Strain-Dependent Role of BrkA during Bordetella pertussis Infection of the Murine Respiratory Tract

Bordetella pertussis, the causative agent of whooping cough,expresses many virulence factors believed to be involved ininfection and disease progression. While these factors as agroup are required for infection, deletion of individual virulencefactor genes generally has limited effects on the ability ofB. pertussis to efficiently infect the respiratory tract ofmice, suggesting they may perform noncritical or redundant functions.We have recently observed that a B. pertussis strain, putativelywith a mutation of a single gene, brkA, results in a severedefect in vivo. Although BrkA has been shown to be requiredfor B. pertussis to resist complement-mediated killing in vitro,the relevance of these findings to the in vivo role of BrkAduring infection has not been examined. Transducing this mutationinto multiple wild-type B. pertussis strains allowed us to confirmthe in vitro phenotype of reduced resistance to serum complement.All ${Delta}$ brkA mutants were increased in their sensitivity to complementin vitro, both in the presence and absence of antibodies. However,these strains differed substantially in their phenotypes invivo. ${Delta}$ brkA mutants of recent clinical isolates were indistinguishablefrom wild-type strains in their efficient infection of respiratoryorgans, suggesting that the function of BrkA in these strainsis noncritical or redundant. In contrast, multiple ${Delta}$ brkA strainsderived from Tohama I were severely defective during the firstweek postinoculation compared to their wild-type parent. Thisdefect was present even in complement-deficient mice, revealinga complement-independent phenotype for the ${Delta}$ brkA mutant in respiratorytract infection.

INTRODUCTION

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Introduction

Bordetella pertussis, the causative agent of whooping cough,contains the bvgAS two-component system that controls the expressionof many virulence factors, including pertussis toxin, adenylatecyclase, dermonecrotic toxin, filamentous hemagglutinin, fimbriae,pertactin, and BrkA (Bordetella resistance to serum killing)(3, 7, 28). As a group, these bvg-regulated proteins have beenshown to be important factors in effective infection and diseaseprogression. B. pertussis mutants locked in the Bvg^– phase,in which the expression of multiple virulence factors is decreased,are rapidly cleared from the respiratory tracts of inoculatedmice (5, 16), but deletions of single virulence factors havevarying, less-severe effects on colonization, suggesting thatthey may perform noncritical or redundant functions (18).

To survive in the host environment, bacteria must be able toescape killing by numerous host mechanisms, including complement.The various Bordetella species have developed several differentmechanisms to resist complement-mediated killing, both in thepresence and absence of antibodies. The lipopolysaccharide (LPS)O antigens of Bordetella bronchiseptica and Bordetella parapertussisprevent activation of complement in naive serum (2). Deletionof the locus required for O-antigen assembly results in dramaticallyincreased sensitivity to serum complement in vitro in both speciesbut substantially different phenotypes in vivo; the B. parapertussismutant was defective but the B. bronchiseptica mutant was not,indicating that in vitro complement resistance does not necessarilycorrelate with in vivo phenotypes (2).

B. pertussis naturally lacks O antigen, due to an insertionsequence replacing the locus required for its assembly, andis relatively sensitive to killing by naive serum in vitro,although there is a wide range of sensitivity levels observedamong different isolates (2, 10, 11, 19, 24). However, evenstrains that are highly sensitive to serum complement in vitroefficiently infect mice, again reflecting a lack of correlationbetween in vitro complement sensitivity and in vivo phenotypes(2, 10). Interestingly, B. pertussis appears to have multiplealternative mechanisms to avoid antibody-mediated complementkilling in vitro, including the expression of BrkA (1, 7). WhileBrkA has been implicated in adherence to and invasion of hostcells in in vitro assays, its most well studied function isits ability to mediate resistance to human immune serum killingin vitro (6, 7, 15).

BrkA was identified in a transposon insertion screen for bvg-regulatedgenes (27). A strain with an insertion in the brkA gene wasfound to require a 10-fold-greater challenge dose to cause lethalityin an infant mouse model (7, 26). The brk locus contains twodivergently transcribed open reading frames (ORFs), brkA andbrkB, with a putative bvgA-binding site between them. BrkA isa 103-kDa autotransporter protein, containing a 73-kDa ${alpha}$ -domain,or passenger domain, and a 30-kDa ß-domain, whichacts as the transporter (20, 21, 25). It is similar in sequenceto pertactin, possessing two RGD motifs, an outer membrane localizationsignal, and a proteolytic cleavage site.

The ${Delta}$ brkA mutant strain, RFBP2152, was generated by deletingthe internal 229-bp SalI fragment of the brkA gene in B. pertussisstrain BP338 and replacing it with a gentamicin resistance-OriTcassette (7). We have recently observed that RFBP2152 is severelydefective in mouse lung colonization, being nearly cleared byday 3 postinoculation, whereas wild-type B. pertussis growsto greater than 10⁶ CFU by this time point (23). Consideringthat BrkA is known to mediate resistance to complement killingand that B. pertussis shows substantial strain variation inserum sensitivity (23), we sought to examine the functions ofBrkA in various laboratory strains and recent clinical isolatesof B. pertussis. ${Delta}$ brkA mutants of four different B. pertussisstrains showed increased sensitivity to serum complement invitro, but only Tohama I derivatives were defective in vivoin the lungs of wild-type and complement-deficient mice. Whilethe function(s) of BrkA appears to be redundant in some recentclinical isolates, these findings indicate that the in vivofunction of BrkA in Tohama I-derived strains is independentof its role in complement resistance.

MATERIALS AND METHODS

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Materials and Methods

Bacterial strains and growth. Table 1 lists bacterial strains used in this study. B. pertussisstrains Tohama I, BP338, RFBP2152, and GMT1 have been describedelsewhere (8, 12, 16, 17, 27). B. pertussis strain 6068 is anisolate obtained in 1997 from a subject participating in theNational Institutes of Health-sponsored multicenter Adult AcellularPertussis Vaccine Efficacy Trial (APERT) conducted throughoutthe United States. The study subject was a 29-year-old femalewith a 7-day persistent cough at the time of culture. All B.pertussis strains were maintained on Bordet-Gengou (BG) agar(Difco) containing 7.5% defibrinated sheep blood (Hema Resources)and appropriate antibiotics (20 µg of gentamicin per mlfor all ${Delta}$ brkA strains). Liquid culture bacteria were grown tomid-log phase in Stainer-Scholte (SS) broth containing heptakis(2,6-di-O-methyl)-ß-cyclodextrin(0.1%; Sigma) and appropriate antibiotics.

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TABLE 1. Bacterial strains used in this study

Phage transduction. RFBP2152 was grown overnight, and 5 µl of culture wasadded to 2.5 ml of 0.7% Top Agar at 42 to 45°C. DC3 phage(a gift from Jeff Miller's lab, University of California—LosAngeles) was added in sufficient quantity to cause confluentlysis within 2 days. Lysate was collected by adding 5 ml ofSM buffer (0.1M NaCl, 0.008 M MgSO₄, 0.05 M Tris-Cl [pH 7.5],0.01% gelatin) to the plate and incubating for 3 h at 4°C.The resuspended lysate was passed through sterile syringe filters,and the titer was determined by serial dilution, with TohamaI as the test strain. The lysate was then added, at a multiplicityof infection (MOI) of 0.1 to 0.01, to 500 µl of overnightcultures of BP338, 6068, Tohama I, and GMT1 grown to mid-logphase. These mixtures were incubated for 2 h, with 200-µlaliquots taken every 30 min. The cells were spun down at 12,000x g for 30 s, washed twice with phosphate-buffered saline (PBS),and plated on BG plates containing gentamicin. Transductantswere tested for sensitivity to DC3 and confirmed by Westernblot analysis.

Western blot analysis. B. pertussis cultures were grown to an optical density at 600nm (OD₆₀₀) of 0.4 to 0.9, and 2 to 3 ml of culture was pelletedby centrifugation. The pellets were resuspended in PBS and frozenat –80°C. Samples were then diluted in sample buffer,boiled for 5 min, and run on a sodium dodecyl sulfate-10% polyacrylamidegel (14). Samples were transferred to a polyvinylidene difluoride(PVDF) membrane (Millipore Immobulon) by a semi-dry transferat 10 V for 30 min. Blots were probed with heat-inactivatedrabbit anti-BrkA antiserum (provided by Alison Weiss) diluted1:50,000 and horseradish peroxidase-conjugated goat anti-rabbitsecondary antibody diluted 1:5,000 (Sigma).

Animal experiments. C57BL/6 mice were obtained from Jackson laboratories (Bar Harbor,Maine), and C3^–/– mice, back-crossed extensivelyonto a C57BL/6 background, have been described elsewhere andwere kind gifts of Rick Wetsel (4). All mice were breed in aBordetella-free environment. Mice lightly sedated with isofluorane(Abbott Laboratories) were inoculated by pipetting 50 µlof PBS containing 5 x 10⁵ bacteria onto the tip of the externalnares. Groups of three or four animals were sacrificed on days3, 7, 14, and/or 28 postinoculation. Colonization of variousorgans was quantified by homogenizing each tissue in PBS, platingthe tissue onto BG-blood agar containing 20 µg of gentamicinper ml (for Toh ${Delta}$ brkA, 6068 ${Delta}$ brkA, GMT ${Delta}$ brkA, BP338 ${Delta}$ brkA, and RFBP2152)or without antibiotic (for BP338, 6068, GMT1, and Tohama I)and by counting the number of colonies.

Antibodies. Titers of anti-Bordetella antibodies in sera were determinedby enzyme-linked immunosorbent assay (ELISA) with polyvalentanti-mouse secondary antibodies as previously described (5).Specific classes and isotypes of antibodies were determinedby using appropriate anti-mouse secondary antibodies (SouthernBiotechnology Associates and Pharmingen). Titers were calculatedby the endpoint method, with naive mouse serum as the negativecontrol.

Serum resistance assays. Naïve rabbit serum was obtained from Covance Research Products,Inc., and confirmed to have undetectable levels of anti-Bordetella-specificantibodies by ELISA. Human immune serum was collected from multiplevolunteers, immunized as children with whole and/or acellularvaccine. Serum aliquots were stored at –80°C. Bacteriawere grown in SS broth to mid-log phase and diluted in 1x PBSor SS broth to a final concentration of 100 CFU/µl. Humanimmune serum and naïve rabbit serum were thawed on ice.Forty-five microliters of serum, either neat or diluted in 1xPBS to the appropriate concentration, was added on ice to 5µl of bacteria. Controls were processed in the same manner,except that 45 µl of heat-inactivated rabbit serum dilutedin PBS to a final assay concentration of 10% was used in placeof the naïve complement active serum. A final concentrationof approximately 500 CFU/50 µl in the indicated concentrationof serum was used for all experiments. All samples were platedon BG agar plates with appropriate antibiotics and incubatedfor 3 to 4 days, after which CFU were enumerated. Percent survivalwas determined as a percentage of controls incubated in PBS.All serum assay experiments were run in triplicate and independentlyrepeated.

RESULTS

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Results

RFBP2152 shows a severe colonization defect on day 3 postinoculation. We have recently observed that RFBP2152 does not effectivelycolonize the respiratory tract of mice and is rapidly cleared(23, 26). The magnitude of this colonization defect is extraordinarilysevere for a single virulence factor gene mutation. Such a severecolonization defect in normal adult mice has been observed onlyfor bvgAS mutants, in which the expression of multiple virulencefactors is disregulated. Normal colony morphology and growthrate indicate that RFBP2152 is not a bvg mutant. Additionally,the presence of a gentamicin resistance cassette alone cannotaccount for the defect, as other wild-type B. pertussis strainswith a Gen^r insertion behave normally in vitro and in vivo (unpublisheddata). In order to determine that the parent strain, TohamaI derivative BP338, was not defective in vivo, groups of C57BL/6mice were inoculated intranasally with 10⁵ CFU of BP338 or RFBP2152in a volume of 50 µl of PBS. The respiratory organs wereharvested on day 3 postinoculation and homogenized in PBS, andthe number of bacteria in the lungs, trachea, and nasal cavitywas quantified. BP338 reached levels on the order of 10⁶ CFUin the lungs, 10^3.5 CFU in the nasal cavity, and 10² CFU inthe trachea (Fig. 1). These levels are consistent with thoseobserved with other wildtype B. pertussis strains (13). As previouslyobserved, RFBP2152 was severely defective in colonization ofthe lungs and trachea (Fig. 1) (23). The inability of RFBP2152to colonize the lower respiratory tract is apparently not theresult of a colonization defect in the parent strain. This invivo defect is extremely severe for a single virulence factormutation and suggests that brkA expression is critical duringB. pertussis infection but does not rule out the possibilityof a second site mutation acquired in the process of derivingthe ${Delta}$ brkA mutant.

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FIG. 1. Colonization by wild-type B. pertussis, BP338, and the ${Delta}$ brkA mutant, RFBP2152, on day 3 postinoculation. Groups of three 4-to 6-week-old C57BL/6 mice were inoculated with 5 x 10⁵ CFU of BP338 (solid bars) or RFBP2152 (open bars) delivered in a 50-µl volume of PBS into the nares. The number of bacteria recovered from the nasal cavity, trachea, and lungs at 3 days postinoculation is expressed as the log₁₀ mean ± the standard error. Dashed line indicates limit of detection.

Recent clinical isolates do not require BrkA for efficient colonization of the murine respiratory tract. In order to determine whether the large colonization defectof RFBP2152 is due to the ${Delta}$ brkA mutation alone or additionalmutations in RFBP2152, the original brkA insertion mutationwas independently transduced by phage DC3 into the B. pertussisstrain Tohama I and the original Tohama I-derived parent strainBP338, producing Toh ${Delta}$ brkA and BP338 ${Delta}$ brkA, respectively. Additionally,since the serum sensitivity of B. pertussis strains varies greatlyand BrkA is thought to function in resisting complement killing,we sought to investigate the function of BrkA in recent clinicalisolates (strains not derived from Tohama I). Therefore, the ${Delta}$ brkA mutation was also transduced from RFBP2152 into B. pertussisstrains 6068 and GMT1. Immunoblots of whole-cell lysates showthat Toh ${Delta}$ brkA, BP338 ${Delta}$ brkA, 6068 ${Delta}$ brkA, and GMT1 ${Delta}$ brkA lack the 73-kDaprocessed BrkA protein present in wild-type B. pertussis (Fig.2A). Groups of 3 C57BL/6 mice were inoculated with 10⁵ CFU ofwild-type and ${Delta}$ brkA strains of each isolate and dissected 3 dayspostinoculation (Fig. 2B). All wild-type strains reached levelson the order of 10⁶ CFU in the lungs. Toh ${Delta}$ brkA and RFBP2152 showedmoderate (1/100 of wild-type levels) and severe (1/10,000 ofwild-type levels) defects, respectively, in colonization ofthe lungs. Interestingly, BP338 ${Delta}$ brkA showed a defect significantlydifferent from that of RFBP2152; however, this defect was notstatistically different from that seen in Toh ${Delta}$ brkA. Since thesame ${Delta}$ brkA mutation is present in both strains, RFBP2152 andBP338 ${Delta}$ brkA, and each is derived from the same parent strain,these results strongly suggest that RFBP2152 has some additionalmutation resulting in a more severe in vivo defect. Interestingly,the ${Delta}$ brkA mutants of the recent clinical isolates GMT1 and 6068efficiently colonized mouse lungs, indicating there may be differentialstrain-dependent requirement for BrkA-mediated functions, possiblydue to a redundant mechanism in the recent clinical isolates.

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FIG. 2. (A) Western blot analysis of wild-type and ${Delta}$ brkA strains of B. pertussis. Phage transduction was performed to transfer the ${Delta}$ brkA mutation from RFBP2152 into several strains of B. pertussis. Western blot analysis was used to confirm successful transductants, verifying the presence of the 73-kDa processed BrkA protein in wild-type strains BP338, Tohama I, 6068, and GMT1 and its absence in their respective mutants, RFBP2125, BP338 ${Delta}$ brkA, Toh ${Delta}$ brkA, 6068 ${Delta}$ brkA, and GMT1 ${Delta}$ brkA. (B) Colonization by wild-type and ${Delta}$ brkA mutants of B. pertussis at 3 days postinoculation. Groups of three 4-to 6-week-old C57BL/6 mice were inoculated with 5 x 10⁵ CFU of BP338, RFBP2152, BP338 ${Delta}$ brkA, Tohama I, Toh ${Delta}$ brkA, 6068, 6068 ${Delta}$ brkA, GMT1, or GMT1 ${Delta}$ brkA delivered in a 50-µl volume of PBS into the nares. The number of bacteria recovered from the lungs at 3 days postinoculation is expressed as the log₁₀ mean ± the standard error. Key statistical differences between groups are indicated (*, P < 0.05). Dashed line indicates limit of detection.

BrkA is involved in resisting both antibody-dependent and -independent complement killing in vitro. Since BrkA has previously been shown to have a role in resistingcomplement killing in vitro, it is possible that the strain-dependentseverity of the in vivo colonization defect could be attributableto differential serum sensitivity of the ${Delta}$ brkA strains. Wild-typeand ${Delta}$ brkA strains were assayed to determine their sensitivitiesto various concentrations of naïve rabbit serum (anti-Bordetellaantibodies were undetectable by ELISA) for 1 h at 37°C (Fig.3). Wild-type strains showed significant variation in theirserum sensitivity. GMT1 was completely resistant to naive serumat all tested concentrations, while 6068 and Tohama I showeda steady decline in survival with increasing serum concentrations( $~$ 50% survival at 90% serum). BP338 was much more sensitive tonaïve serum, with no survival at serum concentrations of50% and greater. All ${Delta}$ brkA mutants showed much greater sensitivityto naïve serum than their wild-type counterparts (Fig.3). Toh ${Delta}$ brkA, BP338 ${Delta}$ brkA, and RFBP2152 were completely killedat serum concentrations of 10% and higher. Although both 6068 ${Delta}$ brkAand GMT1 ${Delta}$ brkA were much more sensitive than their parental wild-typestrains, they both required 50% serum to be completely killed(>99%), suggesting these recent clinical isolates may havesome additional protection not shared by Tohama I derivatives.In addition, the magnitude of the defect, relative to the parentalstrains, was much greater for GMT1 ${Delta}$ brkA than for 6068 ${Delta}$ brkA, suggestingthere may be additional differences between these isolates.Additional experiments performed using serum from naïvemice and B-cell-deficient mice gave similar results, indicatingthat killing is indeed antibody independent and not speciesdependent (data not shown).

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FIG. 3. Naïve serum resistance of wild-type and ${Delta}$ brkA mutant strains of B. pertussis at various concentrations of serum. In vitro grown bacteria were diluted to a concentration of 500 CFU/50 µl and treated with various concentrations of naïve rabbit serum for 1 h at 37°C. Serum resistance is expressed as the percentage of bacteria that survived ± the standard error. All samples were run in triplicate, and each strain was tested at least twice.

All of the wild-type and ${Delta}$ brkA strains were sensitive to humanimmune serum, even at very low concentrations (Fig. 4). Nonesurvived concentrations of 5% or higher. These results are consistentwith human immune serum killing of other Bordetella subspecies,as B. parapertussis is completely killed by 1% immune serumand B. broncheseptica shows no survival at concentrations of10% serum or higher (2). Mutants lacking BrkA were generallymore sensitive at multiple concentrations, and BP338 ${Delta}$ brkA, RFBP2152,6068 ${Delta}$ brkA, and Toh ${Delta}$ brkA were almost completely killed by serumconcentrations of 0.05% and greater. These data indicate thatBrkA is involved in resisting both antibody-independent and-dependent pathways of complement killing in vitro. AlthoughB. pertussis isolates vary considerably in their sensitivitiesto complement, the increased sensitivity of all ${Delta}$ brkA mutantsto both naïve and immune serum confirms the significanceof BrkA in this phenotype.

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FIG. 4. Immune serum resistance of wild-type and ${Delta}$ brkA mutant strains of B. pertussis at various concentrations of serum. In vitro-grown bacteria were diluted to a concentration of 500 CFU/50 µl and treated with different concentrations of human immune serum for 1 h at 37°C. Serum resistance is expressed as the percentage of bacteria that survived ± the standard error. All samples were run in triplicate, and each strain was tested at least twice.

Toh ${Delta}$ brkA is defective early in colonization of wild-type mice. Since the serum sensitivity assays suggest that the ${Delta}$ brkA strainsare more sensitive to complement killing both in the presenceand absence of antibodies, we hypothesized that the defect incolonization on day 3 postinoculation might persist throughoutinfection and result in earlier clearance of the bacteria fromthe lungs. In order to test this possibility, groups of threeC57BL/6 mice were inoculated with 5 x 10⁵ CFU of Tohama I orToh ${Delta}$ brkA and sacrificed on days 3, 7, 14, and 28 days postinoculation,and numbers of bacteria in the lungs were quantified (Fig. 5).The wild-type Tohama I strain was recovered at 100-fold-highernumber of CFU than the Toh ${Delta}$ brkA strain on days 3 and 7, thoughthis defect was gone by day 14. ELISA (data not shown) revealedno significant differences in overall antibody production onday 28 between Tohama I and Toh ${Delta}$ brkA-infected mice, suggestingthe lack of defect at later time points is not a result of adeficiency in antibody production. The lower number of bacteriaonly at early time points suggests that BrkA is required priorto substantial antibody production and indicates that resistanceto antibody-mediated complement activation is not an importantfunction of BrkA in mice.

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FIG. 5. Colonization by Tohama I and Toh ${Delta}$ brkA in the lungs of wild-type mice. Groups of three 4-to 6-week-old C57BL/6 mice were then inoculated with 5 x 10⁵ CFU of Tohama I ( ${blacksquare}$ ) or Toh ${Delta}$ brkA ( ${blacklozenge}$ ) delivered in a 50-µl volume of PBS into the nares. The number of bacteria recovered from lungs at each indicated time postinoculation is expressed as the log₁₀ mean ± the standard error.

The function of BrkA in vivo is independent of its role in complement resistance. Since the severity of the early colonization defect of the TohamaI-derived ${Delta}$ brkA strains correlates with their greater susceptibilityto naïve serum in vitro, we hypothesized that this colonizationdefect could be attributable to their greater sensitivity toantibody-independent complement killing in vivo. If this werethe case, then in mice deficient in complement component 3 (C3^–/–mice), the ${Delta}$ brkA strains would colonize at the same level aswild-type B. pertussis. In order to test this, groups of C3^–/–mice were inoculated with 10⁵ CFU of BP338, BP338 ${Delta}$ brkA, TohamaI, or Toh ${Delta}$ brkA and dissected 3 days postinoculation. The lungsof C3^–/– mice contained approximately 100-times-morewild-type bacteria than mutant of either background (Fig. 6).The defect of Tohama I-derived ${Delta}$ brkA strains in vivo is thereforenot attributable to their increased complement sensitivity seenin vitro, since it was observed even in complement-deficientmice. These results reveal an additional, significant role forBrkA in respiratory tract colonization by Tohama I-derived strains.

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FIG. 6. Colonization of wild-type and C3-deficient mice by Tohama I-derived wild-type and ${Delta}$ brkA mutants of B. pertussis. Groups of three 4-to 6-week-old C57B1/6 and C3^–/– mice were inoculated with 5 x 10⁵ CFU of Tohama I, Toh ${Delta}$ brkA, BP338, or BP338 ${Delta}$ brkA delivered in a 50-µl volume of PBS into the nares. The number of bacteria recovered from the lungs at 3 days postinoculation is expressed as the log₁₀ mean ± the standard error. Statistical differences between groups are indicated (*, P < 0.05). Dashed line indicates limit of detection.

DISCUSSION

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Discussion

Previous studies have shown significant variance in complementsensitivity between strains of B. pertussis (23). In order torigorously assess the role of BrkA in resisting complement-mediatedkilling, the same ${Delta}$ brkA mutation was introduced into severaldifferent strains. Two well studied laboratory strains, TohamaI and its nalidixic acid-resistant variant, BP338, as well astwo recent clinical isolates, 6068 and GMT1, were chosen asrepresentative strains of diverse origins with a wide rangeof serum sensitivities. Infection studies with wild-type strainsand their respective ${Delta}$ brkA mutants showed that BrkA is requiredfor efficient colonization of mice by Tohama I-derived strainsbut does not appear to have a critical role during early infectionby recent clinical isolates. This is possibly the result ofexpression of a compensatory mechanism in both recent isolates,making the function of BrkA redundant in these strains, as hasbeen observed for other Bordetella virulence factors (18).

While previous in vitro studies have shown BrkA to be involvedin resisting antibody-dependent complement killing in vitro,our observations suggest this is not a critical function ofBrkA during infection of the murine respiratory tract. The defectin colonization of Tohama I-derived ${Delta}$ brkA strains was observedon days 3 and 7, when B. pertussis-specific antibodies are undetectable,but was not observed on days 14 and thereafter, when B. pertussis-specificantibodies are readily detectable. The defect of Tohama I-derived ${Delta}$ brkA strains at early time points and the fact that B. pertussisis sensitive to antibody-independent complement killing in vitro,lead us to hypothesize that BrkA may be involved in resistingalternative pathway complement killing. Our in vitro experimentswere able to confirm earlier reports that BrkA is required forserum resistance in the presence of B. pertussis-specific antibodiesbut also showed BrkA to be important in the absence of theseantibodies (Fig. 3 and 4). Killing of B. pertussis was observedin similar assays performed with naive mouse serum and withserum from B-cell-deficient mice (µMT), confirming, respectively,that this phenotype was not dependent on the species from whichthe serum was obtained and that killing was independent of antibodypresence. Additionally, serum from complement-deficient micefailed to kill any of these strains, indicating that complement,as opposed to antimicrobial peptides, is responsible for thereduction of CFU (data not shown). Together these data indicatethat BrkA provides resistance to the antibody-dependent and-independent pathways of complement killing in vitro.

To determine whether this in vitro complement sensitivity couldaccount for the in vivo colonization defect, complement-deficientmice were infected with Tohama I-derived strains and their ${Delta}$ brkAmutants. Interestingly, the ${Delta}$ brkA strains were still defective,compared with wild-type B. pertussis, in their ability to colonizeC3^–/– mice, suggesting that the critical functionof BrkA in vivo is independent of its effects in resisting complement-mediatedlysis. This lack of correlation between in vitro complementsensitivity and in vivo infection ability is not unprecedented(2, 10). All the B. pertussis wild-type strains colonize miceat approximately 10⁶ CFU in the lungs on day 3 postinoculation,despite the fact that they have dramatically different sensitivitiesto naïve serum at what are thought to be physiologicallyrelevant concentrations ( $~$ 10% to 20%) (22). This may be explainedby the fact that B. pertussis has been shown to acquire resistanceto complement-mediated killing during the first 24 h of infection,even in the absence of BrkA (23).

Previous in vitro studies have described additional putativefunctions of BrkA, including adherence to and invasion of hostcells and resistance to killing by antimicrobial peptides (6,7, 9). However, these experiments were performed using BP2041,the original Tn5 insertion mutation of brkA in BP338, a strainnot analyzed in this study. The results of our study highlightthe variability of B. pertussis strains, both in their abilityto resist serum complement and in their requirement for BrkA,suggesting the need for a more in-depth examination of the functionof BrkA in vitro and in vivo.

ACKNOWLEDGMENTS

We thank Jane Pishko for critical reading and editing of themanuscript and Alison Weiss for helpful discussions and providingantibodies.

This work was supported by USDA grant 2002-35204-11684 and NIHgrant AI 053075.

FOOTNOTES

* Corresponding author. Mailing address: Department of Veterinary Science, Penn State University, 115 Henning Building, University Park, PA 16802. Phone: (814) 863-8522. Fax: (814) 863-6140. E-mail: eth10{at}psu.edu.

Editor: D. L. Burns

REFERENCES

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