA-based biologicals.