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Previous Article | Next Article 
Infection and Immunity, June 2000, p. 3362-3367, Vol. 68, No. 6
0019-9567/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
Pilus-Mediated Adherence of Haemophilus
influenzae to Human Respiratory Mucins
Martin
Kubiet,1
Reuben
Ramphal,1
Allan
Weber,2 and
Arnold
Smith2,*
Department of Medicine, University of
Florida, Gainesville, Florida 32611,1 and
Department of Microbiology, University of Missouri, Columbia,
Missouri 652122
Received 16 December 1999/Returned for modification 22 February
2000/Accepted 16 March 2000
 |
ABSTRACT |
Haemophilus influenzae, especially the nontypeable
strains, are among the most common pathogens encountered in patients
with chronic lung disease and otitis media. We and others have
demonstrated that respiratory isolates of nontypeable H. influenzae bind to human mucins, but the mechanism of binding is
not entirely clear. We have therefore examined the role of pili in the
adherence of both type b and nontypeable H. influenzae to
human respiratory mucins. We used isogenic H. influenzae
strains with a mutation in the structural gene for pilin
(hifA), a laboratory H. influenzae strain
transformed with a type b pilus gene cluster (from strain C54),
antibodies raised against H. influenzae HifA, and
Escherichia coli strains carrying a cloned type b pilus
gene cluster (from strain AM30) in these studies. All bacteria lacking
HifA or the pilus gene cluster had decreased adherence of piliated
H. influenzae to mucins, and Fab fragments of anti-HifA
antibodies inhibited the adherence. E. coli strains
carrying the cloned type b pilus gene cluster were six to seven times
more adhesive than strains carrying the vector. The role of other
putative adhesins was not examined and thus cannot be excluded, but
these studies support a role for pili in the binding of H. influenzae to human respiratory mucins.
| |
INTRODUCTION |
Haemophilus influenzae
continues to be an important pathogen encountered in lung diseases such
as chronic bronchitis and cystic fibrosis (25) and in otitis
media (37). This organism is able to colonize the
respiratory tract for prolonged periods in patients with chronic
bronchitis and cystic fibrosis, undergoing antigenic drift in certain
outer membrane proteins (15). It has the potential to attach
to both airway mucus (3, 22, 24, 29) and airway cells
(11, 20, 34, 35, 40) or both (43), but there appears to be a preference for mucus during the early encounter with
the respiratory epithelium (30). This ability to attach to
mucus may in part explain the potential of this organism to persist in
the respiratory tract, since mucociliary clearance is abnormal in these diseases.
A variety of surface structures on H. influenzae can mediate
adherence to eukaryotic cells. Scott and Old (32) first
reported that H. influenzae possessed mannose-resistant
hemagglutinating (MRHA) fimbriae. In 1982, two groups separately
reported that type b H. influenzae possessed MRHA surface
structures, which they called pili, that mediated adherence to human
buccal epithelial cells or oropharyngeal cells (16, 27).
Others have found that type b H. influenzae with
peritrichous pili had greater binding to buccal epithelial cells than
to HEp-2 cells (31), while a different laboratory, surveying
nontypeable H. influenzae (ntHi) isolated from sputum or
conjunctiva, found that 3 of 15 isolates possessed fimbriae, primarily
polar in location (1).
Pili are present on both typeable H. influenzae and ntHi and
mediate MRHA through the erythrocyte (RBC) antigen AnWj. These structures also mediate binding to buccal epithelial cells
(39), with the receptors on those cells being sialyl
gangliosides (38). The pilins from all strains examined up
to this time, whether on typeable H. influenzae or ntHi, are
68% identical and 77% similar at the amino acid level (2, 6, 7,
12).
Other surface structures which mediate the adhesion of ntHi to
eukaryotic cells have also been characterized. High-molecular-weight surface proteins identified as HMW-1 and HMW-2 facilitate adherence to
Chang epithelial cells (33). HMW-1 and HMW-2 are unique to ntHi and are not found on type b H. influenzae
(33). The ntHi isolates which lack HMW-1 and HMW-2 genes
usually possess another adhesin gene, identified as hia, and
occasionally a portion of the pilus gene cluster (20). Some
ntHi isolates also produce a protein identified as Hap with sequence
similarity to H. influenzae immunoglobulin A (IgA) protease,
which also facilitates binding to Chang cells (34). Surface
fimbrils (Hsf), proteins closely related to Hia, are also present on
the surfaces of certain H. influenzae isolates
(35). We chose not to study these other adhesins.
Recently, the affinity of H. influenzae for mucus,
particularly that of the nontypeable strains, has been demonstrated in vitro by quantitative studies of adhesion to highly purified mucins (8, 30), native mucins (22), and crude mucus
(3), but the surface structures that mediate the adherence
of H. influenzae to these targets have not been clearly
defined. Pili, which are found on both type b (11) and
nontypeable strains (1), have been implicated in adherence
to oropharyngeal cells, and we suspected that this structure might be
involved in the binding to mucin. However, there are conflicting
reports on the role of surface appendages in binding to mucus. Read and
colleagues reported that a piliated ntHi strain (strain R890 from our
collection) was bound to mucus after inoculation of human nasal
turbinates in organ culture (29); but a different laboratory
reported that a clone from the same transformation (R881) did not bind
better to crude mucus in vitro (8). However, Davies et al.
(8) used an agglutination assay, while Read and colleagues
(29) assessed adherence with the scanning electron
microscope. Others have reported that certain outer membrane proteins
mediate the interaction of ntHi with highly purified mucins
(30). Thus, the issue appears to be unsettled. Since pili
appear to be important for colonization of host tissue by other
bacterial species and because hifA mutants have decreased ability to colonize primate respiratory mucosa (42), we
sought to reexamine their role in binding to mucins harvested from the human respiratory tract. In this manuscript, we report studies on the
role of pili in the adherence of H. influenzae to human respiratory mucins.
| |
MATERIALS AND METHODS |
Bacteria.
Table 1 depicts the
bacterial strains used in this study. The parental strain (Eagan) is
phenotypically a nonpiliated H. influenzae type b isolate,
while strain R1369 is its fimbriated derivative which mediates MRHA
(36). Strain RKAW5 is a nonpiliated derivative of R1369
(42) in which a kanamycin cassette is inserted in
hifA, the gene encoding pilin. R906 is a laboratory
derivative of H. influenzae Rd (5) lacking the
pilus gene cluster, and R881 is the piliated derivative of R906
produced by transformation with a DNA fragment containing the pilus
gene cluster from strain C54 (27). A library of chromosomal
DNA from H. influenzae strain C54 was partially digested
with SauA1 and ligated into BamHI-digested pHC79
(18). Clones in Escherichia coli DH5
were
screened by colony hybridization with a nick-translated PstI
fragment (pCD1) (42) containing the 5' end of the pilus gene
cluster (hifA, hifB, and a portion of
hifC) from strain R1369. One cosmid, containing a 28-kb
insert, which had homology to pCD1 was partially digested with
ClaI and was used to transform strain R906 made competent by
the M-IV technique (17). Transformants adhering to human RBCs were subcultured and banded on Percoll (13), and the
band was aspirated and subcultured. Several colonies which were
hemagglutination positive (R881 through R890) were frozen in skim milk
at 
70°C. The presence or absence of the type b capsule on H. influenzae was tested by slide agglutination with anti-type
antisera (Difco, Detroit, Mich.).
E. coli DH5 has been described before and was obtained
from Bethesda Research Laboratories; E. coli strain ORN103,
obtained from Paul Orndorff (23), has genotype thr-l
leu-6 thi-l 
(argF-lac) U169 xyl-7 ara-13 mtl-2
gal-6 rpsL fhuA2 minA minB recA13 (pilABCDFE hyp).
E. coli strains were transformed with plasmids by the
calcium heat shock method, which we have performed previously
(5). Plasmid pEMBL8 (10) was obtained from
Riccardo Cortese, Heidelberg, Germany, and plasmid pMH140, which
contains the pilus gene cluster from a type b strain (AM30; also called
770235 f+b0), was obtained from Marieke van
Ham, Amsterdam, The Netherlands (40).
H. influenzae strains were grown on chocolate agar plates,
which were made with tryptic soy agar enriched with 5% horse RBCs, 2%
Fildes enrichment (Difco), and bacitracin (100 µg/ml; Sigma, St.
Louis, Mo.) and then stored at 4°C in sealed bags. The same medium
was used to grow strain RKAW5, but it also contained 20 µg of
kanamycin/ml. All strains were kept frozen at 70°C in aliquots in
25% (vol/vol) glycerol and taken from the frozen stocks for each
adhesion experiment. All E. coli strains were grown on L agar containing ampicillin at 100 µg/ml.
Respiratory mucin.
Human tracheobronchial mucin (HTBM) was
prepared from the tracheobronchial secretions of a single patient with
chronic obstructive pulmonary disease. The mucin was purified from the
secretions by a method previously described (22, 44).
Extensive delipidation was not carried out; therefore, these mucins
represent native mucins.
Assay of bacterial adherence to mucin.
Adherence assays were
performed by using 96-well microtiter plates (catalog no. 76-242-05;
ICN Biomedicals, Costa Mesa, Calif.). One hundred microliters of HTBM
solution at a concentration of 100 µg/ml was added to the wells and
left at 37°C overnight to allow the mucin to coat the wells. Prior to
addition of the bacteria, the wells were washed five times with 0.2 ml
of sterile phosphate-buffered saline (PBS) by using a hand-held
microtiter plate washer. Three coated wells and a "negative,"
uncoated control well were used for each assay.
Bacteria were grown for 8 to 12 h on chocolate agar plates
containing antibiotics as appropriate in a 5% CO2
incubator at 37°C. The organisms were harvested from the plates,
suspended in sterile PBS, and adjusted to a density of 108
to 5 × 108 CFU/ml (A580 of
0.2); this density was used for all experiments. One hundred
microliters of the bacterial suspension was added to the mucin-coated
wells and to the negative-control wells and allowed to incubate for 60 min at 37°C. The wells were then washed 15 times with sterile PBS to
remove unbound bacteria. At the density used, nonspecific binding of
H. influenzae to the polystyrene microtiter plates was
minimal. The inoculum at the beginning of the experiment was determined
by performing serial dilutions of the bacterial suspension in sterile
PBS and then plating 100 µl of each dilution in duplicate on
chocolate agar plates. For studies examining the effect of antipilin
antibodies the procedure was modified as follows. The initial bacterial
concentration was doubled, 100 µl of the bacterial suspension was
added to 100 µl of the antipilin or control (not agglutinating
piliated cells) antibody, and the mixture was mixed and allowed to
stand at room temperature for 10 min. Next, 100 µl of this mixture
was placed in the experimental and control wells and incubated for 60 min. Each organism was tested in triplicate on each microtiter plate.
In the original method for assessing mucin adherence, 0.5% Triton
X-100 (Sigma) was used as a desorbing agent to remove bacteria from the
wells. We have recently reported that 0.5% Tween 20 (Sigma) provided
increased recovery of H. influenzae over Triton X-100 (22). On the basis of these observations, 250 µl of 0.5%
Tween 20 was added to each well and allowed to desorb bacteria for 15 min at room temperature. The wells were then mixed 20 times with a
micropipette, and 100 µl of the solution was removed and diluted in
sterile PBS. The diluted solution was plated in duplicate on chocolate
agar plates. The plates were incubated for 24 h in a 5%
CO2 incubator at 37°C. The colonies were identified as
H. influenzae by morphological characteristics, Gram
staining, and their dependence on heme and 
-NAD+ for
aerobic growth. Randomly selected colonies from each experiment were
tested to confirm that the colonies were H. influenzae. Each experiment was replicated at least three times. Adherent E. coli cells were enumerated by the same technique except that the
bacteria were quantitated by overnight incubation on L agar containing ampicillin at 100 µg/ml.
Hemagglutination.
To test whether a correlation between
bacterial adherence to HTBM and hemagglutination exists, the relevant
strains were tested as follows. H. influenzae cells were
grown for 12 h on chocolate agar plates in a 5% CO2
incubator at 37°C. The organisms were suspended in sterile PBS and
adjusted to an A580 of 1.0. Serial dilutions of
the bacterial suspension were made, and 100 µl of each concentration
was placed in a glass agglutination plate. One hundred microliters of a
2% suspension of multiply washed human RBCs (type O+) was
placed in each well, and the contents of the wells were mixed
thoroughly. The plates were gently agitated for 1 h at 37°C in a
humidified environment and examined for hemagglutination at each
dilution. Control wells contained and equal amount of sterile PBS and
RBCs. E. coli strains were processed in the same manner
except that they were grown on L agar containing ampicillin. A positive
control was run with each set of experiments by using a
hemagglutination-positive piliated strain of Pseudomonas
aeruginosa (28).
ELISA.
Costar (Corning Science Products, Acton, Mass.)
96-well enzyme immunoassay plates were coated with gel-purified HifA at
1.0 and 4.0 µg/ml in the 20 mM bicarbonate buffer by being incubated for 18 h at 4°C. To reduce nonspecific binding, 100 µl of 3%
bovine serum albumin in PBS (blocking buffer) was added to the rinsed plates and an additional overnight incubation was performed. The antibody source (serum or ascitic fluid) was then geometrically diluted
in blocking buffer and incubated for 2 h at room temperature. Each
well was then washed three times with blocking buffer before addition
of the secondary antibody (goat anti-mouse IgG or goat anti-rabbit IgG;
Bio-Rad, Richmond, Calif.) conjugated to horseradish peroxidase (HRP).
The plates were then rinsed three times with blocking buffer and twice
with PBS; 100 µl of HRP substrate (Kirkegaard-Perry Inc.,
Gaithersburg, Md.) was added, and the plates were incubated for 30 min
at room temperature; 50 µl of 2 M H2SO4 was
added, and A450 was read with an MR5000
enzyme-linked immunosorbent assay (ELISA) reader (Dynatech, Chantilly,
Va.).
Antipilin antibody production.
AF100 is ascitic fluid from
mice elicited by sarcoma 180/TG cells after the mice have been
immunized with HifA purified from strain R1369 (26). HifA,
the structural subunit of the MRHA pili, was purified as described
previously (36), except that the final product from that
purification scheme was electrophoresed in sodium dodecyl sulfate-10%
polyacrylamide gel electrophoresis gel. After localization of the band
with the appropriate mobility by immersion of the gel in ice-cold 0.1 M
KCl, the band was excised and the protein was eluted with a Hoefer
Transphor model TE50X into 0.05 M ammonium bicarbonate, pH 10.5. To
"renature" the pilin, this fraction was lyophilized and the pellet
was dissolved in 1 ml of PBS. The protein content was estimated from
its absorbance at 280 mm. Female Swiss Webster mice, 6 to 8 weeks old,
were inoculated subcutaneously with 100 µg of purified HifA
emulsified with 0.2 ml of Ribi adjuvant. Thirty and 45 days later each
mouse was inoculated intraperitoneally with an additional 100 µg of
HifA dissolved in 0.1 ml of PBS. Two weeks later ascites was induced in
the mice by the intraperitoneal injection of 106 sarcoma
180/TG cells (26). Ascitic fluid was harvested daily from
each mouse beginning 1 week later and centrifuged at 12,000 × g for 15 min, and the supernatant was used as a source of
antibody. AF100 is the ascitic fluid from a single mouse.
Mouse IgG was purified from AF100 using the Pierce (Rockford, Ill.)
ImmunoPure G kit. Ascites fluid (2 ml) was centrifuged at
10,000 × g for 10 min at 4°C to remove the
particulate material. It was then applied to a protein G column, which
was washed extensively, and the IgG was eluted. The fractions with an
A280 >0.1 were pooled and stored in 20 mM
sodium phosphate buffer (pH 7.0) containing 10 mM EDTA. Two IgG
purification procedures yielded 800 µg of protein. This material was
digested overnight with papain, and the Fab fragments were isolated
with an ImmunoPure Fab preparation kit (Pierce). The mixture was
applied to a protein A column, and the early
A280 peak was pooled according to the
manufacturer's instructions. This material was dialyzed against PBS
and used as an anti-HifA Fab fragment.
Monoclonal antibodies were developed against HifA by the method of
Davis (9). Six-week-old female BALB/C mice were immunized by
the intraperitoneal administration of 50 µg of purified HifA (gel
purified as described above) emulsified in Ribi adjuvant. Three weeks
later the animals were boosted with the same amount and by the same
route, again after emulsification in Ribi adjuvant. Seven to 10 days
after the second immunization, the animals were bled by retro-orbital
puncture and the antibody titer was determined by ELISA. ELISA was
performed using polyclonal goat anti-mouse IgG antisera conjugated to
alkaline phosphatase. Crude HifA fractions prepared by ammonium sulfate
precipitation of sheared-cell (R1369) supernatant were used as the
antigen, coating the ELISA plates with 5 µg of protein. If the titer
(defined as the highest dilution yielding an
A405 exceeding that seen with nonimmune sera by
0.1) was >1:2,000, the spleen was harvested. If the titer was
<1:2,000, then an additional 50 µg of HifA in PBS was administered
intraperitoneally. Five to 7.5 Sp2/O cells, on average, were fused to
each spleen cell. Thymocyte feeder cells were used during cloning by
limiting dilution. Culture supernatants were screened by ELISA (as
described above) when the growth in the wells was 30 to 60% confluent.
One reactive IgG3 monoclonal antibody was developed and identified as
37-D.
Western blot analysis.
To verify the specificity of the
anti-HifA antisera, we performed Western blot analysis, essentially as
previously described (5). Fifty micrograms of protein
derived from whole-cell lysates (in running buffer) was electrophoresed
on a sodium dodecyl sulfate-12.5% polyacrylamide gel electrophoresis
gel. The separated proteins were electrophoretically transferred to
Immobilon, along with prestained molecular size standards loaded
concurrently. After transfer, the membranes were stained with Ponceau S
to determine the locations of the relevant bands and to determine that
transfer had occurred. The membrane was then immersed in a blocking
solution consisting of 1% skim milk in PBS for 60 min at room
temperature. Following this, they were rinsed and immersed for 60 min
at room temperature in solution containing anti-HifA antibody (mouse
ascites fluid AF100 diluted 1:500). The membranes were subsequently
washed in PBS containing 0.1% sodium dodecyl sulfate at room
temperature for 10 min and then were washed five times for 5 min each
in PBS. They were then reacted with goat antibody directed to mouse IgG purchased from Bio-Rad. The secondary antibody was conjugated to HRP,
and the membranes were developed using 4-chloro-1-naphthol and hydrogen
peroxide in Tris-buffered saline at pH 7.5.
| |
RESULTS |
All H. influenzae isolates which were previously found
to agglutinate O+ human RBCs had this property, as
indicated in Table 1, before they were tested for adherence to mucin.
Only E. coli strains R2745 and R2746 hemagglutinated human RBCs.
Effect of piliation on adherence of H. influenzae to
mucin.
Strain R1369 is a phase variant selected for pilus
expression by RBC adsorption, while the other type b derivative lacking pili was produced by the insertion of an antibiotic resistance cassette
into hifA (RKAW5). Strain R1369 bound to mucin extremely well (Fig. 1), as extensively as the
previously reported nontypeable sputum strains (22); the
isogenic, nonpiliated hifA mutant was markedly reduced in
its ability to adhere to mucin. Similarly, the laboratory ntHi strain
R906 lacking the pilus gene cluster showed about 5% of the adherence
of the same strain expressing a type b pilus gene cluster (R881) (Fig.
1).
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FIG. 1.
Adherence of piliated and nonpiliated isogenic mutants
of H. influenzae to native respiratory mucins. Strains R1369
and R881 are piliated, type b and nontypeable respectively. All other
strains lack detectable pili (Table 1). Values are means. Error bars,
standard deviations.
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|
Studies with the pilus gene cluster.
E. coli strains
DH5 and ORN103 were both transformed with the pilus gene cluster in
the vector pEMBL8. Both E. coli strains carrying and
expressing the cloned pilus gene cluster from a type b H. influenzae isolate had six- to sevenfold increased binding to
mucin compared to E. coli carrying the vector alone (Fig.
2). However the number of bacteria
adhering was considerably lower than that seen with the H. influenzae strains.
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FIG. 2.
Adherence of E. coli strains carrying the
pilus gene cluster to mucins. Plasmid pEMBL8 is the vector into which
the pilus gene cluster from strain AM30 was cloned, yielding pMH140.
Values are means. Error bars, standard deviations.
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|
Specificity of the anti-HifA antibody.
Figure
3 depicts the reactivity of AF100
antisera with the test E. coli and H. influenzae.
The reactivity was greatest with H. influenzae strain R1369,
the source of the HifA used for immunization. Although the HifA
expressed by strain R881 is from a different type b strain (C54 versus
R1369), cross-reactivity is seen (lane 5 versus lane 8). This antibody
preparation also reacted with a protein of similar mobility encoded by
pMH140, but the reactivity was considerably diminished (lanes 3 and 4).
The E. coli expressing the pilus gene cluster (pMH140) was
derived from H. influenzae strain AM30. AM30 is a type b
H. influenzae strain in which 148 of the 196 amino acid
residues in HifA are identical to those in strain R1369 HifA (2,
37). Thus the cross-reactivity is not unexpected.
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FIG. 3.
Western blot analysis of H. influenzae and
E. coli strains with AF100 antibody preparation. Lane 1, R3180; lane 2, R2747; lane 3, R2746; lane 4, R2745; lane 5, R881; lane
6, RKAW5; lane 7, 3-15; lane 8, R1369; lane 9, R906. The mobility of
the molecular weight standards is indicated to the right.
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|
Effect of antifimbrial antibodies on adherence.
Antibodies
raised against renatured pilin from a type b strain (R1369) were used
to test for inhibition of adhesion. The adherence of the type b strain
R1369 was reduced about 95%, and those of the hemagglutinating ntHi
strains R881 and 3-15 were reduced by about 90%, in the presence of
AF100 compared with adherence in the presence of control antibody 37-D
(Fig. 4). Monoclonal antibody 37-D, which
does not agglutinate alpha-fimbriated strains, had no detectable effect
on mucin adherence.
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FIG. 4.
Effect of mouse anti-HifA antibodies on adhesion of type
b H. influenzae and ntHi strains to mucins. 37-D, a mouse
monoclonal antibody that reacts with pilin from strain R1369 in ELISA
but not on Western blots or in agglutination assays with any of the
H. influenzae strains used in these studies and that was
used as a control. AF100 is a mouse polyclonal antibody against pilin
raised in ascitic fluid; it agglutinates piliated H. influenzae strains at a 1:4 dilution. Error bars, standard
deviations.
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|
Although we could not observe bacterial agglutination in the antibody
inhibition experiments with an inverted microscope, we tested Fab
fragments of AF100 IgG prepared as described above. A commercially
available heterologous mouse Fab preparation was used as a control
reagent (Accurate Chemicals, Westbury, N.Y.). Both the anti-HifA Fab
and the control Fab preparations were used at a protein concentration
of 0.86 µg/ml, which was the maximum concentration of the anti-HifA
Fab available. Neither preparation (undiluted) caused microscopic
agglutination of the strains tested. The levels of adhesion of strains
R881 and 3-15 were reduced by about 95 and 90%, respectively, by the
anti-HifA Fab fragment, compared to the effect of the control Fab
reagent (Fig. 5). Furthermore, this
anti-HifA Fab preparation also inhibited the adherence of the E. coli strains carrying the gene encoding the pilus gene cluster
(Fig. 6).
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FIG. 5.
Effect of mouse anti-HifA Fab fragments (Fab) on the
adherence of ntHi to respiratory mucins. C, treatment with control
mouse Fab fragments. R881 expresses type b pili, while strain 3-15 is a
piliated nontypeable isolate. Error bars, standard deviation.
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FIG. 6.
Effect of mouse anti-HifA Fab fragments (Ab) on adhesion
of E. coli strains carrying the pilus gene cluster. C,
control (treatment with nonimmune mouse Fab fragments). Error bars,
standard deviations.
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| |
DISCUSSION |
We investigated the role of hemagglutinating pili in the binding
of H. influenzae to human tracheobronchial mucin. We show that strains bearing pili of both type b and ntHi bound to mucin better
than their nonpiliated derivatives. Furthermore, the binding of both
encapsulated and nonencapsulated but piliated H. influenzae to mucin was blocked by pretreatment with antibodies directed to its
structural subunit, HifA. To further support the observation that
fimbriae are involved in adhesion to mucins, we examined the adherence
of two E. coli strains carrying and expressing the cloned
pilus gene cluster (hifABCDE) from H. influenzae
strain AM30 (41). The E. coli strains which
contained the cloned pilus gene cluster had a six- to sevenfold
increased binding compared to the E. coli strains carrying
the vector alone.
A polyclonal mouse antibody raised against highly purified HifA
inhibited binding to mucin. Monoclonal antibody 37-D, also directed
against HifA of strain R1369 but only recognizing a three-dimensional epitope, did not inhibit binding. This is not surprising as Gilsdorf et
al. (14) found that polyclonal antibodies raised against hydrophilic peptides comprising various portions of pilin did not bind
well to the native structure on the surface of type b H. influenzae. Others have found a similar dependence of the
immunogenicity of E. coli WF96 fimbriae on the
three-dimensional conformation (19). We found that
monoclonal antibody 37-D reacts with HifA or with piliated H. influenzae only under ELISA conditions. There is no detectable
reactivity with HifA on Western blot analysis, nor does this monoclonal
antibody mediate agglutination of piliated H. influenzae
(data not shown). Monoclonal antibody 37-D can be viewed as a control
for mouse polyclonal antibody AF100, which agglutinates piliated organisms.
To verify that the inhibition of mucin binding by the antibody
preparations was not due to bacterial agglutination, we prepared IgG
and then monovalent Fab fragments from the AF100 antibody preparation.
We found that this preparation also inhibited mucin binding of H. influenzae and E. coli expressing H. influenzae pili on their surfaces.
There are multiple surface adhesins which could have mediated the
adhesion of H. influenzae to mucin. These studies have only examined the role of hemagglutinating pili and find that pili play a
major role. However, these data do not rule out a role for other
morphologically distinct H. influenzae adhesins
(high-molecular-weight proteins, Hia, and Hsf-Hap, for example) which
may be present on naturally occurring clinical isolates which lack
pili. The binding of several nonpiliated H. influenzae
strains to highly purified mucins (in an agglutination assay) was
demonstrated by Davies et al. (8), indicating that there are
other adhesins present on some ntHi strains. These studies allow us to
conclude that pili are involved in the adherence of H. influenzae to mucus but do not rule out the existence of other
adhesins for mucin epitopes.
This study differs significantly in its conclusions from one of the
previous reports on the role of pili (8), wherein this structure was found not to be involved in adherence to mucins. In fact
two of the same strains used in the present study, the nontypeable Rd
derivative strain R906 and strain R881, a transformant with a type b
pilus gene cluster, were used by Davies et al.; neither strain bound to
mucins in that study (8). It is our belief that these
differences may reflect the method of mucin preparation and/or the
sensitivities of the assay systems used. Mucins for our assay were
prepared by ultracentrifugation in Cs-Br (44), whereas the
mucins used in the previous report were prepared by solubilization in 6 M guanidinium chloride and then two cycles of Cs-Cl guanidinium
chloride ultracentrifugation. The latter method is reported to remove
more of the noncovalently attached lipids and nucleic acids from the
native mucins compared to what is seen in situ. However, the assay
system used in the previous study was not quantitative, and the lower
limit of detection of bacterial binding by aggregation and slot blot
was not reported. Theoretically, our assay can detect 100 CFU bound to
the microtiter plates. One additional factor is the choice of mucins
for the assays. We used mucins from the same patient throughout our
studies, but it is not clear whether the same mucin preparations were
used in the previous studies (8). Aside from technical
differences, the differing conclusions raise the question of what is
the most appropriate target to study in order to mimic as close as one can the in vivo environment. Is it more appropriate to study crude mucus, native mucins, or highly purified mucins? Each may have its
advantages for a given purpose. If one is interested in a specific
chemical group of mucins interacting with a defined microbial product,
then highly purified mucin may be the substance of choice. On the other
hand, native mucins or crude mucus may be more appropriate to detect
interactions that occur in vivo. The results of this study also
contrast with those investigating the role of pili in another organism,
P. aeruginosa, which resides in the mucus of patients with
cystic fibrosis. Pili are not needed for the binding of P. aeruginosa to preparations of native mucins (28), even
though H. influenzae and P. aeruginosa are
reported to bind to the same cellular glycolipids (21).
The presence of pili may allow ntHi a survival advantage in that these
surface appendages allow binding to human mucus, which may permit
progression to other stages of the infectious process such as tissue
injury and invasion. Alternately, in conditions where the clearance of
tracheobronchial secretions is impaired (i.e., cystic fibrosis and
chronic bronchitis) this mucus adherence may mediate a state of chronic colonization.
| |
ACKNOWLEDGMENTS |
This work was supported by grants from the American Lung
Association of Florida (M.K.) and Public Health Service grants NHLBI HL
33622 (R.R.) and NIAID AI 20625 (A.L.S.) from the National Institute of
Heart, Lung and Blood Diseases and the National Institute of Allergy
and Infectious Diseases.
We are indebted to Joseph St. Geme, Jr., for his careful reading of the
manuscript and helpful comments.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Molecular Microbiology & Immunology, University of Missouri-Columbia, M616 Medical Science Building, DC044.00, Columbia, MO 65212. Phone: (573) 882-8989. Fax: (573) 882-4287. E-mail:
SmithAL{at}missouri.edu.
Editor:
D. L. Burns
| |
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Infection and Immunity, June 2000, p. 3362-3367, Vol. 68, No. 6
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Copyright © 2000, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
