Poly-N-Acetylglucosamine Production in Staphylococcus aureus Is Essential for Virulence in Murine Models of Systemic Infection

The contribution of the Staphylococcus aureus surface polysaccharidepoly-N-acetylglucosamine (PNAG) to virulence was evaluated inthree mouse models of systemic infection: bacteremia, renalabscess formation, and lethality following high-dose intraperitoneal(i.p.) infection. Deletion of the intercellular adhesin (ica)locus that encodes the biosynthetic enzymes for PNAG productionin S. aureus strains Mn8, Newman, and NCTC 10833 resulted inmutant strains with significantly reduced abilities to maintainbacterial levels in blood following intravenous or i.p. injection,to spread systemically to the kidneys following i.p. injection,or to induce a moribund/lethal state following i.p. infection.In the bacteremia model, neither growth phase nor growth mediumused to prepare the S. aureus inoculum affected the conclusionthat PNAG production was needed for full virulence. As the SarAregulatory protein has been shown to affect ica transcription,PNAG synthesis, and biofilm formation, we also evaluated S.aureus strains Mn8 and 10833 deleted for the sarA gene in therenal infection model. A decrease in PNAG production was seenin sarA mutants using immunoblots of cell surface extracts butwas insufficient to reduce the virulence of sarA-deleted strainsin this model. S. aureus strains deleted for the ica genes weremuch more susceptible to antibody-independent opsonic killinginvolving human peripheral blood leukocytes and rabbit complement.Thus, PNAG confers on S. aureus resistance to killing mediatedby these innate host immune mediators. Overall, PNAG productionby S. aureus appears to be a critical virulence factor as assessedin murine models of systemic infection.

INTRODUCTION

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Introduction

Staphylococcus aureus is well-known for its ability to elaboratea broad range of virulence factors that are thought to be keyto this organism's abilities to colonize, infect, and eventuallycause disease in a variety of host tissues. Among these factorsare bacterial proteins that bind to host extracellular matrixproteins that are referred to as MSCRAMMs (16, 65, 75); capsularpolysaccharides (CP) such as CP5 and CP8 (54); extracellulartoxins, hemolysins, and superantigens (36, 53, 62); proteinA (20); mediators of antibiotic resistance (26, 67); proteasesand lipases (11, 22); formation of biofilms (17, 59); and ironacquisition (45, 66, 70). Regulatory proteins also impact theproduction of virulence factors, with prominent systems includingthe products of the accessory gene regulator (agr) locus (39),the staphylococcal accessory regulator (sar) locus (6), proteinsencoded by two-component regulatory systems (4, 58), and transcriptionalfactors and their regulators, such as sigB and rsbU (29).

While acknowledging the multifactorial nature of S. aureus pathogenesis,typical virulence studies in animals for new virulence factorsusually evaluate changes in tissue levels of mutant strainscompared with parental controls or some change in lethality(3, 7, 54, 58). Such studies can be useful for determining theimpact of a virulence factor on the organism's overall abilityto cause disease, but often the evaluation must be done to takeaccount of the fact that many S. aureus virulence factors arepart of redundant systems. In these cases, loss of a singlefactor does not markedly change the virulence phenotype. Virulencestudies are sometimes coupled with investigations into the vaccinepotential of certain factors, with the expectation that if theloss of production of the vaccine antigen reduces virulencesufficiently, then escape mutants unable to elaborate the vaccinefactor are unlikely to emerge under selective pressure fromvaccine-induced immunity (23, 35, 44). Overall, finding antigensthat both contribute to virulence and serve as targets for protectiveimmunity in S. aureus could underscore the vaccine potentialof such factors.

Prior work has evaluated the vaccine potential of the poly-N-acetylglucosamine(PNAG) surface polysaccharide elaborated by S. aureus (42, 47-49)and Staphylococcus epidermidis (47, 51, 63) and also recentlyfound to be produced by Escherichia coli (74) and members ofthe genus Actinobacillus (30). Enzymes encoded by the intercellularadhesin (ica) locus are responsible for synthesis of staphylococcalPNAG (8, 24, 49; reviewed in reference 21), and the polysaccharidehas also been referred to as the capsular polysaccharide/adhesinof S. epidermidis (50, 51, 69) and polysaccharide intercellularadhesin (PIA) (40, 41) and mistakenly referred to as a poly-N-succinylglucosamine (PNSG) molecule (47, 49). Clinical isolates of S.epidermidis are more likely to carry the ica genes than arecommensal strains (51, 77), and among isolates of S. aureus,the ica locus was one of seven genes found to be more frequentlypresent in invasive strains than in commensal isolates fromhealthy blood donors (56). Deletion of the ica locus in S. epidermidisdecreases virulence in models of foreign-body or device-relatedinfection when bacteria are inoculated onto freshly implantedforeign bodies (60, 61) but not when inoculated onto foreignbodies that had been resident in animal tissues for 2 weeksprior to infection (15). Deletion of the ica locus in S. aureusfailed to alter virulence in rats or mice when bacteria wereinoculated into tissue cages implanted 2 weeks prior to infection(15, 18, 34). Other types of studies with ica-deleted strainsof S. aureus have not been reported.

Therefore, we evaluated the contribution of PNAG to virulenceof S. aureus using outcomes wherein systemic spread of the organismwould be a key component of the pathological outcomes. Thesemodels would require that PNAG contribute to resistance to hostinnate phagocytic capabilities, as opposed to contributing tobiofilm formation on an implanted foreign body. In the seriesof experiments reported here, we evaluated the effect on virulenceof loss of the ica locus in three different S. aureus strainsusing murine models of bacteremia, renal infection, and lethality.Furthermore, because the sarA locus has been found to regulatetranscription of the ica locus and PNAG production in vitro(1, 72) and the SarA protein binds to the promoter of the icalocus (28), we evaluated the virulence of two of the strainsdeleted for the sarA locus in the murine model of renal infection.Overall, we found that complete loss of the ica locus and inabilityto produce PNAG severely compromised the virulence of all threeS. aureus strains in all three models of infection, whereaspartial reduction of PNAG production in strains deleted forthe sarA locus had no impact on the virulence of S. aureus inthe renal infection model.

MATERIALS AND METHODS

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Materials and Methods

Bacterial strains. The characteristics of the strains used are shown in Table 1.Staphylococcus aureus strain NCTC 10833 (referred to as 10833hereafter) (ATCC 25904) is a CP-negative, clumping factor-positivevariant of a throat swab isolate. S. aureus strain Mn8 is aCP8 clinical isolate originally obtained from a patient withtoxic shock syndrome (33) and kindly provided by Patrick Schlievert,Minneapolis, MN. S. aureus strain Newman is a CP5 strain thathas been used for many virulence studies of S. aureus (12, 46,55) and was kindly provided by Timothy Foster, Dublin, Ireland.Capsule serotypes were confirmed by Robert Solinga in the laboratoryof Jean Lee, Boston, MA, using immunodiffusion (54).

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TABLE 1. Bacterial strains used in this study

The ica locus was replaced with a tetracycline (Tet) resistancecassette by homologous recombination as described previously(8, 27) in S. aureus strains 10833, Mn8, and Newman to produceS. aureus strains 10833ica::tet, MN8ica::tet, and Newman ica::tet,respectively, but referred to as ${Delta}$ ica strains. All of the ica::tetstrains were complemented with the intact chromosomal ica locusby homologous recombination. Briefly, the ica::tet strains weretransformed with plasmid pWT, which was constructed as previouslydescribed (27) by inserting the cloned ica locus from S. aureusstrain MN8 into the temperature-sensitive shuttle vector pBT9(5). Transformants were subcultured twice in tryptic soy broth(TSB) at 42°C in the presence of chloramphenicol (Cm) toselect for chromosomal integration of the plasmid. Integrantswere subcultured twice in TSB at 30°C in the absence ofantibiotics to promote excision of the pBT9 plasmid and retentionof the ica locus and then grown on tryptic soy agar (TSA) withoutantibiotics. Single colonies were replica plated onto TSA withoutantibiotics and TSA containing 5 µg Tet/ml or 5 µgchloramphenicol (Cm)/ml. Tet/Cm-sensitive colonies were analyzedby PCR for the presence of the intact ica locus and assessedfor production of PNAG as described below. S. aureus strainALC1342, which has the sarA locus from S. aureus strain RN6390replaced by an erythromycin cassette (76), was kindly providedby Ambrose Cheung, Hanover, NH. The mutation was transducedto strains Mn8 and 10833 using phage 80 (28), and loss of thesarA locus in erythromycin-resistant transductants was confirmedby PCR analysis.

Production of PNAG. Synthesis of the PNAG polysaccharide by the strains in thisstudy was assessed using a semiquantitative immunoblot methodas described previously (9) with some modifications. Approximately5 x 10⁹ CFU from 5 ml of overnight cultures grown in TSB plus1% glucose was collected by centrifugation, and the cell pelletswere resuspended in 250 µl 0.5 M EDTA and then boiledfor 5 min. The cells were removed by centrifugation, and thecleared surface extract was treated with 1 mg proteinase K/mlat 65°C for 30 min, after which the protease was inactivatedby boiling for 5 min. The material in 200 µl of surfaceextracts, either undiluted or diluted 1:10 in Tris-bufferedsaline, was immobilized on nitrocellulose using a slot blotvacuum manifold. The blots were blocked with 5% bovine serumalbumin and probed with 200 ng/ml of a goat antibody raisedto a conjugate of deacetylated PNAG (dPNAG) and diphtheria toxoid(43) and affinity purified on a column of immobilized dPNAGas described previously (31). After the blots were washed, theywere treated with a 1:10,000 dilution of swine anti-goat antibodyconjugated to horseradish peroxidase. Immunoreactive bands weredetected using the enhanced chemiluminescent reagent (AmershamBiosciences, Piscataway, NJ) and visualized on autoradiographicfilm.

Preparation of bacteria for animal studies. For the bacteremia studies, S. aureus strains were grown onTSA plates overnight and inoculated the next morning into TSBto achieve an optical density of 0.1 (optical density at 650nm [OD₆₅₀]). The cultures were incubated on a rotor rack at37°C until an OD₆₅₀ of 0.4 was reached. Bacteria were washedonce with sterile saline, resuspended in phosphate-bufferedsaline (PBS) to predetermined optical densities, and kept onice until injected into the animals. The actual inocula wereverified by viable counts. The inocula used were between 4.5x 10⁷ and 5.0 x 10⁸ CFU/mouse.

For some of the bacteremia studies, strain Newman was grownovernight at 37°C on Columbia salt agar plates, then suspendedin 2% NaCl, and adjusted to the appropriate challenge dose byOD measurements. The inocula were verified by viable counts.

For the two infection studies initiated by i.p. injection, bacteriawere grown overnight on TSA plates and suspended in PBS to anOD of 0.4 ( $~$ 2.5 x 10⁹ CFU/ml).

Animal experiments. Female Swiss-Webster mice (5 to 7 weeks old) were obtained fromCharles River Laboratories (Kingston, MA). Female and male inbredFVB mice (4 to 6 weeks old) were obtained from Jackson Laboratory(Bar Harbor, ME).

For the bacteremia studies, Swiss-Webster mice were infectedby i.v. injection of 0.2 ml of bacteria and sacrificed after2 and 4 h. A sample of 0.5 ml blood was obtained by using asterile heart stick, mixed with 20 µl of heparin (Sigma),and plated onto TSA plates. Bacteremia was quantified by colonycounts after overnight growth plated from duplicate samples.The lower limit of detection was 2 CFU/ml of blood. Sampleswith no bacterial colonies were assigned a value of 1 CFU forpurposes of statistical analysis.

For the renal abscess model, Swiss-Webster mice were injectedi.p. with 0.2 ml of a suspension of bacteria adjusted to contain5 x 10⁸ CFU of each strain in the inoculum. Plate counts verifiedthe actual infectious dose, and all were within 5% of this target.After 5 days the animals were sacrificed and their kidneys wereremoved, weighed, and homogenized for determination of bacterialCFU/g kidney following dilution and plating. Dilutions weremade in TSB containing 0.05% Tween to prevent bacterial adherenceto the pipette tips and walls of the dilution vessels.

For the lethality model, 4- to 6-week-old inbred FVB mice wereused, as mice of this strain and age have been found to be moresusceptible to S. aureus infection by the i.p. route (T. Maira-Litranand G. B. Pier, unpublished observation). The mice were injectedi.p. with $~$ 5 x 10⁸ to 1 x 10⁹ CFU S. aureus strains in 0.2 mlPBS. Mice were monitored twice daily for signs of illness, andwhen they were moribund, as determined by an inability to moveupon repeated stimulus, inability to right itself after beingplaced on its side, piloerection, rapid respiration, and overallappearance of illness associated with imminent death, the animalswere humanely sacrificed and counted as dead for the outcomesin this experiment. Mice that expired in between observationswere also counted as lethal events for data analysis.

Opsonophagocytic assay. Analyses of the susceptibility of ica-deleted, sarA-deletedwild-type (WT) and ica-deleted then ica-complemented strainsto the opsonic killing activities of human polymorphonuclearneutrophils (PMN) and different concentrations of complement(infant rabbit serum; Accurate Chemical and Scientific, Westbury,NY) were carried out as described previously (42). All componentswere prepared in RPMI medium containing 15% fetal calf serum(HyClone, Logan, UT). Briefly, a 100 µl suspension ofbacteria at 2 x 10⁷ to 4 x 10⁷ CFU/ml was mixed with 100 µlof 2 x 10⁶ human leukocytes purified by dextran sedimentationand 100 µl of infant rabbit serum diluted from 1:5 to1:25, and this mixture was rotated for 90 min at 37°C. SurvivingCFU were determined by dilution and plating for bacterial enumeration.Survival was calculated in comparison to the mean number ofCFU surviving in tubes without PMN or without complement.

Statistical analysis. Statistical significance for two-way comparisons was determinedby an unpaired t test. Analysis of variance (ANOVA) for multigroupcomparisons was used on log-transformed data, and the Tukey'smultiple-comparison test was used for posthoc analysis for pairwisecomparisons. Results from Fisher's exact test were calculatedin a Microsoft Excel spreadsheet containing the appropriateformula. Remaining statistical results were calculated usingthe Prism 3 software package on a Macintosh computer.

RESULTS

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Results

PNAG production by S. aureus strains. We evaluated the production of PNAG by the three S. aureus strainsand their ${Delta}$ ica and ica-complemented isogenic variants, as wellas by the two strains deleted for the sarA gene that we used.Using a semiquantitative immunoblot method (Fig. 1), we showedthat the ${Delta}$ ica strains made no detectable PNAG, the ica-complementedstrains made WT levels of PNAG, and the ${Delta}$ sarA strains had reducedbut detectable synthesis of PNAG.

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FIG. 1. Immunoblot analysis of PNAG expression by strains of S. aureus (listed along the left-hand side of the blot) evaluated in animal models of infection. Undiluted and 1:10 diluted boiled EDTA extracts from 5 x 10⁹ cells were applied by a vacuum manifold to the membrane which was probed with 200 ng/ml of affinity-purified goat antibody raised to a conjugate of dPNAG and diphtheria toxoid (43) followed by swine anti-goat immunoglobulin G conjugated to horseradish peroxidase.

Reduced levels of ${Delta}$ ica strains in the blood of i.v. infected mice. We first evaluated the ability of three strains of S. aureuswith serotype CP5 (Newman), CP8 (Mn8), or CP-nontypeable (10833)isolates with intact or deleted ica loci for their ability tobe cleared from mouse blood 2 and 4 h after intravenous (i.v.)injection. As shown in Fig. 2, at both 2 and 4 h postinjection,the strains deleted for the ica genes had significantly (P <0.05) reduced blood levels compared to both the WT and ica-complementedstrains. There was no significant difference (P > 0.05) betweenthe blood levels of the WT or complemented strains. Table 2shows the results of a comparison of the proportion of animalswith any detectable S. aureus in their blood (i.e., documentedbacteremia) with those that had no detectable bacteria in theirblood samples (<2 CFU/ml). Although there were reduced proportionsof animals with documented bacteremia in all groups challengedwith ${Delta}$ ica strains, the proportion was significantly lower comparedto the WT parental strain only in strain 10833 at 4 h postinfectionand strain Mn8 at both 2 and 4 h postinfection. However, forstrain Newman at both 2 h and 4 h postinfection, two of themice in each of the ${Delta}$ ica groups had only 1 CFU on the blood cultureplate (2 CFU/ml blood), meaning that four of eight mice in the ${Delta}$ ica groups had $≤$ 2 CFU/ml blood, compared with all eight WT orica-complemented mice with $≥$ 3 CFU/ml blood. Using this as a basisfor comparing rates of bacteremia, a P value of 0.038 (Fisher'sexact test) is achieved. Thus, when analyzing all six of thecomparisons of S. aureus ${Delta}$ ica strains with their isogenic WTcounterparts (Fig. 1), five of the six comparisons showed significantlyreduced rates of bacteremia ( $≤$ 2 CFU/ml compared to $≥$ 3 CFU/ml)in an evaluation of WT and ${Delta}$ ica S. aureus strains.

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FIG. 2. Comparison of CFU/ml of blood 2 and 4 h postinfection using three strains of S. aureus with either a WT ica locus, the ica locus deleted and replaced with a tetracycline resistance cassette ( ${Delta}$ ica), or with the WT ica locus placed back into the chromosome (complemented [Comp] strain) of the ${Delta}$ ica strain. Bars represent mean CFU/ml blood, error bars the standard deviations. Eight mice per group were used. The lower limit of detection is 2 CFU/ml. P values for strain 10833 represent pairwise comparisons between the ${Delta}$ ica strain and both the WT and Comp strains determined by Tukey's multiple-comparison test. Overall ANOVA for all three strains yielded a P value of <0.001. There was no significant difference (P > 0.05) in CFU/ml blood comparing any of the WT and isologous S. aureus Comp strains.

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TABLE 2. Proportion of mice with positive blood cultures ( $≥$ 2 CFU/ml) after infection under the indicated conditions with different strains of S. aureus

Previous reports indicated that demonstrating differences inthe virulence of WT and CP mutant strains of S. aureus in amouse bloodstream infection system, as well as the binding ofcomplement, are affected by the method of growth of the organisms(10, 68). To determine whether similar in vitro growth conditionsaffected the demonstration of a role for PNAG in S. aureus virulence,we compared the blood levels of ${Delta}$ ica and ica-complemented strainsof S. aureus Newman taken directly from a Columbia agar plateafter overnight growth, which enhances CP expression (68). Asshown in Fig. 3, at 2 h and 4 h postinjection the ${Delta}$ ica strainstill had significantly reduced blood levels compared with thecomplemented strain. The proportion of infected animals withdocumented bacteremia ( $≥$ 2 CFU/ml) following injection of bacteriagrown on Columbia salt agar medium is shown in Table 2. Alongthe same lines, because the route of injection could affectvirulence, we compared the blood levels of the complementedand ${Delta}$ ica S. aureus Newman strains 2 h and 4 h following i.p.injection of bacteria taken from log-phase growth in broth.The levels of the complemented strains in blood were lower whenthe strains were injected by the i.p. route compared to thei.v. route (Fig. 2), but again the ${Delta}$ ica strain had significantlyreduced levels in blood even following i.p. injection (Fig.3) and significantly reduced rates of bacteremia (Table 2).Overall, the ${Delta}$ ica strains had reduced levels in the blood ofmice 2 h and 4 h postinjection regardless of whether the bacteriawere injected i.p. or i.v., and growth on Columbia salt agarmedium to promote CP expression did not affect the virulenceof the ${Delta}$ ica mutant of S. aureus Newman.

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FIG. 3. Comparison of the method of growth of the challenge inoculum or the route of injection on the CFU/ml in blood 2 and 4 h postinfection achieved by S. aureus strain Newman either deleted for the ica locus ( ${Delta}$ ica) or with the WT ica locus placed back into the chromosome (complemented [Comp] strain). Bars represent mean CFU/ml blood, error bars the standard deviations. Eight mice per group were used. The lower limit of detection is 2 CFU/ml. P values were determined by t test.

Evaluation of the virulence of ${Delta}$ ica and ${Delta}$ sarA mutants of S. aureus strains in a renal infection model. We next analyzed the virulence of the WT, ${Delta}$ ica, and ica-complementedvariants of S. aureus Mn8, Newman, and 10833 in a renal infectionmodel by measuring the levels of bacteria in the kidneys 5 daysafter i.p. infection with $~$ 5 x 10⁸ CFU/mouse. As shown in Fig.4, for all three of the ${Delta}$ ica variants, the levels of bacteriain the kidneys were significantly reduced or undetectable comparedto the WT and ica-complemented strains. For strain Mn8, noneof eight mice had detectable ${Delta}$ ica mutant bacteria in their kidneys,and for strain 10833, five of eight mice infected with the ${Delta}$ icamutant had apparently sterile kidneys. For strain Newman, whilefive of six mice infected with the ${Delta}$ ica mutant had detectablebacteria in their kidneys, the numbers were quite low, withless than 1,000 CFU/gram measured. In contrast, surviving miceinfected with the WT or ica-complemented strains had bacteriallevels ranging from 10,000 to 10,000,000 CFU/g kidney. The statisticalanalyses of these results are also shown in Fig. 4.

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FIG. 4. Comparison of CFU/g kidney 5 days after i.v. infection with $~$ 5 x 10⁸ CFU of three strains of S. aureus with either a wild-type (WT) ica locus ( ${blacklozenge}$ ), the ${Delta}$ ica strain with the WT ica locus placed back into the chromosome (complemented [Comp] strain) ( ${blacksquare}$ ), or the ${Delta}$ ica strain ( ${blacktriangleup}$ ). For S. aureus strains MN8 and 10833, we also performed infections with the sarA::erm strain ( ${Delta}$ sarA) (•). Each point is the result from one mouse. The lower limit of detection is 10 CFU/g kidney. Kidneys in mice found dead were not analyzed for CFU/g due to postmortem effects on bacterial levels. Overall ANOVA for results with all three strains gave a P value of <0.001. The results of pairwise comparisons for each strain using Tukey's multiple-comparison test are shown. P values of <0.05 are highlighted in boldface type.

As the dose of the WT and ica-complemented S. aureus strainsinjected into the mice to cause renal infections was lethalfor a proportion of the animals, we also analyzed lethal outcomes,comparing the combined results of mice infected with all threeWT and ica-complemented strains with the results of mice infectedwith all three of the ${Delta}$ ica mutants. Overall, 17 of 48 (35%) miceinfected with the WT or ica-complemented strains died, comparedwith 0 of 22 mice infected with the ${Delta}$ ica mutants (P = 0.0005,Fisher's exact test).

Because SarA has been reported both to bind to the ica promoter(28) and to promote ica transcription and biofilm formationin S. aureus (1, 72), we investigated the virulence of ${Delta}$ sarAmutants of S. aureus strains Mn8 and 10833 in the renal infectionmodel. The levels of these mutants in the kidneys 5 days afteri.p. injection were not significantly reduced compared to thelevels of either WT or ica-complemented S. aureus strains (Fig.4). The ${Delta}$ sarA strains were recovered from the kidneys at significantlyhigher levels than the ${Delta}$ ica strains were (Fig. 4). Thus, althoughthe ${Delta}$ sarA mutants of S. aureus Mn8 and 10833 showed somewhatreduced production of PNAG (Fig. 1), this reduction was insufficientto affect virulence, consistent with other reports that strainsin which only sarA was deleted maintain virulence in a kidneyinfection model (6, 7).

Effect of deleting the ica locus on virulence of S. aureus in a high-dose i.p. injection model. As a third determination of the roles of the ica locus and PNAGproduction in virulence, we examined lethality following i.p.injection of inbred 4- to 6-week-old FVB mice with ${Delta}$ ica mutantand ica-complemented S. aureus strains. Preliminary analysisindicated that in these mice, as well as strain A/J mice, a1-log-unit-lower dose of S. aureus was needed for a lethal infectionin most of the mice compared to the lethal doses determinedfor outbred Swiss-Webster mice and inbred BALB/c, C3H/HeN, C57BL/6,and SJ/L mice (T. Maira-Litran and G. B. Pier, unpublished observations).As shown in Table 3, for all three S. aureus strains injectedi.p. at a dose of $~$ 5 x 10⁸ –10⁹ CFU, survival rates wereonly 0 to 12.5% in animals injected with the ica-complementedstrains versus 83.3% to 100% survival in mice injected withthe ${Delta}$ ica strains.

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TABLE 3. Comparison of the lethality of ica-complemented and ${Delta}$ ica strains of S. aureus following i.p. injection into FVB mice

Role of PNAG in S. aureus resistance to complement-mediated phagocytosis. In S. epidermidis it has been shown that loss of PNAG productionleads to increased sensitivity to antibody-independent opsonophagocytosisby white blood cells (64, 73). To determine whether the samemechanism is operative in S. aureus, where production of othercapsular polysaccharides could compensate for loss of PNAG synthesis,we analyzed the susceptibility to killing by complement andhuman phagocytes of WT, ica-complemented, ${Delta}$ ica, and ${Delta}$ sarA S. aureusstrains. As shown in Fig. 5, all three ${Delta}$ ica mutant strains weremuch more readily killed, particularly in the presence of thehighest complement concentrations tested, whereas the WT, ica-complemented,and ${Delta}$ sarA strains were clearly less susceptible to complement-mediatedphagocytic killing. Notably, the two ica-deleted strains withclassic S. aureus CP, Mn8 (CP8), and Newman (CP5), were somewhatmore resistant to complement-mediated opsonic killing than wasthe ica-deleted unencapsulated strain 10833, as this strainwas killed by all concentrations of complement tested.

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FIG. 5. Susceptibility of WT, ica-complemented (Comp), ${Delta}$ ica (ica–) and ${Delta}$ sarA (sarA–) strains of S. aureus to opsonic killing mediated by various concentrations of infant rabbit serum as a source of complement.

DISCUSSION

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Discussion

The virulence properties of S. aureus are clearly multifactorial,involving a large array of surface and secreted factors encompassinga range of biochemical entities, including proteins, polysaccharides,peptidoglycans, and teichoic acids. Production of virulencefactors is regulated by complex genetic interactions whose propertiesare only minimally understood at present (4, 6, 14, 19). Thus,there is usually not a global or complete loss of virulencewhen a single factor is interrupted, and the effects on virulenceof loss of single genes or single genetic loci are quite contextual,depending on the S. aureus strain, the animal system, the tissueinfected, and the outcome measured (57). With these caveats,we consistently found, in three mouse models of infection, usingthree divergent S. aureus strains, that the loss of PNAG viadeletion of the ica locus had a profound effect on virulence.The ${Delta}$ ica bacterial mutants were poorly able to sustain bacteremiain blood, poorly able to disseminate from the peritoneum tothe kidney, and unable to mediate lethal events following high-doseperitoneal infection. Overall, our results indicate that PNAGproduction by S. aureus is important for high-level virulencein murine models of systemic infection, likely due to PNAG protectingthe bacterial cells from innate host defenses, encompassingphagocytes and complement.

It should be noted that chromosomally complemented strains hadto be used, since many S. aureus plasmids containing antibioticresistance genes that are used for transcomplementation cannotbe maintained in vivo, even with antibiotic selection (2). Also,most plasmids used for S. aureus complementation are multicopyplasmids (12) which could result in increased transcriptionof the ica genes which leads to increased production of PNAG(27, 72). This would likely affect experimental outcomes, ashappened in a study on the role of clumping factor B (ClfB)in a rat model of endocarditis (12), wherein there was no differencein virulence between a WT and ClfB mutant but overexpressionof clfB from a multicopy plasmid resulted in increased virulence.Although achieving a WT phenotype by chromosomal complementationof the initial ${Delta}$ ica strains ensured that no secondary mutationswere introduced during strain manipulations, we cannot totallyexclude the possibility that the tet gene inserted into the ${Delta}$ ica strains did not have an effect on transcription of othergenes that might have impacted the phenotypes seen here withthe ${Delta}$ ica strains.

Prior studies in S. epidermidis on strains unable to producePNAG indicated a loss of virulence in models of both systemicinfection (63, 64) and local, foreign-body-related infection(60, 61, 71). However, in S. aureus, interruption of the icalocus did not materially affect pathogenesis in rat or mousemodels of foreign-body infection (15, 18, 34). Thus, there appearsto be some differences in the role PNAG plays in S. epidermidisversus S. aureus foreign-body infection. In addition, we alsofound that even though SarA is a transcriptional activator ofica, production of PNAG is not dependent enough on SarA to rendera sarA mutant deficient in virulence to the same degree as isloss of the ica locus. The reduced amount of PNAG made by ${Delta}$ sarAstrains appears to be sufficient for S. aureus to maintain resistanceto host defenses and retain essentially WT levels of virulencein the mouse renal infection model used to compare the pathogenesisof ${Delta}$ ica and ${Delta}$ sarA strains to WT S. aureus Mn8 and Newman strains.

Among S. aureus strains, the most studied surface polysaccharidesare the CP5 and CP8 antigens (54), chemically related but immunologicallydistinct polymers that have been shown to play important rolesin S. aureus virulence (13, 54). As with many bacterial capsularpolysaccharides, S. aureus CP antigens appear to protect thebacterial cells from innate immunity mediated by complementand phagocytes (10, 54, 68), similar to what we report in thiswork for PNAG expression. These results suggest both CP expressionand PNAG expression may be needed for full resistance of S.aureus strains to innate immunity mediated by phagocytes andcomplement. Supporting this conclusion are the data generatedhere with the ica-deleted strains Mn8 (CP8) and Newman (CP5),which both retained more resistance to complement-mediated phagocytickilling than did the ica-deleted and unencapsulated strain 10833.Thus, both PNAG and CP expression appear to protect S. aureuscells from innate host phagocytic effectors, consistent withfindings that these two surface polysaccharides have somewhatsimilar functions in regard to S. aureus resistance to hostimmune effectors.

Virtually 100% of analyzed S. aureus human clinical strainscarry an ica locus (8, 32). We have shown that with sensitiveenough methods, reliant on good immunologic reagents, all examinedhuman clinical bacteremic strains of S. aureus produce detectablePNAG (42). However, some commensal strains of S. aureus do notcarry an ica locus as shown in the study that compared invasiveand noninvasive isolates of S. aureus (56). Peacock et al. (56)found that the invasive strains were much more likely to carryan intact ica locus than the commensal S. aureus strains. Whenthese findings are placed in the context of the animal studiesreported here describing a significant loss of virulence forthree S. aureus strains lacking the ica genes in three modelsof systemic infection, it appears that PNAG expression may becritical for disease manifestations to emerge in individualswith systemic S. aureus infection.

In addition to S. aureus and strains of coagulase-negative staphylococci,it has been recently demonstrated that E. coli has an ica-homologouslocus, designated ycdSRQP in the E. coli K-12 sequenced genomebut renamed pga, that encodes proteins that synthesize PNAG(74). Also, Actinobacillus actinomycetemcomitans and Actinobacilluspleuropneumoniae (30) possess an ica-homologous genetic locusencoding production of PNAG, and it further appears that theYersinia pestis hms locus is another ica homologue (38). Moreica homologues are found in other gram-negative bacteria (74).Whether PNAG plays a similar role in virulence for these otherorganisms is not currently known, although deletion of the hmslocus in Y. pestis did not affect virulence in a mouse modelof bubonic plague (37). However, the hms locus is essentialfor transmission of Y. pestis from flea vectors to mammalianhosts (25), indicating a role in the natural transmission cycleof Y. pestis.

Overall, for S. aureus, while we were able to demonstrate anessential role for PNAG production in the virulence of thisorganism in settings of systemic spread using mice as hosts,it is anticipated that the role of PNAG in the virulence ofdisease in humans will be dependent on the site of infection,the organism's ability to elaborate other virulence factors,and the state of host immunity to multiple S. aureus antigens.With more and more information emerging about the virulenceof S. aureus infections, we can expect that these data willbe useful for devising new and appropriate intervention strategies,such as multicomponent vaccines, that could help blunt the impactof infection and disease by one of the most common nosocomialpathogens isolated in the early 21st century.

ACKNOWLEDGMENTS

This work was supported by NIH grants AI46706 (G.B.P.) and AI061590(K.J.).

FOOTNOTES

* Corresponding author. Mailing address: Channing Laboratory, 181 Longwood Ave., Boston, MA 02115. Phone: (617) 525-2269. Fax: (617) 525-2510. E-mail: gpier{at}channing.harvard.edu.

Editor: J. B. Bliska

REFERENCES

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