Attenuation and Persistence of and Ability To Induce Protective Immunity to a Staphylococcus aureus aroA Mutant in Mice
http://www.100md.com
感染与免疫杂志 2006年第6期
Departamento de Microbiología, Parasitología e Inmunología, Facultad de Medicina, Universidad de Buenos Aires, C1121ABG Buenos Aires, Argentina
ABSTRACT
Staphylococcus aureus is the most important etiological agent of bovine mastitis, a disease that causes significant economic losses to the dairy industry. Several vaccines to prevent the disease have been tested, with limited success. The aim of this study was to obtain a suitable attenuated aro mutant of S. aureus by transposon mutagenesis and to demonstrate its efficacy as a live vaccine to induce protective immunity in a murine model of intramammary infection. To do this, we transformed S. aureus RN6390 with plasmid pTV1ts carrying Tn917. After screening of 3,493 erythromycin-resistant colonies, one mutant incapable of growing on plates lacking phenylalanine, tryptophan, and tyrosine was isolated and characterized. Molecular characterization of the mutant showed that the affected gene was aroA and that the insertion occurred 756 bp downstream of the aroA start codon. Complementation of the aroA mutant with a plasmid carrying aroA recovered the wild-type phenotype. The mutant exhibited a 50% lethal dose (1 x 106 CFU/mouse) higher than that of the parental strain (4.3 x 104 CFU/mouse). The aroA mutant showed decreased ability to persist in the lungs, spleens, and mammary glands of mice. Intramammary immunization with the aroA mutant stimulated both Th1 and Th2 responses in the mammary gland, as ascertained by reverse transcription-PCR, and induced significant protection from challenge with either the parental wild-type or a heterologous strain isolated from a cow with mastitis.
INTRODUCTION
Bovine mastitis is one of the most important diseases of dairy cows throughout the world. It is also a major cause of economic losses to the dairy industry because it leads to decreased milk production and low-quality milk (17). Staphylococcus aureus is the most prevalent infectious agent that affects the bovine udder. After entering the mammary gland through the teat canal and adapting to the udder environment, S. aureus multiplies rapidly, and an inflammatory reaction ensues, leading to tissue damage (61). Staphylococcal mastitis is extremely difficult to control by treatment alone. However, effective programs of postmilking use of germicidal teat dips, strict milking time hygiene, dry cow therapy, and culling can result in a markedly reduced incidence of S. aureus (14). A number of vaccines to prevent the disease and reduce the severity of intramammary (ima) infection have been described. These vaccines, however, have failed to prevent the development of staphylococcal mastitis (29, 58, 63), thus making other strategies for preventing ima infection indispensable. Although a number of molecules have been suggested as potential useful antigens for single-component vaccines, none of these approaches have been entirely successful so far (8, 36). The use of live attenuated vaccines may be considered an alternative approach. Indeed, these vaccines may have the advantage that they represent a greater pool of antigens, which may induce a broader and perhaps more intense protective immune response against bacterial aggression (5).
Bacterial attenuation can be achieved by different mechanisms. One is to introduce mutations into a key metabolic pathway whose function is essential for bacteria to survive and grow in vivo to cause disease. Several virulent strains have been attenuated by inactivation of genes in the aromatic amino acid biosynthesis pathway. Aromatic-dependent mutants of Salmonella enterica serovar Typhimurium (38), Yersinia pestis (40), Bordetella pertussis (50), Corynebacterium pseudotuberculosis (53), Pseudomonas aeruginosa (44), and Listeria monocytogenes (1) have been shown to be avirulent and to stimulate protective immunity in different hosts. Requirement of p-aminobenzoic acid (PABA), a precursor of folic acid that is not synthesized by mammals, has been singled out as the likely reason for reduced virulence of these bacterial strains (25). Since bacteria are unable to take up exogenous folate and the availability of PABA is limited in vertebrate tissues, the growth of aro mutants in vivo is severely restricted.
In the present study, an aroA mutant of S. aureus was generated by transposon mutagenesis, and experiments were conducted to test its reduced virulence, ability to colonize the mammary gland, and efficacy to induce protective immunity in a murine model of ima infection. The utilization of bacterial auxotrophs in the development of alternative immunoprophylactic approaches to prevent S. aureus infection is supported by this study.
MATERIALS AND METHODS
Bacterial strains, phage, and growth conditions. S. aureus laboratory virulent strain RN6390 (12) was kindly provided by A. L. Cheung (Darmouth Medical School, Hanover, NH). S. aureus RN4220 (a mutant of the 8325-4 strain that accepts foreign DNA) was used as a genetic intermediate to deliver the temperature-sensitive plasmid pTV1ts (64). S. aureus clinical strain MB319 (55) was utilized in heterologous challenge experiments. Bacteriophage 11 was used to produce a phage lysate of strain RN4220 containing pTV1ts as previously described (11). The lysate was used to infect parental strain RN6390. Transductants were selected on brain heart infusion (BHI) (Difco, Detroit, MI) agar with chloramphenicol (Cm) (10 μg/ml). All strains were grown in BHI medium or in the defined minimum medium (DMM) for S. aureus described by Patee and Neveln (42). When necessary, Cm (10 μg/ml) or erythromycin (Em) (10 μg/ml) (Sigma, St. Louis, MO) was added. In certain experiments, colonies were replicated onto DMM agar plates minus different combinations of tryptophan (Trp) (0.05 mM), phenylalanine (Phe) (0.24 mM), tyrosine (Tyr) (0.28 mM), PABA (0.05 mg/liter), and 2,3-dihydrobenzoic acid (DHB) (10 mg/liter) (Sigma). S. aureus wild-type (wt) and aroA mutant strains were grown in BHI broth (supplemented with 10 μg/ml Em for the aroA mutant) to exponential phase, extensively washed with physiologic saline solution (PSS), and suspended in PSS to the desired density for inoculation to mice.
Transposon mutagenesis and screening for auxotrophic mutants. Transposition of Tn917 carried by pTV1ts was performed essentially as previously described (24). S. aureus RN6390 carrying pTV1ts was grown in BHI broth containing Cm (10 μg/ml) at 30°C overnight. The culture was diluted into BHI broth containing Em (15 μg/ml), grown overnight at 42°C, and plated at 42°C on BHI agar containing Em to select for transposon mutants. These mutants were screened for the aromatic amino acid auxotrophic phenotype. To do this, Em-resistant (Emr) colonies were replicated onto DMM agar plates without Trp, Phe, Tyr, PABA, or DHB.
DNA manipulations and Southern hybridization. Chromosomal DNA was purified from S. aureus strain RN6390 or the auxotrophic mutant FB306 (obtained in this study) after bacterial lysis with lysostaphin (5 mg/ml) and lysozyme (10 mg/ml) by the method of Pitcher et al. (43). Restriction endonucleases (Promega, Madison, WI) were used as recommended by the manufacturer. Chromosomal DNA was digested with EcoRI and separated by electrophoresis, transferred to and hybridized on a Zeta-Probe GT membrane (Bio-Rad, Hercules, CA) and blotted with a 1.8-kb Tn917 BglII fragment used as a probe labeled with digoxigenin by using the DIG DNA labeling kit (Boehringer Mannheim, Germany) (31).
Complementation. A 1.4-kb fragment encompassing the aroA gene from S. aureus RN6390 was amplified by PCR using primers 5'-CTC TCT AGA ACA TTA CAA CAT GCA TGT GAA C-3' and 5'-ACG CGT CGA CTG CGT CAT CGT TGT CAG TAG T-3'. Restriction sites for XbaI and SalI (underlined) were introduced into the fragment at the 5' and 3' ends, respectively. The PCR fragment was restricted and ligated into vector pALC1743 (kindly provided by A. L. Cheung) after deletion of the gfp gene and then transformed into Escherichia coli DH5 (Invitrogen, Carlsbad, CA) (28). Restriction analysis and DNA sequencing confirmed the orientation and authenticity of the cloned gene. The recombinant plasmid was electroporated into strain FR306, and Cm- and Em-resistant colonies were selected. Transformants were tested for restoration of the wild-type phenotype.
DNA amplification and sequencing. The junction fragment comprising the Tn917 right end and the flanking chromosomal DNA (see Fig. 1A and B) was amplified from mutant FB306 using inverse PCR. Briefly, genomic DNA from the mutant was digested with HindIII and ligated at a concentration of <2 ng/ml. PCR was performed using 20 to 30 ng of ligated template DNA and 50 pmol each of primer P3 (identical to nucleotides 5485 to 5503 of Tn917, GenBank database accession number M11180) and primer P4 (complementary to nucleotides 4393 to 4410 of Tn917) for 30 cycles, with 1 cycle consisting of 94°C for 1 min, 55°C for 1 min, and 72°C for 1 min. The product was sequenced using the chain termination method of Sanger et al. (52) on an ABI 373A automated DNA sequencer (Applied Biosystems, Foster City, CA). Chromatograms were analyzed using the SeqEd package (Applied Biosystems).
RNA isolation and RT-PCR. Total RNA from the mammary glands of immunized and control mice was extracted using the Trizol reagent (Gibco-BRL, Life Technologies) according to the manufacturer's instructions. Chloroform-isoamyl alcohol purification was performed as described previously (13). Total RNA was quantified by spectrophotometry at 260 nm, and RNA quality was determined by the ratio of optical density at 260 nm/optical density at 280 nm. Ratios higher than 1.8 were considered acceptable. The levels of gamma interferon (IFN-) and interleukin 4 (IL-4) transcripts were determined by reverse transcription-PCR (RT-PCR) from 3 μg of template RNA using the Access RT-PCR system (Promega, Madison, WI). Primers for IFN- and IL-4 and conditions for RT-PCR have been described elsewhere (59). RT-PCR products were separated on 2% agarose gels with a 100-bp ladder as size marker (Promega, Madison, WI) and visualized by staining with ethidium bromide. PCR using primers for -actin (59) was performed on each individual sample as a positive-control standard. Analysis was performed using the Scion Image Beta software (Scion Corp., Frederick, Md.).
Determination of virulence for mice. Swiss outbred mice were bred and maintained in the vivarium of the Department of Microbiology, School of Medicine, University of Buenos Aires, Buenos Aires, Argentina. Animal care was done in accordance with the guidelines set forth by the U.S. National Institutes of Health (37). For 50% lethal dose (LD50) studies, 6-week-old, male Swiss mice were injected intraperitoneally (i.p.) with 0.5 ml of a suspension containing the bacterial strain and 2% (wt/vol) brewer's yeast in BHI broth (35). Four groups each comprising 10 mice received serial log dilutions of bacteria, and the LD50 was determined after 3 days by the method of Reed and Muench (47).
Persistence studies in vivo. Eight to 10 male, 6-week-old Swiss mice were inoculated with each strain. For intravenous (i.v.) inoculation, mice were injected with 0.2 ml of the bacterial suspension in PSS (6 x 107 CFU/mouse) into the tail vein. After different times (1 and 24 h), the lungs were excised and homogenized separately in 2 ml of sterile distilled water (16). After injection (6.5 x 106 CFU/0.5 ml of 2% brewer's yeast in BHI) by the i.p. route, the lungs were removed at different times (3 and 5 h) and homogenized. For ima inoculation, six female Swiss mice received 0.05 ml of the bacterial suspension in PSS (2 x 105 CFU/gland) into the left fourth (L4) and right fourth (R4) mammary glands as described previously (10, 21). After 24 h and 96 h, the L4 and R4 glands were removed and homogenized. Viable counts were performed on these homogenates by plating samples on BHI agar.
Immunization and wild-type challenge. Approximately 7 days before parturition, female Swiss mice were immunized with 0.05 ml of a suspension of S. aureus (5 x 105 CFU/gland) by ima inoculation into the L4 and R4 mammary glands. The suspension contained S. aureus FB306 or heat-killed (30 min at 60°C) RN6390 S. aureus. A booster injection containing the same dose was administered 7 days later by the same route. Fourteen days after the second injection, mice were challenged by the ima route with 0.05 ml of an RN6390 suspension (5 x 105 CFU/gland) or with a suspension containing 1 x 106 CFU/gland of S. aureus MB319 (23). Viable bacterial counts were performed on mammary gland homogenates.
Statistical analysis. Nonparametric data were analyzed with the Mann-Whitney test using GraphPad software (PRISM, version 2.2). Fisher's exact test was used for statistical comparison of proportions.
RESULTS
Characterization of the transposon mutant. After Tn917 mutagenesis of S. aureus virulent strain RN6390, aromatic amino acid-dependent mutants were screened. To do this, 3,493 Emr colonies were replicated onto different DMM agar plates without Trp, Phe, Tyr, and PABA or on DHB containing Em. Ten mutants exhibited auxotrophic phenotype, but only one aromatic amino acid-dependent mutant (named FB306) did not grow on DMM agar plates without the three aromatic amino acids as well as PABA and DHB. Therefore, the nutritional requirement of mutant FB306 to grow in vitro suggested that the affected enzyme responsible for the observed auxotrophic phenotype is one of those required for the synthesis of shikimic acid and chorismic acid (2). By transduction using 11, the Tn917 insertion of mutant FB306 was moved back into the wild-type RN6390 strain. Over 100 Emr transductants were demonstrated to be dependent of the three aromatic amino acids as well as of PABA and DHB. The in vitro growth rates of mutant FB306 and parental strain RN6390 in DMM supplemented with aromatic amino acids, plus PABA and DHB, under antibiotic-free conditions did not differ significantly from each other (ca. 60 min). The reversion frequency of the mutant was lower than 2 x 10–14. In order to perform Southern blot analysis of mutant FB306, DNA was digested with EcoRI or HindIII, subjected to electrophoresis, and probed with a 1.8-kb BglII internal fragment from Tn917 (Fig. 1B). DNA from wild-type strain RN6390 did not hybridize with the probe (data not shown). One hybridization band was observed after EcoRI digestion, indicating that there was a single transposon insert in the chromosome. Digestion of FB306 DNA with HindIII yielded a 1.29-kb band that represented the HindIII fragment within Tn917 plus two additional bands (3 and 1.8 kb) which represented the junction fragment between the transposon and chromosomal DNA (Fig. 1C).
The DNA flanking one side of the inserted transposon in the FB306 mutant was amplified by inverse PCR using primers P3 and P4 (Fig. 1B). Approximately 700 bp, including the HindIII fragment encompassing the region marked by the Tn917 insertion, was sequenced. The nucleotide sequence exhibited 99% identity with the 3-phosphoshikimate 1-carboxyvinyltransferase (aroA) gene of S. aureus COL, Mu50, N315, MSSA476 and MW2, as well as 98% identity with the aroA gene of S. aureus MRSA252. Subsequent similarity searches of available S. aureus genome sequences (www.ncbi.nlm.nih.gov) revealed the presence of a single copy of the aroA gene, indicating that it is widely conserved in S. aureus. Nucleotide sequence analysis revealed that insertion of transposon Tn917 had occurred 756 bp downstream from the aroA (ca. 1,300 bp) start codon in FB306. To confirm that the lesion in aroA is responsible for the observed phenotype, a genetic complementation study was performed. As expected, complementation of the FB306 mutant with the plasmid carrying the aroA gene recovered the wild-type phenotype.
The S. aureus aroA mutant is attenuated in mice. Introduction of the aroA mutation into S. aureus RN6390 increased the log LD50 for Swiss mice from 4.8 to 6.0. In addition, 43% of mice inoculated by the i.v. route with a high dose (2 x 107 CFU/mouse) of the aroA mutant were in good health by day 31 postchallenge, when the experiment was terminated. In contrast, 100% of the animals injected by the i.v. route with an identical dose of wild-type S. aureus RN6390 died by day 10 after challenge (Fig. 2). Moreover, histopathological analysis of kidneys from mice inoculated by the i.v. route with 2 x 107 CFU/mouse of wild-type S. aureus or the aroA mutant revealed that the mutant induced histopathological changes of lesser magnitude compared with those found in mice challenged with wild-type S. aureus (Fig. 3).
Persistence studies. Both the S. aureus parental strain and the FB306 aroA mutant were investigated for their abilities to colonize the lungs, spleens, and mammary glands of mice. Previous results from our laboratory were considered to choose the different times postchallenge (21, 23). Groups of mice were infected i.p. with 6.7 x 106 CFU/mouse of wild-type RN6390 or the FR306 aroA mutant. Bacterial counts in lungs and spleens were determined at 3 and 5 h postchallenge. Viable counts of the aroA mutant in the lungs decreased significantly compared with those of S. aureus RN6390 at 3 h postchallenge (Fig. 4A). Similar results were observed in the spleens of mice inoculated by the i.p. route (Fig. 4B).
In other experiments, groups of mice were challenged by the i.v. route with a suspension of the aroA mutant (6.5 x 107 CFU/mouse) or the wild-type RN6390 S. aureus. In blood the inoculated bacteria are rapidly and efficiently phagocytosed. Mice were sacrificed at 1 and 24 h, and the numbers of CFU in the lungs were determined. One hour after challenge, the number of CFU of the aroA mutant decreased significantly compared with that of the RN6390 strain (3.3 x 104 CFU/ml for the aroA mutant versus 1.3 x 105 CFU/ml for the wt; P = 0.04) (Fig. 5A). Viable counts of the aroA mutant were significantly reduced 24 h postinfection (3.3 x 104 CFU/ml at 1 h versus 2.4 x 102 CFU/ml at 24 h; P = 0.017). These results demonstrate that the aroA mutant has a reduced ability to multiply within lungs and spleens. All FB306 colonies recovered from mice conserved their aroA phenotype.
In experiments to ascertain the survival of the aroA mutant in the mammary gland, groups of female mice were inoculated by the ima route with 1.9 x 105 CFU/gland of wild-type RN6390 or the aroA mutant. At 1 and 4 days after challenge, mice were sacrificed, and the mammary glands were removed and homogenized. Aliquots from homogenates were obtained to determine the bacterial viable counts. At 1 day after inoculation, the number of CFU of the aroA mutant recovered from mammary glands was significantly decreased compared with that of the wild-type RN6390 (9.4 x 103 CFU/ml for the aroA mutant versus 4.8 x 105 CFU/ml for the wt; P = 0.004). Similar results were obtained by 4 days after ima challenge (9.3 x 102 CFU/ml for the aroA mutant versus 4.1 x 104 CFU/ml for the wt; P = 0.03) (Fig. 5B). These results show that the S. aureus FB306 aroA mutant has reduced ability to persist in the mouse mammary gland.
Immunization studies. In vaccination studies using S. aureus live attenuated mutants, it is important to consider mucosal immunity induced by deposition of the antigen. For this reason, to determine whether vaccination with the S. aureus aroA mutant induced protection, mice were immunized with the aroA mutant by the ima route. Another group of mice was immunized with heat-killed RN6390 by the same route. Immunized mice and age-matched nonimmunized controls were challenged 14 days later with either the parental wild-type RN6390 strain (5 x 105 CFU/gland) or a heterologous virulent clinical strain (namely, MB319) (1 x 106 CFU/gland) isolated from milk of a cow with mastitis. Ninety-six hours postchallenge, viable counts were assessed in the mammary glands to determine whether immunization affected colonization or clearance of the virulent strains. The number of RN6390 CFU recovered from mammary glands of mice immunized with the aroA mutant (aroA-immunized mice) was significantly reduced compared with that of nonimmunized controls (1,052 ± 538 total CFU for aroA-immunized mice versus 1.6 x 105 ± 9.5 x 104 total CFU for control mice; P = 0.02). Similar differences were observed when the number of RN6390 CFU recovered from mammary glands of aroA-immunized mice was compared with that of heat-killed-RN6390-immunized mice (1,052 ± 538 total CFU for aroA-immunized mice versus 2.5 x 105 ± 1.5 x 105 total CFU for heat-killed-RN6390-immunized mice; P = 0.01) (Fig. 6A). In addition, ima immunization with the aroA mutant significantly decreased the number of CFU of heterologous strain MB319 compared with the viable counts of MB319 recovered from control mice (nonimmunized and MB319 challenged) (38 ± 9.4 total CFU for aroA-immunized mice versus 1,316 ± 801 total CFU for control mice; P = 0.01) (Fig. 6B). Therefore, immunization with the aroA mutant conferred significant protection from challenge with homologous and heterologous virulent S. aureus.
By 96 h after challenge with S. aureus RN6390 (3 x 105 CFU/gland), histological studies of mammary glands locally immunized with the aroA mutant and nonimmunized controls were performed. The mammary glands of unvaccinated and challenged mice showed moderate polymorphonuclear leukocyte and mononuclear cell infiltration and mild vascular congestion. Conversely, the mammary tissue of vaccinated and challenged mice did not exhibit infiltration (Fig. 7).
Immune responses induced by the aroA mutant. To establish whether ima immunization with the aroA mutant induced adaptive responses in mice, production of IFN- and IL-4 mRNAs was determined as an indirect measurement of activation of different subsets of T cells (Th1 and Th2, respectively). Ninety-six hours after challenge with the wild-type strain RN6390 or heterologous strain MB319, the relative mRNA levels of IFN- and IL-4 were determined in mammary glands by RT-PCR. Mammary glands from mice immunized with the aroA mutant showed an increase in the level of IFN- transcripts compared with control, unvaccinated mice (Fig. 8). Similar results were observed when IL-4 mRNA levels in the vaccinated group were compared with those found in the control group (Fig. 8). Moreover, the increase observed in cytokine gene expression was independent of the S. aureus challenge strain (RN6390 or MB319) (data from mice challenged with MB319 not shown). Therefore, the results suggest that ima immunization with the aroA mutant induced activation of Th1 and Th2 cell subsets in the mammary gland.
DISCUSSION
Mutations in the basic branch of the aromatic amino acid biosynthesis pathway proved to be efficient in attenuating virulence, e.g., in Listeria monocytogenes (57), Shigella dysenteriae (62), Pseudomonas aeruginosa (44), Neisseria gonorrhoeae (9), and Bacillus anthracis (27), but they failed to do so in Mycobacterium tuberculosis (41). The main objective of this study was to ascertain whether an aro mutant of S. aureus could be attenuated and immunogenic. To do this, mutagenesis by transposition was chosen as a preliminary method. The results obtained in this investigation encourage us to begin the construction of an unmarked aroA deletion mutant of S. aureus to be utilized in field trials.
Target genes may be inactivated by integration of a transposable element. Such inactivation is usually the consequence of transcriptional interruption or of a negative polar effect on the expression of genes located downstream (15, 20). In this report, we describe the isolation and characterization of an S. aureus strain with a Tn917 insertion mutation in the aroA gene. Whereas aromatic amino acid-dependent mutants of other gram-positive bacteria were constructed by transposon mutagenesis (1, 27, 53), this is the first report of an attenuated aro mutant of S. aureus that is evaluated for its protective efficacy as a potential vaccine. The aro mutants are auxotrophs for aromatic amino acids, PABA (a precursor of folic acid), and DHB (a precursor for ubiquinone). S. aureus FB306 is phenotypically an aro mutant, because it proliferates only in minimal medium supplemented with Trp, Phe, and Tyr as well as PABA and DHB. The auxotrophic phenotype of mutant FB306 was stable both in vitro and in vivo. Indeed, its reversion frequency was <2 x 10–14. This result is consistent with previous observations concerning the effect of Tn917 as a chromosomal mutagen: precise excision of insertions is extremely rare, and deletions occur in about 10% of the insertion events (51). Finally, the idea that an undefined point mutation selected at 42°C (pTV1ts curing temperature) could have been responsible for the FB306 mutant aro auxotrophic phenotype might be hypothesized. In our experience, however, point mutations in S. aureus have a reversion frequency in the range from 10–6 to 10–8, much higher than the value of less than 2 x 10–14 observed in this study. This finding makes unlikely that a potential point mutation could have been responsible for the aro auxotrophic phenotype found in S. aureus FB306.
The FB306 mutant erythromycin marker was mobilized into the wild-type strain RN6390 by using phage 11, and the same auxotrophic phenotype was observed. It is suggested, therefore, that the dependence of aromatic amino acids, as well as PABA and DHB, of the FB306 mutant was due to Tn917 insertion. Southern blot analysis of FB306 mutant DNA digested with EcoRI exhibited one hybridizing band, which indicated that a single copy of the transposon was inserted into the chromosome. The site of the Tn917 insertion was confirmed by sequence analysis. The transposon interrupted the aroA gene (756 bp downstream from start codon), which codes for the 3-phosphoshikimate 1-carboxyvinyltransferase of the chorismic acid biosynthesis pathway (39). The identified nucleotide sequence was 98 to 99% identical to the aroA S. aureus published sequences. These deviations could be due to strain variation. Moreover, genetic complementation confirmed that the lesion in aroA was responsible for the phenotype observed in the FB306 aroA mutant. While aroA is the last gene in the aroCBA operon, there is a gene immediately downstream of aroA whose function is unknown but is similar to that coding Bacillus subtilis hypothetical protein YpiA (GenBank). The location of ypiA is conserved in many organisms, indicating that it may be important to the aromatic acid pathway. Indeed, the genes involved in the shikimate pathway and folate, ubiquinone, and aromatic amino acid synthesis are known in many bacteria, fungal pathogens, and apicomplexan parasites (49). Whether ypiA is involved in any enzymatic step of the shikimate pathway or major branches from chorismate should be investigated.
We hypothesized that introduction of a nonreverting mutation into the S. aureus chromosome causing dependence on aromatic metabolites may result in an attenuated mutant which would have reduced ability to multiply in mammalian tissues. Our results showed that the aroA mutant was indeed attenuated, as demonstrated by an increase in its LD50 and increased survival of mice compared with those of the parental wild type. The results also demonstrated that the mutation in the 3-phosphoshikimate 1-carboxyvinyltransferase restricted the in vivo growth of the aroA mutant compared with the wild-type RN6390 S. aureus counterpart. Similar findings were reported in aroA mutants of Listeria monocytogenes (57), Bordetella bronchiseptica (7, 25, 34), Bordetella pertussis (50), Aeromonas salmonicida (60), Pasteurella multocida (26), and Yersinia enterocolitica (3). In contrast, Salmonella enterica serovar Typhimurium aroA mutants persisted for several weeks in the livers and spleens of orally infected mice (25, 32). Although milk is an excellent culture medium for many bacteria (4), the aroA mutant was much less efficient at colonizing the murine mammary gland compared with the wild-type parental RN6390 strain. It is likely that attenuation was due to starvation for essential aromatic metabolites rather than indirect effects on the expression of putative virulence factors.
Hemin-auxotrophic small-colony variants have been isolated from bovine S. aureus ima infections (54). These auxotrophic mutants can appear after apparently successful antimicrobial therapies (45). In view of these findings, it can be speculated that auxotrophic S. aureus could become a potential pathogen in the mammary gland, since small-colony variants frequently revert to the wild-type phenotype in vitro (33). Such would not be the case of the auxotrophic aro mutant described here, because its reversion frequency is extremely low and the nutritional requirement to restore the normal phenotype is not found in mammals, thus making its growth restricted in vivo. The latter is one of the facts that makes the use of an aro mutant as a potential vaccine attractive. Indeed, the S. aureus aroA mutant obtained in this study was cleared faster than the wild-type bacteria from different tissues (lung, spleen, and mammary gland) within a time frame suitable to make an S. aureus aroA mutant an attractive vaccine prospect.
It is generally accepted that attenuated strains are more potent than nonliving bacteria in stimulating immune responses (5). Indeed, live attenuated bacteria produce most of the antigens normally expressed during natural infection. An important issue of the study of auxotrophic mutants is to reach the right balance between attenuation and immunogenicity, since overattenuated bacteria may not produce certain key antigens necessary for the induction of protective immunity in vivo. A point of concern is the fact that an increase in the somatic cell count could be induced as a result of an S. aureus aroA mutant inoculation of cows. However, low levels of polymorphonuclear leukocytes and mononuclear cells and less damage were observed in the mammary gland after administration of the aroA mutant compared with the wild-type strain in the mouse mammary gland. Furthermore, in previous experiments, we have seen that the number of leukocytes was not increased in milk after ima administration of an attenuated S. aureus strain (23). Recently, Brouillette and Malouin (4) have demonstrated that after bacterial inoculation in the mouse mammary gland, polymorphonuclear infiltration, tissue damage, and S. aureus-host cell interactions are similar to those found in the bovine mammary gland. Therefore, even though certain differences may exist between murine and bovine hosts, the results obtained for mouse mammary gland infection may provide valid experimental data to support final testing of a vaccine strain in cows. In any event, the potential increase in the milk somatic cell counts needs to be assessed in cows immunized by the ima route using the desired auxotrophic S. aureus strain under construction.
The choice of the appropriate immunization route and scheme to obtain protective immune responses should be of concern (30), because it can determine failure or success of vaccination. In this regard, we demonstrated that ima but not i.p. application of live attenuated S. aureus strains stimulates murine mucosal responses against the wild type (21). In practice, ima administration of the vaccine in cows is laborious and needs trained personal. However, the efficacy of local immunization of cattle against Streptococcus uberis experimental ima challenge was demonstrated (18, 19). In the present study we utilized the same route of administration (ima) and immunization scheme defined in a previous study with temperature-sensitive mutants (23), and we were able to obtain significant protection after immunization with the aroA mutant. Interestingly, significant reduction in the number of CFU of virulent challenging S. aureus strains (RN6390 and MB319, both producers of hemolysins) was observed in the mammary glands of mice immunized with the aroA mutant. Moreover, ima immunization of mice with the S. aureus aroA mutant induced high levels of both IFN- and IL-4 transcripts in the mammary gland. In previous studies, we have demonstrated the feasibility of inducing Th1 and Th2 responses against S. aureus in the mouse mammary gland by local immunization with temperature-sensitive mutants of S. aureus during late pregnancy (22).
Raupach and Kaufmann observed that IFN- plays a central role in the early bacterial control of infection with Salmonella enterica serovar Typhimurium aroA strains (46). Previous evidence suggests that IFN- could elicit functional changes in phagocytic cells of the mammary gland that could make it effective in the control of bovine mastitis (56). Riollet et al. (48) have detected IFN- transcripts sporadically in cells derived from milk of cows immunized with alpha-hemolysin by ima injection. Conversely, IL-4 mRNAs were not detected in any of the samples at any time by the same authors. This observation suggests that an orientation towards a Th1-type response was induced by immunization with a single staphylococcal component, such as alpha-hemolysin. Ima immunization of mice with the aroA mutant under study induced high levels of both IFN- and IL-4 transcripts, which agrees with the fact that multiple antigens are involved in the adaptive response to a live attenuated vaccine. It can be speculated that although the S. aureus aroA mutant was able to grow poorly in vivo, it could still produce important virulence factors to induce an appropriate immune response. Interestingly, mice immunized with the S. aureus aroA mutant were protected from ima heterologous challenge with the most prevalent clone of S. aureus (MB319 strain) recovered from milk of cows with mastitis in Argentina (6). Since the genotypic background of the aroA mutant can be discriminated from those of bovine field isolates from the same region (7), our results support the performance of controlled field studies on isolated and small herds in Argentina to evaluate the protective efficacy of an aroA mutant.
This is the first time an aroA mutant of S. aureus was tested for its protective ability to be used as a vaccine. Although differences may exist between the bovine and murine mammary glands, the results of the present study may contribute to the rational design of a live attenuated vaccine to prevent mastitis caused by S. aureus in dairy cows.
ACKNOWLEDGMENTS
This work was supported in part by grants from ANPCyT (PICT 05/10648 and PICT 08/11740) and Universidad de Buenos Aires (UBACYT M-009), Buenos Aires, Argentina.
We thank Daniela Centron for help with DNA sequence analysis. We thank Ambrose L. Cheung (Dartmouth Medical School, Hanover, New Hampshire) for providing S. aureus strain RN6390 and plasmid pALC1743.
REFERENCES
1. Alexander, J. E., P. W. Andrew, D. Jones, and I. S. Roberts. 1993. Characterization of an aromatic amino acid-dependent Listeria monocytogenes mutant: attenuation, persistence, and ability to induce protective immunity in mice. Infect. Immun. 61:2245-2248.
2. Bentley, R. 1990. The shikimate pathway: a metabolic tree with many branches. Crit. Rev. Biochem. Mol. Biol. 25:307-384.
3. Bowe, F., P. O'Gaora, D. Maskell, M. Cafferkey, and G. Dougan. 1989. Virulence, persistence, and immunogenicity of Yersinia enterocolitica O:8 aroA mutants. Infect. Immun. 57:3234-3236.
4. Brouillette, E., and F. Malouin. 2005. The pathogenesis and control of Staphylococcus aureus-induced mastitis: study models in the mouse. Microbes Infect. 7:560-568.
5. Brown, F., G. Dougan, E. M. Hoey, S. J. Martin, B. K. Rima, and A. Trudgett. 1993. Vaccine design. John Wiley & Sons, Chichester, England.
6. Buzzola, F. R., L. Quelle, M. I. Gomez, M. Catalano, L. Steele-Moore, D. Berg, E. Gentilini, G. Denamiel, and D. O. Sordelli. 2001. Genotypic analysis of Staphylococcus aureus from milk of dairy cows with mastitis in Argentina. Epidemiol. Infect. 126:445-452.
7. Buzzola, F. R., L. S. Quelle, L. Steele-Moore, D. Berg, G. Denamiel, E. Gentilini, and D. O. Sordelli. 2001. Molecular diversity of live-attenuated prototypic vaccine strains and clinical isolates of Staphylococcus aureus. FEMS Microbiol. Lett. 202:91-95.
8. Carter, E. W., and D. E. Kerr. 2003. Optimization of DNA-based vaccination in cows using green fluorescent protein and protein A as a prelude to immunization against staphylococcal mastitis. J. Dairy Sci. 86:1177-1186.
9. Chamberlain, L. M., R. Strugnell, G. Dougan, C. E. Hormaeche, and R. Demarco de Hormaeche. 1993. Neisseria gonorrhoeae strain MS11 harbouring a mutation in gene aroA is attenuated and immunogenic. Microb. Pathog. 15:51-63.
10. Chandler, R. L. 1970. Experimental bacterial mastitis in the mouse. J. Med. Microbiol. 3:273-282.
11. Cheung, A. L., J. M. Koomey, C. A. Butler, S. J. Projan, and V. A. Fischetti. 1992. Regulation of exoprotein expression in Staphylococcus aureus by a locus (sar) distinct from agr. Proc. Natl. Acad. Sci. USA 89:6462-6466.
12. Cheung, A. L., K. Eberhardt, and J. H. Heinrichs. 1997. Regulation of protein A synthesis by the sar and agr loci of Staphylococcus aureus. Infect. Immun. 65:2243-2249.
13. Chomczynski, P., and N. Sacchi. 1987. Single-step method of RNA isolation by acid guanidinium thiocyanate-phenol-chloroform extraction. Anal. Biochem. 162:156-159.
14. Crist, W. L., R. J. Harmon, J. O'Leary, and A. J. McAllister. 20 February 2006, posting date. Mastitis and its control. Cooperative Extension Service, University of Kentucky College of Agriculture. Publication ASC-140. [Online.] http://www.ca.uky.edu/agc/pubs/asc/asc140/asc140.pdf.
15. Dobinsky, S., K. Bartscht, and D. Mack. 2002. Influence of Tn917 insertion of transcription of the icaADBC operon in six biofilm-negative transposon mutants of Staphylococcus epidermidis. Plasmid 47:10-17.
16. Dougan, G., S. Chatfield, D. Pickard, J. Bester, D. O'Callaghan, and D. Maskell. 1988. Construction and characterization of vaccine strains of Salmonella harboring mutations in two different genes. J. Infect. Dis. 158:1329-1335.
17. Fetrow, J. 2000. Mastitis: an economic consideration, p. 3-47. In Proceedings of the 29th Annual Meeting of the National Mastitis Council, Atlanta, Ga. National Mastitis Council, Madison, Wis.
18. Finch, J. M., A. W. Hill, T. R. Field, and J. A. Leigh. 1994. Local vaccination with killed Streptococcus uberis protects the bovine mammary gland against experimental intramammary challenge with the homologous strain. Infect. Immun. 62:3599-3603.
19. Finch, J. M., A. Winter, A. W. Walton, and J. A. Leigh. 1997. Further studies on the efficacy of a live vaccine against mastitis caused by Streptococcus uberis. Vaccine 10:1138-1143.
20. Galas, D. J., and M. Chandler. 1989. Bacterial insertion sequences, p. 109-162. In E. B. Berg and M. M. Howe (ed.), Mobile DNA. American Society for Microbiology, Washington, D.C.
21. García, V. E., M. I. Gomez, M. F. Iglesias, N. Sanjuan, M. M. Gherardi, M. C. Cerquetti, and D. O. Sordelli. 1996. Intramammary immunization with live-attenuated Staphylococcus aureus: microbiological and immunological studies in a mouse mastitis model. FEMS Immunol. Med. Microbiol. 14:45-51.
22. Gomez, M. I., D. O. Sordelli, F. R. Buzzola, and V. E. García. 2002. Induction of cell-mediated immunity to Staphylococcus aureus in the mouse mammary gland by local immunization with a live attenuated mutant. Infect. Immun. 70:4254-4260.
23. Gomez, M. I., V. E. García, M. M. Gherardi, M. C. Cerquetti, and D. O. Sordelli. 1998. Intramammary immunizations with live-attenuated Staphylococcus aureus protects mice from experimental mastitis. FEMS Immunol. Med. Microbiol. 20:21-27.
24. Grüter, L., H. Feucht, M. Mempel, and R. Laufs. 1993. Construction of a slime negative transposon mutant in Staphylococcus epidermidis using the Enterococcus faecalis transposon Tn917. Microbiol. Immunol. 37:35-40.
25. Hoiseth, S. K., and B. A. D. Stocker. 1981. Aromatic-dependent Salmonella typhimurium are non-virulent and effective as live vaccines. Nature 291:238-239.
26. Homchampa, P., R. A. Strugnell, and B. Adler. 1992. Molecular analysis of the aroA gene of Pasteurella multocida and vaccine potential of constructed aroA mutants. Mol. Microbiol. 8:3585-3593.
27. Ivins, B. E., S. L. Welkos, G. B. Knudson, and S. F. Little. 1990. Immunization against anthrax with aromatic compound-dependent (AroA–) mutants of Bacillus anthracis and with recombinant strains of Bacillus subtilis that produce anthrax protective antigen. Infect. Immun. 58:303-308.
28. Khal, B. C., M. Goulian, W. V. Wamel, M. Herrmann, S. M. Simon, G. Kaplan, G. Peters, and A. L. Cheung. 2000. Staphylococcus aureus RN6390 replicates and induces apoptosis in a pulmonary epithelial cell line. Infect. Immun. 68:5385-5392.
29. Leitner, G., E. Lubachevsky, E. Glikman, M. Winkler, A. Saran, and Z. Trainin. 2003. Development of a Staphylococcus aureus vaccine against mastitis in dairy cows. I. Field trial. Vet. Immunol. Immunopathol. 93:31-38.
30. Leitner, G., B. Yadlin, A. Glickman, M. Chaffer, and A. Saran. 2000. Systemic and local immune response of cows to intramammary infection with Staphylococcus aureus. Res. Vet. Sci. 69:181-184.
31. Maniatis, T., E. F. Fritsch, and J. Sambrook. 1982. Molecular cloning: a laboratory manual. Cold Spring Harbor Laboratory Press, Cold Spring Harbor, N.Y.
32. Maskell, D., K. J. Sweeney, D. O'Callaghan, C. E. Hormaeche, F. Y. Liew, and G. Dougan. 1987. Salmonella typhimurium aroA mutants as carriers of the Escherichia coli heat-labile enterotoxin B subunit to the murine secretory and systemic immune systems. Microb. Pathog. 2:211-220.
33. Massey, R. C., A. Buckling, and S. J. Peacock. 2001. Phenotypic switching of antibiotic resistance circumvents permanent costs in Staphylococcus aureus. Curr. Biol. 11:1810-1814.
34. McArthur, J. D., N. P. West, J. N. Cole, H. Jungnitz, C. A. Guzman, J. Chin, P. R. Lehrbach, S. P. Djordjevic, and M. J. Walker. 2003. An aromatic amino acid auxotrophic mutant of Bordetella bronchiseptica is attenuated and immunogenic in a mouse model of infection. FEMS Microbiol. Lett. 221:7-16.
35. Mei, J., F. Nourbakhsh, C. Ford, and D. Holden. 1997. Identification of Staphylococcus aureus virulence genes in a murine model of bacteraemia using signature-tagged mutagenesis. Mol. Microbiol. 26:399-407.
36. Michie, C. A. 2002. Staphylococcal vaccines. Trends Immunol. 23:461-463.
37. National Research Council. 1996. Guide for the care and use of laboratory animals (NIH guide, revised). National Academy Press, Washington, D.C.
38. O'Callaghan, D., D. Maskell, F. Y. Liew, C. S. F. Easmon, and G. Dougan. 1998. Characterization of aromatic- and purine-dependent Salmonella typhimurium: attenuation, persistence, and ability to induce protective immunity in BALB/c mice. Infect. Immun. 56:419-423.
39. O'Connell, C., P. Pattee, and T. J. Foster. 1993. Sequence and mapping of the aroA gene of Staphylococcus aureus 8325-4. J. Gen. Microbiol. 139:1449-1460.
40. Oyston, P. C. F., P. Russell, D. Williamson, and R. W. Titball. 1996. An aroA mutant of Yersinia pestis is attenuated in guinea-pigs, but virulent in mice. Microbiology 142:1847-1853.
41. Parish, T., and N. G. Stoker. 2002. The common aromatic amino acid biosynthesis pathway is essential in Mycobacterium tuberculosis. Microbiology 148:3069-3077.
42. Patee, P. A., and S. Neveln. 1975. Transformation analysis of three linkage groups in Staphylococcus aureus. J. Bacteriol. 124:201-204.
43. Pitcher, D., N. Saundres, and R. Owen. 1989. Rapid extraction of bacterial genomic DNA with guanidium thiocyanate. Lett. Appl. Microbiol. 8:151-153.
44. Priebe, G. P., M. M. Brinig, K. Hatano, M. Grout, F. T. Coleman, G. B. Pier, and J. B. Goldberg. 2002. Construction and characterization of a live, attenuated aroA deletion mutant of Pseudomonas aeruginosa as a candidate intranasal vaccine. Infect. Immun. 70:1507-1517.
45. Proctor, R. A., O. Vesga, M. F. Otten, S. P. Koo, M. R. Yeamen, H. G. Sahl, and A. S. Bayer. 1996. Staphylococcus aureus small-colony variants cause persistent and resistant infections. Chemotherapy 42:47-52.
46. Raupach, B., and S. H. Kaufmann. 2001. Bacterial virulence, proinflammatory cytokines and host immunity: how to choose the appropriate Salmonella vaccine strain Microbes Infect. 3:1261-1269.
47. Reed, L. J., and H. Muench. 1938. A simple method for estimating fifty percent endpoints. Am. J. Hyg. 27:493-497.
48. Riollet, C., P. Rainard, and B. Poutrel. 2000. Kinetics of cells and cytokines during immune-mediated inflammation in the mammary gland of cows systemically immunized with Staphylococcus aureus alpha-toxin. Inflamm. Res. 49:486-496.
49. Roberts, C. W., F. Roberts, R. E. Lyons, M. J. Kirisits, E. J. Mui, J. Finnerty, J. J. Johnson, D. J. Ferguson, J. R. Coggins, T. Krell, G. H. Coombs, W. K. Milhous, D. E. Kyle, S. Tzipori, J. Barnwell, J. B. Dame, J. Carlton, and R. McLeod. 2002. The shikimate pathway and its branches in apicomplexan parasites. J. Infect. Dis. 185(Suppl. 1):S25-S36.
50. Roberts, M., D. Maskell, P. Novotny, and G. Dougan. 1990. Construction and characterization in vivo of Bordetella pertussis aroA mutants. Infect. Immun. 58:732-739.
51. Sandman, K., R. Losick, and P. Youngman. 1987. Genetic analysis of Bacillus subtilis spo mutations generated by Tn917-mediated insertional mutagenesis. Genetics 117:603-617.
52. Sanger, F., S. Nicklen, and A. R. Coulson. 1977. DNA sequencing with chain-terminating inhibitors. Proc. Natl. Acad. Sci. USA 74:5463-5467.
53. Simmons, C. P., A. L. M. Hodgson, and R. A. Strugnell. 1997. Attenuation and vaccine potential of aroQ mutants of Corynebacterium pseudotuberculosis. Infect. Immun. 65:3048-3056.
54. Sompolinsky, D., M. Cohen, and G. Ziv. 1974. Epidemiological and biochemical studies on thiamine-less dwarf-colony variants of Staphylococcus aureus as etiological agents of bovine mastitis. Infect. Immun. 9:217-228.
55. Sordelli, D. O., F. R. Buzzola, M. I. Gomez, L. Steele-Moore, D. Berg, E. Gentilini, M. Catalano, A. J. Reitz, T. Tollersrud, G. Denamiel, P. Jeric, and J. C. Lee. 2000. Capsule expression by bovine isolates of Staphylococcus aureus from Argentina: genetic and epidemiologic analyses. J. Clin. Microbiol. 38:846-850.
56. Sordillo, L. M., K. Shafer-Weaver, and D. DeRosa. 1997. Immunobiology of the mammary gland. J. Dairy Sci. 80:1851-1865.
57. Stritzker, J., J. Janda, C. Schoen, M. Taupp, S. Pilgrim, I. Gentschev, P. Schreier, G. Geginat, and W. Goebel. 2004. Growth, virulence, and immunogenicity of Listeria monocytogenes aro mutants. Infect. Immun. 72:5622-5629.
58. Tenhagen, B. A., D. Edinger, B. Baumgartner, P. Kalbe, G. Klunder, and W. Heuwieser. 2001. Efficacy of a herd-specific vaccine against Staphylococcus aureus to prevent post-partum mastitis in dairy heifers. J. Vet. Med. Ser. A 48:601-607.
59. Ulett, G. C., N. Ketheesan, and R. G. Hirst. 2000. Cytokine gene expression in innately susceptible BALB/c mice and relatively resistant C57BL/6 mice during infection with virulent Burkholderia pseudomallei. Infect. Immun. 68:2034-2042.
60. Vaughn, L. M., P. R. Smith, and T. J. Foster. 1993. An aromatic-dependent mutant of the fish pathogen Aeromonas salmonicida is attenuated in fish and is effective as a live vaccine against the salmonid disease furunculosis. Infect. Immun. 61:2172-2182.
61. Waldvogel, F. A. 2000. Staphylococcus aureus, p. 2069-2092. In G. L. Mandell, J. E. Bennett, and R. Dolin (ed.), Principles and practice of infectious disease. Churchill Livingstone, Philadelphia, Pa.
62. Walker, J. C., and N. K. Verma. 1997. Cloning and characterization of the aroA and aroD genes of Shigella dysenteriae type 1. Microbiol. Immunol. 41:809-813.
63. Yancey, R. J., Jr. 1999. Vaccines and diagnostic methods for bovine mastitis: fact and fiction. Adv. Vet. Med. 41:257-273.
64. Youngman, P. 1985. Plasmid vectors for recovering and exploiting Tn917 transpositions in Bacillus and other gram-positive bacteria, p. 79-104. In K. G. Hardy (ed.), Plasmids: a practical approach. IRL Press, Oxford, England.(Fernanda R. Buzzola, Marí)
ABSTRACT
Staphylococcus aureus is the most important etiological agent of bovine mastitis, a disease that causes significant economic losses to the dairy industry. Several vaccines to prevent the disease have been tested, with limited success. The aim of this study was to obtain a suitable attenuated aro mutant of S. aureus by transposon mutagenesis and to demonstrate its efficacy as a live vaccine to induce protective immunity in a murine model of intramammary infection. To do this, we transformed S. aureus RN6390 with plasmid pTV1ts carrying Tn917. After screening of 3,493 erythromycin-resistant colonies, one mutant incapable of growing on plates lacking phenylalanine, tryptophan, and tyrosine was isolated and characterized. Molecular characterization of the mutant showed that the affected gene was aroA and that the insertion occurred 756 bp downstream of the aroA start codon. Complementation of the aroA mutant with a plasmid carrying aroA recovered the wild-type phenotype. The mutant exhibited a 50% lethal dose (1 x 106 CFU/mouse) higher than that of the parental strain (4.3 x 104 CFU/mouse). The aroA mutant showed decreased ability to persist in the lungs, spleens, and mammary glands of mice. Intramammary immunization with the aroA mutant stimulated both Th1 and Th2 responses in the mammary gland, as ascertained by reverse transcription-PCR, and induced significant protection from challenge with either the parental wild-type or a heterologous strain isolated from a cow with mastitis.
INTRODUCTION
Bovine mastitis is one of the most important diseases of dairy cows throughout the world. It is also a major cause of economic losses to the dairy industry because it leads to decreased milk production and low-quality milk (17). Staphylococcus aureus is the most prevalent infectious agent that affects the bovine udder. After entering the mammary gland through the teat canal and adapting to the udder environment, S. aureus multiplies rapidly, and an inflammatory reaction ensues, leading to tissue damage (61). Staphylococcal mastitis is extremely difficult to control by treatment alone. However, effective programs of postmilking use of germicidal teat dips, strict milking time hygiene, dry cow therapy, and culling can result in a markedly reduced incidence of S. aureus (14). A number of vaccines to prevent the disease and reduce the severity of intramammary (ima) infection have been described. These vaccines, however, have failed to prevent the development of staphylococcal mastitis (29, 58, 63), thus making other strategies for preventing ima infection indispensable. Although a number of molecules have been suggested as potential useful antigens for single-component vaccines, none of these approaches have been entirely successful so far (8, 36). The use of live attenuated vaccines may be considered an alternative approach. Indeed, these vaccines may have the advantage that they represent a greater pool of antigens, which may induce a broader and perhaps more intense protective immune response against bacterial aggression (5).
Bacterial attenuation can be achieved by different mechanisms. One is to introduce mutations into a key metabolic pathway whose function is essential for bacteria to survive and grow in vivo to cause disease. Several virulent strains have been attenuated by inactivation of genes in the aromatic amino acid biosynthesis pathway. Aromatic-dependent mutants of Salmonella enterica serovar Typhimurium (38), Yersinia pestis (40), Bordetella pertussis (50), Corynebacterium pseudotuberculosis (53), Pseudomonas aeruginosa (44), and Listeria monocytogenes (1) have been shown to be avirulent and to stimulate protective immunity in different hosts. Requirement of p-aminobenzoic acid (PABA), a precursor of folic acid that is not synthesized by mammals, has been singled out as the likely reason for reduced virulence of these bacterial strains (25). Since bacteria are unable to take up exogenous folate and the availability of PABA is limited in vertebrate tissues, the growth of aro mutants in vivo is severely restricted.
In the present study, an aroA mutant of S. aureus was generated by transposon mutagenesis, and experiments were conducted to test its reduced virulence, ability to colonize the mammary gland, and efficacy to induce protective immunity in a murine model of ima infection. The utilization of bacterial auxotrophs in the development of alternative immunoprophylactic approaches to prevent S. aureus infection is supported by this study.
MATERIALS AND METHODS
Bacterial strains, phage, and growth conditions. S. aureus laboratory virulent strain RN6390 (12) was kindly provided by A. L. Cheung (Darmouth Medical School, Hanover, NH). S. aureus RN4220 (a mutant of the 8325-4 strain that accepts foreign DNA) was used as a genetic intermediate to deliver the temperature-sensitive plasmid pTV1ts (64). S. aureus clinical strain MB319 (55) was utilized in heterologous challenge experiments. Bacteriophage 11 was used to produce a phage lysate of strain RN4220 containing pTV1ts as previously described (11). The lysate was used to infect parental strain RN6390. Transductants were selected on brain heart infusion (BHI) (Difco, Detroit, MI) agar with chloramphenicol (Cm) (10 μg/ml). All strains were grown in BHI medium or in the defined minimum medium (DMM) for S. aureus described by Patee and Neveln (42). When necessary, Cm (10 μg/ml) or erythromycin (Em) (10 μg/ml) (Sigma, St. Louis, MO) was added. In certain experiments, colonies were replicated onto DMM agar plates minus different combinations of tryptophan (Trp) (0.05 mM), phenylalanine (Phe) (0.24 mM), tyrosine (Tyr) (0.28 mM), PABA (0.05 mg/liter), and 2,3-dihydrobenzoic acid (DHB) (10 mg/liter) (Sigma). S. aureus wild-type (wt) and aroA mutant strains were grown in BHI broth (supplemented with 10 μg/ml Em for the aroA mutant) to exponential phase, extensively washed with physiologic saline solution (PSS), and suspended in PSS to the desired density for inoculation to mice.
Transposon mutagenesis and screening for auxotrophic mutants. Transposition of Tn917 carried by pTV1ts was performed essentially as previously described (24). S. aureus RN6390 carrying pTV1ts was grown in BHI broth containing Cm (10 μg/ml) at 30°C overnight. The culture was diluted into BHI broth containing Em (15 μg/ml), grown overnight at 42°C, and plated at 42°C on BHI agar containing Em to select for transposon mutants. These mutants were screened for the aromatic amino acid auxotrophic phenotype. To do this, Em-resistant (Emr) colonies were replicated onto DMM agar plates without Trp, Phe, Tyr, PABA, or DHB.
DNA manipulations and Southern hybridization. Chromosomal DNA was purified from S. aureus strain RN6390 or the auxotrophic mutant FB306 (obtained in this study) after bacterial lysis with lysostaphin (5 mg/ml) and lysozyme (10 mg/ml) by the method of Pitcher et al. (43). Restriction endonucleases (Promega, Madison, WI) were used as recommended by the manufacturer. Chromosomal DNA was digested with EcoRI and separated by electrophoresis, transferred to and hybridized on a Zeta-Probe GT membrane (Bio-Rad, Hercules, CA) and blotted with a 1.8-kb Tn917 BglII fragment used as a probe labeled with digoxigenin by using the DIG DNA labeling kit (Boehringer Mannheim, Germany) (31).
Complementation. A 1.4-kb fragment encompassing the aroA gene from S. aureus RN6390 was amplified by PCR using primers 5'-CTC TCT AGA ACA TTA CAA CAT GCA TGT GAA C-3' and 5'-ACG CGT CGA CTG CGT CAT CGT TGT CAG TAG T-3'. Restriction sites for XbaI and SalI (underlined) were introduced into the fragment at the 5' and 3' ends, respectively. The PCR fragment was restricted and ligated into vector pALC1743 (kindly provided by A. L. Cheung) after deletion of the gfp gene and then transformed into Escherichia coli DH5 (Invitrogen, Carlsbad, CA) (28). Restriction analysis and DNA sequencing confirmed the orientation and authenticity of the cloned gene. The recombinant plasmid was electroporated into strain FR306, and Cm- and Em-resistant colonies were selected. Transformants were tested for restoration of the wild-type phenotype.
DNA amplification and sequencing. The junction fragment comprising the Tn917 right end and the flanking chromosomal DNA (see Fig. 1A and B) was amplified from mutant FB306 using inverse PCR. Briefly, genomic DNA from the mutant was digested with HindIII and ligated at a concentration of <2 ng/ml. PCR was performed using 20 to 30 ng of ligated template DNA and 50 pmol each of primer P3 (identical to nucleotides 5485 to 5503 of Tn917, GenBank database accession number M11180) and primer P4 (complementary to nucleotides 4393 to 4410 of Tn917) for 30 cycles, with 1 cycle consisting of 94°C for 1 min, 55°C for 1 min, and 72°C for 1 min. The product was sequenced using the chain termination method of Sanger et al. (52) on an ABI 373A automated DNA sequencer (Applied Biosystems, Foster City, CA). Chromatograms were analyzed using the SeqEd package (Applied Biosystems).
RNA isolation and RT-PCR. Total RNA from the mammary glands of immunized and control mice was extracted using the Trizol reagent (Gibco-BRL, Life Technologies) according to the manufacturer's instructions. Chloroform-isoamyl alcohol purification was performed as described previously (13). Total RNA was quantified by spectrophotometry at 260 nm, and RNA quality was determined by the ratio of optical density at 260 nm/optical density at 280 nm. Ratios higher than 1.8 were considered acceptable. The levels of gamma interferon (IFN-) and interleukin 4 (IL-4) transcripts were determined by reverse transcription-PCR (RT-PCR) from 3 μg of template RNA using the Access RT-PCR system (Promega, Madison, WI). Primers for IFN- and IL-4 and conditions for RT-PCR have been described elsewhere (59). RT-PCR products were separated on 2% agarose gels with a 100-bp ladder as size marker (Promega, Madison, WI) and visualized by staining with ethidium bromide. PCR using primers for -actin (59) was performed on each individual sample as a positive-control standard. Analysis was performed using the Scion Image Beta software (Scion Corp., Frederick, Md.).
Determination of virulence for mice. Swiss outbred mice were bred and maintained in the vivarium of the Department of Microbiology, School of Medicine, University of Buenos Aires, Buenos Aires, Argentina. Animal care was done in accordance with the guidelines set forth by the U.S. National Institutes of Health (37). For 50% lethal dose (LD50) studies, 6-week-old, male Swiss mice were injected intraperitoneally (i.p.) with 0.5 ml of a suspension containing the bacterial strain and 2% (wt/vol) brewer's yeast in BHI broth (35). Four groups each comprising 10 mice received serial log dilutions of bacteria, and the LD50 was determined after 3 days by the method of Reed and Muench (47).
Persistence studies in vivo. Eight to 10 male, 6-week-old Swiss mice were inoculated with each strain. For intravenous (i.v.) inoculation, mice were injected with 0.2 ml of the bacterial suspension in PSS (6 x 107 CFU/mouse) into the tail vein. After different times (1 and 24 h), the lungs were excised and homogenized separately in 2 ml of sterile distilled water (16). After injection (6.5 x 106 CFU/0.5 ml of 2% brewer's yeast in BHI) by the i.p. route, the lungs were removed at different times (3 and 5 h) and homogenized. For ima inoculation, six female Swiss mice received 0.05 ml of the bacterial suspension in PSS (2 x 105 CFU/gland) into the left fourth (L4) and right fourth (R4) mammary glands as described previously (10, 21). After 24 h and 96 h, the L4 and R4 glands were removed and homogenized. Viable counts were performed on these homogenates by plating samples on BHI agar.
Immunization and wild-type challenge. Approximately 7 days before parturition, female Swiss mice were immunized with 0.05 ml of a suspension of S. aureus (5 x 105 CFU/gland) by ima inoculation into the L4 and R4 mammary glands. The suspension contained S. aureus FB306 or heat-killed (30 min at 60°C) RN6390 S. aureus. A booster injection containing the same dose was administered 7 days later by the same route. Fourteen days after the second injection, mice were challenged by the ima route with 0.05 ml of an RN6390 suspension (5 x 105 CFU/gland) or with a suspension containing 1 x 106 CFU/gland of S. aureus MB319 (23). Viable bacterial counts were performed on mammary gland homogenates.
Statistical analysis. Nonparametric data were analyzed with the Mann-Whitney test using GraphPad software (PRISM, version 2.2). Fisher's exact test was used for statistical comparison of proportions.
RESULTS
Characterization of the transposon mutant. After Tn917 mutagenesis of S. aureus virulent strain RN6390, aromatic amino acid-dependent mutants were screened. To do this, 3,493 Emr colonies were replicated onto different DMM agar plates without Trp, Phe, Tyr, and PABA or on DHB containing Em. Ten mutants exhibited auxotrophic phenotype, but only one aromatic amino acid-dependent mutant (named FB306) did not grow on DMM agar plates without the three aromatic amino acids as well as PABA and DHB. Therefore, the nutritional requirement of mutant FB306 to grow in vitro suggested that the affected enzyme responsible for the observed auxotrophic phenotype is one of those required for the synthesis of shikimic acid and chorismic acid (2). By transduction using 11, the Tn917 insertion of mutant FB306 was moved back into the wild-type RN6390 strain. Over 100 Emr transductants were demonstrated to be dependent of the three aromatic amino acids as well as of PABA and DHB. The in vitro growth rates of mutant FB306 and parental strain RN6390 in DMM supplemented with aromatic amino acids, plus PABA and DHB, under antibiotic-free conditions did not differ significantly from each other (ca. 60 min). The reversion frequency of the mutant was lower than 2 x 10–14. In order to perform Southern blot analysis of mutant FB306, DNA was digested with EcoRI or HindIII, subjected to electrophoresis, and probed with a 1.8-kb BglII internal fragment from Tn917 (Fig. 1B). DNA from wild-type strain RN6390 did not hybridize with the probe (data not shown). One hybridization band was observed after EcoRI digestion, indicating that there was a single transposon insert in the chromosome. Digestion of FB306 DNA with HindIII yielded a 1.29-kb band that represented the HindIII fragment within Tn917 plus two additional bands (3 and 1.8 kb) which represented the junction fragment between the transposon and chromosomal DNA (Fig. 1C).
The DNA flanking one side of the inserted transposon in the FB306 mutant was amplified by inverse PCR using primers P3 and P4 (Fig. 1B). Approximately 700 bp, including the HindIII fragment encompassing the region marked by the Tn917 insertion, was sequenced. The nucleotide sequence exhibited 99% identity with the 3-phosphoshikimate 1-carboxyvinyltransferase (aroA) gene of S. aureus COL, Mu50, N315, MSSA476 and MW2, as well as 98% identity with the aroA gene of S. aureus MRSA252. Subsequent similarity searches of available S. aureus genome sequences (www.ncbi.nlm.nih.gov) revealed the presence of a single copy of the aroA gene, indicating that it is widely conserved in S. aureus. Nucleotide sequence analysis revealed that insertion of transposon Tn917 had occurred 756 bp downstream from the aroA (ca. 1,300 bp) start codon in FB306. To confirm that the lesion in aroA is responsible for the observed phenotype, a genetic complementation study was performed. As expected, complementation of the FB306 mutant with the plasmid carrying the aroA gene recovered the wild-type phenotype.
The S. aureus aroA mutant is attenuated in mice. Introduction of the aroA mutation into S. aureus RN6390 increased the log LD50 for Swiss mice from 4.8 to 6.0. In addition, 43% of mice inoculated by the i.v. route with a high dose (2 x 107 CFU/mouse) of the aroA mutant were in good health by day 31 postchallenge, when the experiment was terminated. In contrast, 100% of the animals injected by the i.v. route with an identical dose of wild-type S. aureus RN6390 died by day 10 after challenge (Fig. 2). Moreover, histopathological analysis of kidneys from mice inoculated by the i.v. route with 2 x 107 CFU/mouse of wild-type S. aureus or the aroA mutant revealed that the mutant induced histopathological changes of lesser magnitude compared with those found in mice challenged with wild-type S. aureus (Fig. 3).
Persistence studies. Both the S. aureus parental strain and the FB306 aroA mutant were investigated for their abilities to colonize the lungs, spleens, and mammary glands of mice. Previous results from our laboratory were considered to choose the different times postchallenge (21, 23). Groups of mice were infected i.p. with 6.7 x 106 CFU/mouse of wild-type RN6390 or the FR306 aroA mutant. Bacterial counts in lungs and spleens were determined at 3 and 5 h postchallenge. Viable counts of the aroA mutant in the lungs decreased significantly compared with those of S. aureus RN6390 at 3 h postchallenge (Fig. 4A). Similar results were observed in the spleens of mice inoculated by the i.p. route (Fig. 4B).
In other experiments, groups of mice were challenged by the i.v. route with a suspension of the aroA mutant (6.5 x 107 CFU/mouse) or the wild-type RN6390 S. aureus. In blood the inoculated bacteria are rapidly and efficiently phagocytosed. Mice were sacrificed at 1 and 24 h, and the numbers of CFU in the lungs were determined. One hour after challenge, the number of CFU of the aroA mutant decreased significantly compared with that of the RN6390 strain (3.3 x 104 CFU/ml for the aroA mutant versus 1.3 x 105 CFU/ml for the wt; P = 0.04) (Fig. 5A). Viable counts of the aroA mutant were significantly reduced 24 h postinfection (3.3 x 104 CFU/ml at 1 h versus 2.4 x 102 CFU/ml at 24 h; P = 0.017). These results demonstrate that the aroA mutant has a reduced ability to multiply within lungs and spleens. All FB306 colonies recovered from mice conserved their aroA phenotype.
In experiments to ascertain the survival of the aroA mutant in the mammary gland, groups of female mice were inoculated by the ima route with 1.9 x 105 CFU/gland of wild-type RN6390 or the aroA mutant. At 1 and 4 days after challenge, mice were sacrificed, and the mammary glands were removed and homogenized. Aliquots from homogenates were obtained to determine the bacterial viable counts. At 1 day after inoculation, the number of CFU of the aroA mutant recovered from mammary glands was significantly decreased compared with that of the wild-type RN6390 (9.4 x 103 CFU/ml for the aroA mutant versus 4.8 x 105 CFU/ml for the wt; P = 0.004). Similar results were obtained by 4 days after ima challenge (9.3 x 102 CFU/ml for the aroA mutant versus 4.1 x 104 CFU/ml for the wt; P = 0.03) (Fig. 5B). These results show that the S. aureus FB306 aroA mutant has reduced ability to persist in the mouse mammary gland.
Immunization studies. In vaccination studies using S. aureus live attenuated mutants, it is important to consider mucosal immunity induced by deposition of the antigen. For this reason, to determine whether vaccination with the S. aureus aroA mutant induced protection, mice were immunized with the aroA mutant by the ima route. Another group of mice was immunized with heat-killed RN6390 by the same route. Immunized mice and age-matched nonimmunized controls were challenged 14 days later with either the parental wild-type RN6390 strain (5 x 105 CFU/gland) or a heterologous virulent clinical strain (namely, MB319) (1 x 106 CFU/gland) isolated from milk of a cow with mastitis. Ninety-six hours postchallenge, viable counts were assessed in the mammary glands to determine whether immunization affected colonization or clearance of the virulent strains. The number of RN6390 CFU recovered from mammary glands of mice immunized with the aroA mutant (aroA-immunized mice) was significantly reduced compared with that of nonimmunized controls (1,052 ± 538 total CFU for aroA-immunized mice versus 1.6 x 105 ± 9.5 x 104 total CFU for control mice; P = 0.02). Similar differences were observed when the number of RN6390 CFU recovered from mammary glands of aroA-immunized mice was compared with that of heat-killed-RN6390-immunized mice (1,052 ± 538 total CFU for aroA-immunized mice versus 2.5 x 105 ± 1.5 x 105 total CFU for heat-killed-RN6390-immunized mice; P = 0.01) (Fig. 6A). In addition, ima immunization with the aroA mutant significantly decreased the number of CFU of heterologous strain MB319 compared with the viable counts of MB319 recovered from control mice (nonimmunized and MB319 challenged) (38 ± 9.4 total CFU for aroA-immunized mice versus 1,316 ± 801 total CFU for control mice; P = 0.01) (Fig. 6B). Therefore, immunization with the aroA mutant conferred significant protection from challenge with homologous and heterologous virulent S. aureus.
By 96 h after challenge with S. aureus RN6390 (3 x 105 CFU/gland), histological studies of mammary glands locally immunized with the aroA mutant and nonimmunized controls were performed. The mammary glands of unvaccinated and challenged mice showed moderate polymorphonuclear leukocyte and mononuclear cell infiltration and mild vascular congestion. Conversely, the mammary tissue of vaccinated and challenged mice did not exhibit infiltration (Fig. 7).
Immune responses induced by the aroA mutant. To establish whether ima immunization with the aroA mutant induced adaptive responses in mice, production of IFN- and IL-4 mRNAs was determined as an indirect measurement of activation of different subsets of T cells (Th1 and Th2, respectively). Ninety-six hours after challenge with the wild-type strain RN6390 or heterologous strain MB319, the relative mRNA levels of IFN- and IL-4 were determined in mammary glands by RT-PCR. Mammary glands from mice immunized with the aroA mutant showed an increase in the level of IFN- transcripts compared with control, unvaccinated mice (Fig. 8). Similar results were observed when IL-4 mRNA levels in the vaccinated group were compared with those found in the control group (Fig. 8). Moreover, the increase observed in cytokine gene expression was independent of the S. aureus challenge strain (RN6390 or MB319) (data from mice challenged with MB319 not shown). Therefore, the results suggest that ima immunization with the aroA mutant induced activation of Th1 and Th2 cell subsets in the mammary gland.
DISCUSSION
Mutations in the basic branch of the aromatic amino acid biosynthesis pathway proved to be efficient in attenuating virulence, e.g., in Listeria monocytogenes (57), Shigella dysenteriae (62), Pseudomonas aeruginosa (44), Neisseria gonorrhoeae (9), and Bacillus anthracis (27), but they failed to do so in Mycobacterium tuberculosis (41). The main objective of this study was to ascertain whether an aro mutant of S. aureus could be attenuated and immunogenic. To do this, mutagenesis by transposition was chosen as a preliminary method. The results obtained in this investigation encourage us to begin the construction of an unmarked aroA deletion mutant of S. aureus to be utilized in field trials.
Target genes may be inactivated by integration of a transposable element. Such inactivation is usually the consequence of transcriptional interruption or of a negative polar effect on the expression of genes located downstream (15, 20). In this report, we describe the isolation and characterization of an S. aureus strain with a Tn917 insertion mutation in the aroA gene. Whereas aromatic amino acid-dependent mutants of other gram-positive bacteria were constructed by transposon mutagenesis (1, 27, 53), this is the first report of an attenuated aro mutant of S. aureus that is evaluated for its protective efficacy as a potential vaccine. The aro mutants are auxotrophs for aromatic amino acids, PABA (a precursor of folic acid), and DHB (a precursor for ubiquinone). S. aureus FB306 is phenotypically an aro mutant, because it proliferates only in minimal medium supplemented with Trp, Phe, and Tyr as well as PABA and DHB. The auxotrophic phenotype of mutant FB306 was stable both in vitro and in vivo. Indeed, its reversion frequency was <2 x 10–14. This result is consistent with previous observations concerning the effect of Tn917 as a chromosomal mutagen: precise excision of insertions is extremely rare, and deletions occur in about 10% of the insertion events (51). Finally, the idea that an undefined point mutation selected at 42°C (pTV1ts curing temperature) could have been responsible for the FB306 mutant aro auxotrophic phenotype might be hypothesized. In our experience, however, point mutations in S. aureus have a reversion frequency in the range from 10–6 to 10–8, much higher than the value of less than 2 x 10–14 observed in this study. This finding makes unlikely that a potential point mutation could have been responsible for the aro auxotrophic phenotype found in S. aureus FB306.
The FB306 mutant erythromycin marker was mobilized into the wild-type strain RN6390 by using phage 11, and the same auxotrophic phenotype was observed. It is suggested, therefore, that the dependence of aromatic amino acids, as well as PABA and DHB, of the FB306 mutant was due to Tn917 insertion. Southern blot analysis of FB306 mutant DNA digested with EcoRI exhibited one hybridizing band, which indicated that a single copy of the transposon was inserted into the chromosome. The site of the Tn917 insertion was confirmed by sequence analysis. The transposon interrupted the aroA gene (756 bp downstream from start codon), which codes for the 3-phosphoshikimate 1-carboxyvinyltransferase of the chorismic acid biosynthesis pathway (39). The identified nucleotide sequence was 98 to 99% identical to the aroA S. aureus published sequences. These deviations could be due to strain variation. Moreover, genetic complementation confirmed that the lesion in aroA was responsible for the phenotype observed in the FB306 aroA mutant. While aroA is the last gene in the aroCBA operon, there is a gene immediately downstream of aroA whose function is unknown but is similar to that coding Bacillus subtilis hypothetical protein YpiA (GenBank). The location of ypiA is conserved in many organisms, indicating that it may be important to the aromatic acid pathway. Indeed, the genes involved in the shikimate pathway and folate, ubiquinone, and aromatic amino acid synthesis are known in many bacteria, fungal pathogens, and apicomplexan parasites (49). Whether ypiA is involved in any enzymatic step of the shikimate pathway or major branches from chorismate should be investigated.
We hypothesized that introduction of a nonreverting mutation into the S. aureus chromosome causing dependence on aromatic metabolites may result in an attenuated mutant which would have reduced ability to multiply in mammalian tissues. Our results showed that the aroA mutant was indeed attenuated, as demonstrated by an increase in its LD50 and increased survival of mice compared with those of the parental wild type. The results also demonstrated that the mutation in the 3-phosphoshikimate 1-carboxyvinyltransferase restricted the in vivo growth of the aroA mutant compared with the wild-type RN6390 S. aureus counterpart. Similar findings were reported in aroA mutants of Listeria monocytogenes (57), Bordetella bronchiseptica (7, 25, 34), Bordetella pertussis (50), Aeromonas salmonicida (60), Pasteurella multocida (26), and Yersinia enterocolitica (3). In contrast, Salmonella enterica serovar Typhimurium aroA mutants persisted for several weeks in the livers and spleens of orally infected mice (25, 32). Although milk is an excellent culture medium for many bacteria (4), the aroA mutant was much less efficient at colonizing the murine mammary gland compared with the wild-type parental RN6390 strain. It is likely that attenuation was due to starvation for essential aromatic metabolites rather than indirect effects on the expression of putative virulence factors.
Hemin-auxotrophic small-colony variants have been isolated from bovine S. aureus ima infections (54). These auxotrophic mutants can appear after apparently successful antimicrobial therapies (45). In view of these findings, it can be speculated that auxotrophic S. aureus could become a potential pathogen in the mammary gland, since small-colony variants frequently revert to the wild-type phenotype in vitro (33). Such would not be the case of the auxotrophic aro mutant described here, because its reversion frequency is extremely low and the nutritional requirement to restore the normal phenotype is not found in mammals, thus making its growth restricted in vivo. The latter is one of the facts that makes the use of an aro mutant as a potential vaccine attractive. Indeed, the S. aureus aroA mutant obtained in this study was cleared faster than the wild-type bacteria from different tissues (lung, spleen, and mammary gland) within a time frame suitable to make an S. aureus aroA mutant an attractive vaccine prospect.
It is generally accepted that attenuated strains are more potent than nonliving bacteria in stimulating immune responses (5). Indeed, live attenuated bacteria produce most of the antigens normally expressed during natural infection. An important issue of the study of auxotrophic mutants is to reach the right balance between attenuation and immunogenicity, since overattenuated bacteria may not produce certain key antigens necessary for the induction of protective immunity in vivo. A point of concern is the fact that an increase in the somatic cell count could be induced as a result of an S. aureus aroA mutant inoculation of cows. However, low levels of polymorphonuclear leukocytes and mononuclear cells and less damage were observed in the mammary gland after administration of the aroA mutant compared with the wild-type strain in the mouse mammary gland. Furthermore, in previous experiments, we have seen that the number of leukocytes was not increased in milk after ima administration of an attenuated S. aureus strain (23). Recently, Brouillette and Malouin (4) have demonstrated that after bacterial inoculation in the mouse mammary gland, polymorphonuclear infiltration, tissue damage, and S. aureus-host cell interactions are similar to those found in the bovine mammary gland. Therefore, even though certain differences may exist between murine and bovine hosts, the results obtained for mouse mammary gland infection may provide valid experimental data to support final testing of a vaccine strain in cows. In any event, the potential increase in the milk somatic cell counts needs to be assessed in cows immunized by the ima route using the desired auxotrophic S. aureus strain under construction.
The choice of the appropriate immunization route and scheme to obtain protective immune responses should be of concern (30), because it can determine failure or success of vaccination. In this regard, we demonstrated that ima but not i.p. application of live attenuated S. aureus strains stimulates murine mucosal responses against the wild type (21). In practice, ima administration of the vaccine in cows is laborious and needs trained personal. However, the efficacy of local immunization of cattle against Streptococcus uberis experimental ima challenge was demonstrated (18, 19). In the present study we utilized the same route of administration (ima) and immunization scheme defined in a previous study with temperature-sensitive mutants (23), and we were able to obtain significant protection after immunization with the aroA mutant. Interestingly, significant reduction in the number of CFU of virulent challenging S. aureus strains (RN6390 and MB319, both producers of hemolysins) was observed in the mammary glands of mice immunized with the aroA mutant. Moreover, ima immunization of mice with the S. aureus aroA mutant induced high levels of both IFN- and IL-4 transcripts in the mammary gland. In previous studies, we have demonstrated the feasibility of inducing Th1 and Th2 responses against S. aureus in the mouse mammary gland by local immunization with temperature-sensitive mutants of S. aureus during late pregnancy (22).
Raupach and Kaufmann observed that IFN- plays a central role in the early bacterial control of infection with Salmonella enterica serovar Typhimurium aroA strains (46). Previous evidence suggests that IFN- could elicit functional changes in phagocytic cells of the mammary gland that could make it effective in the control of bovine mastitis (56). Riollet et al. (48) have detected IFN- transcripts sporadically in cells derived from milk of cows immunized with alpha-hemolysin by ima injection. Conversely, IL-4 mRNAs were not detected in any of the samples at any time by the same authors. This observation suggests that an orientation towards a Th1-type response was induced by immunization with a single staphylococcal component, such as alpha-hemolysin. Ima immunization of mice with the aroA mutant under study induced high levels of both IFN- and IL-4 transcripts, which agrees with the fact that multiple antigens are involved in the adaptive response to a live attenuated vaccine. It can be speculated that although the S. aureus aroA mutant was able to grow poorly in vivo, it could still produce important virulence factors to induce an appropriate immune response. Interestingly, mice immunized with the S. aureus aroA mutant were protected from ima heterologous challenge with the most prevalent clone of S. aureus (MB319 strain) recovered from milk of cows with mastitis in Argentina (6). Since the genotypic background of the aroA mutant can be discriminated from those of bovine field isolates from the same region (7), our results support the performance of controlled field studies on isolated and small herds in Argentina to evaluate the protective efficacy of an aroA mutant.
This is the first time an aroA mutant of S. aureus was tested for its protective ability to be used as a vaccine. Although differences may exist between the bovine and murine mammary glands, the results of the present study may contribute to the rational design of a live attenuated vaccine to prevent mastitis caused by S. aureus in dairy cows.
ACKNOWLEDGMENTS
This work was supported in part by grants from ANPCyT (PICT 05/10648 and PICT 08/11740) and Universidad de Buenos Aires (UBACYT M-009), Buenos Aires, Argentina.
We thank Daniela Centron for help with DNA sequence analysis. We thank Ambrose L. Cheung (Dartmouth Medical School, Hanover, New Hampshire) for providing S. aureus strain RN6390 and plasmid pALC1743.
REFERENCES
1. Alexander, J. E., P. W. Andrew, D. Jones, and I. S. Roberts. 1993. Characterization of an aromatic amino acid-dependent Listeria monocytogenes mutant: attenuation, persistence, and ability to induce protective immunity in mice. Infect. Immun. 61:2245-2248.
2. Bentley, R. 1990. The shikimate pathway: a metabolic tree with many branches. Crit. Rev. Biochem. Mol. Biol. 25:307-384.
3. Bowe, F., P. O'Gaora, D. Maskell, M. Cafferkey, and G. Dougan. 1989. Virulence, persistence, and immunogenicity of Yersinia enterocolitica O:8 aroA mutants. Infect. Immun. 57:3234-3236.
4. Brouillette, E., and F. Malouin. 2005. The pathogenesis and control of Staphylococcus aureus-induced mastitis: study models in the mouse. Microbes Infect. 7:560-568.
5. Brown, F., G. Dougan, E. M. Hoey, S. J. Martin, B. K. Rima, and A. Trudgett. 1993. Vaccine design. John Wiley & Sons, Chichester, England.
6. Buzzola, F. R., L. Quelle, M. I. Gomez, M. Catalano, L. Steele-Moore, D. Berg, E. Gentilini, G. Denamiel, and D. O. Sordelli. 2001. Genotypic analysis of Staphylococcus aureus from milk of dairy cows with mastitis in Argentina. Epidemiol. Infect. 126:445-452.
7. Buzzola, F. R., L. S. Quelle, L. Steele-Moore, D. Berg, G. Denamiel, E. Gentilini, and D. O. Sordelli. 2001. Molecular diversity of live-attenuated prototypic vaccine strains and clinical isolates of Staphylococcus aureus. FEMS Microbiol. Lett. 202:91-95.
8. Carter, E. W., and D. E. Kerr. 2003. Optimization of DNA-based vaccination in cows using green fluorescent protein and protein A as a prelude to immunization against staphylococcal mastitis. J. Dairy Sci. 86:1177-1186.
9. Chamberlain, L. M., R. Strugnell, G. Dougan, C. E. Hormaeche, and R. Demarco de Hormaeche. 1993. Neisseria gonorrhoeae strain MS11 harbouring a mutation in gene aroA is attenuated and immunogenic. Microb. Pathog. 15:51-63.
10. Chandler, R. L. 1970. Experimental bacterial mastitis in the mouse. J. Med. Microbiol. 3:273-282.
11. Cheung, A. L., J. M. Koomey, C. A. Butler, S. J. Projan, and V. A. Fischetti. 1992. Regulation of exoprotein expression in Staphylococcus aureus by a locus (sar) distinct from agr. Proc. Natl. Acad. Sci. USA 89:6462-6466.
12. Cheung, A. L., K. Eberhardt, and J. H. Heinrichs. 1997. Regulation of protein A synthesis by the sar and agr loci of Staphylococcus aureus. Infect. Immun. 65:2243-2249.
13. Chomczynski, P., and N. Sacchi. 1987. Single-step method of RNA isolation by acid guanidinium thiocyanate-phenol-chloroform extraction. Anal. Biochem. 162:156-159.
14. Crist, W. L., R. J. Harmon, J. O'Leary, and A. J. McAllister. 20 February 2006, posting date. Mastitis and its control. Cooperative Extension Service, University of Kentucky College of Agriculture. Publication ASC-140. [Online.] http://www.ca.uky.edu/agc/pubs/asc/asc140/asc140.pdf.
15. Dobinsky, S., K. Bartscht, and D. Mack. 2002. Influence of Tn917 insertion of transcription of the icaADBC operon in six biofilm-negative transposon mutants of Staphylococcus epidermidis. Plasmid 47:10-17.
16. Dougan, G., S. Chatfield, D. Pickard, J. Bester, D. O'Callaghan, and D. Maskell. 1988. Construction and characterization of vaccine strains of Salmonella harboring mutations in two different genes. J. Infect. Dis. 158:1329-1335.
17. Fetrow, J. 2000. Mastitis: an economic consideration, p. 3-47. In Proceedings of the 29th Annual Meeting of the National Mastitis Council, Atlanta, Ga. National Mastitis Council, Madison, Wis.
18. Finch, J. M., A. W. Hill, T. R. Field, and J. A. Leigh. 1994. Local vaccination with killed Streptococcus uberis protects the bovine mammary gland against experimental intramammary challenge with the homologous strain. Infect. Immun. 62:3599-3603.
19. Finch, J. M., A. Winter, A. W. Walton, and J. A. Leigh. 1997. Further studies on the efficacy of a live vaccine against mastitis caused by Streptococcus uberis. Vaccine 10:1138-1143.
20. Galas, D. J., and M. Chandler. 1989. Bacterial insertion sequences, p. 109-162. In E. B. Berg and M. M. Howe (ed.), Mobile DNA. American Society for Microbiology, Washington, D.C.
21. García, V. E., M. I. Gomez, M. F. Iglesias, N. Sanjuan, M. M. Gherardi, M. C. Cerquetti, and D. O. Sordelli. 1996. Intramammary immunization with live-attenuated Staphylococcus aureus: microbiological and immunological studies in a mouse mastitis model. FEMS Immunol. Med. Microbiol. 14:45-51.
22. Gomez, M. I., D. O. Sordelli, F. R. Buzzola, and V. E. García. 2002. Induction of cell-mediated immunity to Staphylococcus aureus in the mouse mammary gland by local immunization with a live attenuated mutant. Infect. Immun. 70:4254-4260.
23. Gomez, M. I., V. E. García, M. M. Gherardi, M. C. Cerquetti, and D. O. Sordelli. 1998. Intramammary immunizations with live-attenuated Staphylococcus aureus protects mice from experimental mastitis. FEMS Immunol. Med. Microbiol. 20:21-27.
24. Grüter, L., H. Feucht, M. Mempel, and R. Laufs. 1993. Construction of a slime negative transposon mutant in Staphylococcus epidermidis using the Enterococcus faecalis transposon Tn917. Microbiol. Immunol. 37:35-40.
25. Hoiseth, S. K., and B. A. D. Stocker. 1981. Aromatic-dependent Salmonella typhimurium are non-virulent and effective as live vaccines. Nature 291:238-239.
26. Homchampa, P., R. A. Strugnell, and B. Adler. 1992. Molecular analysis of the aroA gene of Pasteurella multocida and vaccine potential of constructed aroA mutants. Mol. Microbiol. 8:3585-3593.
27. Ivins, B. E., S. L. Welkos, G. B. Knudson, and S. F. Little. 1990. Immunization against anthrax with aromatic compound-dependent (AroA–) mutants of Bacillus anthracis and with recombinant strains of Bacillus subtilis that produce anthrax protective antigen. Infect. Immun. 58:303-308.
28. Khal, B. C., M. Goulian, W. V. Wamel, M. Herrmann, S. M. Simon, G. Kaplan, G. Peters, and A. L. Cheung. 2000. Staphylococcus aureus RN6390 replicates and induces apoptosis in a pulmonary epithelial cell line. Infect. Immun. 68:5385-5392.
29. Leitner, G., E. Lubachevsky, E. Glikman, M. Winkler, A. Saran, and Z. Trainin. 2003. Development of a Staphylococcus aureus vaccine against mastitis in dairy cows. I. Field trial. Vet. Immunol. Immunopathol. 93:31-38.
30. Leitner, G., B. Yadlin, A. Glickman, M. Chaffer, and A. Saran. 2000. Systemic and local immune response of cows to intramammary infection with Staphylococcus aureus. Res. Vet. Sci. 69:181-184.
31. Maniatis, T., E. F. Fritsch, and J. Sambrook. 1982. Molecular cloning: a laboratory manual. Cold Spring Harbor Laboratory Press, Cold Spring Harbor, N.Y.
32. Maskell, D., K. J. Sweeney, D. O'Callaghan, C. E. Hormaeche, F. Y. Liew, and G. Dougan. 1987. Salmonella typhimurium aroA mutants as carriers of the Escherichia coli heat-labile enterotoxin B subunit to the murine secretory and systemic immune systems. Microb. Pathog. 2:211-220.
33. Massey, R. C., A. Buckling, and S. J. Peacock. 2001. Phenotypic switching of antibiotic resistance circumvents permanent costs in Staphylococcus aureus. Curr. Biol. 11:1810-1814.
34. McArthur, J. D., N. P. West, J. N. Cole, H. Jungnitz, C. A. Guzman, J. Chin, P. R. Lehrbach, S. P. Djordjevic, and M. J. Walker. 2003. An aromatic amino acid auxotrophic mutant of Bordetella bronchiseptica is attenuated and immunogenic in a mouse model of infection. FEMS Microbiol. Lett. 221:7-16.
35. Mei, J., F. Nourbakhsh, C. Ford, and D. Holden. 1997. Identification of Staphylococcus aureus virulence genes in a murine model of bacteraemia using signature-tagged mutagenesis. Mol. Microbiol. 26:399-407.
36. Michie, C. A. 2002. Staphylococcal vaccines. Trends Immunol. 23:461-463.
37. National Research Council. 1996. Guide for the care and use of laboratory animals (NIH guide, revised). National Academy Press, Washington, D.C.
38. O'Callaghan, D., D. Maskell, F. Y. Liew, C. S. F. Easmon, and G. Dougan. 1998. Characterization of aromatic- and purine-dependent Salmonella typhimurium: attenuation, persistence, and ability to induce protective immunity in BALB/c mice. Infect. Immun. 56:419-423.
39. O'Connell, C., P. Pattee, and T. J. Foster. 1993. Sequence and mapping of the aroA gene of Staphylococcus aureus 8325-4. J. Gen. Microbiol. 139:1449-1460.
40. Oyston, P. C. F., P. Russell, D. Williamson, and R. W. Titball. 1996. An aroA mutant of Yersinia pestis is attenuated in guinea-pigs, but virulent in mice. Microbiology 142:1847-1853.
41. Parish, T., and N. G. Stoker. 2002. The common aromatic amino acid biosynthesis pathway is essential in Mycobacterium tuberculosis. Microbiology 148:3069-3077.
42. Patee, P. A., and S. Neveln. 1975. Transformation analysis of three linkage groups in Staphylococcus aureus. J. Bacteriol. 124:201-204.
43. Pitcher, D., N. Saundres, and R. Owen. 1989. Rapid extraction of bacterial genomic DNA with guanidium thiocyanate. Lett. Appl. Microbiol. 8:151-153.
44. Priebe, G. P., M. M. Brinig, K. Hatano, M. Grout, F. T. Coleman, G. B. Pier, and J. B. Goldberg. 2002. Construction and characterization of a live, attenuated aroA deletion mutant of Pseudomonas aeruginosa as a candidate intranasal vaccine. Infect. Immun. 70:1507-1517.
45. Proctor, R. A., O. Vesga, M. F. Otten, S. P. Koo, M. R. Yeamen, H. G. Sahl, and A. S. Bayer. 1996. Staphylococcus aureus small-colony variants cause persistent and resistant infections. Chemotherapy 42:47-52.
46. Raupach, B., and S. H. Kaufmann. 2001. Bacterial virulence, proinflammatory cytokines and host immunity: how to choose the appropriate Salmonella vaccine strain Microbes Infect. 3:1261-1269.
47. Reed, L. J., and H. Muench. 1938. A simple method for estimating fifty percent endpoints. Am. J. Hyg. 27:493-497.
48. Riollet, C., P. Rainard, and B. Poutrel. 2000. Kinetics of cells and cytokines during immune-mediated inflammation in the mammary gland of cows systemically immunized with Staphylococcus aureus alpha-toxin. Inflamm. Res. 49:486-496.
49. Roberts, C. W., F. Roberts, R. E. Lyons, M. J. Kirisits, E. J. Mui, J. Finnerty, J. J. Johnson, D. J. Ferguson, J. R. Coggins, T. Krell, G. H. Coombs, W. K. Milhous, D. E. Kyle, S. Tzipori, J. Barnwell, J. B. Dame, J. Carlton, and R. McLeod. 2002. The shikimate pathway and its branches in apicomplexan parasites. J. Infect. Dis. 185(Suppl. 1):S25-S36.
50. Roberts, M., D. Maskell, P. Novotny, and G. Dougan. 1990. Construction and characterization in vivo of Bordetella pertussis aroA mutants. Infect. Immun. 58:732-739.
51. Sandman, K., R. Losick, and P. Youngman. 1987. Genetic analysis of Bacillus subtilis spo mutations generated by Tn917-mediated insertional mutagenesis. Genetics 117:603-617.
52. Sanger, F., S. Nicklen, and A. R. Coulson. 1977. DNA sequencing with chain-terminating inhibitors. Proc. Natl. Acad. Sci. USA 74:5463-5467.
53. Simmons, C. P., A. L. M. Hodgson, and R. A. Strugnell. 1997. Attenuation and vaccine potential of aroQ mutants of Corynebacterium pseudotuberculosis. Infect. Immun. 65:3048-3056.
54. Sompolinsky, D., M. Cohen, and G. Ziv. 1974. Epidemiological and biochemical studies on thiamine-less dwarf-colony variants of Staphylococcus aureus as etiological agents of bovine mastitis. Infect. Immun. 9:217-228.
55. Sordelli, D. O., F. R. Buzzola, M. I. Gomez, L. Steele-Moore, D. Berg, E. Gentilini, M. Catalano, A. J. Reitz, T. Tollersrud, G. Denamiel, P. Jeric, and J. C. Lee. 2000. Capsule expression by bovine isolates of Staphylococcus aureus from Argentina: genetic and epidemiologic analyses. J. Clin. Microbiol. 38:846-850.
56. Sordillo, L. M., K. Shafer-Weaver, and D. DeRosa. 1997. Immunobiology of the mammary gland. J. Dairy Sci. 80:1851-1865.
57. Stritzker, J., J. Janda, C. Schoen, M. Taupp, S. Pilgrim, I. Gentschev, P. Schreier, G. Geginat, and W. Goebel. 2004. Growth, virulence, and immunogenicity of Listeria monocytogenes aro mutants. Infect. Immun. 72:5622-5629.
58. Tenhagen, B. A., D. Edinger, B. Baumgartner, P. Kalbe, G. Klunder, and W. Heuwieser. 2001. Efficacy of a herd-specific vaccine against Staphylococcus aureus to prevent post-partum mastitis in dairy heifers. J. Vet. Med. Ser. A 48:601-607.
59. Ulett, G. C., N. Ketheesan, and R. G. Hirst. 2000. Cytokine gene expression in innately susceptible BALB/c mice and relatively resistant C57BL/6 mice during infection with virulent Burkholderia pseudomallei. Infect. Immun. 68:2034-2042.
60. Vaughn, L. M., P. R. Smith, and T. J. Foster. 1993. An aromatic-dependent mutant of the fish pathogen Aeromonas salmonicida is attenuated in fish and is effective as a live vaccine against the salmonid disease furunculosis. Infect. Immun. 61:2172-2182.
61. Waldvogel, F. A. 2000. Staphylococcus aureus, p. 2069-2092. In G. L. Mandell, J. E. Bennett, and R. Dolin (ed.), Principles and practice of infectious disease. Churchill Livingstone, Philadelphia, Pa.
62. Walker, J. C., and N. K. Verma. 1997. Cloning and characterization of the aroA and aroD genes of Shigella dysenteriae type 1. Microbiol. Immunol. 41:809-813.
63. Yancey, R. J., Jr. 1999. Vaccines and diagnostic methods for bovine mastitis: fact and fiction. Adv. Vet. Med. 41:257-273.
64. Youngman, P. 1985. Plasmid vectors for recovering and exploiting Tn917 transpositions in Bacillus and other gram-positive bacteria, p. 79-104. In K. G. Hardy (ed.), Plasmids: a practical approach. IRL Press, Oxford, England.(Fernanda R. Buzzola, Marí)