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Infection and Immunity, September 1999, p. 4673-4678, Vol. 67, No. 9
0019-9567/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
Fibronectin Binding Protein and Host Cell Tyrosine
Kinase Are Required for Internalization of Staphylococcus
aureus by Epithelial Cells
Katarzyna
Dziewanowska,1
Joseph M.
Patti,2
Claudia F.
Deobald,1
Kenneth W.
Bayles,1
William R.
Trumble,1 and
Gregory
A.
Bohach1,*
Department of Microbiology, Molecular Biology
and Biochemistry, University of Idaho, Moscow, Idaho
83844,1 and Inhibitex Inc., Norcross,
Georgia 300922
Received 7 December 1998/Returned for modification 4 May
1999/Accepted 8 June 1999
 |
ABSTRACT |
Staphylococcus aureus expresses several surface
proteins that promote adherence to host cell extracellular matrix
proteins, including fibronectin (Fn). Since this organism has recently
been shown to be internalized by nonprofessional phagocytes, a process that typically requires high-affinity binding to host cell receptors, we investigated the role of its Fn binding proteins (FnBPs) and other
surface proteins in internalization by the bovine mammary gland
epithelial cell line (MAC-T). Efficient internalization of S. aureus 8325-4 required expression of FnBPs; an isogenic mutant
(DU5883), not expressing FnBPs, was reduced by more than 95% in its
ability to invade MAC-T cells. Moreover, D3, a synthetic peptide
derived from the ligand binding domain of FnBP, inhibited the
internalization of the 8325-4 strain in a dose-dependent fashion and
the efficiency of staphylococcal internalization was partially correlated with Fn binding ability. Interestingly, Fn also inhibited the internalization and adherence of S. aureus 8325-4 in a
dose-dependent manner. In contrast to internalization, adherence of
DU5883 to MAC-T was reduced by only approximately 40%, suggesting that
surface binding proteins, other than FnBPs, can mediate bacterial
adherence to cells. Adherence via these proteins, however, does not
necessarily result in internalization of the staphylococci. An
inhibitor of protein tyrosine kinase, genistein, reduced MAC-T
internalization of S. aureus by 95%, indicating a
requirement for a host signal transduction system in this process.
Taken together, these results indicate that S. aureus
invades nonprofessional phagocytes by a mechanism requiring interaction
between FnBP and the host cell, leading to signal transduction and
subsequent rearrangement of the host cell cytoskeleton.
| |
INTRODUCTION |
Staphylococcus aureus is
the etiological agent of a wide range of infectious and toxigenic
illnesses of humans and animals. Although it has many virulence
factors, a key to its success as a pathogen is its ability to colonize
and persist at various sites within its cadre of potential hosts. In
addition to persistence in healthy hosts, this organism is well known
for the ability to induce long-lasting chronic infections that resist
conventional therapy. Although S. aureus is not
traditionally considered to be an intracellular pathogen, it is now
well documented that it can enter nonprofessional phagocytic cells such
as endothelial and epithelial cells (4, 5, 6, 20, 49, 50,
53). We have been exploring the possibility that maintenance in
an intracellular niche can promote long-term colonization in the host
and also can play a role in maintaining chronic infections.
Previously, our laboratories reported that during its invasion cycle of
bovine epithelial cells in vitro, S. aureus escapes from the
endosomal vesicle, appears to multiply within the cytoplasm, and
induces apoptosis (5). These steps were proposed to be mediated by the global regulators agr and sar
(57). Although the gene products required for S. aureus to induce these effects were not identified in previous
publications, we hypothesized that bacterial surface molecules were
involved in internalization, since Agr and Sar mutants and cells in the
exponential phase were internalized more efficiently (57).
It is known that invasion of cells by other microorganisms studied thus
far is a multistep process, beginning with attachment, which initiates
complex changes in the host cell cytoskeleton and membrane (10,
11, 14, 23, 24, 36, 43, 44). A strong link between bacterial internalization and host cell signaling through protein tyrosine kinases (PTK) has been well documented in several host cell-bacterium interactions (1, 7, 9, 12, 13, 16, 17, 28, 42, 45, 46).
The ability of S. aureus to colonize the surface of host
tissues is facilitated by several bacterial surface proteins that have
a high affinity for extracellular-matrix components. These proteins,
termed MSCRAMMs (microbial surface components recognizing adhesive
matrix molecules), recognize fibronectin (Fn), fibrinogen, collagen,
vitronectin, laminin, and other ligands (39). The demonstration in 1978 that Fn in plasma binds to S. aureus
first suggested a possible role for Fn adherence as a virulence factor (29). Fn binds to S. aureus with a very high
affinity (Kd = 1.8 nM), such that the
reaction is practically irreversible under physiological conditions
(30, 31, 37, 40, 55). Two Fn binding protein (FnBP) genes,
fnbA and fnbB, which confer the Fn binding
phenotype, have been cloned from S. aureus 8325-4. The
deduced protein sequences (for FnBPA and FnBPB) are 45% identical in
their N-terminal region (domain A), whereas the Fn binding regions
(domains 1 to 3), the wall-spanning regions (domain W), and the
membrane anchor regions (domain M) have 95% identical amino acids
(27, 47). Most invasive strains of S. aureus bind Fn, and the number of the bound Fn molecules correlates with the extent
of tissue invasiveness (41).
The purpose of the present study was to investigate some of the early
events in the internalization of S. aureus by epithelial cells. Considering the significance of FnBPs in invasion of tissues by
S. aureus, we explored the hypothesis that FnBPs play a key role in internalization of the organism by nonprofessional phagocytes. In addition to demonstrating that FnBPs play a role in this process, S. aureus internalization was shown to require PTK activity
similar to that induced by other organisms capable of entering
nonprofessional phagocytes.
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MATERIALS AND METHODS |
Bacterial strains and growth conditions.
The S. aureus laboratory strains and clinical isolates used in this study
are listed in Table 1. All strains were
grown in Todd-Hewitt (TH) broth (Difco Laboratories) at 37°C with
aeration, in the presence of antibiotics when necessary. For the
experiments, the bacterial cells were collected by centrifugation,
washed with sterile 150 mM phosphate-buffered saline (PBS) (pH 7.2),
and resuspended in invasion medium (described below).
Cell culture and invasion assay.
An established bovine
mammary epithelial cell line (MAC-T) (22) was cultured as
described previously (5). Briefly, the cells were grown in
high-glucose Dulbecco's modified Eagle's medium (Gibco-BRL)
supplemented with 10% heat-inactivated fetal bovine serum (HyClone),
insulin (5 µg/ml), hydrocortisone (5 µg/ml), penicillin (100 U/ml),
and streptomycin sulfate (100 µg/ml). The MAC-T cells were seeded
(6.0 × 104 per well) in 24-well culture plates
(Costar) and incubated at 37°C under 6% CO2. Upon
reaching confluency, the cells were washed once with sterile PBS and
incubated overnight (37°C under 6% CO2) in invasion
medium (growth medium without antibiotics or serum) (1.0 ml/well).
For most bacterial internalization assays, the following standard assay
was used. Confluent MAC-T cell monolayers (approximately
2.0 × 10
5 to 2.5 × 10
5 cells/well) were washed
once with the invasion medium and inoculated
with bacteria suspended in
invasion medium (approximately 10
6 to 10
7
bacteria per well) to produce multiplicities of infection (MOI)
of 5 to
25. After incubation for 1 h (37°C under 6% CO
2),
the
wells were washed once with PBS and then 1.0 ml of invasion medium
supplemented with 100 µg of gentamicin was added to each well.
The
plates were incubated for an additional 1 h with the gentamicin
to
kill extracellular bacteria. The monolayers were washed four
times with
sterile PBS, detached from the plates by being treated
(5 min at
37°C) with 100 µl of trypsin solution (0.25%) in Hanks
balanced
salt solution (HBSS) (Gibco-BRL), and then lysed by the
addition of 900 µl of sterile deionized water. The cell lysates
were serially diluted
10-fold and plated in triplicate on TH agar
plates to quantify
intracellular
staphylococci.
In some experiments, gentamicin was omitted so that the adherent
bacteria could be quantified. To assess internalization in
the presence
of various effectors, the standard assay described
above was modified
as follows. Prior to inoculation with washed
bacteria, confluent MAC-T
monolayers were incubated for 15 min
with invasion medium containing D3
synthetic peptide (
34) (5
to 20 µM) or the PTK inhibitor
genistein (250 µM) (Calbiochem)
(
2,
3) and then inoculated
with bacteria. In experiments
with bacteria pretreated with bovine Fn
(Calbiochem), aliquots
of bacterial cell suspensions (100 µl,
containing approximately
5 × 10
7 cells) were added to
900-µl aliquots of PBS containing 0.1% bovine
serum albumin (BSA),
0.1% Tween 80, and 0 to 50 pmol of bovine
Fn. The cell suspension was
incubated with shaking for 1 h, washed
twice with PBS containing
0.1% BSA and 0.1% Tween 80, and resuspended
in 1.0 ml of invasion
medium. Aliquots of this suspension (100
µl, approximately 5 × 10
6 cells) were used to inoculate the MAC-T cell
monolayers. The
inoculum size was verified for each suspension by
serial 10-fold
dilutions and plating on TH agar. The following steps of
these
experiments were carried out as described above for the standard
assay.
Adherence of bacteria to Fn-coated microtiter wells.
Wells
in a 96-well microtiter plate were coated by addition (to each well) of
100 µl of bovine Fn solution (50 µg/ml in HBSS with bivalent ions)
or 0.1% BSA (to estimate nonspecific binding) and incubation overnight
at 22 to 25°C. After the wells were washed three times with HBSS, any
residual binding sites were blocked by adding 100 µl of
heat-denatured 0.1% BSA in HBSS (free of bivalent ions) and incubating
the mixture for 60 min at room temperature. After the wells were washed
once with invasion medium supplemented with 0.1% BSA, 100 µl of
bacterial cell suspension (5 × 105 cells in invasion
medium supplemented with 0.1% BSA) was added. The specificity for Fn
binding was confirmed by adding invasion medium containing soluble
bovine Fn (final concentration, 10 or 50 nM) to some wells. The plates
were incubated for 1 h at room temperature and washed four times
with PBS to remove nonadherent bacteria. Adherent bacterial cells were
detached from the wells by adding 25 µl of 0.25% trypsin solution in
HBSS and incubating the mixture for 5 min at 37°C. Detached bacteria
were quantified by plating as described above. The results were
recorded as the Fn adherence index (100 × CFU recovered/CFU
added), which reflected the relative ability of various strains to
adhere to the Fn-coated wells under the conditions used.
| |
RESULTS |
FnBP is required for efficient internalization of S. aureus 8325-4 by MAC-T cells.
S. aureus
expresses several MSCRAMM proteins which could potentially
mediate binding and internalization by eukaryotic cells. To assess the
role of FnBPs in these processes, invasion assays were performed to
compare the internalization potential of parental strain 8325-4 (expressing FnBPA and FnBPB) and its double mutant DU5883 (not
expressing FnBPs). Similar to results previously reported for S. aureus Novel and RN6390 (5, 57), 8325-4 exhibited a
dose-dependent pattern of internalization (Fig.
1). In comparison, internalization of the
DU5883 strain was reduced by more than 95% at all doses tested.
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FIG. 1.
Internalization of S. aureus 8325-4 and
DU5883 by MAC-T cells. A dose-response internalization assay was
performed by inoculating MAC-T cell monolayers with various numbers of
bacterial cells to generate the MOI indicated. After 1 h of
incubation, extracellular bacteria were killed with gentamicin and the
number of intracellular bacteria was determined. Data points represent
the means of results from three separate but identically processed
infected MAC-T cultures. Results of one representative experiment are
shown in this figure. The experiment was performed 10 times.
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Additional experiments confirmed that the results presented in Fig.
1
were specific to FnBPs and not due to a secondary effect
of the
mutation. First, internalization of DU5883 was restored
to levels 4.5 times higher than that of the parental 8325-4 strain
by complementation
with pFNBPA4, a plasmid which causes
S. aureus transformants
to overexpress FnBPA (
19) (Table
2). Second,
internalization of
S. aureus by MAC-T cells could be blocked by
pretreating monolayers
with an excess of a synthetic peptide corresponding
to a conserved
functional region of the FnBP proteins. A well-characterized
and
previously described peptide (
34), designated D3, is a
37-amino-acid
synthetic peptide corresponding to one of the Fn binding
domains
of staphylococcal FnBPs. The results presented in Fig.
2 show
that the addition of D3, at
concentrations ranging from 5 to 20
µM, inhibited
S. aureus 8325-4 internalization in a dose-dependent
manner. These
data indicate that the D3 peptide interferes with
internalization by
competing with FnBP for its cellular receptor.
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FIG. 2.
Effect of D3 peptide on internalization of S. aureus 8325-4 by MAC-T cells. D3 peptide was added to MAC-T cells
15 min prior to infection and remained in the medium during the
experiment. Data are presented as percentage of bacteria (mean and
standard error of the mean) internalized in the absence of D3 peptide
and represent the mean of triplicate values. An MOI of 5 was used for
these experiments, and 100% internalization was equivalent to 4 × 104 CFU.
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Although FnBPs were shown above to be required for optimal
internalization of
S. aureus by MAC-T cells, they are only
two
of a cadre of MSCRAMMs and other proteins potentially expressed
on
the surface of staphylococcal cells. It was therefore important
to
determine whether alteration of other surface proteins could
significantly reduce internalization of
S. aureus by
nonprofessional
phagocytes. To accomplish this objective, two other
isogenic surface
protein knockout mutants of
S. aureus
8325-4 were assessed in
the standard invasion assay. Unlike DU5883, a
protein A-deficient
strain, DU5875 (
33), and a fibrinogen
binding protein MSCRAMM-deficient
strain, DU5880 (
32), were
internalized only slightly less efficiently
than was the parental
strain 8325-4 (Table
2). This suggested
that unlike FnBPs, these two
representative surface proteins do
not play a significant role in the
internalization of
S. aureus by MAC-T
cells.
Comparison of Fn binding with internalization efficiency.
The
FnBP content of staphylococcal isolates, as indicated by their ability
to bind Fn, is highly variable (41). Since FnBPs were shown
above to be required for the most efficient internalization of 8325-4, it was of interest to determine if heterogeneity in Fn binding ability
by different S. aureus strains correlates with their
internalization. Two bovine mastitis isolates (Novel and 305) and three
well-characterized human isolates (Newman, MN8, and ATCC 19095) were
compared for the ability to (i) bind to Fn immobilized on plastic
surfaces and (ii) enter MAC-T cells in a standard invasion assay. All
of the wild-type strains were internalized by the MAC-T cells, albeit
with different efficiencies (Table 3).
Their internalization could be reduced to levels comparable to that of
the double mutant DU5883 by saturating host and/or bacterial receptors
with soluble Fn. The two bovine isolates (Novel and 305) were
internalized efficiently (12.9 and 17.8%) and displayed a high level
of binding to immobilized Fn, as indicated by their adherence indices
in Table 3. Conversely, strain 19095, which bound poorly to Fn, was
internalized at levels (0.5%) only slightly higher than the FnBP
double mutant DU5883 (0.1%).
As shown in Table
3, the relative ability to adhere to Fn was strain
dependent. Although in most cases there was an association
between Fn
binding and uptake by MAC-T cells, factors other than
Fn binding
affected internalization with some isolates. For example,
the Newman
and MN8 strains bound comparably to immobilized Fn
but differed
significantly in their internalization efficiencies
(1.5 and 18.0%,
respectively). Combined, these data suggest that
FnBP levels generally
correlate with internalization efficiency.
However, the lack of
complete correlation between the efficiency
in adherence to immobilized
Fn and in internalization by MAC-T
indicates that for some strains,
production of hemolysins or other
toxic extracellular molecules could
affect the ability of cells
to internalize
S. aureus.
Alternatively, contact with eukaryotic
cells may induce certain changes
on the bacterial or host cell
surface, affecting the accessibility of
FnBPs or their receptors.
It is also possible that other factors such
as capsule or other
MSCRAMMs enhance or reduce internalization
regardless of their
ability to bind to
Fn.
Adherence to MAC-T cells by surface proteins other than FnBPs does
not promote efficient internalization.
For other facultative
intracellular pathogens, adherence is necessary but not sufficient to
induce internalization by epithelial cells. High-affinity
receptor-ligand interactions and subsequent events, including signal
transduction, must be specifically induced prior to internalization
(43, 46). To assess if the uptake of S. aureus
has similar requirements, experiments were conducted to measure both
adherence to and internalization by MAC-T cells for the 8325-4 and
DU5883 strains, two isogenic strains shown above to be internalized at
significantly different levels. Approximately 5 × 106
CFU of S. aureus was added to cultures of confluent MAC-T
cell monolayers, and the adherent and internalized organisms were
quantified as described above (Fig. 3).
Under standard conditions, 35% of 8325-4 cells adhered to the
monolayers. Consistent with the results discussed above, approximately
4% of 8325-4 cells were resistant to gentamicin and therefore were
presumed to be intracellular. Involvement of the Fn binding residues of
FnBPs in both of these processes was suggested by the observation that
both internalization and adherence of any staphylococcal strain used in
this study could be significantly reduced by addition of excess Fn to
cultures during the infection (Table 3) or by preincubation of
bacterial cells with Fn and washing prior to adding them to the
monolayer experiment (Fig. 3).
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FIG. 3.
Comparison of internalization and adherence of S. aureus 8325-4 and DU5883 by MAC-T cells. Monolayers were incubated
with bacteria for 1 h at an MOI of 20. Thereafter, either
extracellular bacteria were killed by adding gentamicin or the wells
were washed and the adherent and internalized bacteria were quantified.
The number of adherent bacteria was calculated by subtracting the
internalized bacteria from the total count. To assess the effect of Fn,
bacterial cells were pretreated with Fn at the concentration shown and
washed before being added to the monolayers. Data are presented as the
percentage of bacteria adherent or internalized compared to the
original inoculum and represent the means and standard errors of the
mean of three independent experiments.
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As described above,
S. aureus produces a vast array of
MSCRAMMs that are involved in adherence to various extracellular-matrix
molecules. Although our results suggested that FnBP-mediated adherence
and the ability to be internalized are related, our goal was to
determine if these events could be uncoupled. Interestingly, 21%
of
the DU5883 cells adhered to the MAC-T cells, indicating that
the
inability to express FnBPs was associated with a reduction
in adherence
of only 40%, compared to the parental strain, 8325-4.
In contrast to
the moderate reduction in adherence, the absence
of FnBPs in strain
DU5883 nearly completely abrogated internalization.
Therefore, with
regard to adherence to epithelial cells, strain
DU5883 may compensate
for the lack of FnBPs with additional surface
binding proteins, most
probably MSCRAMMs recognizing other extracellular-matrix
proteins.
However, binding to MAC-T cells via these alternate
surface ligands
cannot promote efficient internalization of the
organism. Thus,
although
S. aureus possesses numerous MSCRAMMs
that allow
the organism to bind to extracellular-matrix proteins,
binding of
8325-4 via FnBPs is responsible for the majority of
internalization by
MAC-T
cells.
Genistein reversibly inhibits internalization of S. aureus by MAC-T cells.
Internalization of obligate and
facultative intracellular pathogens requires activation and
participation of the host cell cytoskeleton (10). Although
not entirely elucidated, in many cases the pathways leading to
cytoskeletal rearrangement are initiated by PTK activation induced by
bacterial binding to host cell receptors. Since cytochalasin D, an
inhibitor of actin polymerization, blocks internalization of
staphylococci by MAC-T cells (5), it was of interest to
determine if PTK activity is required for uptake of S. aureus, as in other systems.
Based on results summarized in Fig.
4, it
was concluded that efficient internalization of 8325-4 requires PTK
activity. A
15-min preincubation with genistein, an inhibitor of PTKs,
reduced
internalization of the organism by greater than 95% compared
to
untreated controls. The inhibition was not the result of
genistein-induced
toxicity for either the staphylococci or the MAC-T
cells, since
removal of the genistein by washing resulted in a partial
recovery
after as little as 15 min. At 45 min after the removal of
genistein,
the level of internalization reached 79% of that of the
untreated
control.
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FIG. 4.
Effect of genistein on internalization of S. aureus 8325-4 by MAC-T cells. MAC-T cells were pretreated with
genistein (250 µM) for 15 min immediately prior to inoculation with
bacteria (MOI = 11). Control cultures had no genistein added.
Genistein was retained in all cultures for 60 min. After 60 min, the
genistein was removed by washing the monolayers and internalized
bacteria were quantified immediately (0) or after an additional period
of incubation (minutes) indicated on the abscissa. Data are presented
as the percentage of bacteria internalized in the absence of genistein
and are means and standard errors of the mean of three independent
experiments.
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| |
DISCUSSION |
Although not traditionally considered an intracellular
pathogen, S. aureus can enter endothelial cells (6, 20,
49, 50, 53), epithelial cells (4, 5), and osteoblasts
(21) in vitro. We and others reported previously that uptake
requires host cytoskeletal rearrangements and induced membrane
structures similar to those seen during entry of Listeria
and Yersinia spp. into nonprofessional phagocytes
(5). The present study investigated early events in S. aureus internalization by MAC-T cells. It showed that
internalization of S. aureus shares two fundamental
requirements with intracellular pathogens: (i) a crucial ligand (FnBP)
on the bacterial surface and (ii) PTK activity probably representing host cell signal transduction.
The conclusion that FnBPs are required for efficient internalization by
nonprofessional phagocytes arose from several lines of evidence.
Mutants unable to express FnBPs were dramatically reduced in their
ability to enter MAC-T cells, whereas strains with mutations in genes
encoding other surface proteins (clumping factor [fibrinogen binding
protein] and protein A) were internalized only slightly less
efficiently. We obtained similar results with other cell lines in
vitro, including HEp-2 (9) and Caco-2 (12) cells
of human origin (our unpublished results), indicating that the
requirement for FnBPs is not limited to entry into bovine epithelial
cells. S. aureus FnBPs have long been recognized for their
role in colonization and invasion of tissues by binding to Fn in the
extracellular matrix. It is now clear that they are also required for
internalization by epithelial cells. It is generally agreed that
colonization of the vascular endothelium or mucosal surfaces is a
prerequisite to internalization of bacteria by nonprofessional phagocytes. The outcome of colonization is determined largely by
receptor-ligand interactions between the host cell and the pathogen
surfaces as described by Isberg and Tran Van Nhieu (25).
FnBPs could induce internalization through several possible mechanisms.
One possibility is that they are the ligand or part of a ligand complex
that interacts directly with a host cell surface receptor. As such,
they could function similarly to ligands reported for
Listeria spp. (18), Yersinia spp.
(24, 26), or Neisseria gonorrhoeae
(54). Alternatively, the FnBPs could act indirectly by
exposing or stabilizing an appropriate conformation of another surface
protein which functions as the true ligand. Our results showing that D3
or soluble Fn blocks internalization and our demonstration that Fn
binding correlates with the ability of staphylococci to interact
with host cell receptors suggest that the former possibility is most
likely for S. aureus.
Although strain DU5883 is deficient in FnBPs, its adherence to MAC-T
cells was reduced by only 40% compared to that of parental strain
8325-4. Similarly, Flock et al. (15) reported no difference in adherence of these two strains in vivo with a rat endocarditis model. Thus, either in vitro or in vivo, other surface molecules such
as MSCRAMMs compensate for the lack of Fn binding by DU5883, allowing
the organism to bind to cells. However, our results confirmed that
adherence alone is insufficient to induce internalization, since uptake
of DU5883 by MAC-T cells was nearly completely abrogated. It is
generally assumed that uptake of microorganisms has two essential
requirements: (i) binding to a host cell receptor with an affinity
sufficient to transduce an appropriate signal through the membrane, and
(ii) subsequent cytoskeletal rearrangement leading to uptake. It is now
clear that the uptake of staphylococci occurs via the same general
mechanisms. We and others have shown previously that entry of S. aureus into nonprofessional phagocytes is characterized by changes
in the host cell membrane, leading to engulfment of the bacterium
(4, 5). In addition, uptake was impaired by cytochalasin D,
an inhibitor of actin polymerization. The present study has further
extended these observations by demonstrating a requirement for PTK
activity; uptake was sensitive to genistein, an inhibitor of PTK
activity. The effect was not due to a toxicity for the host cell or
bacteria, since inhibition of internalization was reversed by removal
of genistein from the cultures.
The host cell ligand responsible for FnBP-mediated internalization
remains to be determined. One possibility is that S. aureus utilizes a receptor employed by other organisms. Several host cell
proteins are known to bind and mediate bacterial internalization by
involvement of different host signal transduction systems. Different
classes of protein kinases participate in this process (12,
42-46, 52, 56). Isberg and Leong (24) reported that 
1-integrins are receptors for invasin, a protein that
promotes the entry of Yersinia spp. into host cells. The
integrins interact with the cytoskeleton by noncovalent binding between
cytoplasmic domains of integrin -chains and various actin binding
proteins within the focal adhesion complex (56). Likewise,
Mengaud et al. (35) identified E-cadherins as the cell
receptor for Listeria monocytogenes internalin. Rosenshine
et al. (46) showed that enteropathogenic Escherichia
coli attached to epithelial cells, causing actin polymerization at
the adherence site and phosphorylation of epithelial membrane protein
Hp90, which then associates directly with bacterial intimin.
The role of Fn in internalization remains to be determined. The Fn
binding capacity partly correlated with the ability of various strains
of staphylococci to be internalized, and excess soluble Fn blocked
internalization by the MAC-T cells. These results are consistent with
several potential models of uptake. In one model, Fn is a bifunctional
molecule which forms a "bridge" between FnBP and a cellular
receptor, linking the bacteria to the cell surface. If this were the
case, a likely candidate for a cellular receptor would be the
-integrins, which are well known for their ability to bind to Fn
or other extracellular-matrix components. Several well-characterized
intracellular pathogens are internalized by binding to integrins.
Furthermore, as described above, integrins have the potential to induce
signal transduction, leading to cytoskeletal rearrangements. While this
"bridge" model may be supported by circumstantial evidence, several
lines of evidence suggest that S. aureus may bind directly
to a host cell receptor without an Fn bridge. Our demonstration that
S. aureus internalization is blocked by Fn is consistent
with a direct-binding mode. Presumably, Fn blocks a site on the FnBP,
which binds to the host cell receptor. Furthermore, the affinity of Fn
binding to 51-integrin receptor is lower
(Kd = 8 × 10
7) than the
affinity of ligands such as invasin (Kd = 5 × 109) and is generally not believed to be
sufficiently high to induce internalization (24, 25, 51).
For example, Isberg and colleagues showed that the interaction of Fn
with 51-integrin molecules is too weak to
mediate internalization and that particles or bacteria artificially
coated with Fn are not internalized (24, 25). Identification
of the receptors and ligands involved is an area under investigation in
our laboratories, and it should differentiate between these two
potential mechanisms of binding.
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ACKNOWLEDGMENTS |
This work was supported by PHS grants AI28401 (G.A.B.) and
AI38901 (K.W.B.), the United Dairymen of Idaho (G.A.B.), and a sabbatical fellowship from the Organization for Economic Cooperation and Development (W.R.T.).
We are grateful to Tim Foster, who supplied many of the strains used in
this study.
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FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Microbiology, Molecular Biology and Biochemistry, University of Idaho, Moscow, ID 83844-3052. Phone: (208) 885-6666. Fax: (208) 885-6518. E-mail: gbohach{at}uidaho.edu.
Editor:
V. A. Fischetti
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Infection and Immunity, September 1999, p. 4673-4678, Vol. 67, No. 9
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Abstract
Introduction
