Staphylococcus aureus Serotype 5 Capsular Polysaccharide Is Antiphagocytic and Enhances Bacterial Virulence in a Murine Bacteremia Model

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Infection and Immunity, November 1998, p. 5183-5189, Vol. 66, No. 11
0019-9567/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.

Staphylococcus aureus Serotype 5 Capsular Polysaccharide Is Antiphagocytic and Enhances Bacterial Virulence in a Murine Bacteremia Model

Manoj Thakker, Jin-Sir Park, Vincent Carey, and Jean C. Lee^*

Channing Laboratory, Department of Medicine, Brigham and Women's Hospital and Harvard Medical School, Boston, Massachusetts 02115

Received 2 April 1998/Returned for modification 9 July 1998/Accepted 25 August 1998

	ABSTRACT

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Controversy persists over the role that the capsular polysaccharide plays in the pathogenesis of Staphylococcus aureus infections.To address this issue, we compared the mouse virulence of S. aureusReynolds and capsule-defective mutant strains cultivated underconditions of high or low capsule expression. Strain Reynoldscells cultivated on Columbia salt agar plates expressed ~100-foldmore type 5 capsular polysaccharide than did cells cultivatedin Columbia salt broth. The relative virulence of strain Reynoldsand its capsule-defective mutants after growth on either solidor liquid medium was examined in mice challenged intraperitoneallyor intravenously. The results indicated that agar-grown Reynoldscells were cleared from the bloodstream of mice less readily thanbroth-grown Reynolds cells. When the parental and mutant strainswere cultivated on solid medium, strain Reynolds sustained a higherlevel of bacteremia than did the capsular mutants. We performedin vitro opsonophagocytic killing assays to determine whetherstaphylococcal virulence for mice correlated with resistance tophagocytosis. S. aureus Reynolds cultivated on solid medium wassusceptible to phagocytic killing only in the presence of specificcapsular antibodies and complement. Strain Reynolds grown in brothshowed opsonic requirements for phagocytic killing that were similarto those of the capsular mutants (grown in broth or on agar);i.e., the bacteria were opsonized for phagocytosis by nonimmuneserum with complement activity. These studies indicate that optimalexpression of capsule enhances bacterial virulence in the mousemodel of bacteremia, probably by rendering the organisms resistantto opsonophagocytic killing by leukocytes.

	INTRODUCTION

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Capsular polysaccharides are produced by ~90% of Staphylococcus aureus strains. Although 11 capsular serotypes have been described,most isolates of S. aureus belong to capsule types 5 or 8 (4,13, 15, 22). Previous studies from our laboratory utilizedTn918 mutagenesis of strain Reynolds to isolate mutants that werealtered in type 5 capsular polysaccharide (CP5) expression (2).Initial results comparing the virulence of wild-type strains andthat of mutant strains revealed that the capsule did not enhancestaphylococcal virulence in several animal models of infection(2, 5). In addition, we reported that broth-grown S. aureusstrains expressing serotype 5 or 8 capsules did not resist opsonophagocytickilling by human polymorphonuclear leukocytes (29). In contrast,Karakawa et al. (14) reported that microcapsules elaboratedby type 5 and 8 S. aureus strains were antiphagocytic. Nilssonet al. (19) recently showed that mice inoculated with S. aureusexpressing CP5 had a higher frequency of arthritis and a moresevere form of the disease than animals inoculated with nonencapsulatedmutant strains. Furthermore, macrophages were able to ingest andkill nonencapsulated S. aureus mutants to a greater degree thanthe parental strain could. Thus, the role of the capsule in staphylococcalvirulence seems to be dependent on the particular assay or animalmodel of infection tested.

S. aureus serotype CP5 and CP8 expression is greatly influenced by environmental and bacterial growth conditions, such asthe culture medium and the growth phase of the organism (8,23). Growth of S. aureus under iron limitation or on solid mediumaugmented production of CP8 (18). We demonstrated that S. aureusharvested from endocardial vegetations of infected rabbits expresseda high level of CP8, similar to that of organisms cultivated onagar (18). CP5 production was found to be inhibited by highlevels of yeast extract, alkaline growth conditions, CO₂, andanaerobiosis (8, 12, 23) but enhanced by growth of thebacterium in milk (24).

The objective of this study was to reexamine the virulence of the serotype 5 strain Reynolds when its capsule expression wasoptimized by cultivation on solid medium. The results indicatethat the parental strain is more virulent than the capsule-defectivemutants in a mouse bacteremia model of staphylococcal infection.We attribute the enhanced virulence to the antiphagocytic natureof the bacterial CP, since in vitro assays indicate that the parentalstrain resists phagocytic killing by human polymorphonuclear leukocytesin nonimmune serum. Capsule-deficient mutant strains (or the parentalstrain grown in broth) were opsonized for phagocytosis by complementalone.

	MATERIALS AND METHODS

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Bacteria. The S. aureus isolates used for this study include the parental strain Reynolds, Tn918-insertional mutant JL236, and mutantJL243 (derived by mutagenesis with ethyl methanesulfonate) (2).The strains were maintained in skim milk at $-$ 70°C and cultivatedfor 24 h at 37°C in Columbia medium (Difco Laboratories, Detroit,Mich.) supplemented with 2% NaCl. Solid medium was prepared bythe addition of 15 g of Bacto Agar (Difco Laboratories) per liter.Broth-grown staphylococcal cultures were incubated end over endin screw-cap glass tubes (16 by 150 mm) containing 6 ml of medium;the tubes were rotated at 65 rpm on a multipurpose rotator (model151; Scientific Industries, Inc.). The bacteria were harvested,washed once in PBS (10 mM sodium phosphate-0.15 M NaCl [pH 7.3]),and suspended to an optical density at 650 nm of 0.4. Bacteriawere diluted to the appropriate concentration for testing, andCFU were verified by plate counts performed in duplicate on trypticsoy agar (Becton Dickinson Microbiology Systems, Cockeysville,Md.).

CP5 quantitation. An enzyme-linked immunosorbent assay (ELISA) inhibition method (18) was used to quantitate CP5 expression by S. aureus.The assay is based on the ability of encapsulated bacteria (trypsinizedto remove protein A) or purified CP5 to absorb capsular antibodiesfrom immune serum. The method is sensitive to CP5 (<1 ng/ml) andis useful for quantitating capsule production by different S.aureus strains or by the same strain grown under different conditions.

Briefly, wells of a microtiter plate were coated with purified CP5 (4 µg/ml) coupled to poly-L-lysine by the cyanuric chloridemethod (11). After 18 h at 4°C, the microtiter plate was washedand blocked at 4°C overnight with 0.05% skim milk. Suspensionsof S. aureus cells were trypsinized (1 mg of trypsin/ml of 0.1M phosphate buffer, pH 8) for 60 min at 37°C to remove proteinA, washed, and serially diluted threefold from ~5 × 10⁷ to ~5 × 10⁴ CFU/ml. Polyclonal CP5-specific antiserum was diluted 1:20,000and incubated overnight at 4°C with serial dilutions of the bacteriaor purified CP (1 µg/ml to 0.1 ng/ml). Samples were centrifuged,and the absorbed serum samples (supernatants) were added to thecoated and blocked microtiter plate. Following a 2-h incubationwith absorbed or nonabsorbed serum samples, the plates were washedwith PBS-Tween and alkaline phosphatase-conjugated goat anti-rabbitimmunoglobulin G (Organon Teknika-Cappel, Durham, N.C.; 1:3,000)was added to each well. After 2 h at ambient temperature, theplate was again washed and p-nitrophenol phosphate substrate wasadded. Following a 30-min incubation at room temperature, thereaction was stopped with 3 M NaOH, and absorbance at 405 nm wasmeasured by an ELISA reader (Biotek, Inc., Burlington, Vt.). Theconcentration of sample (bacterial cells) that resulted in 50%inhibition of antibody binding was determined, and the CP contentof the sample was calculated from the CP5 standard curve. Specificitywas shown by experiments demonstrating that only CP5, but notCP8, inhibited the reaction.

Analysis of cell wall extracts. Cell wall extracts made from S. aureus protoplasts were prepared by the method of Cheung and Fischetti (6). Bacteria harvestedfrom either Columbia salt agar (CSA) plates or Columbia salt broth(CSB) were suspended in 0.6 ml of digestion buffer (30% raffinosein 0.05 M Tris [pH 7.5] with 0.145 M NaCl) containing 100 µg oflysostaphin (Aplin & Barrett, Trowbridge, United Kingdom) and10 µg of DNase (Worthington Diagnostics, Freehold, N.J.). Thesamples were incubated with gentle rotation for 2 h at 37°C. Theprotoplasts were collected by centrifugation at 8,000 × g for10 min, and the supernatant was stored at $-$ 70°C. The samples wereelectrophoresed in a sodium dodecyl sulfate-9% polyacrylamidegel and stained with Coomassie brilliant blue.

Animal experiments. Female CD-1 mice, 8 to 10 weeks old, were obtained from Charles River Laboratories, Kingston, Mass. For lethality studies,five groups of 9 to 11 CD-1 mice were challenged intraperitoneally(i.p.) with serial dilutions of S. aureus grown on CSA plates.The inocular sizes ranged from ~10¹⁰ to ~10⁸ CFU/mouse. Mortality was assessed on a daily basis for 3 days.The 50% lethal doses (LD₅₀s) were estimated by using a probitmodel of the dose-response relationship. The null hypothesis ofcommon LD₅₀s was tested by the likelihood ratio test. Sublethalbacteremia was initiated by challenging groups of 8 to 20 miceby the intravenous (i.v.) route with ~2 × 10⁶ CFU/mouse or by the i.p. route with ~2 × 10⁷ CFU/mouse. After inoculation separate groups of animals werebled from the tail at specified times, and the bacteremia levelswere estimated by quantitative plate counts performed in duplicateon tryptic soy agar plates with 5% sheep blood (Becton DickinsonMicrobiology Systems). Statistical significance was determinedwith the Welch modification of the unpaired Student's t test.

Opsonophagocytic killing assay. The in vitro opsonophagocytic killing of S. aureus by human polymorphonuclear leukocytes (PMNs) was determined as describedpreviously (29). Antibodies to CP5 were elicited by immunizationof rabbits with strain Reynolds, and antibodies to noncapsularcell wall determinants were removed by absorption of the serumwith trypsinized (to remove protein A) cells of acapsular mutantJL243. Rabbit serum containing antibodies to noncapsular staphylococcalcell wall antigens was obtained by immunizing rabbits with killedcells of either mutant JL240, strain Lafferty, or strain NT857(29). These sera were referred to as teichoic acid antiserabecause each immunoprecipitated with purified teichoic acid. Allrabbit sera were heat inactivated at 56°C for 30 min prior touse. Pooled normal human serum was obtained by venipuncture froma group of eight healthy adult volunteers. Human serum from volunteersimmunized with a conjugate vaccine composed of CP5 linked covalentlyto recombinant Pseudomonas aeruginosa exotoxoid A (9) was kindlyprovided by Ali Fattom, Nabi, Rockville, Md. Guinea pig serum(Pel-Freez Biologicals) was used as a source of nonimmune serumcomplement. Percent killing was defined as the reduction in CFUper milliliter after 60 or 120 min of incubation compared withthat at time zero. The data presented are the means of at leasttwo independent experiments.

	RESULTS

Top Abstract Introduction Materials & Methods Results Discussion References

Quantitation of CP5 expression by S. aureus cultivated on solid or in liquid medium. Culture conditions have a profound effect on the level of CP5 production by S. aureus Reynolds (Table 1). Broth-grown cellsexpressed only ~1% of the amount of cell-associated CP5 generatedby cells grown on solid medium, a result consistent with our previousreport on the relative expression of CP8 by S. aureus Becker whencultivated on solid or in liquid medium (18). The CP5-deficientmutant strain JL236 expressed ~9% of wild-type levels of CP5,and the acapsular mutant JL243 produced negligible amounts ofCP5.

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TABLE 1. CP5 expression measured by ELISA inhibition for S. aureus serotype 5 strains

Analysis of cell wall extracts made from S. aureus cultivated on agar or in broth. Figure 1 shows a comparison of the cell wall-associated proteins expressed by S. aureus Reynolds, JL236, and JL243 cultivatedeither on CSA or in CSB. The proteins associated with the cellwall of staphylococci cultivated on solid medium differed fromthose expressed by broth-grown cells. As expected, the bandingpatterns for the broth-grown parental and mutant strains wereidentical, as were the banding patterns for the parental and mutantstrains grown on solid medium. The conclusion from this experimentis that there are many differences, in addition to capsule expression,between cells cultivated in liquid or on solid medium. Thus, wehave compared the virulence of strain Reynolds cells cultivatedin broth or on agar with the virulence of the CP5 mutant strains(JL236 and JL243) cultivated under the same conditions.

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FIG. 1. Cell wall extracts were made from S. aureus strains cultivated on CSA (A) or CSB (B). Samples were subjected to sodium dodecyl sulfate-polyacrylamide gel electrophoresis, and the gel was stained with Coomassie brilliant blue. Positions of molecular mass markers run on the gel are indicated on the right.

Effect of CP5 production on staphylococcal lethality. S. aureus Reynolds and acapsular mutant JL243 were cultivated on CSA plates at 37°C for 24 h. Suspensions of each bacterialstrain were prepared, and groups of 9 to 11 mice were challengedi.p. with either strain at inoculum sizes ranging from 10¹⁰ to 10⁸ CFU/mouse. After 24 h the LD₅₀ of agar-grown strain Reynoldswas 6.2 × 10⁸ CFU (95% confidence interval = 3.8 × 10⁸ to 9.9 × 10⁸ CFU). At the same time point, only three of nine mice given thehighest challenge dose (9.3 × 10⁹ CFU) of mutant JL243 had died, yielding an extrapolated LD₅₀of 9.9 × 10⁹ CFU. The difference (P < 10⁵) in lethality induced by these two bacterial strains at 24 hlikely reflects their relative abilities to be cleared effectivelyby host phagocytic cells. By day 3 after challenge, the LD₅₀ ofstrain Reynolds was 3.9 × 10⁸ CFU (95% confidence interval = 2.6 × 10⁸ to 5.9 × 10⁸ CFU), whereas that for mutant JL243 was 4.1 × 10⁹ CFU (95% confidence interval = 2.6 × 10⁹ to 6.3 × 10⁹ CFU; P = 1.5 × 10⁵). These results confirm an observation made earlier by othersthat rodents are very resilient to high doses of S. aureus administeredi.p. (1).

Effect of CP5 production on bacteremia. To provide a more sensitive measure of staphylococcal virulence, groups of 9 to 20 mice were inoculated i.p. with sublethaldoses (~2 × 10⁷ CFU) of S. aureus, and their bacteremia levels were monitoredover time. As shown in Fig. 2, bacterial concentrations in theblood of animals challenged with agar-grown strain Reynolds weresignificantly higher (P $<=$ 0.0019) at all time points than thoseof mice challenged with broth-grown strain Reynolds. Similarly,the bacteremia levels in mice infected with agar-grown strainReynolds were significantly greater (P < 0.0002) at each timepoint than those of mice challenged with the mutant strain JL236or JL243 grown on similar medium. At 24 h after challenge, culturesof blood from the infected animals were sterile (<10 CFU/ml; notshown). These findings suggest that maximal CP5 expression byS. aureus allowed the inoculum to disseminate more effectivelyfrom the peritoneal cavity to the bloodstream.

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FIG. 2. Results of quantitative blood cultures from groups of 9 to 20 mice challenged i.p. with 2 × 10⁷ CFU of S. aureus. The values shown are means ± SEM (error bars).

In a separate experiment groups of 8 to 19 mice were inoculated i.v. with ~2 × 10⁶ CFU of S. aureus. Blood was collected from the animals at timepoints ranging from 10 min to 24 h after inoculation, and quantitativeblood cultures were performed on the samples. As shown in Fig.3, there was a very rapid initial clearance of both wild-typeand mutant strains of S. aureus from the blood following i.v.injection. However, the bacteremia levels were significantly higherfor mice challenged with the parental strain Reynolds at 10 min(P < 0.0001), 60 min (P $<=$ 0.024), and 180 min (P < 0.031) thanfor those challenged with each of the mutant strains. At 120 minafter challenge, strain Reynolds was recovered from the bloodin significantly greater numbers than was strain JL236 (P = 0.0302),but the difference in bacteremia levels between the parental strainand mutant JL243 did not reach significance (P = 0.0986). By 4h after challenge, the results of the quantitative blood culturesfrom all of the mice were similar, achieving a steady-state concentrationof ~10² CFU/ml of blood. By 24 h the blood cultures showed <10 CFU/ml(not shown).

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FIG. 3. Results of quantitative blood cultures from groups of 8 to 19 mice challenged i.v. with 2 × 10⁶ CFU of S. aureus. The values shown are means ± SEM (error bars).

Effect of CP5 production on opsonophagocytic killing by human PMNs in vitro. To determine whether the relative virulence of the parental and mutant strains correlated with their resistance to phagocytosis,we examined the opsonic requirements for phagocytic killing ofeach S. aureus strain by human PMNs. When the staphylococcal strainswere cultivated in broth culture, each isolate was opsonized forphagocytic killing by either capsular antibodies and complementor complement alone (Fig. 4). Capsular antibodies alone (no complementactivity) showed less opsonic activity, although the inoculumwas reduced by >60% after 1 or 2 h of incubation with PMNs. Theseopsonic requirements for phagocytic killing are similar to thosepreviously reported for S. aureus serotype 5 and 8 strains grownin broth culture (29).

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FIG. 4. In vitro opsonophagocytic killing of S. aureus strains (cultivated in CSB) by human PMNs in the presence of rabbit CP5 antiserum (ab). Nonimmune guinea pig serum was added as a complement (C') source. The values shown are means ± SEM (error bars).

When strain Reynolds was cultivated on solid medium to enhance CP5 expression, it was susceptible to phagocytic killing onlyin the presence of both capsular antibodies and complement (Fig.5). Little or no killing (5.5% reduction in CFU per milliliter)occurred when strain Reynolds was incubated with complement alone.In contrast, mutants JL243 and JL236 cultivated on agar were stillefficiently opsonized for phagocytosis by either capsular antibodiesand complement or complement alone (Fig. 5). When the PMNs wereincubated with S. aureus and heat-inactivated CP5-specific serum(no added complement), the reduction in CFU per milliliter wasrelated to the amount of CP5 produced by each strain; i.e., 36%of strain Reynolds cells were killed, 23% of mutant JL236 cellswere killed, and only 6% of mutant JL243 cells were killed bythe PMNs after 120 min of incubation. Clearly the target antigenrecognized by this antiserum on the capsule-deficient mutant strainswas diminished.

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FIG. 5. In vitro opsonophagocytic killing of S. aureus strains (cultivated on CSA plates) by human PMNs in the presence of rabbit capsular type 5 antiserum (ab). Nonimmune guinea pig serum was added as a complement (C') source. The values shown are means ± SEM (error bars).

To determine whether antibodies to noncapsular cell wall determinants like peptidoglycan and teichoic acid could substitutefor capsular antibodies in opsonizing serotype 5 S. aureus forphagocytosis, additional experiments comparing S. aureus strainscultivated in broth or on agar plates were performed. As shownin Fig. 6, broth-grown staphylococci were killed by phagocytesin the presence of antibodies to noncapsular cell wall antigens(teichoic acid antibodies) and complement (>92% killing) or complementalone ( $>=$ 90% killing [Fig. 5]). Teichoic acid antibodies alone(no complement) were much less efficient in opsonizing the broth-grownstaphylococcal strains for phagocytosis (44, 29, and 12% killingfor strains Reynolds, JL236, and JL243, respectively).

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FIG. 6. In vitro opsonophagocytic killing of S. aureus strains (cultivated in CSB) by human PMNs in the presence of sera raised against nontypeable S. aureus strains (NT857, JL240, and Lafferty). The antisera contain antibodies (ab) to cell wall antigens such as teichoic acid, but the sera are negative for CP5 antibodies. The values shown are means ± SEM (error bars). C', complement.

Opsonophagocytic killing was poor (47% reduction in CFU per milliliter) when agar-grown strain Reynolds was opsonized withteichoic acid antibodies and complement (Fig. 7). In contrast,>92% of mutant JL243 and JL236 cells (cultivated on CSA plates)were killed by the PMNs in the presence of teichoic acid antibodiesand complement. Teichoic acid antibodies alone were poorly opsonicfor each of the S. aureus strains cultivated on agar (Fig. 7).

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FIG. 7. In vitro opsonophagocytic killing of S. aureus strains (cultivated on CSA plates) by human PMNs in the presence of sera raised against nontypeable S. aureus strains (NT857, JL240, and Lafferty). The antisera contain antibodies (ab) to cell wall antigens such as teichoic acid, but the sera are negative for CP5 antibodies. The values shown are means ± SEM (error bars). C', complement.

Normal humans have serum antibodies to S. aureus cell wall components, including peptidoglycan, teichoic acid, CP5, and CP8(3, 7, 9, 26, 28). Because phagocytic clearance isthe host's primary defense against the staphylococcus, we wantedto determine whether pooled fresh, normal human serum was opsonicfor strain Reynolds and its mutants. As shown in Fig. 8, freshnormal human serum with complement activity (unheated) was opsonicfor the capsule-negative mutant strains whether they were cultivatedin broth or on agar plates (>91% killing). Similarly, 88% of thebroth-grown strain Reynolds inoculum was killed by the PMNs aftera 2-h incubation. However, if strain Reynolds was harvested fromagar plates, only 22 and 45% of the inoculum was opsonized forkilling in fresh normal human serum after 1 and 2 h of incubation,respectively. The differences in opsonophagocytic killing betweenbroth- and agar-grown S. aureus Reynolds were significant at 1h (P = 0.01) but not at 2 h (P = 0.10). Likewise, when agar-grownstrain Reynolds was contrasted with the mutant strains grown onagar, the differences in killing were significant at 1 h (P =0.02) but not at 2 h (P = 0.13 and P = 0.14, comparing strainReynolds with mutants JL236 and JL243, respectively). When wetested the opsonic activity of a pool of sera from human volunteersimmunized with a conjugate vaccine composed of CP5 linked covalentlyto recombinant P. aeruginosa exotoxoid A, 88% ± 3.6% and 95% ±1.2% (means ± standard errors of the means [SEM]) of the agar-grownReynolds inoculum was killed in the opsonophagocytic assay after1 and 2 h, respectively (data not shown in Fig. 8). When the sameimmune serum was heat inactivated, it lost all opsonic activityagainst agar-grown Reynolds cells (0% killing).

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FIG. 8. In vitro opsonophagocytic killing of S. aureus strains by human PMNs in the presence of pooled, fresh normal human serum. The values shown are means ± SEM (error bars).

The pool of serum from nonimmunized adults was heated to inactivate complement and retested in the opsonophagocytic killingassay. As shown Fig. 9, 81% of broth-grown Reynolds cells werekilled in the presence of heated normal serum, whereas there wasno killing of agar-grown Reynolds cells under the same conditions(P = 0.0178 for the 2-h values). The mutant strains JL236 andJL243 cultivated in broth or on agar showed an intermediate levelof opsonophagocytic killing in heated human serum, ranging from47 to 88% killing (Fig. 9). The differences in killing betweenagar-grown strain Reynolds (0%) and agar-grown mutants JL236 (88%)and JL243 (61.5%) at 2 h were significant (P < 0.02).

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FIG. 9. In vitro opsonophagocytic killing of S. aureus strains by human PMNs in the presence of pooled, heat-inactivated, normal human serum. The values shown are means ± SEM (error bars).

	DISCUSSION

Top Abstract Introduction Materials & Methods Results Discussion References

Expression of S. aureus cell-associated and secreted antigens is highly influenced by environmental culture conditions. Manystaphylococcal exoproteins are produced in the postexponentialgrowth phase, whereas cell-associated proteins are preferentiallyproduced during exponential growth (16, 21). Alpha-toxin expressionhas been shown to be dependent on growth rate (25), temperature,osmolarity, and concentrations of oxygen and CO₂ (20). Cheungand Fischetti (6) reported that S. aureus cells cultivatedon agar showed a greater abundance of cell-wall-associated, high-molecular-weightproteins than broth-grown cells. We confirmed the findings ofthe latter study and observed that S. aureus cells grown on agarplates produced ~100-fold more CP5 than did broth-grown cells.This fact has undoubtedly influenced the results from differentlaboratories that have focused on the role of the S. aureus capsulein virulence. Broth-grown S. aureus cultures were used for challengein the animal virulence studies reported by Baddour et al. (5)and Albus et al. (2). Both of these studies failed to showthat capsule expression enhanced staphylococcal virulence. Incontrast, the recent study reported by Nilsson et al. (19) utilizedthe same S. aureus isolates as the previous two studies, but thebacterial strains were cultivated on agar. These investigatorsshowed that the parental strain was more virulent than the capsule-defectivemutants in a mouse model of arthritis. It is likely that bothculture conditions and the type of infection model tested influencedthe conclusions of these studies.

Different laboratories have also reported conflicting data regarding the antiphagocytic properties of the S. aureus capsuleas measured in an in vitro opsonophagocytic killing assay (14,29). Similarly, these differences may be due to variabilityin bacterial growth conditions, which are now recognized to greatlyinfluence in vitro capsule expression (8, 12, 18, 23,24).

In the present study, we report that capsule type 5 S. aureus Reynolds cultivated under conditions of maximum CP5 expressionwas more virulent for mice than mutant strains defective in CP5expression. Only modest differences attributable to encapsulationwere evident when virulence was assessed in the lethal peritonitismodel or when bacteremia was quantified following i.v. challengewith S. aureus. The most striking, biologically relevant differencein staphylococcal virulence was observed when bacteremia levelswere measured after i.p. challenge of the mice (Fig. 2). Our datasuggest that the abundant capsule expressed by S. aureus cultivatedon solid medium allowed the organism within the peritoneal cavityto escape local defenses and transit more efficiently throughthe lymphatics to the bloodstream of the animals.

The mouse virulence of the S. aureus strains under study correlated with their resistance to opsonophagocytic killing by humanPMNs; i.e., when cultivated under conditions of high CP5 expression,strain Reynolds was killed only when it was opsonized by complementand capsular antibodies. In contrast, organisms with little capsule(broth-grown strain Reynolds and mutants JL236 and JL243 cultivatedin broth or on agar) were effectively opsonized for phagocytosisby complement alone. Copious amounts of CP5 may mask other cellwall antigens like teichoic acid and peptidoglycan that are targetsfor complement deposition. Verbrugh et al. (27) demonstratedby transmission electron microscopy that C3b bound to the cellwall of the highly encapsulated strain M beneath the capsularlayer and was physically separated from complement receptors onthe PMN membrane. The large capsule produced by this serotype1 S. aureus strain physically masked complement deposited on thecell wall. When strain M was mixed with type-specific antibodiesand complement, the deposition of complement not only on the cellwall but throughout the capsular layer led to efficient phagocyticuptake and killing. Whether CP5 is produced by strain Reynoldsin quantities sufficient to mask complement deposited on its cellwall remains to be determined.

Overall, the results of this study indicate that the role of the S. aureus capsule in bacterial virulence is markedly influencedby the in vitro bacterial culture conditions. When capsule expressionwas maximized, the parental strain Reynolds was more virulentfor mice than capsule-defective mutant strains. Furthermore, therewas a correlation between mouse virulence of the wild-type andmutant strains and their resistance to opsonophagocytic killingby human PMNs. These findings are consistent with recent studiesthat show that antibodies to the S. aureus capsule are protectivein disseminated staphylococcal infections of mice (10) or rats(17).

	ACKNOWLEDGMENTS

This work was supported by Public Health Service grant AI-29040 from the National Institute of Allergy and Infectious Diseasesand by the William F. Milton Fund of Harvard University.

We thank Derek Frederickson and Thuyanh Dang Le for their technical assistance. We acknowledge Ali Fattom for providing uswith human serum from volunteers immunized with the S. aureuscapsule-conjugate vaccine.

	FOOTNOTES

^* Corresponding author. Mailing address: Channing Laboratory, 181 Longwood Ave., Boston, MA 02115. Phone: (617) 525-2652. Fax:(617) 731-1541. E-mail: jean.lee{at}channing.harvard.edu.

Editor: V. A. Fischetti

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Top Abstract Introduction Materials & Methods Results Discussion References

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