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Infection and Immunity, May 2003, p. 2966-2969, Vol. 71, No. 5
0019-9567/03/$08.00+0     DOI: 10.1128/IAI.71.5.2966-2969.2003
Copyright © 2003, American Society for Microbiology. All Rights Reserved.

Immunization with Genetic Toxoids of the Arcanobacterium pyogenes Cholesterol-Dependent Cytolysin, Pyolysin, Protects Mice against Infection

Department of Veterinary Science and Microbiology, The University of Arizona, Tucson, Arizona 85721

Received 21 October 2002/ Returned for modification 18 December 2002/ Accepted 21 January 2003

	ABSTRACT

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Pyolysin (PLO), a cholesterol-dependent cytolysin expressed by Arcanobacterium pyogenes, is an important host-protective antigen. However, this molecule is toxic and requires inactivation prior to its use as a vaccine. Three genetically toxoided, nonhemolytic PLO molecules, HIS-PLO.F₄₉₇, HIS-PLO.P₄₉₉, and HIS-PLO.A₅₂₂, were found to be nontoxic, and vaccinated mice were protected from infection, indicating the potential of these toxoids as vaccines. Furthermore, in a mouse model of infection, A. pyogenes carrying the F₄₉₇ mutation was as attenuated as a PLO-deficient strain, indicating that the cytolytic activity of PLO is important in virulence.

	TEXT

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Arcanobacterium pyogenes, a widely distributed inhabitant of the mucous membranes of domestic animals, is found associated with the respiratory, gastrointestinal, and genital tracts (10, 18, 28, 40), and infection with this organism can occur following a precipitating injury or infection. Economically important diseases caused by this organism include mastitis and abortion in dairy cows (23) and liver abscesses in feedlot cattle (22, 26).

A. pyogenes expresses a cholesterol-dependent cytolysin (CDC), pyolysin (PLO) (6), which is a major virulence factor in infections by this organism. CDCs, expressed by many gram-positive pathogens, exert their effects by binding to cholesterol and forming large, oligomeric pores in eukaryotic-cell membranes (7). The CDCs can affect a wide variety of physiological processes in the host, including complement activation (33), up-regulation of cytokine production (15, 30, 39), and inhibition of the respiratory burst and bactericidal activity of polymorphonuclear leukocytes and monocytes (27, 32), and are directly cytotoxic for polymorphonuclear leukocytes and macrophages (19, 42). PLO is also an important host-protective antigen, as formalin-inactivated, recombinant, His-tagged PLO (HIS-PLO) was efficacious as a vaccine in mice (19). However, the toxicity of PLO limits its usefulness as a vaccine without prior inactivation.

The CDCs possess a characteristic, C-terminal undecapeptide sequence, which has been implicated in the initial interaction of the toxin with the host cell membrane (13, 14, 16). Mutational analysis of the undecapeptide in PLO and other CDCs has identified residues which are critical for cytolytic activity (8, 9, 21, 24, 34). Specifically, we have shown that replacement of tryptophan 497 with phenylalanine or deletion of a proline residue at position 499 significantly reduced the hemolytic and cholesterol binding activities of PLO (8). In addition, other residues, not found within the undecapeptide region, affect the pore-forming ability of CDCs, particularly residues involved in the formation of the transmembrane hairpins (36, 37) and residues located at the C terminus of the protein (31, 38). Knowledge of the residues critical for toxic activity allowed the design of genetic toxoids, i.e., recombinant toxins with mutations affecting activity, for use as immunoprophylactic agents.

Three genetically toxoided HIS-PLO proteins were evaluated for their potential as vaccines. The previously described HIS-PLO.F₄₉₇ and HIS-PLO.P₄₉₉ proteins have mutations in the PLO undecapeptide region which significantly reduce the hemolytic and cholesterol binding activities of these molecules (8). As it was unknown whether antibodies to a native undecapeptide were required to neutralize PLO activity, a mutant HIS-PLO molecule which contained a mutation outside the undecapeptide region was also chosen. This mutant protein, HIS-PLO.A₅₂₂, was selected from a number of mutations identified by error-prone PCR. Briefly, error-prone PCR was performed in the presence of 5 mM MgCl₂, as previously described (12), by using primers 5'-acagcatcctcgagtgccggattgggaaac-3' and 5'-tggaattccctaggatttgacattgt-3', which amplify the A. pyogenes plo gene. PCR products were cloned into the six-His tag vector pTrcHis B (Invitrogen) by using the XhoI and EcoRI restriction sites incorporated into the primers (underlined), and nonhemolytic colonies were identified on Luria-Bertani agar containing 5% ovine blood and 100 µg of ampicillin/ml following electroporation of Escherichia coli DH5. Plasmid DNA was extracted from nonhemolytic colonies (3) and subjected to automated DNA sequencing to identify mutations. One such plasmid, pJGS128, was found to contain two mutations. The first mapped to codon 43 of plo and resulted in no change in the amino acid sequence (CCG to CCA), while a second mutation in codon 522 resulted in a threonine (ACG) to alanine (GCG) change. HIS-PLO.A₅₂₂ was purified by using TALON resin (Clontech) as previously described (8). The hemolytic and cholesterol binding activities of HIS-PLO.A₅₂₂ were then assessed (8). HIS-PLO.A₅₂₂ had significantly reduced hemolytic and cholesterol binding activities compared with HIS-PLO, with 0.8 and 2.6% of wild-type activities, respectively. The ability of HIS-PLO.A₅₂₂ to bind to host cell membranes was also determined as previously described (11). HIS-PLO.A₅₂₂ was able to bind to host cell membranes as well as HIS-PLO did (Fig. 1), despite the significant reduction in cholesterol binding of this mutant (2.6% of wild type). This result is consistent with the suggestion that PLO may bind to other host cell membrane receptors in addition to cholesterol (8).

View larger version (36K): [in this window] [in a new window]   FIG. 1. Membrane binding activity of HIS-PLO proteins. HIS-PLO proteins were diluted to a concentration of 2.5 µg/ml in bovine serum albumin (1 mg/ml), 0.5 ml was added to an equal volume of 10% ovine blood, and the mixture was incubated on ice for 20 min. The cells were subsequently harvested by centrifugation and lysed in sodium dodecyl sulfate-polyacrylamide gel electrophoresis sample buffer. Samples incubated with HIS-PLO (lane 1) or HIS-PLO.A522 (lane 2) were separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, transferred to nitrocellulose, and immunostained with a 1/100 dilution of goat anti-HIS-PLO. The position of the 55-kDa PLO band is indicated by the arrow. Molecular mass markers, in kilodaltons, are indicated on the left.

Groups of five outbred ICR mice were immunized i.p. with 10 µg of HIS-PLO toxoids in Ribi MPL+TDM emulsion (Corixa) on days 0 and 14. The mice were bled from the orbital sinus on day 27, and the serum antibody responses were determined using a PLO hemolysis neutralization assay (6). Formalin-inactivated HIS-PLO gave the best antibody response, followed by HIS-PLO.A₅₂₂ and then HIS-PLO.P₄₉₉ and HIS-PLO.F₄₉₇, which contained mutations in the undecapeptide (Table 1). The differences in antibody responses to the vaccines may be due to the formalin treatment allowing for better exposure of important epitopes, as in the case of formalin-inactivated HIS-PLO, or the presence of a wild-type undecapeptide resulting in the production of more neutralizing antibodies, as for HIS-PLO and HIS-PLO.A₅₂₂. To determine whether these antibody titers were protective, the immunized mice and five unimmunized control mice were challenged i.p. with 4.7 x 10⁸ CFU of A. pyogenes BBR1 (19) 28 days postvaccination. All five unimmunized and challenged mice displayed signs of illness by 24 to 48 h, with large numbers of bacteria recovered from the liver and peritoneal fluid (PF) (Table 1). In contrast, all the mice immunized with HIS-PLO proteins displayed no signs of illness at any time and no bacteria were isolated from the liver and PF at 7 days postchallenge (Table 1). Therefore, immunization with any of these toxoids resulted in complete protection against A. pyogenes in this animal model, indicating that these genetic toxoids may have utility as vaccines.

View larger version (14K): [in this window] [in a new window]   FIG. 2. Maps of the plasmids used to construct A. pyogenes strains JGS350 and JGS351. Plasmid names are shown on the left. BamHI (B), EcoRI (E), HindIII (H), NruI (N), SalI (S), and XhoI (X) sites are shown. Restriction sites shown in parentheses were destroyed during the construction of these plasmids. The shaded area of pJGS135 indicates the six-His tag encoded by pTrcHis B. A bar indicating 0.5 kb is shown on the right.

Southern blotting of A. pyogenes genomic DNA digested with EcoRI-XhoI revealed a 3.6-kb band in BBR1 and 3.1-kb bands in JGS350 and JGS351 when probed with a plo-specific probe (data not shown). The presence of erm(X) in JGS350 and JGS351 was confirmed with an erm(X)-specific probe, while the lack of vector sequences was confirmed by using a pHSS21-specific (vector) probe (data not shown). Furthermore, the plo genes from BBR1, JGS350, and JGS351 were amplified by PCR and the products were digested with BamHI. Incorporation of the F₄₉₇ mutation results in loss of the BamHI site in plo (Fig. 2). The products from BBR1 and JGS350, but not JGS351, were digested by BamHI (data not shown), confirming the allelic replacement of the wild-type plo gene in JGS351 by the integration of the F₄₉₇ mutation and the erm(X) gene as the result of a double crossover event.

The activity of PLO in culture supernatant fluid (CSF) from BBR1, JGS350, or JGS351 was determined by hemolytic assay (8). CSF from JGS351 contained no measurable hemolytic activity (titer, <1). In contrast, the average titers of BBR1 and JGS350 CSF were 32 and 32, respectively, indicating that insertion of the erm(X) cassette had no effect on the expression of PLO in JGS350. Additionally, Western blotting with antiserum against PLO revealed that similar amounts of PLO protein were expressed by the three strains (data not shown).

The relative levels of virulence of BBR1 and JGS351 were assessed in a mouse i.p. challenge model. Groups of eight outbred ICR mice were challenged with 10-fold serial dilutions of A. pyogenes BBR1 or JGS351 as previously described (19), and the mice were monitored over 7 days. The infection rates and bacterial viable counts for strains BBR1 and JGS351 are shown in Table 2. In this model, infection with 3.7 x 10⁹ CFU of BBR1 was uniformly lethal to mice within less than 16 h (Table 2). Challenge with 3.7 x 10⁸ CFU of BBR1 resulted in infection of seven-eighths of the mice within 48 to 72 h, while 10-fold-fewer CFU of BBR1 were unable to establish an infection. In contrast, six-eighths of the mice challenged with 1.8 x 10¹⁰ and only three-eighths of the mice challenged with 1.8 x 10⁹ CFU of JGS351 were infected. All the mice challenged with 1.8 x 10⁸ CFU of JGS351 remained clinically normal, and at necropsy, no bacteria were isolated (Table 2). For JGS351, the 50% infectious dose, as calculated by the Reed-Muench method (41), was 5.6 x 10⁹ CFU, 1.7 log₁₀ higher than for BBR1 (9.9 x 10⁷ CFU) and approximately the same as for a plo knockout strain, PLO-1 (6.5 x 10⁹ CFU [19]).

Genetic toxoids of PLO provide a major advantage over native or recombinant PLO in that they do not require inactivation prior to their use as vaccines. The results obtained in this study indicate that these genetic toxoids may be efficacious veterinary vaccines. Vaccination experiments designed to prevent disease in economically important animals, such as the prevention of liver abscesses in feedlot cattle or mastitis in dairy cows, are an important step in determining the efficacy of PLO-based vaccines for A. pyogenes disease.

	ACKNOWLEDGMENTS

 
This work was supported by NRICGP/USDA award 99-35204-7818.

We thank Dawn M. Bueschel for excellent technical assistance.

	FOOTNOTES

 
* Corresponding author. Mailing address: Department of Veterinary Science and Microbiology, The University of Arizona, 1117 East Lowell St., Tucson, AZ 85721. Phone: (520) 621-2745. Fax: (520) 621-6366. E-mail: jost{at}u.arizona.edu.

Editor: A. D. O'Brien

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