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Infection and Immunity, September 1998, p. 4183-4192, Vol. 66, No. 9
Pasteur Merieux Connaught Canada Research,
North York, Ontario, Canada M2R 3T4,1 and
Department of Microbiology and Infectious Diseases, University
of Calgary, Calgary, Alberta, Canada T2N 4N12
Received 8 January 1998/Returned for modification 29 April
1998/Accepted 16 June 1998
The transferrin binding protein genes (tbpA and
tbpB) from two strains of Moraxella
catarrhalis have been cloned and sequenced. The
genomic organization of the M. catarrhalis
transferrin binding protein genes is unique among known bacteria in
that tbpA precedes tbpB and there is a third
gene located between them. The deduced sequences of the M. catarrhalis TbpA proteins from two strains were
98% identical, while those of the TbpB proteins from the same
strains were 63% identical and 70% similar. The third gene, tentatively called orf3, encodes a protein of
approximately 58 kDa that is 98% identical between the two strains.
The tbpB genes from four additional strains of
M. catarrhalis were cloned and sequenced,
and two potential families of TbpB proteins were identified based
on sequence similarities. Recombinant TbpA (rTbpA), rTbpB, and
rORF3 proteins were expressed in Escherichia coli and
purified. rTbpB was shown to retain its ability to bind human
transferrin after transfer to a membrane, but neither rTbpA nor
rORF3 did. Monospecific anti-rTbpA and anti-rTbpB antibodies were
generated and used for immunoblot analysis, which demonstrated that
epitopes of M. catarrhalis TbpA and TbpB
were antigenically conserved and that there was constitutive expression
of the tbp genes. In the absence of an appropriate animal
model, anti-rTbpA and anti-rTbpB antibodies were tested for their
bactericidal activities. The anti-rTbpA antiserum was not
bactericidal, but anti-rTbpB antisera were found to kill heterologous
strains within the same family. Thus, if bactericidal ability is
clinically relevant, a vaccine comprising multiple rTbpB antigens may
protect against M. catarrhalis disease.
In recent years,
Moraxella (Branhamella) catarrhalis has
gained recognition as a significant human pathogen (for reviews, see references 5, 9, and 24). It
has been identified as a cause of bacteremia, epiglottitis, meningitis,
otitis media, and pneumonia in children, adults, and the elderly.
M. catarrhalis is the third leading
cause of otitis media in children, responsible for about 20% of
disease, following Streptococcus pneumoniae and nontypeable
Haemophilus influenzae. In adults and the elderly, M. catarrhalis is mainly associated with
chronic respiratory ailments such as bronchitis or pneumonia, where it
exacerbates the disease. Invasive diseases such as bacteremia and
meningitis are less common but can be fatal (7, 18, 23).
Approximately 70% of children will experience at least one bout of
otitis media by the time they are 3 years old, with many children
having multiple episodes (36). The peak incidence of otitis
media occurs in children between 1 and 2 years of age, at a time when
their language skills are developing. Recurrent or chronic otitis media
can lead to deafness, speech impairment, or learning disabilities.
Treatments include antibiotics or surgery to remove tonsils and
adenoids or the insertion of tympanostomy tubes. The estimated cost of
these primary treatments is about $2 billion dollars per year in the
United States alone (3), with secondary costs such as speech
therapy and special education classes costing billions more per year.
In addition, most strains of M. catarrhalis
are resistant to Bacteria have evolved several mechanisms to overcome host iron
restriction, including the use of siderophores and iron binding proteins such as transferrin, lactoferrin, hemin, and
hemoglobin binding proteins. To obtain iron from host iron binding
proteins, M. catarrhalis utilizes both
transferrin and lactoferrin binding proteins (31). Other
characterized bacterial transferrin receptors are composed of two
proteins, transferrin binding protein A (TbpA) and transferrin
binding protein B (TbpB). In vivo, both TbpA and TbpB bind human
transferrin, but only TbpB will still bind transferrin after sodium
dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) and
electroblotting (31). The tbpA and
tbpB genes, encoding the TbpA and TbpB proteins, from
strains of Actinobacillus pleuropneumoniae, H. influenzae, Neisseria gonorrhoeae, N. meningitidis, and Pasteurella haemolytica have been
cloned and sequenced (2, 6, 10, 11, 20, 22, 27). The TbpA
proteins are generally highly conserved within a species, while the
TbpB proteins tend to be more variable. For N. meningitidis, it was found that the TbpB proteins could be
separated into two families based on sequence and antigenicity
(28); however, there are common antigenic domains in the
TbpB proteins from N. meningitidis, N. gonorrhoeae, H. influenzae, and A. pleuropneumoniae (17, 33). Furthermore, TbpBs from
N. meningitidis, H. influenzae, and
A. pleuropneumoniae have been demonstrated to be
protective antigens in various animal challenge models (1, 21, 22,
29).
In this report, we describe the cloning and sequence analysis of the
genes encoding the Tbps from M. catarrhalis. Recombinant Tbps (rTbps) were expressed
in Escherichia coli, and the purified proteins were used
to immunize animals. It was found that rTbpB elicited bactericidal
antibodies and could therefore represent a potential antigen for
inclusion in a vaccine against M. catarrhalis.
Recombinant DNA techniques.
Restriction endonucleases were
purchased from Boehringer Mannheim (Laval, Quebec, Canada), New England
Biolabs (Mississauga, Ontario, Canada), Bethesda Research Laboratories,
or Pharmacia and were used according to the manufacturers'
specifications. Oligonucleotides were synthesized on an ABI model 380B
DNA synthesizer and purified by chromatography (Oligonucleotide
Purification Cartridge; Perkin-Elmer, Foster City, Calif.). To
facilitate the cloning of some of the tbp fragments,
additional restriction enzyme sites for ClaI,
MstII, SfiI, and AvrII were introduced
between the SalI and HindIII sites of
pBluescript.SK, generating plasmid pSKMA. Other recombinant DNA
methods were performed as specified by Sambrook et al. (30).
Bacterial strains and media.
M.
catarrhalis 3 and 4223 were clinical isolates provided
by T. Murphy (State University of New York, Buffalo); strains Q8 and R1
were gifts from M. Bergeron (University of Laval, Montreal, Quebec, Canada); strain LES-1 was obtained from L. Stenfors (University of Tromso, Tromso, Finland); strain VH-9 was obtained from V. Howie (University of Texas, Galveston); strains H-04 and M35 were obtained from G. D. Campbell (Louisiana State University,
Shreveport); and strain ATCC 25240 was purchased from the American Type
Culture Collection (Rockville, Md.). M. catarrhalis strains were maintained on Mueller-Hinton
agar (Becton Dickinson, Cockeysville, Md.) or grown in brain
heart infusion medium (BHI; Difco, Detroit, Mich.), with or
without the addition of
ethylenediamine-di(O-hydroxyphenylacetic acid) (EDDA; Sigma,
St. Louis, Mo.) as described previously (15). E. coli strains were grown in YT (Difco) or NZCYM (Becton Dickinson) medium supplemented with 100 µg of ampicillin per ml as
required.
Purification of native TbpA and TbpB and generation of
antisera.
Native TbpA and TbpB were individually purified
from M. catarrhalis 4223 by affinity
chromatography using human transferrin immobilized on Sepharose as
described previously (41). Guinea pigs (Hartley outbred;
Charles River, Quebec, Quebec, Canada) were immunized intramuscularly
on day 1 with 5 µg of purified protein emulsified in complete
Freund's adjuvant (Difco) and were boosted on days 14 and 29 with the
same dose of protein emulsified in incomplete Freund's adjuvant
(Difco). Blood was collected on day 42.
Cloning the M. catarrhalis tbp
genes.
Chromosomal DNA and EMBL3 libraries were prepared as
described previously (22). Briefly, chromosomal DNA from
M. catarrhalis 4223, Q8, and M35 was
partially digested with Sau3AI and size fractionated.
Fragments of 15 to 23 kb were ligated with BamHI-digested EMBL3 arms (Promega, Madison, Wis.) and packaged according to the
manufacturer's instructions. The 4223 library, grown in the presence of 200 µM EDDA, was screened with anti-TbpA and anti-TbpB antibodies, and three putative clones that reacted with both antisera were identified. The production of the appropriate protein bands was confirmed by reactivity of the antisera with electroblotted protein obtained from trichloroacetic acid-precipitated culture lysates.
0019-9567/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
The Transferrin Binding Protein B of Moraxella
catarrhalis Elicits Bactericidal Antibodies and Is a
Potential Vaccine Antigen
ABSTRACT
Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
INTRODUCTION
Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
-lactam antibiotics such as the penicillins,
although treatment with cephalosporin, macrolide, and tetracycline
antibiotics has been successful (8, 25). The need for an
effective otitis media vaccine is obvious.
MATERIALS AND METHODS
Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
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-32P]dCTP-labeled oligonucleotide probes that
differed by four nucleotides (underlined) and were based on the
TbpA-specific sequence
IRDLTRYDPG: I R D L T R Y D P G ATT CGC GAC TTA ACA CGC TAT GAC CCT GGC ATT CGT GAT TTA ACT CGC TAT GAC CCT GGT
Phage clone SLRD-A contained a 13-kb SalI
insert of the Q8 tbp locus, and the tbpA and
tbpB genes were localized by restriction enzyme and Southern
blot analyses. Fragments were subcloned into pSKMA: plasmid pSLRD1
contains a 1.6-kb SalI-AvrII insert, plasmid pSLRD2 contains a 2-kb AvrII fragment, plasmid pSLRD4
contains a 4.1-kb AvrII insert, pSLRD3 contains a 2.2-kb
AvrII-EcoRI fragment, and plasmid pSLRD5 contains
a 3.8-kb EcoRI-PstI insert. Figure 1B illustrates
the restriction map and subclones of the Q8 transferrin receptor locus.
The M35 phage library was screened with a digoxigenin-labeled
(Boehringer Mannheim) 4223 tbpA gene probe. Phage clone
M35-2.3 was found to contain a 13-kb insert of the M35 tbp
genes. The tbpB gene was localized to a 7.5-kb
NheI-SalI fragment by restriction enzyme and
Southern blot analyses and was subcloned into pBR328, generating
plasmid pLEM40.
PCR amplification of M. catarrhalis tbpB genes from additional strains. The tbpB gene was PCR amplified from three additional M. catarrhalis strains (3, LES-1, and R1), using oligonucleotide primers based on the sequences 5'-GATGGGATAAGCACGCCCTACTT-3' (sense) and 5'-CCCATCAGCCAAACAAACATTGTGT-3' (antisense), which are found in the intergenic regions surrounding 4223 tbpB.
PCR amplification was performed in buffer containing 10 mM Tris-HCl (pH 8.9), 25 mM KCl, 5 mM (NH4)2SO4, and 2 mM MgSO4. Each 100-µl reaction mixture contained 10 ng of chromosomal DNA, 1 µg of each primer, 2.5 U of Pwo DNA polymerase (Boehringer Mannheim), and 0.2 mM deoxynucleoside triphosphates (Perkin-Elmer). The cycling conditions were 25 cycles of 95°C for 30 s, 45°C for 1.0 min, and 72°C for 2.0 min, followed by a 10-min elongation at 72°C. Specific 2.4-kb fragments were amplified, and DNA was purified for direct sequencing by agarose gel extraction, using a Geneclean kit (Bio 101 Inc., Vista, Calif.).Sequencing of the M. catarrhalis tbp genes. Plasmid DNA for sequencing was prepared by using a Qiagen (Chatsworth, Calif.) Plasmid Midi kit. To ensure a complete sequence, phage DNA was used to sequence across the joins of subclones. DNA samples were sequenced with an ABI model 373A DNA sequencer, using dye terminator chemistry. Oligonucleotide primers 17 to 25 bases in length were used to sequence both strands of the genes.
Construction of clones expressing rTbpA or rTbpB. Plasmids pLEM3 and pLEM25 contain the strain 4223 tbpA gene (Fig. 1A). pLEM 3 was digested with BglI and HindIII to generate a 1.8-kb fragment comprising most of tbpA but without the extreme 5' sequence. Oligonucleotides were synthesized to re-create the first 61 bases of the tbpA gene to the BglI site, and an NdeI site was added at the 5' end for cloning purposes. The NdeI-BglI oligonucleotides were ligated with the BglI-HindIII fragment and cloned into plasmid pT7-7 (35) that had been digested with NdeI and HindIII, generating plasmid pLEM27. pLEM25 was digested with HindIII to excise the 1.6-kb 3' fragment of tbpA, which was inserted into pLEM27 that had been digested with HindIII and dephosphorylated. DNA from the resulting plasmid, pLEM29, was used to transform E. coli BL21(DE3) cells. Since the 4223 and Q8 tbpA genes were so similar, only the 4223 rTbpA protein was expressed.
Constructs that would express the M. catarrhalis rTbpB proteins with or without their lipoprotein signal sequences were generated. Plasmid pLEM23 contains most of the 4223 tbpB gene, excluding the extreme 5' end. Oligonucleotides were synthesized to re-create the first 58 bp of the tbpB gene encoding the mature TbpB protein up to an NheI site, and an NdeI site was added at the 5' end for cloning purposes. pLEM23 was digested with NheI and ClaI, excising a 1.0-kb fragment of tbpB which was ligated with the oligonucleotides and pT7-7 that had been digested with NdeI and ClaI. The resulting plasmid, pLEM31, thus contains the 5' half of 4223 tbpB encoding the mature protein. Oligonucleotides were synthesized to re-create the ~104-bp extreme 3' end of tbpB from ClaI to an AvaII site, and a BamHI site was added for cloning purposes. pLEM23 was digested with ClaI and AvaII, and the 0.9-kb fragment was ligated with the AvaII-BamHI oligonucleotides and inserted into pT7-7 that had been digested with BamHI and ClaI, generating plasmid pLEM32. The 1.0-kb NdeI-ClaI fragment of pLEM31 and the 1.0-kb ClaI-BamHI fragment of pLEM32 were ligated into pT7-7 that had been digested with NdeI and BamHI. The resulting plasmid, pLEM33, thus contains the full-length strain 4223 tbpB gene encoding the mature TbpB protein under the control of the T7 promoter. To express the strain 4223 tbpB gene encoding the lipoprotein, pLEM33 was digested with NdeI and NheI to excise the ~58-bp 5' fragment, and NdeI-NheI oligonucleotides encoding the lipoprotein leader sequence were substituted. The resulting plasmid was designated pLEM37. Similar schemes were used to generate the strain Q8 tbpB expression plasmids pSLRD35A and pSLRD35B, which express the lipoprotein and mature protein, respectively.Expression and purification of recombinant proteins.
Plasmid DNA was purified by using a Qiagen Plasmid Midi kit and was
used to transform E. coli BL21(DE3) cells (Novagen,
Madison, Wis.) by electroporation. Overnight cultures were grown in YT broth containing ampicillin, and a 1:50 inoculum was grown to an
optical density at 578 nm (OD578) of 0.3 before induction
with 400 µM isopropyl--D-thiogalactopyranoside for
3 h. rTbpA, rTbpB, and rORF3 were produced as inclusion bodies
in E. coli and were purified by the same process. To
purify rTbpA, cells from 500-ml culture were resuspended in 50 ml
of 50 mM Tris-HCl (pH 8.0) containing 0.1 M NaCl and 5 mM
4-(2-aminoethyl)-benzenesulfonylfluoride protease inhibitor
(Calbiochem, La Jolla, Calif.) and disrupted by sonication (three
10-min pulses, 70% duty circle). The suspension was centrifuged at
20,000 × g for 30 min, and the pellet was extracted
with 50 ml of 50 mM Tris-HCl (pH 8.0) containing 0.5% Triton
X-100 and 10 mM EDTA. The sample was centrifuged as
described above, and the resultant pellet was further extracted with 50 ml of 50 mM Tris-HCl (pH 8.0) containing 2 M urea and 5 mM
dithiothreitol (DTT). Centrifuged as above, the resultant pellet
contained inclusion bodies of rTbpA. The protein was
solubilized in 50 mM Tris-HCl (pH 8.0) containing 6 M guanidine
hydrochloride and 5 mM DTT. The sample was centrifuged for
clarification, and the supernatant was purified on a Superdex 200 gel
filtration column equilibrated in 50 mM Tris-HCl (pH 8.0) containing 2 M guanidine hydrochloride and 5 mM DTT. The fractions were analyzed by
SDS-PAGE; those containing rTbpA were pooled, and Triton X-100 was
added to a final concentration of 0.1%. The sample was dialyzed
overnight at 4°C against 50 mM Tris-HCl (pH 8.0) and clarified by
centrifugation for 30 min, and the supernatant was stored at 
20°C.
Transferrin binding assay. The transferrin binding activity of rTbpA, rTbpB, and rORF3 was assessed by the method of Schryvers and Lee (31), with modifications. Briefly, purified recombinant protein was subjected to discontinuous electrophoresis through SDS-12.5% polyacrylamide gels. The proteins were electrophoretically transferred to a polyvinylidene difluoride (PVDF) membrane (Millipore, Bedford, Mass.) and incubated with horseradish peroxidase (HRP)-conjugated human transferrin (1:50 dilution; Jackson ImmunoResearch Labs Inc., Mississauga, Ontario, Canada) at 4°C overnight. LumiGLO substrate (Kirkegaard & Perry Laboratories, Inc., Gaithersburg, Md.) was used for chemiluminescent detection of HRP activity according to the manufacturer's instructions.
Immunization of animals and immunoassays. Groups of five BALB/c mice (Charles River) were injected three times subcutaneously on days 1, 29, and 43 with purified rTbpB (0.3 to 10 µg) in the presence or absence of AIPO4 (1.5 mg per dose). Blood samples were taken on days 14, 28, 42, and 56 for analyzing the anti-rTbpB antibody titers by enzyme-linked immunosorbent assay (ELISA).
Groups of two guinea pigs (Hartley outbred; Charles River) were immunized intramuscularly with 5-µg doses of purified rTbpA or rTbpB emulsified in complete or incomplete Freund's adjuvant as described above. Anti-Tbp antibody titers in guinea pig immune sera were determined by antigen-specific ELISAs as previously described (40). Microtiter wells (Nunc-MAXISORB, Nunc, Roskilde, Denmark) were coated with 50 µl of protein (0.5 µg ml
1). The reactive titer of an antiserum was defined as
the reciprocal of the highest dilution consistently showing a twofold
increase in absorbance at 450 nm over that obtained with the preimmune serum samples.
Whole-cell ELISAs. M. catarrhalis 4223 was grown in the presence of EDDA as described above. Cell pellets were collected by centrifugation, washed with phosphate-buffered saline (PBS), and resuspended in 50 mM carbonate-bicarbonate buffer (pH 9.6). The OD490 of the suspension was adjusted to 0.5, and 200 µl of a 1:100 dilution of whole bacteria was used to coat microtiter wells. The plates were air dried at 37°C overnight and then blocked with PBS-0.1% bovine serum albumin at 37°C for 1 h (250 µl per well). After three washes with PBS-0.1% Tween 20, 200 µl of antiserum at an appropriate dilution (in PBS-0.1% gelatin) was added to the wells and further incubated at 37°C for 2 h. Affinity-purified F(ab')2 fragment of donkey anti-guinea pig immunoglobulin G (heavy plus light chain) antibodies conjugated to HRP (Jackson ImmunoResearch Laboratories) was used as the reporter. The reactions were developed by using tetramethylbenzidine-H2O2 (ADI), and absorbancies were measured at 450 nm (using 540 nm as a reference wavelength) in a Flow Multiskan MCC microplate reader (ICN Biomedicals).
Antigenic conservation of Tbps in M. catarrhalis. M. catarrhalis strains were grown in BHI medium with or without 25 µM EDDA. Sample concentrations were standardized, and whole-cell lysates were separated by SDS-PAGE and electrophoretically transferred to PVDF membranes. Guinea pig anti-4223 rTbpA or anti-4223 rTbpB antibody was used as primary antibody, and HRP-conjugated goat anti-guinea pig immunoglobulin G antibody was used as secondary antibody. Approximately 90 M. catarrhalis strains, obtained from North America or Finland, were tested for their antigenic reactivities.
Bactericidal antibody activity.
The bactericidal antibody
assay was performed as previously described (39). Briefly,
the M. catarrhalis strains were grown to an
OD578 of 0.5 in BHI medium containing 25 µM EDDA.
The bacteria were diluted so that approximately 150 to 450 CFU was
added to each reaction. Guinea pig anti-rTbpA or anti-rTbpB
antiserum and prebleed serum controls were heated to 56°C
for 30 min to inactivate endogenous complement and were diluted 1:64
with Veronal buffer containing 0.1% bovine serum albumin (VBS)
(39). Guinea pig complement (Biowhittaker, Walkersville,
Md.) was diluted 1:10 in VBS. Aliquots of 25 µl each of diluted
antiserum, bacteria, and complement were added to duplicate wells of a
96-well microtiter plate (Nunc). The plates were incubated at 37°C
for 60 min, with gentle shaking at 70 rpm on a rotary platform; 50 µl
of each reaction mixture was plated onto Mueller-Hinton agar plates
(Becton Dickinson), which were incubated at 37°C for 24 h and
then at room temperature for 24 h before the bacteria were
counted. Antisera were determined to be bactericidal if 
50% of
bacteria were killed compared with preimmune serum controls. Each assay
was repeated at least twice in duplicate. Anti-4223 rTbpB antisera from
two guinea pigs gave identical results at 1:64 dilution; however, only
one of two anti-Q8 rTbpB antisera exhibited bactericidal activity at
1:64 dilution. Statistical analysis was performed by the Mann-Whitney
rank sum test.
Nucleotide sequence accession numbers. The nucleotide sequences of the genes in the tbp loci from M. catarrhalis 4223 and Q8 have been deposited at GenBank and assigned accession no. AF039312 and AF039315, respectively. The accession numbers for the nucleotide sequences of the tbpB genes from M. catarrhalis 3, LES-1, M35, and R1 are AF039311, AF039313, AF039314, and AF039316, respectively.
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RESULTS |
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Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
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Cloning of the M. catarrhalis tbp genes. The genomic tbp genes were cloned from a phage expression library of M. catarrhalis 4223, using monospecific anti-TbpA and anti-TbpB antisera. The genomic tbp genes were cloned from additional phage libraries of M. catarrhalis Q8 and M35, using DNA probes. The phage clones contained approximately 13-kb inserts which had very similar restriction enzyme maps. The entire insert could not be cloned into plasmids, and so multiple subclones of the 4223 and Q8 tbp genes encompassing the whole sequence were generated (Fig. 1). The M35 tbpB gene was subcloned and the tbpB genes from three additional M. catarrhalis strains (3, LES-1, and R1) were amplified by PCR using primers derived from the flanking regions of 4223 tbpB.
Analysis of the nucleotide sequence of the tbp
genes.
The 4223- and Q8-derived tbp genes were
sequenced in their entirety and were found to include three complete
genes and two partial genes, found at each end of the 13-kb
inserts. The arrangement of the M. catarrhalis tbp genes was unique compared with that of
other known bacterial tbp operons, in that the
tbpA gene preceded the tbpB gene, with an
intergenic distance of approximately 2.8 kb. A third open reading
frame, designated orf3, was found to be located between
tbpA and tbpB. The tbpA,
tbpB, and orf3 genes are approximately 3.2, 2.1, and 1.5 kb, respectively, in length. The distance between
tbpA and orf3 is about 1 kb, and that between orf3 and tbpB is approximately 273 bp.
Putative promoter elements could be identified upstream of all three
genes (Fig. 2A). We did not find a
complete Fur (ferric uptake regulator)-binding sequence overlapping the
10 region of the promoter, such as identified in other bacterial
tbpB promoters (Fig. 2B).
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Analysis of the deduced amino acid sequences of the Tbps. The deduced strain 4223 and strain Q8 TbpA proteins are 1,074 and 1,070 residues, respectively, in length and are 98% identical (Fig. 3). The encoded 4223 and Q8 TbpA proteins have molecular masses of 119.4 and 118.9 kDa, respectively. The M. catarrhalis TbpA protein sequences are somewhat larger than sequences of other known TbpA proteins, but there is still about 40% identity and 52 to 53% similarity with the H. influenzae, N. gonorrhoeae, and N. meningitidis TbpA proteins, as illustrated in Fig. 3 (6, 20, 22). The main difference between the M. catarrhalis TbpA and other TbpA proteins appears to be an approximately 112-residue insert in the M. catarrhalis proteins between residues 572 and 684. There is another, smaller insert of 19 residues located between residues 800 and 819.
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Expression, purification, and characterization of recombinant proteins. The 4223 rTbpA, 4223 rTbpB, Q8 rTbpB, and 4223 rORF3 proteins were produced as inclusion bodies in E. coli, using the inducible T7 promoter system. The rTbpA and rORF3 proteins were produced at ~10% of total protein, while the rTbpB protein (with lipoprotein leader) was produced at about 20% of total protein. The proteins have been purified by similar methods which involve enrichment for the inclusion bodies after sonic disruption of the cells, solubilization of the inclusion bodies, and then by Superdex 200 chromatography (Fig. 5A). The recombinant proteins were further characterized for their ability to bind to human transferrin after transfer to a PVDF membrane as described for the N. meningitidis and H. influenzae rTbpB proteins (22, 37). Both the 4223 and Q8 rTbpB proteins bound human transferrin (Fig. 5B), but under the same conditions, rTbpA and rORF3 did not bind (data not shown).
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Antigenic conservation and bactericidal antibody activities. Hyperimmune sera directed against the purified rTbpA or rTbpB proteins were raised in guinea pigs. As shown in Table 1, the recombinant TbpA and TbpB proteins generated high-titer antibodies. On immunoblot analysis, the anti-rTbpA antiserum recognized specific proteins in all of the 32 M. catarrhalis strains tested, and both the anti-4223 rTbpB and anti-Q8 rTbpB antisera recognized specific proteins in all of approximately 90 M. catarrhalis strains tested. Representative immunoblot data for samples grown under iron-replete or iron-deficient conditions and probed with anti-rTbpA or anti-rTbpB antiserum are presented in Fig. 6.
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50% killing was chosen as significant. Anti-4223
rTbpA antibody was not bactericidal against either the homologous strain or strain Q8 and was not tested further.
Anti-4223 rTbpB antibody was bactericidal against the homologous strain and five of eight heterologous strains, while anti-Q8 rTbpB antibody killed two heterologous strains (Table
2).
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DISCUSSION |
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Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
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The bacterial tbp loci from A. pleuropneumoniae, H. influenzae, N. gonorrhoeae, N. meningitidis, and P. haemolytica have been cloned and sequenced, and the gene arrangement has always been found to be tbpB followed by tbpA (2, 10, 11, 20, 22, 27). The distance between the two genes has ranged from as little as 13 bp for H. influenzae to 87 bp for N. meningitidis (20, 22). A single promoter sequence has been identified upstream of the tbpB gene, suggesting that the genes form an operon. In addition, the polar effects of transcriptional terminators in the N. gonorrhoeae and N. meningitidis tbpB genes provide direct evidence for an operonic arrangement (2, 19). In M. catarrhalis, there is a unique gene arrangement of tbpA-orf3-tbpB, and there are three potential promoter sequences suggesting possible independent transcription of the genes. This unexpected gene arrangement has been confirmed in three independent clinical isolates of M. catarrhalis, strains 4223, Q8, and M35, indicating that it was not an artifact of cloning. Recently, Ogunnariwo et al. (26) found that the degenerate primers designed to PCR amplify the junctional region between tbpB and tbpA worked in all species tested except M. catarrhalis, M. bovis, and M. lacunata. The lack of a typical tbpB-tbpA gene arrangement in M. catarrhalis demonstrated in this study provides a logical explanation for these findings and also suggests that this situation may apply for the other Moraxella species.
In many bacterial species, the product of the fur gene
represses the transcription of iron-regulated genes. A consensus
sequence for Fur binding has been determined for several E. coli promoters (13), and Fur-binding sequences
overlapping the 10 regions of the N. meningitidis and
H. influenzae tbpB promoters have been identified
(11, 20). However, only a short homologous sequence can be
identified in the 10 region of the M. catarrhalis tbpB promoter, and there is very limited
dyad symmetry (Fig. 2). These data suggest that expression of the
M. catarrhalis Tbps may be regulated by a
novel mechanism.
Consistent with other bacterial Tbps, the M. catarrhalis TbpA proteins from strains 4223 and Q8 are highly conserved, while the corresponding TbpB proteins are more variable. While the M. catarrhalis TbpA proteins are very similar to each other, they are longer than TbpA proteins from other species, the main differences being two inserts of about 112 and 19 residues in the central region of each of the proteins (Fig. 3). Compared to a proposed TbpA/LbpA topology model (12), the inserts are found in the seventh and ninth extracellular loops, respectively. The 112-residue insert contains an extra two cysteine residues and two potential transmembrane sequences located at 587 to 596 and 608 to 617, which could result in extra periplasmic and extracellular loops. When the sequences of the TbpB proteins from six M. catarrhalis strains were compared, they appeared to separate into two groups, one more closely related to strain 4223, which included strains R1 and M35, with the other family comprised of strains Q8 and 3. The TbpB protein from strain LES-1 was equally similar to both families. The six strains from which the tbpB genes were cloned were chosen for their geographic diversity and anatomic source (Table 2). Strains 4223 and 3 are from Buffalo, N.Y.; strains M35, Q8, and R1 are from Montreal, Quebec, Canada; and strain LES-1 is from Finland. Strains 4223, LES-1, and M35 were all derived from patients with otitis media, while strains 3, R1, and Q8 were from sputum or bronchial secretions. There appears to be no correlation between the geographic or anatomic source of the organism and the TbpB sequence. Compared to the TbpB proteins from other organisms, there is limited homology found scattered throughout the sequence in short motifs (27). The conservation of these sequences among the TbpB proteins from several species suggests that they serve a functional or structural role. It is interesting that only the M. catarrhalis 3 TbpB protein contains the VCCSNLEHLKFG motif (conserved residues underlined) found in all other TbpB proteins.
The recombinant TbpA and TbpB proteins were expressed in good yield from E. coli, with the rTbpB proteins expressed at approximately 20% of total protein. Although the M. catarrhalis TbpB protein was designed to be expressed as the mature lipoprotein, it was found that the recombinant protein was expressed as inclusion bodies and was not associated with the membrane. There are two possible explanations for this: first, the M. catarrhalis signal sequence does not function in E. coli; and second, the high expression level of the recombinant protein dictates that the host produces it in inclusion bodies. In this respect, the observation that A. pleuropneumoniae rTbpB was found in both an outer membrane and an inclusion body fraction during high-level expression (10) may indicate that the latter explanation is a greater contributing factor.
Since no other bacterial transferrin receptors had been shown to include a third protein, we wished to determine whether the ORF3 protein was part of the transferrin binding complex for M. catarrhalis. Although the M. catarrhalis rTbpB proteins retained the ability to bind human transferrin after electroblotting, as has been demonstrated for the N. meningitidis and H. influenzae rTbpB proteins (22, 37), neither rTbpA nor rORF3 did. To determine whether the orf3 gene was iron repressible, we had planned to generate specific anti-rORF3 antisera and perform immunoblot analyses of strains grown with and without EDDA. However, although we were able to express rORF3 protein in good yield from E. coli, we were unable to generate antibodies in guinea pigs after five immunizations, and the protein was not studied further (data not shown).
The rTbpA and rTbpB proteins were both found to be highly immunogenic, and polyclonal antibodies were used to assess antigenic conservation and bactericidal antibody activity. By immunoblot analysis, specific ~115-kDa TbpA and ~80-kDa TbpB proteins were identified in all strains examined. Both TbpA and TbpB were found to be produced constitutively when grown in BHI medium under iron-sufficient conditions (Fig. 6). However, in some strains it appeared that the expression of TbpA (samples 1, 7, and 9) and/or TbpB (samples 1 to 3 and 6 to 8) could be increased under iron-limiting conditions, i.e., the addition of the iron chelator EDDA. This effect could be reversed upon addition of exogenous iron (data not shown). The immunoblot results are consistent with the earlier finding of Schryvers and Lee (31), who used dot bots to show that M. catarrhalis expressed low levels of transferrin and lactoferrin binding proteins under iron-sufficient conditions. Holland et al. (16) have demonstrated that fresh clinical isolates of H. influenzae type b expressed Tbps constitutively, although passaged laboratory strains expressed iron-regulated Tbps. Hardie et al. (14) have also demonstrated constitutive expression of Tbp in most invasive H. influenzae type b and approximately 40% of commensal Haemophilus species that bound transferrin.
An approximately 80-kDa M. catarrhalis outer membrane protein, designated OMP B1, has been identified in patient sera from adults with bronchiectasis or children with otitis media (4, 32). This protein was shown to bind transferrin and, judging from its molecular weight, would therefore appear to be TbpB. More extensive studies on the human immune response to the transferrin receptor proteins indicate that there is a strong reactivity against TbpB but little or no reactivity against TbpA (30a).
There is currently no animal model of otitis media caused by
M. catarrhalis, and so bactericidal
antibody activity was used as a surrogate assay to assess candidate
vaccine antigens, on the assumption that bactericidal antibody activity
may correlate with clearance or protection. M. catarrhalis strains have a tendency to aggregate or
clump, and using the naturally nonclumping strain Q8 or a spontaneous
nonclumping mutant of strain 4223, termed RH408, we had previously
developed a bactericidal antibody assay for M. catarrhalis (39). By expanding the assay to
include aggregating strains, we have been able to use it to screen
candidate vaccine antigens. The anti-rTbpA antibody did not kill
its homologous strain and was not pursued further. TbpA is a
transmembrane protein, and it was possible that we had not
re-formed the native conformation after purification from inclusion
bodies and the antibody was unable to recognize the native TbpA
protein in intact bacteria. However, we have demonstrated that both
anti-rTbpA and anti-rTbpB antibodies recognize intact bacteria in a
whole-cell ELISA with antibody titers of 400 to 1,600, suggesting that
this is not the reason for the lack of bactericidal antibody activity
observed with anti-rTbpA (data not shown). The anti-4223 rTbpB
antibody was bactericidal against the homologous strain and, with an
arbitrary cutoff of 50% killing, was also bactericidal for five of
eight heterologous strains. From our sequence data, strains 4223, M35, and R1 appeared to be closely related, and the bactericidal antibody data showed that anti-4223 rTbpB killed strains 4223, M35, and R1. It
also killed strains VH-9, H-04 and ATCC 25240, suggesting that these
latter strains might have TbpB proteins with sequences similar to
that of 4223 TbpB. The anti-Q8 rTbpB antibody was considerably poorer
at killing heterologous strains, killing only strains H-04 and LES-1.
When the bactericidal antibody activities were quantitated by
increasing antibody dilutions, it was found that anti-Q8 rTbpB antibody
was much less bactericidal against strain Q8 than anti-4223 rTbpB
antibody was against strain 4223. Anti-4223 rTbpB antibody was still
capable of killing 50% of 4223 cells at an antibody dilution of about
1:12,000, whereas anti-Q8 rTbpB antibody killed 50% of Q8 cells at a
maximum dilution of about 1:100. It is not clear why the anti-Q8 rTbpB
antibody has such relatively low bactericidal antibody activity, but it
is interesting that anti-Q8 rTbpB antibody killed LES-1 and the more
potent anti-4223 rTbpB antibody did not. The identification of two
putative families of M. catarrhalis TbpB
proteins based on genetic and antigenic properties is reminiscent of the N. meningitidis TbpB proteins, for which two
families have been identified (28). Strain H-04 is
unique in that it was killed by both anti-rTbpB antisera. It
would be interesting to determine the tbpB gene
sequence from this strain and to investigate whether anti-H-04
rTbpB antiserum can kill M. catarrhalis
strains from both putative families.
In summary, we have cloned and sequenced the transferrin receptor locus from M. catarrhalis and demonstrated that it has a unique organization that includes a third gene. Our data indicate that there are at least two possible families of M. catarrhalis TbpB proteins that can be identified on the basis of their sequences. Using a bactericidal antibody assay to screen, our data demonstrate that antibody raised to a rTbpB protein from one family was able to kill other members of the family but was unable to kill members of the second family. If protection against M. catarrhalis can be afforded by the generation of bactericidal antibodies in the host, then the TbpB proteins represent good candidate vaccine antigens.
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ACKNOWLEDGMENTS |
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We thank Bill Bradley for synthesis of oligonucleotides and Diane England for DNA sequencing. We also acknowledge the excellent technical assistance of Debbie Coleman, Manjit Haer, Deon Persaud, and Wan Xu-Li.
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FOOTNOTES |
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* Corresponding author. Mailing address: Pasteur Merieux Connaught Canada Research, 1755 Steeles Ave., W., North York, Ontario, Canada M2R 3T4. Phone: (416) 667-2932. Fax: (416) 667-2740. E-mail: sloosmore{at}ca.pmc-vacc.com.
Editor: J. G. Cannon
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REFERENCES |
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Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
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|---|
| 1. |
Ala'Aldeen, D. A. A.
1996.
Transferrin receptors of Neisseria meningitidis: promising candidates for a broadly cross-protective vaccine.
J. Med. Microbiol.
44:237-243 |
| 2. |
Anderson, J. E.,
P. F. Sparling, and C. N. Cornelissen.
1994.
Gonococcal transferrin-binding protein 2 facilitates but is not essential for transferrin utilization.
J. Bacteriol.
176:3162-3170 |
| 3. | Bluestone, C. D. 1989. Modern management of otitis media. Pediatr. Clin. North Am. 36:1371-1377[Medline]. |
| 4. | Campagnari, A. A., T. F. Ducey, and C. A. Rebmann. 1996. Outer membrane protein B1, an iron-repressible protein conserved in the outer membrane of Moraxella (Branhamella) catarrhalis, binds human transferrin. Infect. Immun. 64:3920-3924[Abstract]. |
| 5. |
Catlin, B. W.
1990.
Branhamella catarrhalis: an organism gaining respect as a pathogen.
Clin. Microbiol. Rev.
3:293-320 |
| 6. |
Cornelissen, C. N.,
G. D. Biswas,
J. Tsai,
D. K. Paruchuri,
S. A. Thompson, and P. F. Sparling.
1992.
Gonococcal transferrin-binding protein 1 is required for transferrin utilization and is homologous to TonB-dependent outer membrane receptors.
J. Bacteriol.
174:5788-5797 |
| 7. | Daoud, A., F. Abuekteish, and H. Masaadeh. 1996. Neonatal meningitidis due to Moraxella catarrhalis and review of the literature. Ann. Trop. Paediatr. 16:199-201[Medline]. |
| 8. | Doern, G. V., A. B. Brueggemann, G. Pierce, T. Hogan, H. P. Holley, Jr., and A. Rauch. 1996. Prevalence of antimicrobial resistance among 723 outpatient clinical isolates of Moraxella catarrhalis in the United States in 1994 and 1995: results of a 30-center national surveillance study. Antimicrob. Agents Chemother. 40:2884-2886[Abstract]. |
| 9. |
Enright, M. C., and H. McKenzie.
1997.
Moraxella (Branhamella) catarrhalis clinical and molecular aspects of a rediscovered pathogen.
J. Med. Microbiol.
46:360-371 |
| 10. |
Gonzalez, G. C.,
R.-H. Yu,
P. Rosteck, and A. B. Schryvers.
1995.
Sequence, genetic analysis, and expression of Actinobacillus pleuropneumoniae transferrin receptor genes.
Microbiology
141:2405-2416 |
| 11. | Gray-Owen, S. D., S. Loosmore, and A. B. Schryvers. 1995. Identification and characterization of genes encoding the human transferrin-binding proteins from Haemophilus influenzae. Infect. Immun. 63:1201-1210[Abstract]. |
| 12. | Gray-Owen, S. D., and A. B. Schryvers. 1996. Bacterial transferrin and lactoferrin receptors. Trends Microbiol. 4:185-191[Medline]. |
| 13. |
Griggs, D. W., and J. Konisky.
1989.
Mechanism for iron-regulated transcription of the Escherichia coli cir gene: metal-dependent binding of Fur protein to the promoters.
J. Bacteriol.
171:1048-1054 |
| 14. |
Hardie, K. R.,
R. A. Adams, and K. J. Towner.
1993.
Transferrin-binding ability of invasive and commensal isolates of Haemophilus spp.
J. Med. Microbiol.
39:218-224 |
| 15. | Harkness, R. E., M.-J. Guimond, B.-A. McBey, M. H. Klein, D. H. Percy, and B. A. Croy. 1993. Branhamella catarrhalis pathogenesis in SCID and SCID/beige mice. APMIS 101:805-810[Medline]. |
| 16. |
Holland, J.,
P. R. Langford,
K. J. Towner, and P. Williams.
1992.
Evidence for in vivo expression of transferrin-binding proteins in Haemophilus influenzae type b.
Infect. Immun.
60:2986-2991 |
| 17. |
Holland, J.,
T. R. Parsons,
A. A. Hasan,
S. M. Cook,
P. Stevenson,
E. Griffiths, and P. Williams.
1996.
Conservation and antigenic cross-reactivity of the transferrin-binding proteins of Haemophilus influenzae, Actinobacillus pleuropneumoniae and Neisseria meningitidis.
Microbiology
142:3505-3513 |
| 18. | Ioannidis, J. P. A., M. Worthington, J. K. Griffiths, and D. R. Snydman. 1995. Spectrum and significance of bacteremia due to Moraxella catarrhalis. Clin. Infect. Dis. 21:390-397[Medline]. |
| 19. | Irwin, S. W., N. Averil, C. Y. Cheng, and A. B. Schryvers. 1993. Preparation and analysis of isogenic mutants in the transferrin receptor protein genes, tbpA and tbpB, from Neisseria meningitidis. Mol. Microbiol. 8:1125-1133[Medline]. |
| 20. | Legrain, M., V. Mazarin, S. W. Irwin, B. Bouchon, M.-J. Quentin-Millet, E. Jacobs, and A. B. Schryvers. 1993. Cloning and characterization of Neisseria meningitidis genes encoding the transferrin-binding proteins Tbp1 and Tbp2. Gene 130:73-80[Medline]. |
| 21. | Lissolo, L., G. Maitre-Wilmotte, P. Dumas, M. Mignon, B. Danve, and M.-J. Quentin-Millet. 1995. Evaluation of transferrin-binding protein 2 within the transferrin-binding protein complex as a potential antigen for future meningococcal vaccines. Infect. Immun. 63:884-890[Abstract]. |
| 22. | Loosmore, S. M., Y.-P. Yang, D. C. Coleman, J. M. Shortreed, D. M. England, R. E. Harkness, P. S.-C. Chong, and M. H. Klein. 1996. Cloning and expression of the Haemophilus influenzae transferrin receptor genes. Mol. Microbiol. 19:575-586[Medline]. |
| 23. | Meyer, G. A., T. R. Shope, N. J. Waecker, Jr., and F. H. Lanningham. 1995. Moraxella (Branhamella) catarrhalis bacteremia in children. A report of two cases and review of the literature. Clin. Pediatr. 34:146-150. |
| 24. |
Murphy, T. F.
1996.
Branhamella catarrhalis: epidemiology, surface antigenic structure, and immune response.
Microbiol. Rev.
60:267-279 |
| 25. |
Nissinen, A.,
P. Gronroos,
P. Huovinen,
E. Herva,
M.-L. Katila,
T. Klaukka,
S. Kontiainen,
O. Liimatainen,
S. Oinonen, and P. H. Makela.
1995.
Development of -lactamase-mediated resistance to penicillin in middle-ear isolates of Moraxella catarrhalis in Finnish children, 1978-1993.
Clin. Infect. Dis.
21:1193-1196[Medline].
|
| 26. |
Ogunnariwo, J. A., and A. B. Schryvers.
1996.
Rapid identification and cloning of bacterial transferrin and lactoferrin receptor protein genes.
J. Bacteriol.
178:7326-7328 |
| 27. | Ogunnariwo, J. A., T. K. W. Woo, R. Y. C. Lo, G. C. Gonzalez, and A. B. Schryvers. 1997. Characterization of the Pasteurella haemolytica transferrin receptor genes and the recombinant receptor proteins. Microb. Pathog. 23:273-284[Medline]. |
| 28. | Rokbi, B., V. Mazarin, G. Maitre-Wilmotte, and M.-J. Quentin-Millet. 1993. Identification of two major families of transferrin receptors among Neisseria meningitidis strains based on antigenic and genomic features. FEMS Microbiol. Lett. 110:51-58[Medline]. |
| 29. | Rossi-Campos, A., C. Anderson, G.-F. Gerlach, S. Klashinsky, A. A. Potter, and P. J. Willson. 1992. Immunization of pigs against Actinobacillus pleuropneumoniae with two recombinant protein preparations. Vaccine 10:512-518[Medline]. |
| 30. | Sambrook, J., E. F. Fritsch, and T. Maniatis. 1989. Molecular cloning: a laboratory manual, 2nd ed. Cold Spring Harbor Laboratory, Cold Spring Harbor, N.Y. |
| 30a. | Schryvers, A. B. Unpublished data. |
| 31. | Schryvers, A. B., and B. C. Lee. 1989. Comparative analysis of the transferrin and lactoferrin binding proteins in the family Neisseriaceae. Can. J. Microbiol. 35:409-415[Medline]. |
| 32. | Sethi, S., S. L. Hill, and T. F. Murphy. 1995. Serum antibodies to outer membrane proteins (OMPs) for Moraxella (Branhamella) catarrhalis in patients with bronchiectasis: identification of OMP B1 as an important antigen. Infect. Immun. 63:1516-1520[Abstract]. |
| 33. |
Stevenson, P.,
P. Williams, and E. Griffiths.
1992.
Common antigenic domains in transferrin-binding protein 2 of Neisseria meningitidis, Neisseria gonorrhoeae, and Haemophilus influenzae type b.
Infect. Immun.
60:2391-2396 |
| 34. | Struyve, M., M. Moons, and J. Tommassen. 1991. Carboxy-terminal phenylalanine is essential for the correct assembly of a bacterial outer membrane protein. J. Mol. Biol. 218:141-148[Medline]. |
| 35. |
Tabor, S., and S. S. Richardson.
1985.
A bacteriophage T7 RNA polymerase/promoter system for controlled exclusive expression of specific genes.
Proc. Natl. Acad. Sci. USA
82:1074-1078 |
| 36. | Teele, D., J. Klein, B. Rosner, and the Greater Boston Otitis Media Study Group. 1989. Epidemiology of otitis media during the first seven years of life in children in greater Boston: a prospective, cohort study. J. Infect. Dis. 160:83-94[Medline]. |
| 37. |
Vonder Haar, R. A.,
M. Legrain,
H. V. J. Kolbe, and E. Jacobs.
1994.
Characterization of a highly structured domain in Tbp2 from Neisseria meningitidis involved in binding to human transferrin.
J. Bacteriol.
176:6207-6213 |
| 38. | Wu, H. C., and M. Tokunaga. 1986. Biogenesis of lipoproteins in bacteria. Curr. Top. Microbiol. Immunol. 125:127-157[Medline]. |
| 39. | Yang, Y. P., L. E. Myers, U. McGuinness, P. Chong, Y. Kwok, M. H. Klein, and R. E. Harkness. 1997. The major outer membrane protein, CD, extracted from Moraxella (Branhamella) catarrhalis is a potential vaccine antigen that induces bactericidal antibodies. FEMS Immunol. Med. Microbiol. 17:187-199[Medline]. |
| 40. | Yang, Y. P., R. S. Munson, Jr., S. Grass, P. Chong, R. E. Harkness, L. Gissoni, O. James, Y. Kwok, and M. H. Klein. 1997. Effect of lipid modification on the physicochemical, structural, antigenic and immunoprotective properties of Haemophilus influenzae outer membrane protein P6. Vaccine 15:976-987[Medline]. |
| 41. | Yu, R.-H., and A. B. Schryvers. 1993. The interaction between human transferrin and transferrin binding protein 2 from Moraxella (Branhamella) catarrhalis differs from that of other human pathogens. Microb. Pathog. 15:433-445[Medline]. |
Infection and Immunity, September 1998, p. 4183-4192, Vol. 66, No. 9
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Copyright © 1998, American Society for Microbiology. All rights reserved.
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