The Moraxella catarrhalis Porin-Like Outer Membrane Protein CD Is an Adhesin for Human Lung Cells

The outer membrane protein CD (OMPCD) of Moraxella catarrhalisis an outer membrane protein with several attributes of a potentialvaccine antigen. We isolated four transposon mutants of strainO35E on the basis of their reduced binding to A549 human lungcells in microcolony formation assays, and we determined thatthey contain a transposon in ompCD. We also found that thesetransposon insertions had pleiotropic effects: mutants grewslower, became serum sensitive, bound $~$ 10-fold less to A549 cells,and appeared transparent when grown on solid medium. We confirmedthat these various phenotypes could be attributed solely todisruption of ompCD by constructing the isogenic strain O35E.CD1.O35E-ompCD was cloned, and recombinant Escherichia coli bacteriaexpressing the gene product exhibited a 10-fold increase inadherence to A549 cells. This is the first report of M. catarrhalisompCD mutants, and our findings demonstrate that this gene productis an adhesin for human lung cells.

INTRODUCTION

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Introduction

The gram-negative bacterium Moraxella catarrhalis is a pathogenof the human respiratory tract that causes otitis media in youngchildren (17, 20, 33, 44) and lower respiratory tract infectionsin adults with chronic obstructive pulmonary disease (44, 62,63). Patients with underlying conditions appear to be particularlysusceptible, as illustrated by the increasing number of casesof M. catarrhalis-caused wound infections, bronchitis, conjunctivitis,sinusitis, bacteremia, pneumonia, meningitis, pericarditis,and endocarditis (8, 14, 17, 33, 44, 51, 65, 68, 70, 71).

Little is known about pathogenesis by M. catarrhalis. Most researchhas thus far focused on the identification and characterizationof a few outer membrane proteins for vaccine development purposes.These include the adhesins UspA1 (30, 36, 37, 40, 41), UspA2H(36, 41), Hag (21, 22, 31, 54), McaP (69), and MID (23, 24,26, 43, 52), the serum resistance factor UspA2 (3, 4, 15, 18,36, 40, 41), the iron acquisition proteins CopB (2, 5, 11, 28,29, 64), LbpA/LbpB (11, 13, 19, 74), TbpA/TbpB (13, 16, 50,74), and OmpB1 (12, 13, 38, 39), and the highly conserved proteinsouter membrane protein E (OMPE) (9, 10, 45) and OMPCD (32, 46,47, 61). Although no specific biological function has been attributedto OMPCD, this molecule is predicted to be structurally similarto bacterial porins (47) and binds middle ear mucin (59). Thus,OMPCD may be involved in nutrient acquisition and/or adherenceto mucosal surfaces.

The present study describes the isolation and characterizationof ompCD mutants of the M. catarrhalis wild-type strain O35E,and the data demonstrate that OMPCD is an adhesin for A549 humanlung epithelial cells.

MATERIALS AND METHODS

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Materials and Methods

Strains, plasmids, tissue culture cell lines, and growth conditions. Strains and plasmids are described in Table 1. M. catarrhalisstrains were grown at 37°C in Todd Hewitt (TH) broth (Difco)or on TH agar plates in an atmosphere of 92.5% air-7.5% CO₂.M. catarrhalis transposon mutants were selected with 20 µgof kanamycin (KAN)/ml. Escherichia coli strains were grown inLuria-Bertani (LB) broth (Difco) or on LB agar plates. For theselection of recombinant E. coli clones, the LB medium was supplementedwith either 100 µg of ampicillin/ml, 50 µg of KAN/ml,or 15 µg of chloramphenicol/ml. For adherence and serumbactericidal assays with recombinant E. coli cells, 5-ml cultureswere grown overnight at 37°C with shaking (200 rpm). Theseovernight cultures were diluted into 20 ml of fresh broth supplementedwith 0.25 ml of 1000X CopyControl induction solution (Epicentre)and grown at 37°C for 2 h with vigorous shaking (300 rpm).Chang (conjunctival epithelium; ATCC CCL20.2), A549 (type IIalveolar lung epithelium; ATCC CCL85), and human middle earepithelial cells (HMEE) were cultured as described elsewhere(31).

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TABLE 1. Plasmids and strains

Recombinant DNA techniques. Standard molecular biology methods were performed as describedpreviously (60). M. catarrhalis genomic DNA was prepared withthe Invitrogen Easy-DNA kit. Plasmid DNA was purified with theQIAprep Spin Miniprep system (Qiagen). The North2South chemiluminescentnucleic acid hybridization and detection system (Pierce) wasused to perform Southern blotting experiments. A 1.2-kb DNAfragment containing a kan^r cartridge was obtained from the plasmidpUC4K and used as a probe in some of these experiments. The1.2-kb ompCD-specific DNA probe was obtained by PCR using theoligonucleotide primers P1 and P2 (see below).

PCR and cloning. Amplification of DNA fragments was performed with the PlatinumPfx DNA polymerase (Invitrogen) unless indicated otherwise.The ompCD-specific oligonucleotide primers P1 (5'-GTGACAGTCAGCCCACTA-3')and P2 (5'-TTGCTACCAGTGATTACTGC-3') were used to amplify a 1.2-kbDNA fragment from strain O35E that corresponds to a truncatedopen reading frame (ORF). The primers P3 (5'-GGATCGCTATGCTAAAATAGGTGC-3')and P4 (5'-TCAAAAGCTAAGAAAACCGCT-3') were used to generate a1.6-kb amplicon from O35E containing the complete ompCD ORFand which was utilized as template in sequencing reactions aswell as in cloning experiments with the Epicentre CopyControlPCR cloning system. Taq DNA polymerase (Invitrogen) was usedin other PCR-based experiments. The plasmid pCC1.3 correspondsto the Epicentre CopyControl vector pCC1, into which the manufacturer'scontrol DNA insert was cloned.

Transposon mutagenesis and adherence assays. M. catarrhalis O35E transposon mutants were obtained using theEZ::TN <KAN-2> transposome (Epicentre), and mutants werescreened in microcolony formation assays to identify those substantiallyreduced in their adherence to A549 cells, as we have previouslyreported (31). The method used to quantitatively measure theadherence of M. catarrhalis to human tissue culture cell lineshas been described elsewhere and involves a 3-h incubation priorto washing unbound bacteria (31). Adherence assays with E. colirecombinant cells involved a 5-min incubation prior to washingunbound bacteria.

Construction of isogenic mutants. An amplicon of 1.2 kb containing a truncated ompCD ORF fromstrain O35E was generated with the primers P1 and P2 (see above)and was ligated into the vector pUC19, yielding the recombinantplasmid pELCD. The latter was linearized with DraIII, treatedwith Pfu DNA polymerase (Stratagene) to render the restrictedends blunt, and ligated with a 1.2-kb SmaI DNA fragment containingthe kan^r cassette from the plasmid pUC4K. This ligation mixturewas introduced into E. coli TOP10, and transformants were selectedfor resistance to KAN, thereby yielding the plasmid pELCDKAN.A 2.4-kb amplicon, which corresponds to a truncated O35E-ompCDgene interrupted by the kan^r cartridge in the middle of theORF, was generated from pELCDKAN using the primers P1 and P2.This PCR product was then electroporated into M. catarrhalisstrain O35E. The resulting kan^r colonies were screened by PCRwith primers P1 and P2 to identify potential isogenic ompCDmutants (data not shown). Southern blotting experiments wereperformed to confirm that proper allelic exchange had occurredin the isogenic mutant O35E.CD1 (data not shown).

MAbs and characterization of selected protein antigens. The UspA1- and UspA2-specific monoclonal antibody (MAb) 17C7(4), the UspA1-specific MAb 24B5 (18), and the Hag-specificMAb 5D2 (54) have been described elsewhere. The OMPCD MAbs 1D3and 3.9H have been reported previously (46). Outer membranevesicles were prepared as described by others (49, 53). Whole-celllysates of M. catarrhalis strains and E. coli recombinant cellswere prepared as previously reported (18, 53). These preparationswere heated at 100°C for 15 min, resolved by sodium dodecylsulfate-polyacrylamide gel electrophoresis (SDS-PAGE), and eitherstained with Coomassie blue or electrophoretically transferredto polyvinylidene difluoride membranes (Millipore) for Westernblot analysis as previously described (31).

Serum resistance assays. Serum bactericidal assays were performed as reported by Aebiet al. (3). Results are expressed as the percentage (±standard deviation) of bacteria surviving incubation with serum.These assays were performed on at least three separate occasions.

RNA purification and QRT-PCR. The methods, primers, and probes used for RNA purification andquantitative real-time PCR (QRT-PCR) in these experiments havebeen described elsewhere (31).

Nucleotide sequence analysis. The nucleotide sequence data were analyzed as previously reported(31).

Statistical methods. All statistical analyses were performed using a Mann-Whitneytest and GraphPad Prism 2.01 software. P values of <0.05were considered statistically significant.

Nucleotide sequence accession number. The nucleotide sequence of the M. catarrhalis O35E ompCD genehas been deposited in GenBank under the accession number AY493741.

RESULTS

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Results

ompCD mutations have pleiotropic effects. We recently described a mutagenesis and screening approach whichidentified nine adherence mutants in M. catarrhalis strain O35E(31). These mutants showed substantially lower binding to A549human lung cells in microcolony formation assays, and all containeda transposon in the hag gene. This screening approach also yieldedfour adherence mutants that were not described in our originalreport because their growth was significantly impaired. Figure1 illustrates this defect for the representative mutant O35E.TN52.We also found that these four slower-growing mutants expressedwild-type levels of Hag, UspA1, and UspA2 (Fig. 2). Since Hagappears to be the main adhesin for A549 and HMEE cells (23,31), we reasoned that the apparent adherence defect exhibitedby the four slow-growing mutants in microcolony assays mightsimply result from their poor growth.

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FIG. 1. Growth of M. catarrhalis strains in broth cultures. Symbols: squares, O35E; inverted triangles, O35E.TN52.

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FIG. 2. Western blot analysis of M. catarrhalis strains. Proteins present in outer membrane vesicles prepared from the wild-type strain O35E (lane 1), the transposon mutant O35E.TN52 (lane 2), and the isogenic mutant O35E.CD1 (lane 3) were resolved by SDS-PAGE and analyzed by Western blotting with the UspA1- and UspA2-specific MAb 17C7 (A), the UspA1-specific MAb 24B5 (B), and the Hag-specific MAb 5D2 (C). Note that samples were heated at 100°C for 15 min prior to Western blot analysis. Under these conditions, UspA1 migrates as a 125-kDa protein and UspA2 migrates as a high-molecular-weight aggregate that is expressed in large amounts (bracket on the right side of panel A). Positions of molecular mass markers are shown to the left in kilodaltons. The arrowheads indicate selected antigens.

Even though Southern blotting experiments suggested that thesefour isolates are not siblings (data not shown), their coloniesall appeared transparent in contrast to the opaque morphologyof the parent strain O35E (Fig. 3). We also observed that allfour isolates lacked expression of a major OMP of 55 kDa (Fig.4A). Several larger antigens were also absent in the mutants(Fig. 4A).

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FIG. 3. Appearance of M. catarrhalis strains on agar plates. The wild-type strain O35E (bottom left) and the transposon mutant O35E.TN52 (top right) were streaked onto TH agar plates and photographed with lighting from above against a black background. Plates were incubated for 24 h.

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FIG. 4. Western blot analysis of M. catarrhalis strains. Proteins present in outer membrane vesicles prepared from the wild-type strain O35E (lane 1) as well as the transposon mutants O35E.TN52 (lane 2), O35E.TN313 (lane3), O35E.TN593 (lane 4), and O35E.TN649 (lane 5) and from the isogenic mutant O35E.CD1 (lane 6) were resolved by SDS-PAGE and stained with Coomassie blue (A) or analyzed by Western blotting with the OMPCD-specific MAbs 1D3 (B) and 3.9H (C). Positions of molecular mass markers are shown to the right in kilodaltons. The arrow as well as arrowheads indicate antigens that are missing in the transposon as well as the O35E.CD1 mutants.

It was previously shown that OMPCD is a heat-modifiable proteinthat migrates with a molecular mass of approximately 55 kDa(61). We therefore tested by Western blotting whether the majorOMP missing from the transparent mutants was OMPCD. Lanes 2to 5 in Fig. 4B demonstrate that the mutants no longer detectablyexpressed OMPCD. Western blotting experiments with the OMPCD-specificMAb 3.9H (Fig. 4C) also suggested that the higher-molecular-massantigens missing from outer membrane vesicles of the mutants(Fig. 4A) were multimers of OMPCD. When we analyzed the mutantsby PCR, the ompCD-specific primers P1 and P2 yielded an ampliconof 1.2 kb in the parent strain O35E and one of 2.4 kb in thetransposon mutants (data not shown). These results are consistentwith the 1,221-bp EZ::TN <KAN-2> transposon having insertedinto the ompCD gene of all four independently isolated transparentmutants. This was confirmed by Southern blot analysis with ompCD-and transposon-specific probes (data not shown).

We constructed the isogenic ompCD strain O35E.CD1 to test whetherthe various phenotypes of our four transposon mutants couldbe attributed solely to disruption of the ompCD gene. We foundthat O35E.CD1 is transparent (data not shown), has an OMP profileindistinguishable from that of the transposon mutants (Fig.4A, lane 6), lacks expression of OMPCD (Fig. 4B and C, lane6), expresses wild-type levels of Hag, UspA1, and UspA2 (Fig.2), and exhibits a growth defect similar to that of the transposonmutants (data not shown). Furthermore, we observed that O35E.TN52(4.4% ± 8.2% survival) and O35E.CD1 (1.8% ± 2.5%survival) were sensitive to 10% normal human serum, whereasO35E was resistant (117.8% ± 15.4% survival). The uspA2mutant O35E.2 (2.3% ± 2.4% survival) was used as a serum-sensitivecontrol (3, 36), and heat inactivation of the serum abolishedits ability to kill mutants (data not shown).

Taken together, these results demonstrate that ompCD mutationsaffect the growth, colony morphology, and serum resistance ofM. catarrhalis O35E, but they do not affect expression of theadhesins UspA1 and Hag or that of the serum resistance factorUspA2.

The transposon insertion in O35E-ompCD does not significantly affect expression of the gene located directly downstream. BLAST searches of the patented M. catarrhalis genome throughNCBI databases identified the ompCD ORF (nucleotides 79050 to77770 of AX067466) as well as the ORF located directly downstream(nucleotides 77514 to 75670 of AX067466). This ORF is predictedto encode a protein with 70% identity (83% similarity) to Salmonellaenterica serovar Typhimurium GTP-binding elongation factor familyprotein BipA (NP_462889.1). To demonstrate that the variousphenotypes of ompCD mutants were not due to a polar effect onexpression of the gene downstream of ompCD, we used QRT-PCRto measure the expression of M. catarrhalis bipA. We used expressionof the unlinked M. catarrhalis gene purH, which we recentlyreported to be located downstream of the hag gene (31), as anormalization control. No significant change in bipA expressionwas observed between the wild-type strain O35E (relative expression± standard deviation, 1.0 ± 0.7), the O35E.TN52transposon mutant (1.73 ± 0.3), and the O35E.CD1 isogenicmutant (2.2 ± 0.9). Previous work and these data makeit unlikely that the various phenotypes of the ompCD mutantsare due to changes in transcription of bipA.

OMPCD expression affects the adherence of strain O35E to A549 human lung cells. The apparently reduced binding of ompCD mutants to A549 cellsin microcolony formation assays might simply reflect their slowergrowth rate. These assays entail a 40-h incubation with A549cells (31). We therefore measured the adherence of our mutantsafter 3 h of incubation, as previously reported (31). Table2 shows that the transparent mutants attached substantiallyless well to A549 cells, as did the isogenic ompCD strain O35E.CD1.It should be noted that the hag mutant O35E.TN2 (31) was usedas an adherence negative control in the assays.

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TABLE 2. Adherence of M. catarrhalis strains to human cells in vitro

To test whether this was a general defect in adherence, we measuredthe binding of ompCD mutants to Chang monolayers and found thatthey attached at nearly wild-type levels to these conjunctivalcells (Table 2). UspA1 has been reported to be the major adhesinfor Chang cells (3, 36), and the isogenic uspA1 mutant O35E.1was used as an adherence negative control in our assay. Thus,the ompCD mutants express a functional UspA1 adhesin. We alsofound that the lack of OMPCD expression did not adversely affectM. catarrhalis binding to HMEE cells (Table 2). We previouslyreported that Hag is the major adhesin for HMEE cells (31);thus, the hag mutant O35E.TN2 was used as an adherence negativecontrol in these experiments. Taken together, our results demonstratedthat OMPCD expression specifically affects adherence to A549human lung cells.

Cloning and expression of O35E ompCD by recombinant E. coli cells. To determine whether OMPCD plays a direct role in serum resistanceand adherence to A549 cells, we cloned and expressed this genein E. coli strain EPI300 using Epicentre's CopyControl PCR cloningsystem. This system allowed the recombinant plasmid pMHCD1.2to be maintained at a very low copy number. Under these conditions,OMPCD expression was not detectable (data not shown). Upon incubationat 37°C for 2 h and in the presence the CopyControl inducersolution, which boosts the plasmid copy number to 10 to 200per cell, however, recombinant bacteria expressed detectableOMPCD (Fig. 5A). When we tested these induced cells in adherenceassays, we found that OMPCD expression increased binding toA549 monolayers by 10-fold after only 5 min of incubation withthese lung cells (Fig. 5B and C). Thus, OMPCD is an adhesinfor A549 cells. OMPCD expression, however, did not confer serumresistance on E. coli (data not shown).

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FIG. 5. Western blot analysis of and adherence assays with E. coli recombinant bacteria. (A) Proteins present in whole-cell lysates of EPI300 pCC1.3 and EPI300 pMHCD1.2 were resolved by SDS-PAGE and then analyzed by Western blotting with the OMPCD-specific MAb 1D3. These lysates were prepared from cells grown in the presence of the Epicentre's CopyControl inducer solution for 2 h. Positions of molecular mass markers are shown to the right in kilodaltons. (B) Visual adherence assays. Recombinant bacteria were grown under the aforementioned conditions. Unbound bacteria were washed off A549 cells after a 5-min incubation, and the monolayers were stained with Giemsa. (C) Quantitative adherence assays. Results are expressed as the percentage (± standard error) of recombinant bacteria binding to A549 cells after 5 min of incubation.

The ompCD gene harbored by the plasmid pMHCD1.2 was sequencedto verify that no mutations were introduced by PCR. This O35EompCD sequence was also found to be identical to that of ATCC25240 ompCD (accession number L10755) and was deposited in theGenBank database.

DISCUSSION

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Discussion

The M. catarrhalis OMPCD protein exhibits numerous propertiesof a promising vaccine candidate. This antigen is surface exposedand is expressed by virtually all M. catarrhalis isolates testedto date (32, 47, 61). Immunization with recombinant OMPCD confersprotective immunity in a mouse pulmonary clearance test (48),and the protein is an important target of the immune responsein chronic obstructive pulmonary disease patients with M. catarrhalisinfections (46). In addition, the predicted amino acid sequenceof OMPCD is highly conserved among clinical isolates (32, 47),and our results extend these data. We found that the nucleotideand predicted amino acid sequences of O35E ompCD were identicalto those of ATCC 25240 ompCD previously reported by Murphy andcolleagues (47). The biological function(s) of OMPCD, however,has not been determined. Sequence analysis indicated that itis related to porins and that the most closely related geneproduct is the Pseudomonas aeruginosa porin OprF (47). Porinsform a large family of OMPs that are involved in numerous biologicalfunctions, including nutrient acquisition (1, 34, 35). Sinceour data show that ompCD mutants have slower growth rates, OMPCDmay therefore be involved in passage of a nutrient(s) acrossthe M. catarrhalis outer membrane. Our isogenic ompCD mutantswill facilitate the testing of this hypothesis.

Reddy and coworkers previously reported that OMPCD binds mucinglycoproteins, suggesting that it may be involved in adherenceto mucosal surfaces (59). We found that ompCD mutants showedreduced binding to A549 human lung cells, supporting this hypothesis.We also recently showed that the M. catarrhalis O35E Hag proteinis an adhesin for A549 cells (23, 31). Thus, one possible explanationfor the decreased adherence of ompCD mutants is that the lackof OMPCD in the outer membrane affects the proper surface displayof Hag, which in turn reduces adherence to A549 cells. Our results,however, argue against this possibility. We have previouslyshown that Hag is a major adhesin for middle ear cells (31).The ompCD mutant O35E.TN52 binds at near-wild-type levels toHMEE cells, whereas the hag mutant O35E.TN2 no longer attaches(Table 2). The ompCD mutant therefore expresses a functionalHag adhesin. Furthermore, OMPCD expression by recombinant E.coli bacteria increased adherence to A549 cells by 10-fold (Fig.5). These data provide direct proof that OMPCD is an adhesin.Interestingly, P. aeruginosa OprF was recently shown to be anadhesin for A549 cells (7). Our results suggest that both Hagand OMPCD are involved in the binding of M. catarrhalis to A549cells. Bacterial adherence is multifactorial and generally involvesseveral steps, such as initial contact (from a distance) andclose (tight) binding (27, 42, 66, 67). Since Pearson et al.demonstrated that Hag forms extended projections that coverM. catarrhalis O35E cells (54), Hag may initially contact A549cells, whereas OMPCD is necessary for a closer interaction.Thus, both Hag and OMPCD may cooperate in specifically conferringadherence to A549 cells. We are currently investigating thishypothesis.

Our data also show that ompCD mutants are serum sensitive. Thiseffect, however, might be indirect, since expression of recombinantOMPCD does not confer E. coli with the ability to resist thebactericidal activity of human complement. The lack of OMPCDexpression in the outer membrane may thus affect proper surfacedisplay of a serum resistance factor, which in turn rendersbacteria sensitive to complement killing. Candidate serum resistancefactors include UspA2 (3, 36), CopB (29), fur-regulated genes(25), OmpE (45), and LOS (75). The transparent appearance ofompCD mutants may also be indirectly linked to the lack of OMPCDexpression. For instance, it has been demonstrated for gram-negativepathogens such as Haemophilus influenzae (73) and Neisseriameningitidis (6) that changes in LOS structure and/or levelsof expression cause differences in colony opacity.

Alternatively, recombinant E. coli bacteria may not expressenough OMPCD to confer serum resistance, or the protein requiresposttranslational modification that is not achieved in thisheterologous genetic background. It is interesting that searchesusing the NCBI Conserved Domain Search tool indicate that OMPCDis related to the OmpA OMP and related peptidoglycan-associated(lipo)proteins family (COG2885; E value of 4e-24). E. coli K1OmpA has been shown to mediate invasion of human brain microvascularendothelial cells (55, 57, 58) and thus is almost certainlyinvolved in physical interactions with mammalian cells. Furthermore,E. coli OmpA plays a role in serum resistance. An ompA mutantshowed greater sensitivity to normal human serum (72), and Prasadaraoand colleagues recently demonstrated that OmpA contributes toserum resistance by binding to the complement C4b binding protein(56). Thus, M. catarrhalis OMPCD may very well play direct rolesin resistance to complement killing and colony opacity.

In summary, this study reports the characterization of M. catarrhalisompCD mutants isolated by their reduced adherence properties.Phenotypic analyses indicate that the lack of OMPCD expressionleads to pleiotropic effects. The availability of isogenic strainsas well as recombinant clones expressing the protein will facilitateestablishing whether OMPCD is directly involved in nutrientacquisition, resistance to complement killing, and/or conferringthe opaque appearance of M. catarrhalis wild-type strains. Ourfinding that OMPCD is an adhesin for human lung cells also suggeststhat a vaccine containing this protein (or portions thereof)may interfere with adherence, which is an important step inbacterial pathogenesis. Identifying an M. catarrhalis OMPCDepitope(s) involved in adherence and evaluating its vaccinogenicpotential could significantly contribute to the developmentof a vaccine for this important human pathogen.

ACKNOWLEDGMENTS

This study was supported in part by institutional start-up fundsfrom the Medical College of Ohio, a grant from the ThrasherResearch Fund (award number 02816-6), and a grant from the NationalInstitute of Allergy and Infectious Diseases, National Institutesof Health (AI051477) to E.R.L.

We thank Tim Murphy at the University of Buffalo and Eric Hansenat the University of Texas Southwestern Medical Center in Dallasfor providing M. catarrhalis strains and antibodies. We alsothank Thomas DeMaria at Ohio State University for providingcultures of human middle ear cells. We also thank Tim Murphy,Eric Hansen, Robert Blumenthal, and Mark Wooten for their helpfulcomments on the manuscript.

FOOTNOTES

* Corresponding author. Mailing address: Department of Microbiology and Immunology, Medical College of Ohio, Health Education Building, 3055 Arlington Ave., Toledo, Ohio 43614-5806. Phone: (419) 383-6626. Fax: (419) 383-3002. E-mail: elafontaine{at}mco.edu.

Editor: V. J. DiRita

REFERENCES

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