John F. Hewetson

Detection of ricin by colorimetric and chemiluminescence ELISA.

A highly sensitive and specific ELISA was developed to detect ricin in biological fluids. The assay utilizes an affinity-purified goat polyclonal antibody to adsorb ricin from solution. The same antibody (biotinylated) is then used to form a sandwich, and avidin-linked alkaline phosphatase allows color development and measurement of optical density at 405 nm. Our routine assay uses a standard curve over the range of 0-10 ng/ml ricin, with accurate quantitation below 1 ng/ml (100 pg/well) in assay buffer as well as in a 1:10 dilution of human urine or 1:50 dilution of human serum spiked with ricin. Ricin measured in spiked samples demonstrated accuracy typically within 5% of the expected value in all matrices. The coefficient of variation ranged from 3-10% at 10 ng/ml to 8-25% at 2.5 ng/ml. Two variations on the routine assay were also investigated. First, lengthened incubation times and additional time for color development allowed accurate quantitation in serum dilutions as low as 1:2. Second, increased concentrations of biotinylated antibody and avidin-linked enzyme from 1:250 to 1:70 enhanced the sensitivity of the assay 10-fold, achieving a detection limit of at least 100 pg/ml (10 pg/well). The assay was also configured to a format based upon chemiluminescence, which allowed quantitation in the 0.1-1 ng/ml range, but was subject to slightly greater variability than the colorimetric assay.

Protection of mice from inhaled ricin by vaccination with ricin or by passive treatment with heterologous antibody

Mice were vaccinated subcutaneously with 25 micrograms kg-1 of ricin in the presence of Freunds complete adjuvant or Ribi adjuvant, followed by a boost 14 days later with 50 micrograms kg-1 ricin in Freunds incomplete adjuvant or Ribi adjuvant, respectively. Three subsequent boosts at 28-day intervals with 25 micrograms kg-1 ricin yielded high anti-ricin antibody titres as determined by ELISA. Vaccinated animals were exposed to an aerosolized LD99 dose of ricin. With the exception of one death not attributable to ricin intoxication, all vaccinated mice survived the lethal aerosol exposure. In addition, a passive protection regimen was evaluated in mice pretreated with 100 micrograms purified goat anti-ricin IgG administered intravenously, and then challenged with ricin intravenously. All were resistant to 125 micrograms kg-1 of ricin, a dose greater than 25 times the intravenous lethal dose. Mice injected intravenously with 5 mg of the same IgG were protected from a lethal aerosol challenge. These results indicated that it is possible to protect animals from inhaled ricin by vaccination or passive administration of specific antibodies.

Monoclonal antibody prophylaxis against the in vivo toxicity of ricin in mice

A BALB/c murine IgG1 monoclonal antibody, designated BG11-G2, specific for ricin was generated. BG11-G2 antibody did not bind to either purified ricin chain A or chain B, but recognized an antigenic determinant whose conformation requires the combination of the two chains in the formation of the native ricin molecule. It did not react with the protein synthesis inhibitor, T-2 mycotoxin, or with the sodium channel blockers, saxitoxin and tetrodotoxin. As little as 0.78 micrograms/ml of BG11-G2 IgG1 anti-ricin monoclonal antibody completely protected against the in vitro toxicity of ricin as determined by [3H]leucine uptake in EL-4 cell assays. Passive intraperitoneal infusion of purified BG11-G2 antibody into BALB/c mice one day prior to a lethal challenge with ricin considerably delayed the onset of toxicity and death. Better protection was obtained with BG11-G2 infused before and after ricin challenge.

An in vivo passive protection assay for the evaluation of immunity in AVA-vaccinated individuals ☆

Samples of human plasma from anthrax vaccine adsorbed (AVA, BioThrax)-vaccinated individuals were used to demonstrate passive protection of A/J mice from a lethal challenge with the Sterne strain of anthrax bacteria. The maximum concentration of human anti-protective antigen IgG in mouse sera 24 h after injection of 260 microg of anti-PA IgG was 134 microg/ml, declining to 91 microg/ml at 72 h (half-life=101.7 h). Mice showed significant survival (p<or=0.001) after injection of serial dilutions up to 1:4 of the standard plasma and challenged with 100 LD50. Similarly, mice injected with the standard anti-AVA plasma and challenged up to 5 days post-treatment also survived (p<or=0.001). Using a cohort of human plasma to measure passive protection, the best correlation between passive protection and an in vitro assay was found to be with the quantitative toxin neutralization assay (minimum fold increase in odds of survival: 2.71, p=0.0062). These results demonstrate a reliable in vivo neutralization method that correlates with standard in vitro measures of neutralizing antibody levels in plasma from individuals vaccinated with the standard anthrax vaccine. This analytical method may provide additional opportunities to compare the efficacy of improved anthrax vaccines with the licensed vaccine.

Anti-idiotype-based vaccines against biological toxins

Biological toxins produced by living organisms represent one of the major sources of contamination of stored grain and agricultural products, and other food sources. The majority of these biological toxins are highly lethal, nonproteinaceous low-molecular-weight chemical compounds which exert their potent toxicity through a variety of mechanisms. Because of their small size, they generally do not induce a significantly high affinity protective antibody response upon toxin exposure, even when conjugated to large protein carriers which enhance their immunogenicity. Moreover, the very toxic nature of biological toxins precludes their use as immunogens in the induction of protective immunity. To circumvent this difficulty, an attempt was made to develop antibody (anti-idiotype)-based vaccines against a protein synthesis inhibitor, the trichothecene mycotoxin T-2, and the sodium channel blockers tetrodotoxin and saxitoxin. Protective monoclonal antitoxin antibodies were first generated and then used to induce specific monoclonal anti-idiotype antibodies. Specific anti-idiotype antibodies were assessed for their ability to induce in vivo protective immunity against toxicity.

RICIN: MECHANISM OF ACTION, DETECTION, AND INTOXICATION

The many uses of ricin for basic research and clinical studies have made it an intensively studied molecule. Although the exact mechanism by which the toxin kills animals is unknown, ricin kills cells by entering the cytosol and inhibiting protein synthesis. In all areas of clinical use, forensic medicine, and basic scientific inquiry, the capability to detect the toxin is of primary importance. Recent efforts to produce a vaccine originate from a perception that this widely available toxic plant protein could be a poor mans weapon of mass destruction.

Protection against ricin intoxication in vivo by anti-idiotype vaccination

A BALB/c murine anti-ricin monoclonal antibody (mAb BG11-G2, IgG1K), was recently isolated and shown to passively protect syngeneic mice against ricin intoxication in vivo. New Zealand White rabbit polyclonal anti-idiotype (anti-Id) antibodies were raised to BG11-G2 anti-ricin mAb, and rendered specific by repeated absorption over agarose normal mouse immunoglobulin (Ig). The absorbed rabbit anti-Id antibodies lost reactivity to normal mouse Ig and to a BALB/c anti-T-2 mycotoxin IgG1K mAb (HD11), but remained reactive with BG11-G2 anti-ricin mAb. The rabbit anti-Id inhibited the binding of BG11-G2 mAb to ricin-coated wells, and elicited a specific and protective anti-ricin antibody response in naive BALB/c mice. Whereas all mice vaccinated with a control rabbit anti-Id antibody preparation died from in vivo ricin challenges, mice immunized with the rabbit anti-Id specific for BG11-G2 mAb were protected to various degrees. All mice vaccinated with rabbit anti-Id to BG11-G2 and challenged with ricin doses of 35 and 50 micrograms kg-1 body weight died from the challenge; however, a delay in the elapsed time between ricin administration and death was observed in these mice as compared to that of the control anti-Id-immune mice. Five of seven mice vaccinated with the rabbit anti-Id to BG11-G2 and subsequently challenged in vivo with a ricin dose of 20 micrograms kg-1 body weight survived the lethal in vivo ricin challenge, whereas all the control mice died.(ABSTRACT TRUNCATED AT 250 WORDS)