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Immunological Characteristics Associated with the Protective Efficacy of Antibodies to Ricin¹

Massimo Maddaloni^*, Corrie Cooke^*, Royce Wilkinson^*, Audrey V. Stout^*, Leta Eng and Seth H. Pincus^2,*,

^* Department of Microbiology and Animal Resources Center, Montana State University, Bozeman, MT 59717; and Research Institute for Children, Children’s Hospital, Louisiana State University Health Sciences Center, New Orleans, LA 70118

	Abstract

Top Abstract Introduction Materials and Methods Results Discussion References

 
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.

	Introduction

Top Abstract Introduction Materials and Methods Results Discussion References

 
Antibodies, induced by immunization or administered passively, have been used to protect against the effects of biological toxins for over a century, since the pioneering work of von Behring and Kitasato (1). The studies of Pappenheimer et al. (2) showed that one mechanism by which Abs can protect is by blocking the entry of toxins into cells. This view is frequently presented in textbooks (3, 4, 5, 6), which ignores an important body of evidence demonstrating that Abs to the toxic A chain of A-B toxins have equal or greater neutralizing activity than anti-B chain Abs, which block toxin adherence (7, 8, 9, 10, 11, 12, 13).

Ricin toxin, derived from the castor bean Ricinus communis, is a prototypic A-B toxin in which the B chain binds to the target cell, and the A chain mediates the toxic activity. Ricin B chain (RBC)³ is a lectin that binds to galactose residues found at the cell surface (e.g., on glycoproteins), whereas the A chain functions enzymatically as an RNA N-glycosidase that depurinates adenine 4324 in the 28S rRNA of the 60S ribosomal subunit (14, 15, 16, 17). Ricin toxin is highly lethal, with an LD₅₀ of <2 µg/kg. Its use as a bioterrorist weapon is of considerable concern. However, ricin has also been used as a therapeutic agent, in the form of immunotoxins where the B chain is replaced by a specific targeting moiety (18, 19). In both cases, the immunogenicity of ricin is a matter of great interest; either active or passive immunity may protect against a bioterrorist exposure, whereas the development of anti-ricin Abs is a major limitation for ricin-based immunotoxins.

In this manuscript we have studied the anti-ricin Ab response and correlated immunologic characteristics of Abs to their protective efficacy, both in vitro and in vivo. The data demonstrate that anti-A chain Abs have the greatest protective efficacy. Although Ab avidity is a major correlate of protection, there exist high avidity Abs that fail to protect in vitro and enhance toxicity in vivo. The mechanism(s) by which anti-A chain Abs protect against ricin intoxication are not fully understood.

	Materials and Methods

Top Abstract Introduction Materials and Methods Results Discussion References

 
Abs and reagents

Ricin holotoxin was obtained from Inland Laboratories (Austin, TX), and purified A and B chains were purchased from Sigma-Aldrich (St. Louis, MO). The IC₅₀, as measured on SP2/0 cells, is 0.01 ng/ml for the holotoxin, 150 ng/ml for the A chain, and 2 ng/ml for the B chain. Alkaline phosphatase- and FITC-conjugated secondary Abs were obtained from Zymed Laboratories (South San Francisco, CA). Guinea pig anti-ricin A chain (RAC) Ab was prepared by immunization of guinea pigs with purified RAC in CFA and boosting in IFA. Protein G agarose was obtained from Sigma-Aldrich.

Immunization with ricin and production of mAbs

BALB/c mice were immunized with 10 µg of either purified RAC or RBC in CFA s.c. Four weeks later they were boosted with 10 µg of the same Ag i.p. in IFA. When mice were to be used to make mAbs, they received an i.v. injection of 10 µg of the same Ag in saline 3 days before death. For the production of mAbs to the holotoxin, mice were immunized and boosted with RAC, they then received two booster immunizations of 10 µg of ricin holotoxin in IFA, 1 mo apart, and an i.v. boost of the holotoxin 3 days before death. mAbs were produced as described previously (20, 21, 22). Splenocytes (5 x 10⁷) and SP2/0 cells (10⁷) were fused with polyethylene glycol, selected in hypoxanthine/aminopterin/thymine medium, and cloned by limiting dilution. Hybridomas secreting anti-ricin mAbs were identified by ELISA using the appropriate Ag. In one fusion, intact ricin toxin (2 ng/ml) was added to select for Abs with ricin-neutralizing activity (23).

ELISA

Abs to RAC, RBC, or holotoxin were detected by ELISA (20, 21, 22). Microtiter wells (Immulon II, Dynatech, Chantilly, VA) were coated with 100 µl of Ag (0.5–3.0 µg/ml) in PBS overnight and then blocked for at least 2 h with 200 µl of Blotto (10% skim milk/0.01% Tween 20; Sigma-Aldrich) in PBS. Because RBC is a lectin, and Ab is a glycoprotein, we have compared the use of Blotto, which contains 0.15 M lactose, to the use of PBS/1% BSA with or without 0.125 M lactose for its ability to block nonspecific lectin binding of Ab by RBC. The data (not shown) demonstrate that Blotto and 0.125 M lactose are equivalent at blocking the binding of irrelevant Abs by RBC and have little effect on the binding by A or B chain Abs to the holotoxin. Therefore, Blotto was used in all ELISA experiments. Test Ab, diluted in Blotto, was added to the coated wells in a volume of 100 µl and incubated overnight at 4°C. The wells were washed six times in PBS containing 0.01% Tween 20 and alkaline phosphatase goat anti-mouse IgG, H+L chain, or IgG isotype-specific Ab was added and incubated for 4 h at room temperature. The plates were again washed, and the colorimetric substrate p-nitrophenyl phosphate (Sigma-Aldrich) was added at a concentration of 0.5 mg/ml in 10% diethanolamine buffer, pH 9.8. Absorbance at 405 nm was read 20–60 min later. In performing Ab competition ELISA, the ability of unconjugated mAbs to compete with an alkaline phosphatase-conjugated mAb for binding to Ag was measured. Anti-ricin mAbs were conjugated to calf intestine alkaline phosphatase (Sigma-Aldrich) by glutaraldehyde cross-linking (21). The unconjugated mAb was added to Ag-coated wells, followed 0.5 h later by the conjugated mAb. After overnight incubation the plates were washed, and substrate was added.

Epitope mapping

Peptide display phage libraries were selected for binding to mAbs as previously described (24, 25). Three different libraries were used: J404 (26, 27), which displays a linear nonamer and has a complexity of 4 x 10⁸; PhD-C7C (New England Biolabs, Beverly MA), displaying a cysteine-constrained, seven-amino acid loop and having a complexity of 2 x 10⁹ phage; and PhD-12 (New England Biolabs) displaying a 12-amino acid linear peptide with a complexity of 2 x 10⁹ phage. Ab was immobilized on cyanogen bromide-activated Sepharose (Sigma-Aldrich) at a concentration of 1 mg/ml beads. Phage (10¹²) were incubated with the Ab-coated beads and the unbound phage were washed away with TBS. Phage were eluted with 0.2 M glycine-HCl, pH 2.5, and reamplified to a titer of 10¹² and reapplied to fresh Ab-coated beads. Three or four successive rounds of amplification, adherence, and elution resulted in the identification of phage that bound uniquely to the selecting Abs and not to irrelevant controls. Binding was confirmed by both plaque lift immunoblots and ELISA (24, 25). Phage were sequenced by automated methods using M13 primers (Davis Sequencing, Davis, CA). Epitopes were mapped onto the three-dimensional structure of ricin using Insight II (Accelrys, San Diego, CA), and the figure was drawn using PyMOL version 0.82 (www.pymol.org).

Inhibition of ricin enzymatic and cell-binding activity

The ability of Abs to inhibit ricin’s enzymatic activity was measured in a cell-free in vitro translation assay using rabbit reticulocyte lysates (Ambion, Austin, TX) as both the source of mRNA and ribosomes. Ab and ricin A chain were mixed, added to the lysate in the presence of [³⁵S]methionine, and incubated for 2 h at 37°C. Protein was precipitated with trichloroacetic acid, and the amount of label incorporated was determined by liquid scintillation counting. The ability of Abs to block the binding of ricin to cells was measured by indirect immunofluorescence and flow cytometry. Anti-B chain Abs were mixed with ricin holotoxin and incubated for 30 min at 24°C, then the mixture was incubated with H9 lymphoma cells for 60 min at 4°C. The cells were washed three times with 1% BSA/PBS/0.01% sodium azide, followed by incubation with guinea pig anti-RAC Abs for 60 min at 4°C. Again the cells were washed and then incubated with FITC-conjugated rabbit anti-guinea pig IgG. The FITC-conjugated Ab had previously been tested for cross-reaction with mouse IgG or for binding to cells in the absence of ricin holotoxin and was found to be negative for both. After a final wash, the cells were analyzed by flow cytometry (FACScan; BD Biosciences, San Jose, CA). Results are reported as the mean fluorescence of 5000 cells.

Neutralization of ricin-mediated cytotoxicity

The ability of Ab to protect against the cytotoxic effect of ricin was measured using an MTT dye reduction assay. Two forms of neutralization were tested. In the first, Ab and ricin holotoxin were mixed and then added to target cells (2 x 10³) in 96-well, flat-bottom plates. In the second, ricin was mixed with hybridoma cell lines secreting anti-ricin Abs, and the survival of the hybridoma cells was measured. Three days later, a mixture of MTS-tetrazolium salt (Promega, Madison, WI) and phenazine methosulfate (Sigma-Aldrich) was added to final concentrations of 0.4 and 0.01 mg/ml, respectively. The cells were incubated for 2.5 h at 37°C, and the absorbance was read at 490 nm.

In vivo protective effects

We used a newly described surrogate assay to measure the ability of Ab to protect mice from the toxic effects of ricin (28). In this assay, hypoglycemia, rather than lethality, was measured. Ricin-immune mice were injected with ricin holotoxin i.p. Passive immunity produced by mAbs was measured by premixing ricin and mAb, then injecting mice with the mixture. Outbred CD-1 mice were injected with ricin or ricin/Ab, and blood sugar was measured at various times thereafter via saphenous venipuncture and a hand-held glucometer. Mice were euthanized when blood sugar levels were 25 mg/dl or the animals became highly lethargic. For statistical purposes, blood sugar levels of euthanized animals were assumed to be 25 mg/dl (the lower limit of detection). All experiments were approved by the institutional animal care and use committee of Montana State University.

	Results

Top Abstract Introduction Materials and Methods Results Discussion References

 
Protection against challenge after immunization with RAC or RBC

To determine whether immunization with RAC could elicit the same degree of protection as immunization with RBC, mice were immunized with either the purified A chain or the purified B chain. After a prime and then a booster immunization, animals were bled, Ab levels were determined, and ricin challenge was performed (Fig. 1). Ab to the intact toxin was measured and was somewhat higher in RAC-immune animals (ELISA results on the left). Mice were then challenged with 200 µg/kg of ricin. Animals were sacrificed when blood sugar reached 25 or when they became comatose. Immunization with RAC resulted in complete protection against this challenge as well as challenges at 600 and 2000 µg/kg. Only partial protection was seen in B chain-immune mice at 200 µg/kg, and no protection was observed in control animals. These results clearly demonstrate that Ab to RAC is highly protective.

View larger version (28K): [in this window] [in a new window]   FIGURE 1. Protection against ricin challenge by mice immunized with either RAC or RBC. Mice were immunized with RAC, RBC, or saline (10 µg of A or B chain sc in CFA, followed 1 mo later by 10 µg i.p. in IFA; challenge was performed 1 mo later). ELISA results are on the left; the response to challenge is on the right. ELISA was performed with a 1/5000 dilution of serum. Results are the mean and SEM of triplicate samples. The challenge dose in micrograms per kilogram is indicated above the arrow. Crosses indicate euthanized mice. No control mice or B chain-immune mice survived the initial challenge, whereas all A chain-immune animals survived three successive challenges with 200, 600, and 2000 µg/kg. This is one of two different experiments yielding essentially the same observations.

To further explore the neutralizing and protective capabilities of Abs to ricin, we have produced a panel of mAbs that bind determinants on the A chain, B chain, or compound determinants present on both A and B chains. Mice were immunized with purified A chain, purified B chain, or purified A chain, followed by ricin holotoxin. Primary immunization with either holotoxin or a mixture of purified A and B chains was lethal in immunogenic doses; the latter group in our study was protected against the lethal effects by the pre-existing anti-A chain Abs. Hybridoma cells were either selected on the basis of binding to ricin or in fusion 2 for their ability to survive in ricin (2 ng/ml). The latter method can be used to select for Abs with neutralizing activity (23). We have identified 20 mAbs specific for RAC, 16 RBC mAbs, and two that recognize compound determinants present on the holotoxin (HoloMab and HAB mAb, depending upon whether individual chains or only the holotoxin are bound). Ig subclass, ELISA binding results of supernatant, and Western blot reactivity of relevant Abs are shown in Table I.

mAbs were purified by protein G affinity chromatography. The relative avidity of binding was determined by ELISA (Fig. 2). Serial dilutions of Ab were incubated in microtiter wells coated with ricin holotoxin. The wells were washed and incubated with alkaline phosphatase-conjugated anti-mouse IgG (H+L) and then with substrate. Binding is reported as A₄₀₅. There was a considerable range of binding activity demonstrated among the Abs. Among the anti-A chain Abs, RAC mAb 18 and RAC mAb 23 demonstrated the greatest relative avidity for intact ricin, whereas RBC mAb 10 and RBC mAb 11 did so for the anti-B chain mAbs. Surprisingly, all the mAbs selected in the presence of ricin toxin (fusion 2) had low avidity.

View larger version (12K): [in this window] [in a new window]   FIGURE 2. Relative avidity of anti-ricin Abs. Anti-ricin mAbs were purified on protein G. Purified Abs were titrated in ELISA for binding to intact ricin holotoxin (50 ng/well). Abs with the highest binding at the lowest concentrations have the greatest relative avidity for ricin. Similar titration curves were performed two to five times for each Ab; the data are representative of those experiments.

View larger version (17K): [in this window] [in a new window]   FIGURE 3. Cross-inhibition among RAC mAbs. Microtiter plates were coated with 50 ng/well of ricin holotoxin. Unconjugated RAC mAbs (5 µg/ml), indicated on the horizontal axis, were added to the coated microtiter wells and incubated for 60 min, the alkaline phosphatase-conjugated Ab indicated at the top of the graph was added, and the mixture was incubated for 4 h. The plates were washed, and colorimetric substrate was added. Abs were tested in up to four different experiments, of which this is representative.

View larger version (55K): [in this window] [in a new window]   FIGURE 4. Epitope mapping of RAC mAbs. Epitopes defined by mapping using peptide display phage libraries were plotted onto the three-dimensional structure of ricin. A, Yellow indicates RAC mAb 17 (AA66–69 HAEL), green RAC mAb 18 (Q173, A178), red enzyme active site (E177, R180, N209), and white residue present in the active site and bound by RAC mAb 18 (W211). B, The two potential sites for RAC mAb 23 binding: green, G213, T217, and S222; and yellow, S156, G159, and T160. The molecule has been rotated on all three axes from A to B to allow best visualization of the epitopes.

Abs that bind to RAC or to the holotoxin were tested for their ability to inhibit ricin enzymatic activity, which was measured as the inhibition of protein synthesis ([³⁵S]Met incorporation) in a cell-free system using rabbit reticulocyte lysates. RAC mAbs 14, 18, and 23 gave the best inhibition of ricin activity, with HAB mAb 1, which binds both chains, giving none (Fig. 5A). Flow cytometry was used to measure the ability of RBC mAbs to block ricin’s binding to cells. RBC mAb and the holotoxin were incubated together and then mixed with H9 tissue culture lymphoma cells. Binding of ricin to the cells was detected using a guinea pig anti-RAC polyclonal and FITC-conjugated anti-guinea pig antiserum. The ability of RAC-mAbs to interfere with binding could not be measured using this assay, because they might compete with the guinea pig serum for binding to RAC. However, studies with FITC-conjugated ricin have shown that RAC mAb 18, the highest avidity RAC mAb, does not inhibit the binding of ricin to cells (not shown). The results demonstrate that all Abs, except RBC mAbs 7 and 16, were able to efficiently block binding of ricin to cells. RBC mAb 7 had no blocking activity, whereas 16 had marginal activity (Fig. 5B).

View larger version (15K): [in this window] [in a new window]   FIGURE 5. Inhibition of ricin enzymatic and binding activities by Abs. A fixed concentration of ricin holotoxin was mixed with varying concentrations of Ab. A, The ability of Abs to block ricin’s inhibition of cell-free protein synthesis was measured. B, Flow cytometry was used to measure binding of ricin to cells. The results are reported as the ratio of binding (mean fluorescence) in the presence of Ab/binding in the absence of Ab. Each Ab was tested one to three times in the different assays; these are the data from the most complete experiment of each.

We next asked which mAbs had the best ability to neutralize the cytotoxicity of ricin. Abs were tested in two forms: the protection afforded H9 cells by free mAbs, and the protection of hybridoma cells by the Abs they were secreting. Preliminary studies demonstrated the minimum LD₁₀₀ of ricin on SP2/0 cells was 0.4 ng/ml; we tested the ability of free Abs to block cytotoxicity at a ricin concentration of 2 ng/ml. The viability of the cells was measured using the MTT dye reduction assay. Results are shown in Fig. 6. Of the RAC mAbs resulting from fusion 1, the best neutralizing activity was seen with Ab 18, followed by 17. Interestingly, Abs 14 and 23 had no effect, even though both were excellent at blocking ricin enzymatic activity, and RAC mAb 23 had high avidity for ricin toxin. RAC mAb 14 bound to ricin with low avidity (Fig. 3), which probably accounts for its failure to neutralize cytotoxicity. RAC mAb 16 also has weak avidity, enzymatic blocking activity, and neutralization. Cell lines from fusion 2 were selected in the presence of ricin and had only weak neutralizing activity. Anti-RBC mAbs (fusion 3) were all less effective than RAC-mAb 18. RBC mAb 7 was ineffective, which corresponds to its inability to block the binding of ricin to cells and its low avidity. RBC mAb 16 was able to neutralize as well as any of the RBC mAbs despite its weak ability to block binding. We have performed experiments in which we mixed Abs to either the same chain or both A and B chains and tested for neutralization. We saw additive, but not synergistic, effects (data not shown). We next tested the ability of hybridomas secreting Abs that bind the A chain to survive in the presence of ricin (Fig. 7). It has previously been shown that intracellular neutralization of ricin occurs in hybridomas (23, 33). The mAbs selected in the presence of ricin (Holo mAb 1, RAC mAb 24, and HAB mAb 1) gave the highest degrees of protection. Of the remaining Abs, only RAC mAb 18 provided any protection. Thus, there appear to be marked differences in the ability of Ab to neutralize ricin in the extracellular milieu and within the cell secreting the Ab.

View larger version (12K): [in this window] [in a new window]   FIGURE 6. Ab-mediated inhibition of ricin cytotoxicity. H9 cells were incubated with ricin (2 ng/ml) and the indicated Ab. Three days later cell viability was assayed by MTT dye reduction. Viability was also measured in the absence of ricin and in the presence of ricin without Ab. Some Abs were tested in protection assays up to 15 times, but at least twice. The data are representative of these experiments.

View larger version (18K): [in this window] [in a new window]   FIGURE 7. Protection of hybridoma cells from ricin-mediated toxicity by secreted Ab. Hybridoma cell lines secreting the indicated Ab (or the nonsecretor parental fusion partner SP2/0) were incubated in the presence of various concentrations of ricin for 3 days, and viability was tested by MTT dye reduction. Cell lines were tested two or three times, and representative data are shown.

Using our in vivo model of ricin intoxication (28), we have studied the protective efficacy of anti-ricin mAbs in mice. In the first experiment we tested a panel of RAC mAbs. Mice were injected with a mixture of 30 µg/kg of ricin and 0.8 mg/kg of Ab, and their blood sugar levels were determined 18 h later. The dose of Ab was chosen on the basis of prior dosing experiments (not shown); lower doses of Ab did not produce statistically significant differences between treated and control groups. If mice were moribund, they were killed, and their blood sugar value was set at 25 mg/dl for statistical purposes. Fig. 8 shows the mean and SEM of blood sugar determinations and mortality. RAC mAb 18 showed significantly (p < 0.001, by Student’s t test) higher blood sugar levels, i.e., protection, compared with the irrelevant Ab. No other Ab protected. RAC mAb 23 had significantly greater mortality (p = 0.004, by ² test), thus appearing to potentiate the toxicity of ricin. We repeated the Ab protection studies, but this time using a lower dose of ricin (15 µg/kg) and the same dose of Ab (0.8 mg/kg). Blood sugar was measured at 18 and 34 h, and mortality was assessed at 34 h (Fig. 9). At 18 h, compared with the irrelevant Ab, RAC mAb 18 provided significant protection (p = 0.0018), and RAC mAb 23 provided significant enhancement (p = 0.0006) of ricin toxicity. At 34 h, protection by RAC mAb 18 was more pronounced; enhancement of toxicity by RAC mAb 23 could not be assessed by blood sugar because of the low values found in control groups. In the next experiment we further tested the ability of RAC mAb 23 to enhance the toxicity of ricin. Mice were injected with 30 µg/kg of ricin mixed with either 0.8 or 1.6 mg/kg of RAC mAb 23, saline, or 1.6 mg/kg of an irrelevant isotype-matched Ab. Blood sugar was measured 13 h later (when all mice were still alive), and the number of surviving mice was determined at 18 h. Fig. 10 shows a dose-related enhancement of toxicity by RAC mAb 23. At both doses of RAC mAb 23, there was a statistically significant depression of blood sugar (p = 0.03 for the low dose, p = 0.0009 for the high dose) and enhanced mortality (p = 0.0192 for the low dose, p = 0.004 for the high dose) compared with irrelevant Ab. Although there was a lower blood sugar and greater mortality in the high dose group compared with the low dose group, the differences were not significant. We have determined that endotoxin contamination of RAC mAb 23 does not account for the enhancement of toxicity. Measuring the amount of endotoxin using Limulus lysate (Sigma-Aldrich) showed there were trace amounts of endotoxin in many Ab preparations that could not be removed by absorption on polymyxin B. We deliberately added LPS to RAC mAbs to equalize the amount and found that this had no influence on the in vivo effect (data not shown). Further, nonspecific lectin binding of RAC mAb 23 is similar to that of the neutralizing Ab RAC mAb 18. Anti-B chain mAbs had no protective efficacy (data not shown).

View larger version (13K): [in this window] [in a new window]   FIGURE 8. In vivo effect of RAC mAbs on ricin toxicity. Mice were injected with 30 µg/kg of ricin holotoxin and 0.8 mg/kg of the indicated Ab. Blood sugar was determined 18 h later. Mice were sacrificed if they became moribund or if their blood sugar level fell below 25 mg/dl. Mean blood sugar levels (±SEM) and survival are shown.

View larger version (13K): [in this window] [in a new window]   FIGURE 9. In vivo effects of Abs to ricin A chain. Mice were injected with 15 µg/kg of ricin and 0.8 mg/kg of Ab. Blood sugar was determined 18 and 34 h later. Mean (±SEM) blood sugar levels and survival are shown.

View larger version (16K): [in this window] [in a new window]   FIGURE 10. Potentiation of ricin toxicity by RAC mAb 23. Mice were injected with 30 µg/kg of ricin and the indicated dose of RAC mAb 23 or 1.6 mg/kg of an irrelevant isotype-matched Ab. Blood sugar was determined 13 h later, and survival was determined at 18 h.

	Discussion

Top Abstract Introduction Materials and Methods Results Discussion References

We have used a newly defined in vivo assay to measure the ability of Ab to protect against ricin toxicity (28). This assay was developed in response to concerns expressed by an institutional animal care and use committee regarding conventional, lethal challenge assay. To identify a surrogate end point, we periodically performed blood chemistry analyses after parenteral administration of a lethal dose of ricin toxin. Much to our surprise, the only metabolic abnormality detected was a profound drop in blood sugar, which is likely to be the cause of death. Blood sugars may be easily, inexpensively, and repetitively monitored on small volumes of blood (25–50 µl), and we have found this assay to be a useful replacement for the lethal challenge.

Ab may neutralize biological toxins in multiple ways. It may prevent the toxin from reaching the target cell. Binding of the toxin to the target cell may be blocked by Ab. The intracellular processing of the toxin necessary for it to reach its site of action may be altered, or the intracellular degradation of the toxin may be enhanced. Ab may block the enzymatic activity that results in the toxic effect. In an intact animal, Ab may enhance the clearance of the toxin from the circulation by Fc-mediated mechanisms. For an optimal antitoxin response, as many of these processes should be harnessed as possible.

In 1890, von Behring and Kitasato (1) first showed that the mechanism of serum-mediated (i.e., Ab) protection from the lethal effects of diphtheria and tetanus was due to toxin neutralization. That finding has served as the basis for immunization of generations of individuals against these two diseases. However, it was not until the elegant studies by Pappenheimer (34) described the structure/function relationships within the diphtheria toxin that it was possible to begin to understand the mechanism by which Ab neutralized the activity of the toxin. In a classic paper (2), he demonstrated that Abs to the cell-binding domain were able to neutralize diphtheria toxin, whereas Abs to the toxic domain were not. This finding was extended when it was shown that Abs to the A chain could protect cells if they were injected intracellularly, but not if they were present in the medium surrounding the cells (35). These studies provided a simple and understandable mechanism to explain Ab neutralization: Ab would attach to the cell-binding domain of a toxin and prevent the toxin from binding to the target cell. This explanation was so attractive that it is often presented in texts as the sole mechanism of Ab-mediated protection (3, 4, 5, 6).

Despite this textbook explanation of the mechanism of Ab-mediated neutralization of toxins in which only anti-B chain Abs are effective, immunologists in the field have long known that the story is more complex. In fact, it was Pappenheimer who with coworkers demonstrated in 1974 (7) that Abs to either chain could neutralize toxins other than diphtheria (7). Using hybrid toxins consisting of RAC and the B chain of abrin, and vice versa, it was shown that anti-ricin or anti-abrin Abs, which would not cross-protect against the other holotoxin, provided both in vivo and in vitro protection against both hybrid toxins. Further, absorptions showed that A or B chain-specific antisera could provide protection against the appropriate holotoxin or hybrid toxin. In the discussion, the difference between these results and those with diphtheria toxin were commented upon. It was argued that perhaps the reason that anti-A chain Abs were ineffective in protecting against diphtheria toxin is that critical antigenic determinants were blocked from access to the Ab. In the years since, a number of investigators have used both polyclonal and mAbs and have clearly demonstrated the in vitro neutralizing and in vivo protective effects of Abs to the A chain of multiple different toxins, including diphtheria (8, 9, 10, 11, 12, 13). Although it has been amply demonstrated that anti-A chain Abs can protect cells in vitro or animals in vivo, the mechanism(s) of this effect is not fully understood.

The role of Ab affinity in protection against toxins is well studied. In the evaluation of Ab responses to toxoid vaccines, the correlation between the affinity of Ab and serum neutralization is established (36, 37). More recently, a particularly elegant and thorough study using recombinant Abs to the protective Ag of anthrax toxin and surface plasmon resonance firmly demonstrated that the ability of Ab to protect macrophages from cytotoxic effect and rats from lethality was directly correlated with Ab affinity (38). No matter what the mechanism(s) by which Ab protects against intoxications, it is not difficult to understand why high affinity Abs function better. Our results are generally consistent with this observation.

	Acknowledgments

 
We thank Jon Jacobs for assistance with the modeling of the ricin epitopes, and Tim Pierce for editorial assistance.

	Footnotes

 
¹ This work was supported by Grant DAAG55-98-1-0245 from the U.S. Army Research Office and Grant AI059376 from the U.S. Public Health Service.

² Address correspondence and reprint requests to Dr. Seth Pincus, Research Institute for Children, 200 Henry Clay Avenue, New Orleans, LA 70118. E-mail address: spincus{at}chnola-research.org

³ Abbreviations used in this paper: RBC, ricin B chain; RAC, ricin A chain.

Received for publication December 15, 2003. Accepted for publication March 8, 2004.

	References

Top Abstract Introduction Materials and Methods Results Discussion References

 

1. von Behring, E., and S. Kitasato. 1890. On the mechanism of immunity in animals to diphtheria and tetanus. Deutsche Med. Wochenschr. [Translated and reprinted in Milestones in Microbiology. T. D. Brock, ed. and translator. ASM Press, 1999] 16:1113.
2. Pappenheimer, A. M., T. Uchida, A. A. Harper. 1972. An immunological study of the diphtheria toxin molecule. Immunochemistry 9:891.[Medline]
3. Janeway, C. A., P. Travers, M. Walport, M. Shlomchik. 2001. Immunobiology. The Immune System in Health and Disease 5th Ed.365. Garland, New York.
4. Parham, P.. 2000. The Immune System 1st Ed.175. Garland, New York.
5. Tizard, I. R.. 1995. Immunology: An Introduction 4th Ed.380. Harcourt Brace, Philadelphia.
6. Goldsby, R. A., T. J. Kindt, B. A. Osborne. 2000. Kuby: Immunology 4th Ed.436. W. H. Freeman, New York.
7. Olsnes, S., A. M. Pappenheimer, R. Meren. 1974. Lectins from Abrus precatorius and Ricinus communis. II. Hybrid toxins and their interactions with chain-specific antibodies. J. Immunol. 113:842.[Abstract/Free Full Text]
8. Foxwell, B. M., S. I. Detre, T. A. Donovan, P. E. Thorpe. 1985. The use of anti-ricin antibodies to protect mice intoxicated with ricin. Toxicology 34:79.[Medline]
9. Zucker, D. R., J. R. Murphy. 1984. Monoclonal antibody analysis of diphtheria toxin. I. Localization of epitopes and neutralization of cytotoxicity. Mol. Immunol. 21:785.[Medline]
10. Lemley, P. V., D. C. Wright. 1992. Mice are actively immunized after passive monoclonal antibody prophylaxis and ricin toxin challenge. Immunology 76:511.[Medline]
11. Lemley, P. V., P. Amanatides, D. C. Wright. 1994. Identification and characterization of a monoclonal antibody that neutralizes ricin toxicity in vitro and in vivo. Hybridoma 13:417.[Medline]
12. Barbieri, J. T., D. Armellini, J. Molkentin, R. Rappuoli. 1992. Construction of a diphtheria toxin A fragment-C180 peptide fusion protein which elicits a neutralizing antibody response against diphtheria toxin and pertussis toxin. Infect. Immun. 60:5071.[Abstract/Free Full Text]
13. Matsuda, M., M. Kamei, N. Sugimoto, Y. Ma, S. Hashizume. 1992. Characteristics of toxin-neutralization by anti-tetanus human monoclonal antibodies directed against the three functional domains [A], [B] and [C] of the tetanus toxin molecule and a reliable method for evaluating the protective effects of monoclonal antibodies. Eur. J. Epidemiol. 8:1.
14. Pastan, I., V. Chaudhary, D. J. FitzGerald. 1992. Recombinant toxins as novel therapeutic agents. Annu. Rev. Biochem. 61:331.[Medline]
15. Robertus, J.. 1991. The structure and action of ricin, a cytotoxic N-glycosidase. Semin. Cell Biol. 1991:23.
16. Vitetta, E. S., P. E. Thorpe. 1991. Immunotoxins containing ricin or its A chain. Semin. Cell. Biol. 2:47.[Medline]
17. Melton-Celsa, A., A. D. O’Brien. 2003. Plant and bacterial toxins as RNA N-glycosidases. D. L. Burns, and J. T. Barbieri, and B. H. Iglewski, and R. Rappuoli, eds. Bacterial Protein Toxins 245. Am. Soc. Microbiol., Washington, DC.
18. Vitetta, E. S., P. E. Thorpe, J. W. Uhr. 1993. Immunotoxins: magic bullets or misguided missiles?. Immunol. Today. 14:252.[Medline]
19. Pincus, S. H.. 1994. Immunotoxins. M. Rosenberg, and G. Moore, eds. In Pharmacology of Monoclonal Antibodies Vol. 113:149. Springer-Verlag, Berlin.
20. Pincus, S. H., A. O. Shigeoka, A. A. Moe, L. P. Ewing, H. R. Hill. 1988. Protective efficacy of IgM monoclonal antibodies in experimental group B streptococcal infection is a function of antibody avidity. J. Immunol. 140:2779.[Abstract]
21. Pincus, S. H., C. J. Stocks, Jr, L. P. Ewing. 1982. Monoclonal anti-(T,G)-A-L antibodies: characterization of fine specificity and idiotype expression. Mol. Immunol. 19:1551.[Medline]
22. Pincus, S. H., W. R. Watson, L. R. Ewing, C. J. Stocks, S. B. Harris, D. R. Rollins. 1984. Monoclonal anti-digoxin antibodies: genotypic and phenotypic characterization. Life Sci. 35:433.[Medline]
23. Furukawa-Stoffer, T. L., D. C. W. Mah, J. W. Cherwonogrodzky, R. J. Weselake. 1999. A novel biological-based assay for the screening of neutralizing antibodies to ricin. Hybridoma 18:505.[Medline]
24. Pincus, S. H., M. J. Smith, J. B. Burritt, P. M. Glee. 1998. Peptides that mimic the protective antigen of group B streptococcal type III capsular polysaccharide. J. Immunol. 160:293.[Abstract/Free Full Text]
25. Glee, P. E., S. H. Pincus, M. J. Smith, D. K. McNamer, J. B. Burritt, J. E. Cutler. 1999. Peptide ligands that bind IgM antibodies and block interaction with antigen. J. Immunol. 163:826.[Abstract/Free Full Text]
26. Burritt, J. B., M. T. Quinn, M. A. Jutila, C. W. Bond, A. J. Jesaitis. 1995. Topological mapping of neutrophil cytochrome B epitopes with phage-display libraries. J. Biol. Chem. 270:16974.[Abstract/Free Full Text]
27. Burritt, J. B., C. W. Bond, K. W. Doss, A. J. Jesaitis. 1996. Filamentous phage display of oligopeptide libraries. Anal. Biochem. 338:1.
28. Pincus, S. H., L. Eng, C. L. Cooke, M. Maddaloni. 2002. Identification of hypoglycemia in mice as a surrogate marker of ricin toxicosis. Comp. Med. 52:530.[Medline]
29. Smith, G. P., J. K. Scott. 1992. Peptide-display phage libaries. Methods Enzymol. 217:228.
30. Montfort, W., J. E. Villafranca, A. F. Monzingo, S. Ernst, B. Katzin, E. Rutenber, N. H. Xuong, R. Hamlin, J. D. Robertus. 1987. The three-dimensional structure of ricin at 2.8A. J. Biol. Chem. 262:5398.[Abstract/Free Full Text]
31. Katzin, B. J., E. J. Collins, J. D. Robertus. 1991. Structure of ricin A-chain at 2.5 A. Proteins 10:251.[Medline]
32. Gould, J. H., M. R. Hartley, P. C. Welsh, D. K. Hoshizaki, A. Frankel, L. M. Roberts, J. M. Lord. 1991. Alteration of an amino acid residue outside the active site of the ricin A chain reduces its toxicity towards yeast ribosomes. Mol. Gen. Genet. 230:81.[Medline]
33. Youle, R. J., M. Colombatti. 1987. Hybridoma cells containing intracellular anti-ricin antibodies show ricin meets secretory antibody before entering the cytosol. J. Biol. Chem. 262:4676.[Abstract/Free Full Text]
34. Pappenheimer, A. M.. Diphtheria: studies on the biology of an infectious disease. Harvey Lect. 76:1980–198145.
35. Yamaizumi, M., T. Uchida, Y. Okada, M. Furusawa. 1978. Neutralization of diphtheria toxin in living cells by microinjection of antifragment A contained within resealed erythrocyte ghosts. Cell 13:227.[Medline]
36. Hagenaars, A. M., R. W. van Delft, J. Nagel. 1984. Comparison of ELISA and toxin neutralization for the determination of tetanus antibodies. J. Immunoassay 5:1.[Medline]
37. Dokmetjian, J., C. Della Valle, V. Lavigne, C. M. de Lujan, M. A. Manghi. 2000. A possible explanation for the discrepancy between ELISA and neutralising antibodies to tetanus toxin. Vaccine 18:2698.[Medline]
38. Maynard, J., C. B. M. Maassen, S. H. Leppla, K. Brasky, J. L. Patterson, B. L. Iverson, G. Georgiou. 2002. Protection against anthrax toxin by recombinant antibody fragments correlates with antigen affinity. Nat. Biotechnol. 20:597.[Medline]

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