【 摘 要 】

Background

Presently, few data exist on the level and duration of anti-protective antigen (PA) IgG in vaccinated livestock. Various adaptation of enzyme-linked immunosorbent assays (ELISAs) have been developed in studies to assess immune response following vaccination, albeit mostly in laboratory rodent models. The quantitative anti-anthrax IgG ELISA in this study describes a method of enumerating the concentration of anti-PA specific IgG present in sera of immunized goats, with the aid of an affinity-purified caprine polyclonal anti-anthrax PA-83 IgG standard. This was compared with the anthrax toxin neutralization assay (TNA) which measures a functional subset of toxin neutralizing anti-PA IgG.

Results

The measured concentrations obtained in the standard curve correlated with the known concentration at each dilution. Percentage recovery of the standard concentrations ranged from 89 to 98% (lower and upper asymptote respectively). Mean correlation coefficient (r²) of the standard curve was 0.998. Evaluation of the intra-assay coefficient of variation showed ranges of 0.23-16.90% and 0.40-12.46% for days 28 and 140 sera samples respectively, following vaccination. The mean inter-assay coefficient of variation for triplicate samples repeated on 5 different days was 18.53 and 12.17% for days 28 and 140 sera samples respectively. Spearman’s rank correlation of log-transformed IgG concentrations and TNA titres showed strong positive correlation (r_s = 0.942; p = 0.01).

Conclusion

This study provides evidence that an indirect ELISA can be used for the quantification of anti-anthrax PA IgG in goats with the added advantage of using single dilutions to save time and resources. The use of such related immunoassays can serve as potential adjuncts to potency tests for Sterne and other vaccine types under development in ruminant species. This is the first report on the correlation of polyclonal anti-anthrax PA83 antibody with the TNA in goats.

【 授权许可】

   
2013 Ndumnego et al.; licensee BioMed Central Ltd.

【 预 览 】

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【 图 表 】

【 参考文献 】

• [1]Hambleton P, Carman JA, Melling J: Anthrax: the disease in relation to vaccines. Vaccine 1984, 2:125-132.
• [2]Koya V, Moayeri M, Leppla SH, Daniell H: Plant-based vaccine: mice immunized with chloroplast-derived anthrax protective antigen survive anthrax lethal toxin challenge. Infect Immun 2005, 73:8266-8274.
• [3]Wright G, Green TW, Kanode JR: Studies on immunity in anthrax. V. Immunizing activity of alum-precipitated protective antigen. J Immunol 1954, 73:387-391.
• [4]Ascenzi P, Visca P, Ippolito G, Spallarossa A, Bolognesi M, Montecucco C: Anthrax toxin: a tripartite lethal combination. FEBS Lett 2002, 531:384-388.
• [5]Collier RJ, Young JAT: Anthrax toxin. Annu Rev Cell Dev Biol 2003, 19:45-70.
• [6]Ezzell JW, Abshire TG, Panchal R, Chabot D, Bavari S, Leffel EK, Purcell B, Friedlander AM, Ribot WJ: Association of Bacillus anthracis capsule with lethal toxin during experimental infection. Infect Immun 2009, 77(2):749-755.
• [7]Jang J, Cho M, Chun JH, Cho MH, Park J, Oh HB, Yoo CK, Rhie G: The poly-γ-d-glutamic acid capsule of Bacillus anthracis enhances lethal toxin activity. Infect Immun 2011, 79:3846-3854.
• [8]Sterne M: The effects of different carbon dioxide concentrations on the growth of virulent anthrax strains. pathogenicity and immunity tests on guinea-pigs and sheep with anthrax variants derived from virulent strains. Onderstepoort J Vet 1937, 9:49-67.
• [9]Mikesell P, Ivins BE, Ristroph JD, Dreier TM: Evidence for plasmid-mediated toxin production in Bacillus anthracis. Infect Immun 1983, 39:371-376.
• [10]Personeus G, Cooper MS, Percival RC: Studies on an anthrax vaccine prepared from nonencapsulated variants of Bacillus anthracis. Am J Vet Res 1956, 17:153-156.
• [11]Ivins BE, Ezzell JW, Jemski J, Hedlund KW, Ristroph JD, Leppla SH: Immunization studies with attenuated strains of Bacillus anthracis. Infect Immun 1986, 52:454-458.
• [12]Sterne M: The use of anthrax vaccines prepared from avirulent (uncapsulated) variants of Bacillus anthracis. Onderstepoort J Vet Sci Anim Indust 1939, 13:307-312.
• [13]Lincoln RE, Walker JS, Klein F: Value of field data for extrapolation in anthrax. Technical manuscript 346. Maryland: Department of the Army, USA; 1967.
• [14]Turnbull PC, Doganay M, Lindeque PM, Aygen B, McLaughlin J: Serology and anthrax in humans, livestock and Etosha National Park wildlife. Epidemiol Infect 1992, 108:299-313.
• [15]Belton FC, Strange RE: Studies on a protective antigen produced in vitro from Bacillus anthracis: medium and methods of production. Br J Exp Pathol 1954, 35:144-152.
• [16]Puziss M, Wright GG: Studies on immunity in anthrax IV: Factors influencing elaboration of the protective antigen of Bacillus anthracis in chemically defined media. J Bacteriol 1954, 68:474-482.
• [17]Turnbull PC, Broster MG, Carman JA, Manchee RJ, Melling J: Development of antibodies to protective antigen and lethal factor components of anthrax toxin in humans and guinea pigs and their relevance to protective immunity. Infect Immun 1986, 52:356-363.
• [18]Johnson-Winegar A: Comparison of enzyme-linked immunosorbent and indirect hemagglutination assays for determining anthrax antibodies. J Clin Microbiol 1984, 20:357-361.
• [19]Hahn UK, Aichler M, Boehm R, Beyer W: Comparison of the immunological memory after DNA vaccination and protein vaccination against anthrax in sheep. Vaccine 2006, 24:4595-4597.
• [20]Shakya KP, Hugh-Jones ME, Elzer PH: Evaluation of immune response to orally administered Sterne strain 34 F2 anthrax vaccine. Vaccine 2007, 25:5374-5377.
• [21]Kelly CD, O’Loughlin C, Gelder FB, Peterson JW, Sower LE, Cirino NM: Rapid generation of an anthrax immunotherapeutic from goats using a novel non-toxic muramyl dipeptide adjuvant. J Immune Based Ther Vaccines 2007, 5:11. BioMed Central Full Text
• [22]Reuveny S, White MD, Adar YY, Kafri Y, Altboum Z, Gozes Y, Kobiler D, Shafferman A, Velan B: Search for correlates of protective immunity conferred by anthrax vaccine. Infect Immun 2001, 69:2888-2893.
• [23]Pitt ML, Little SF, Ivins BE, Fellows P, Barth J, Hewetson J, Gibbs P, Dertzbaugh M, Friedlander AM: In vitro correlate of immunity in a rabbit model of inhalational anthrax. Vaccine 2001, 19:4768-4773.
• [24]Parreiras PM, Sirota LA, Wagner LD, Menzies SL, Arciniega JL: Comparability of ELISA and toxin neutralization to measure immunogenicity of Protective Antigen in mice, as part of a potency test for anthrax vaccines. Vaccine 2009, 27:4537-4542.
• [25]Hering D, Thompson W, Hewetson J, Little S, Norris S, Pace-Templeton J: Validation of the anthrax lethal toxin neutralization assay. Biologicals 2004, 32:17-27.
• [26]Zmuda JF, Zhang L, Richards T, Pham Q, Zukauskas D, Pierre JL, Laird MW, Askins J, Choi GH: Development of an edema factor-mediated cAMP-induction bioassay for detecting antibody-mediated neutralization of anthrax protective antigen. J Immunol Methods 2005, 298:47-60.
• [27]Omland KS, Brys A, Lansky D, Clement K, Lynn F, and the Participating Laboratories: Interlaboratory comparison of results of an anthrax lethal toxin neutralization assay for assessment of functional antibodies in multiple species. Clin Vaccine Immunol 2008, 15:946-953.
• [28]DeSilva B, Smith W, Weiner R, Kelley M, Smolec JM, Lee B, Khan M, Tacey R, Hill H, Celniker A: Recommendations for the bioanalytical method validation of ligand-binding assays to support pharmacokinetic assessments of macromolecules. Pharm Res 2003, 20:1885-1900.
• [29]Koehler S, Huwar T, Baillie L, Beyer W: Vaccination of NMRI mice against Bacillus anthracis using DNA and protein based acellular vaccine candidates and novel adjuvants. In International conference on Bacillus anthracis, B. cereus and B. thuringiensis (Poster session). Bruges; 2011:102.
• [30]Little S, Webster W, Norris S, Andrews G: Evaluation of an anti-rPA IgG ELISA for measuring the antibody response in mice. Biologicals 2004, 32:62-69.
• [31]Miura K, Orcutt AC, Muratova OV, Miller LH, Saul A, Long CA: Development and characterization of a standardized ELISA including a reference serum on each plate to detect antibodies induced by experimental malaria vaccines. Vaccine 2008, 26:193-200.
• [32]Gu M, Hine PM, James Jackson W, Giri L, Nabors GS: Increased potency of BioThrax anthrax vaccine with the addition of the C-class CpG oligonucleotide adjuvant CPG 10109. Vaccine 2007, 25:526-534.
• [33]Leppla SH, Robbins JB, Schneerson R, Shiloach J: Development of an improved vaccine for anthrax. J Clin Invest 2002, 110:141-144.
• [34]Welkos S, Vietri N, Gibbs P: Non-toxigenic derivatives of the Ames strain of Bacillus anthracis are fully virulent for mice: role of plasmid pXO2 and chromosome in strain-dependent virulence. Microb Pathog 1993, 14:381-388.
• [35]Cybulski RJ Jr, Sanz P, O’Brien AD: Anthrax vaccination strategies. Mol Aspects Med 2009, 30:490.
• [36]Welkos S, Little S, Friedlander A, Fritz D, Fellows P: The role of antibodies to Bacillus anthracis and anthrax toxin components in inhibiting the early stages of infection by anthrax spores. Microbiol 2001, 147:1677-1685.
• [37]Baillie LW, Rodriguez AL, Moore S, Atkins HS, Feng C, Nataro JP, Pasetti MF: Towards a human oral vaccine for anthrax: the utility of a Salmonella Typhi Ty21a-based prime boost immunization strategy. Vaccine 2008, 26:6083-6091.
• [38]Findlay JWA, Dillard RF: Appropriate calibration curve fitting in ligand binding assays. AAPS J 2007, 9:260-267.
• [39]Karnes HT, March C: Calibration and validation of linearity in chromatographic biopharmaceutical analysis. J Pharm Biomed Anal 1991, 9:911-918.
• [40]Smith WC, Sittampalam GS: Conceptual and statistical issues in the validation of analytic dilution assays for pharmaceutical applications. J Biopharm Stat 1998, 8:509-532.
• [41]Plikaytis BD, Turner S, Gheesling L, Carlone G: Comparisons of standard curve-fitting methods to quantitate Neisseria meningitidis group A polysaccharide antibody levels by enzyme-linked immunosorbent assay. J Clin Microbiol 1991, 29:1439-1446.
• [42]Vogt RV, Phillips DL, Omar Henderson L, Whitfield W, Spierto FW: Quantitative differences among various proteins as blocking agents for ELISA microtiter Plates. J Immunol Methods 1987, 101:43-50.
• [43]Weiss S, Kobiler D, Levy H, Marcus H, Pass A, Rothschild N, Altboum Z: Immunological correlates for protection against intranasal challenge of Bacillus anthracis spores conferred by a protective antigen-based vaccine in rabbits. Infect Immun 2006, 74:394-398.
• [44]Little SF, Ivins BE, Fellows PF, Pitt MLM, Norris SLW, Andrews GP: Defining a serological correlate of protection in rabbits for a recombinant anthrax vaccine. Vaccine 2004, 3-4:422-430.
• [45]Peachman KK, Rao M, Alving CR, Burge R, Leppla SH, Rao VB, Matyas GR: Correlation between lethal toxin-neutralizing antibody titers and protection from intranasal challenge with Bacillus anthracis Ames strain spores in mice after transcutaneous immunization with recombinant anthrax protective antigen. Infect Immun 2006, 74:794-797.
• [46]Turnbull PC, Tindall BW, Coetzee JD, Conradie CM, Bull RL, Lindeque PM, Huebschle OJ: Vaccine-induced protection against anthrax in cheetah (Acinonyx jubatus) and black rhinoceros (Diceros bicornis). Vaccine 2004, 22:3340-3347.
• [47]O’Connell M, Belanger B, Haaland P: Calibration and assay development using the four-parameter logistic model. Chemometrics Intellig Lab Syst 1993, 20:97-114.