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Infection and Immunity, November 1998, p. 5337-5343, Vol. 66, No. 11
0019-9567/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
Invasion of Aortic and Heart Endothelial Cells by
Porphyromonas gingivalis
Rajashri G.
Deshpande,1
Mahfuz B.
Khan,1 and
Caroline
Attardo Genco2,*
Department of Microbiology and Immunology,
Morehouse School of Medicine, Atlanta, Georgia
30320-1495,1 and
Department of Medicine,
Section of Infectious Diseases, Boston University School of
Medicine, Boston, Massachusetts 021182
Received 5 May 1998/Returned for modification 2 July 1998/Accepted 2 September 1998
 |
ABSTRACT |
Invasion of host cells is believed to be an important strategy
utilized by a number of pathogens, which affords them protection from
the host immune system. The connective tissues of the periodontium are
extremely well vascularized, which allows invading microorganisms, such
as the periodontal pathogen Porphyromonas gingivalis, to readily enter the bloodstream. However, the ability of P. gingivalis to actively invade endothelial cells has not been
previously examined. In this study, we demonstrate that P. gingivalis can invade bovine and human endothelial cells as
assessed by an antibiotic protection assay and by transmission and
scanning electron microscopy. P. gingivalis A7436 was
demonstrated to adhere to and to invade fetal bovine heart endothelial
cells (FBHEC), bovine aortic endothelial cells (BAEC), and human
umbilical vein endothelial cells (HUVEC). Invasion efficiencies of 0.1, 0.2, and 0.3% were obtained with BAEC, HUVEC, and FBHEC, respectively.
Invasion of FBHEC and BAEC by P. gingivalis A7436 assessed
by electron microscopy revealed the formation of microvillus-like
extensions around adherent bacteria followed by the engulfment of the
pathogen within vacuoles. Invasion of BAEC by P. gingivalis
A7436 was inhibited by cytochalasin D, nocodazole, staurosporine,
protease inhibitors, and sodium azide, indicating that cytoskeletal
rearrangements, protein phosphorylation, energy metabolism, and
P. gingivalis proteases are essential for invasion. In
contrast, addition of rifampin, nalidixic acid, and chloramphenicol had
little effect on invasion, indicating that bacterial RNA, DNA, and de
novo protein synthesis are not required for P. gingivalis
invasion of endothelial cells. Likewise de novo protein synthesis by
endothelial cells was not required for invasion by P. gingivalis.
P. gingivalis 381 was demonstrated to adhere to and to invade
BAEC (0.11 and 0.1% efficiency, respectively). However, adherence and
invasion of the corresponding fimA mutant DPG3, which lacks
the major fimbriae, was not detected. These results indicate that
P. gingivalis can actively invade endothelial cells and
that fimbriae are required for this process. P. gingivalis invasion of endothelial cells may represent another strategy utilized by this pathogen to thwart the host immune response.
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INTRODUCTION |
Adult periodontitis is a bacterially
induced chronic inflammatory disease that is the major cause of tooth
loss in the adult population (28). The disease has recently
been associated with cardiovascular disease and preterm delivery of low
birth weight infants (2, 10, 23). Interactions of the
periodontal pathogen Porphyromonas gingivalis with the host
immune system are believed to be the basis for the destructive
inflammatory response which is characteristic of this disease, and the
intimate interaction of P. gingivalis with the host has
become the subject of intense investigation. The innate host defense
system has been postulated to function in limiting the spread of
P. gingivalis within the periodontal pocket by maintaining
an intact epithelial cell barrier. However, several studies have
documented that P. gingivalis can be found within gingival
tissues in vivo, suggesting that it may pass through the epithelial
barrier (24, 26). Invasion of oral epithelial cells by
P. gingivalis in vitro has also been demonstrated by a
number of investigators (8, 14, 16, 22). Reports by Madianos
et al. (16) and by Lamont et al. (14) have
confirmed the ability of P. gingivalis to replicate within KB cells and within primary gingival epithelial cells. P. gingivalis has also been shown to advance into deeper epithelial
layers (24, 26), a process that could play a role in the
systemic spread of the organism.
Ulcerations and disruptions of the basement membrane commonly occur in
periodontitis (20) and may result from the production of
potent P. gingivalis proteases that can degrade type IV
collagen present in the basement membrane (33). The
connective tissues of the periodontium are extremely well vascularized
(9), allowing the invading microorganisms to readily enter
the bloodstream. Thus, in addition to invasion of epithelial cells, the
ability of P. gingivalis to actively invade endothelial
cells could represent an additional mechanism evolved by this pathogen
to evade the host response. The interactions between P. gingivalis outer membrane components and endothelial cells (EC)
have been investigated by Darveau and colleagues, who examined the
ability of P. gingivalis lipopolysaccharide (LPS) to
stimulate an inflammatory response (5). These investigators
found that unlike Escherichia coli LPS, P. gingivalis LPS did not stimulate the expression of E-selectin in
human umbilical cord EC nor did it stimulate neutrophil adhesion to
these cells (5). These observations are consistent with a
role of P. gingivalis in suppressing the innate host
inflammatory response to bacteria. Although these studies demonstrate
that P. gingivalis components can interact with EC and cause
a direct effect on the expression of adhesion molecules, the ability of viable P. gingivalis whole cells to interact with EC (active
invasion process) has not been previously examined. The goal of this
study was to determine whether P. gingivalis invades
vascular EC in vitro. Our results indicate that P. gingivalis can actively invade EC and can replicate
intracellularly. Expression of the major fimbriae is required for both
adherence to and invasion of EC. We have also characterized the
metabolic requirements for invasion of EC by P. gingivalis.
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MATERIALS AND METHODS |
Bacterial strains.
P. gingivalis A7436 was originally
isolated from a patient with refractory periodontitis and was
characterized in our laboratory; strain 381 and its fimA
mutant DPG3 have been described previously (17). P. gingivalis fimA mutant DPG3 was constructed following allelic
exchange of P. gingivalis 381 with the insertionally
inactivated fimA gene (17). As seen previously,
P. gingivalis 381 cultures were electron dense and produced
long slender fimbriae (ca. 15 nm in diameter) that were easily seen in
negatively stained preparations (22). By contrast, we did
not detect these long fimbriae on the surface of the corresponding
P. gingivalis fimA mutant DPG3 (22), indicating
that the insertion mutation in DPG3 blocked fimbria production.
P. gingivalis A7436 and 381 were grown on anaerobic blood
agar (ABA) plates (BBL media; Becton Dickinson Co., Cockeysville, Md.),
and DPG3 was grown on ABA containing erythromycin (10 µg/ml) under
anaerobic conditions in an anaerobic chamber (with 85% N2,
10% CO2, and 5% H2) for 3 to 5 days,
inoculated into fresh Schaedler broth (Difco) (containing erythromycin
for DPG3), and grown for 24 h until the optical density reached
1.0.
Interaction of P. gingivalis with EC.
Adherence
and invasion of P. gingivalis was assessed in bovine aortic
endothelial cells (BAEC), fetal bovine heart endothelial cells (FBHEC),
and human umbilical vein endothelial cells (HUVEC) as described
previously with EC (22). Invasion of KB oral EC (GIBCO-BRL
Life Technologies, Grand Island, N.Y.) was as previously described
(22). BAEC (Repository no. AG08592, N.I.A. Aging Cell Culture Repository, Coriell Institute for Medical Research, Camden, N.J.) and FBHEC (ATCC CRL 1395, American Type Culture Collection [ATCC], Rockville, Md.) were maintained in Dulbecco's modified Eagle
medium (DMEM) (GIBCO-BRL Life Technologies) supplemented with 10%
heat-inactivated newborn calf serum (NCS [GIBCO-BRL]) and
penicillin-streptomycin-glutamine (GIBCO-BRL). FBHEC were supplemented
with 100 ng of fibroblast growth factor (GIBCO-BRL)/ml. HUVEC (ATCC CRL
1730; ATCC) were maintained in F-12K medium (ATCC) supplemented with
heparin (100 µg/ml; Sigma Chemical Co., St. Louis, Mo.) and EC growth
supplement (50 µg/ml; Sigma) in addition to normal human serum and
antibiotic solution as described for BAEC. Subcultivation was performed
on confluent cultures that had been plated 24 h earlier. All EC
were plated at a concentration of 106 cells per ml, as
determined by cell counting on a Coulter Counter (8). For
all invasion assays, we used Falcon six-well flat-bottom plates with a
volume of 15.5 ml/well and a surface area of 9.6 cm2/well.
The multiplicity of infection (MOI) was calculated based on the number
of cells per well at confluence. P. gingivalis strains grown
to an optical density of 1.0 were centrifuged, washed with phosphate-buffered saline (PBS), and resuspended in DMEM containing 1 mM MgCl2 and 0.2 mM CaCl2 at a final
concentration of 108 cells per ml in the absence of serum.
Bacterial suspensions (1.0 ml) were added to confluent EC monolayers
(MOI = 100) and incubated at 37°C in 5% CO2 for
2 h. After incubation, unattached bacteria were removed following
washing of the monolayers twice with PBS. EC were lysed in 1 ml of
sterile distilled water (dH2O) per well and incubated for
30 min, during which they were disrupted by repeated pipetting. Control
experiments demonstrated that exposure to water for 30 min did not
affect bacterial viability. Lysates were serially diluted, plated on
ABA plates, and incubated anaerobically at 37°C for 7 days to
determine the number of organisms that adhered to EC. All assays were
performed in triplicate.
Invasion of EC monolayers by P. gingivalis strains was
quantified by determining the number of CFU recovered following
antibiotic treatment. Confluent EC monolayers were infected with 1.0 ml
of a bacterial suspension (final concentration, 108 cells),
and tissue culture plates were centrifuged at 2,000 × g for 10 min at 4°C to enhance contact between EC and bacteria. Infected monolayers were incubated at 37°C for 1 to 4 h in a 5% CO2 incubator. After every hour, unattached bacteria were
removed following washing of the monolayers twice with PBS. External
adherent cells were killed by incubating the infected monolayers with
DMEM containing 100 µg of metronidazole/ml. This concentration of
antibiotic was sufficient to completely kill 108 bacteria
per ml in 1 h (data not shown). The antibiotic did not affect the
morphology or viability of the EC as detected by their ability to
exclude trypan blue. Controls for antibiotic killing of P. gingivalis were included in all experiments. After exposure to
antibiotic, monolayers were washed twice with PBS, and EC were lysed in
1 ml of sterile dH2O per well and incubated for 30 min. Lysates were diluted and plated on ABA plates and incubated
anaerobically at 37°C for 7 days. CFU of invasive organisms were then
enumerated. Invasion was expressed as the percentage of the initial
inoculum recovered after antibiotic treatment and EC lysis. All assays were performed in triplicate. E. coli JM109 and HB101 were
used as appropriate negative controls for invasion assays with BAEC.
Since our results indicated that cytochalasin D treatment inhibited
P. gingivalis invasion of EC (see below), we also examined
the adherence of
P. gingivalis to EC in cytochalasin
D-treated
cultures. When adherence was measured without cytochalasin D
treatment,
we obtained an adherence efficiency of 0.16%. When
adherence was
measured in cytochalasin D-treated cultures, we observed
an adherence
efficiency of 0.14%. Thus, the adherence assay described
here
is a good readout of the number of bacteria adhering.
To address the possibility of intracellular replication of
P. gingivalis within the EC,
P. gingivalis A7436 was
incubated
with BAEC for 2 h after which the extracellular bacteria
were
killed by antibiotic treatment. After washing of the wells to
remove the antibiotic, the EC were maintained in culture medium
for an
additional 6 h to allow replication of intracellular bacteria.
Lysate was prepared as described above, diluted appropriately,
and
plated on ABA plates, and CFU were enumerated after incubation
under
anaerobic conditions as described above.
Inhibitors of bacterial and EC functions.
The effect of a
variety of inhibitors of procaryotic and eucaryotic cell functions on
P. gingivalis invasion of BAEC was investigated. All
chemicals were obtained from Sigma. The following inhibitors, in the
solvent and at the final concentration indicated, were used:
cytochalasin D, 1 µg/ml in dimethyl sulfoxide (DMSO); nocodazole, 10 µg/ml in DMSO; staurosporine, 1 µM in DMSO; sodium azide, 50 mM in
PBS; cycloheximide, 100 µg/ml in ethanol; chloramphenicol, 5 µg/ml
in DMEM; rifampin, 0.25 µg/ml in acetone; nalidixic acid, 5 µg/ml
in 1 N NaOH; and a cocktail of protease inhibitors containing aprotonin, 2 µg/ml in dH2O; phenylmethylsulfonyl
fluoride, 0.1 mM in methanol; pepstatin, 0.7 µg/ml in methanol; and
benzamidine, 1 mM in methanol. Cytochalasin D and staurosporine were
preincubated with the EC for 30 min prior to the addition of the
bacteria and remained present throughout the invasion assay. Nocodazole
was preincubated with the EC for 1 h on ice and then at 37°C for
30 min prior to reacting with the bacteria. The drug was present during
the invasion assay. Cycloheximide was preincubated with the EC for
4 h before bacterial addition and was present during the assay.
Sodium azide was preincubated with the EC for 4 h and then removed
by washing three times in DMEM prior to bacterial addition. Sodium
azide was also preincubated with P. gingivalis for 4 h
and then removed by washing prior to the assay. Chloramphenicol, rifampin, and nalidixic acid were preincubated with the bacteria for
4 h before reaction with the EC and were present during the assay.
Protease inhibitors were preincubated with the bacteria for 30 min
prior to the assay. All potential inhibitors were tested at the
concentrations used for possible adverse effects on the EC (compared
with cells without the inhibitor) by examining the morphology of the
cells and the confluency of the monolayer and by trypan blue exclusion.
Cytochalasin D, nocodazole, staurosporine, cycloheximide, and the
protease inhibitors were examined for any toxic effects on P. gingivalis as determined by viable cell counting and were found to
have no adverse effect on the viability at the concentrations used.
Ethanol, acetone, DMSO, methanol, and NaOH, which were used as
solvents, were tested at the appropriate concentrations and found to
produce no reduction in P. gingivalis numbers.
Electron microscopy.
Transmission and scanning electron
microscopies (TEM and SEM) were performed on designated samples to
confirm adherence to EC and internalization within the cells. For TEM,
EC were cultured in six-well plates and treated as described for the
invasion experiments, with the following modifications. Following a 2-h
incubation with bacteria, monolayers were washed four times in PBS and
detached from the plastic surface with trypsin. The cell slurry was
then immediately centrifuged for 4 min at 15,000 × g.
The cell pellet was washed twice with PBS and fixed with 2.5%
gluteraldehyde in 0.1 M sodium cacodylate. Cells were pelleted and
postfixed in 1% OsO4 in 0.1 M sodium cacodylate for 1 h, and the ultrathin sections were contrasted with lead citrate and
uranyl acetate before examination by TEM with a 1200EX electron
microscope (JEOL, Tokyo, Japan). For SEM, EC were incubated with
P. gingivalis for 1 h and washed with PBS, and bacteria
attached to EC were observed with a scanning electron microscope
(JSM-820; JEOL).
| |
RESULTS |
Invasion of EC by P. gingivalis.
P. gingivalis
A7436 was found to invade BAEC, FBHEC, and HUVEC at invasion
efficiencies of 0.1, 0.3, and 0.2%, respectively (Table
1). Adherence of P. gingivalis
A7436 to KB epithelial cells was approximately one log higher than that
observed with EC. However, the invasion efficiencies observed for
P. gingivalis A7436 with EC (0.1 to 0.3%) were
approximately one log higher than that observed for P. gingivalis invasion of epithelial cells (0.01%) (Table 1). As
expected, we did not observe invasion of BAEC with E. coli
JM109 or HB101, which were used as negative controls. The invasion
efficiencies observed for E. coli JM109 and HB101 were
0.0007 and 0.005%, respectively (data not shown).
The number of input
P. gingivalis cells was also observed to
influence the invasion efficiency of
P. gingivalis for BAEC.
The invasion efficiency of
P. gingivalis for BAEC at an MOI
of
1:1 was 0.04% and increased to 0.1% at an MOI of 1:10 (Fig.
1).
The maximum invasion efficiency of
0.2% was observed at an MOI
of 1:100. We obtained a slightly lower
level of invasion of BAEC
by
P. gingivalis A7436 at an MOI
of 1:1,000, and thus for the
remainder of the studies described below
we utilized an MOI of
1:100. At an MOI of 1:100, optimal invasion of
BAEC by
P. gingivalis A7436 was observed at 2 h with no
further increase in invasion
with an extended incubation period up to
4 h (data not shown).
We also found that a majority of the
P. gingivalis organisms that
had adhered to the EC were
found to invade as assessed by an antibiotic
protection assay (Table
1). Centrifugation of
P. gingivalis cultures
on the EC
monolayers was observed to slightly enhance the invasion
efficiency but
was not required for active invasion (data not
shown).
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FIG. 1.
MOI of P. gingivalis for BAEC. P. gingivalis A7436 was grown as described in Materials and Methods,
and 105 to 109 CFUs were added to
106 BAEC and incubated as described for the invasion
assays. The invasion efficiency is defined as the percentage of the
inoculum (P. gingivalis) protected from metronidazole
killing after the infection period. For MOI of 0.1, 1.0, 10, 100, and
1,000, 105, 106, 107,
108, and 109 P. gingivalis CFU,
respectively, were used.
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Adherence and invasion efficiencies of the
P. gingivalis
wild-type strains 381 and A7436 to BAEC were similar (Table
2).
In contrast to the results obtained
with the
P. gingivalis wild-type
strain 381, we did not
detect adherence of the
P. gingivalis fimA mutant DPG3 to
BAEC. In agreement with the results obtained in
the adherence assay, we
did not detect invasion of BAEC by
P. gingivalis DPG3. These
results are in agreement with our previous
observations in a KB oral
epithelial cell line (
22) and indicate
that the major
fimbriae are required for invasion of EC.
We also found that
P. gingivalis was capable of replicating
within BAEC, increasing from a mean of 4.2 × 10
6 CFU
detected following a 2-h incubation to a mean of 6.2 × 10
7 CFU detected following a 6-h incubation period (data
not shown).
The BAEC were viable following the 6-h incubation period
with
P. gingivalis as determined by trypan blue dye
exclusion (data
not shown). We were unable to accurately assess the
growth of
P. gingivalis in EC for longer periods of time due
to alterations
in the morphology of the BAEC monolayer following
long-term incubation
with
P. gingivalis A7436.
Electron microscopy.
We next examined the nature of the
interaction of P. gingivalis with EC by electron microscopy.
P. gingivalis wild-type strain A7436 was seen adhering to
BAEC and could be seen entering an individual cell (Fig.
2A and B). P. gingivalis A7436
could be seen intimately attached to both BAEC and to FBHEC (Fig. 2A,
B, E, and F). This intimate attachment included the presence of
microvilli protruding from the EC and surrounding the attached
bacteria; this process may represent the initial formation of a
cytoplasmic vacuole. P. gingivalis A7436 was also visible
within the cytoplasm of BAEC and FBHEC and was detected within what
appeared to be vacuoles (Fig. 2B and F). Similar results were observed
in HUVEC infected with P. gingivalis A7436 (data not shown).
We also observed the presence of microvilli protruding from the cell
surface in BAEC infected with P. gingivalis wild-type strain
381 (Fig. 2C). In contrast, we did not observe microvilli on the
surface of BAEC infected with the fimA mutant strain, nor
did we detect alterations in the BAEC surface (Fig. 2D). Likewise,
P. gingivalis DPG3 was not detected within EC.
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FIG. 2.
Transmission electron micrographs demonstrating P. gingivalis invasion of EC. (A and B) BAEC with P. gingivalis A7436. (A) At the cell surface, bacteria appear to
induce EC structural rearrangements consistent with an endocytic
mechanism. (B) Internalized bacteria are found within vacuole. (C) BAEC
with P. gingivalis 381. Note the apparent contact between
microfilamentous cellular components and surface-adhering P. gingivalis. (D) BAEC with P. gingivalis fimA mutant
DPG3. Absence of intimate interaction between EC surface and bacteria.
(E and F) FBHEC incubated with P. gingivalis A7436. Surface
adherence (E) and engulfment in vacuole (F). Arrows in all panels point
to P. gingivalis. Bars on each image are 0.5 µm unless
otherwise specified. Composite image was constructed with Adobe
Photoshop 3.0.
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We also examined the interactions of
P. gingivalis A7436,
381, and DPG3 with BAEC and FBHEC by SEM. Following the addition
of
P. gingivalis wild-type strain A7436 or 381, profound
changes
in the normal architecture of the EC surface occurred with the
appearance of long microvilli surrounding large bacterial clumps
(Fig.
3B, C, and F). However, no such change
was observed with
the
fimA mutant DPG3 (Fig.
3D). Taken
together, these results
suggest that the major fimbriae may trigger a
sequence of events
that can lead to the reorganization of cytoskeletal
components,
giving rise to long microvilli which facilitate fimbrial
contact
with the EC. In the absence of fimbria expression,
P. gingivalis does not appear to come into contact with the EC nor
does it trigger
host signaling events.
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FIG. 3.
Adherence of P. gingivalis to EC examined by
SEM. (A) Uninfected BAEC. (B) BAEC infected with P. gingivalis A7436. (C) BAEC infected with P. gingivalis
381. (D) BAEC infected with P. gingivalis fimA mutant DPG3.
(E) Uninfected FBHEC. (F) FBHEC infected with P. gingivalis
A7436.
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Metabolic requirements for invasion.
Inhibition of invasion of
BAEC by P. gingivalis with compounds that impede various
metabolic functions of eucaryotic and procaryotic cells was examined as
shown in Table 3. Bacterial DNA and RNA synthesis does not appear to be required for invasion, as nalidixic acid and rifampin did not inhibit P. gingivalis invasion of
BAEC. Similarly, bacterial and BAEC de novo protein synthesis was not required for invasion since both chloramphenicol and cycloheximide did
not reduce the invasion of BAEC by P. gingivalis. All these compounds were also tested at higher concentrations (five times the
concentration indicated in the Materials and Methods section) and were
found to have no effect on the invasion of BAEC by P. gingivalis (data not shown). Cytochalasin D, an inhibitor of actin polymerization, and nocodazole, an inhibitor of microtubule formation, substantially reduced invasion, indicating that both microfilaments and
microtubule activity are required for invasion. Staurosporine, a
broad-spectrum inhibitor of protein kinases, inhibited invasion, suggesting that protein phosphorylation is involved in the EC signaling
pathway that results in bacterial entry into the cell. EC as well as
P. gingivalis energy metabolism is also required for active
invasion of P. gingivalis, as sodium azide (which reduced the proton motive force and inhibits cytochrome oxidase) inhibited invasion when bacteria or BAEC were preincubated with this compound. The cocktail of protease inhibitors, aprotonin, phenylmethylsulfonyl fluoride, pepstatin, and benzamidine, at concentrations predetermined not to be lethal to the BAEC monolayers or to P. gingivalis,
inhibited P. gingivalis invasion of BAEC by 99% (Table 3).
| |
DISCUSSION |
Invasion of epithelial cells by P. gingivalis
has been reported by a number of investigators (8, 14, 16,
22). However, this is the first report on the invasion of EC by
P. gingivalis. We have demonstrated that P. gingivalis can invade FBHEC and BAEC as well as HUVEC. We found
that P. gingivalis was capable of replicating within EC,
suggesting that it has the capacity to persist within this host cell
and possibly to alter the integrity of the EC. We also observed that a
majority of the P. gingivalis organisms that had adhered to
the EC were able to actively invade, suggesting a highly efficient
endocytic uptake of surface-adherent organisms. Similar results have
been observed during invasion of brain microvascular EC by group B
streptococci (21). Whether P. gingivalis uses an
endocytic pathway for uptake into EC has not yet been established; however, analysis of the invasion of EC by P. gingivalis by
electron microscopy supports the endocytic pathway of engulfment. In
addition, studies of P. gingivalis invasion of epithelial
cells have shown that treatment of epithelial cells with
monodansylcadaverine and ouabain, substances that inhibit the formation
of coated pits, results in reduction in the number of invading P. gingivalis (27). Thus it is possible that P. gingivalis utilizes a similar pathway for the invasion of EC.
The major fimbria of P. gingivalis appears to play a major
role in adherence and invasion of BAEC, since we did not detect invasion by the fimA mutant DPG3. Previous studies have
established that P. gingivalis DPG3 does not produce
fimbriae detectable by electron microscopy or Western blot analysis
(17, 22). The involvement of P. gingivalis major
fimbriae in invasion of epithelial cells has been reported previously
(23, 32). We cannot rule out the possibility that molecules
other than fimbriae may also be required for the adherence of P. gingivalis to EC. Our recent results indicate that digestion of
P. gingivalis A7436 with amyloglucosidase, which partially
dissolves the polysaccharide capsule, increases threefold the invasion
efficiency of P. gingivalis for BAEC (6). It is
well documented that in other bacteria the production of a
polysaccharide capsule may interfere with attachment of bacteria to
epithelial and endothelial cells (30, 31). It has been demonstrated that polysaccharide capsule-deficient mutants of Haemophilus influenzae type B exhibit enhanced adherence to
and invasion of human cells (30). Whether the partial
digestion of P. gingivalis capsule helped to unmask or
expose adhesive ligands and fimbriae present on P. gingivalis cell surface remains to be determined.
It appears that invasion of EC by P. gingivalis shares some
similar characteristics with the invasion process for epithelial cells,
while other characteristics are unique to the EC. Electron microscopic
analysis confirmed the intimate interaction of P. gingivalis
A7436 and 381 with BAEC. The interaction of P. gingivalis with BAEC appears to involve attachment to BAEC and subsequent engulfment of the bacteria and is similar to what has been previously observed during invasion of epithelial cells by P. gingivalis (22). Invasion of EC by P. gingivalis does not require bacterial DNA, RNA, or de novo protein
synthesis, while these bacterial functions are reported to be essential
for epithelial cell invasion by P. gingivalis
(14). Endothelial and epithelial cell invasion, however,
seems to require the energy metabolism of both BAEC and bacteria, as
well as the expression of the P. gingivalis proteases (14). In agreement with observations of invasion of
epithelial cells by P. gingivalis (27), our
results indicate that cytoskeletal rearrangements and protein
phosphorylation are required for invasion of BAEC by P. gingivalis. It appears that the receptors required for adherence
of P. gingivalis may be present on the EC surface since de
novo protein synthesis of EC is not required for invasion.
The interactions between P. gingivalis outer membrane
components and EC have been studied extensively by Darveau and
colleagues (5). These investigators have shown that LPS of
P. gingivalis does not stimulate E-selectin expression and
that it can block E-selectin expression by LPS from other gram-negative
bacteria (5). However, it remains to be determined how the
active invasion of EC by viable P. gingivalis cells affects
the regulation of specific adhesion molecules as well as the cytokine
response of the EC. A number of microorganisms have been observed to
actively invade EC by a process that stimulates adhesion molecule
expression and cytokine production (7, 11-13, 15).
Chlamydia pneumoniae, which has recently been linked to
coronary heart disease, has been demonstrated to cause an upregulation
of E-selectin, intercellular adhesion molecule (ICAM-1), and vascular
cell adhesion molecule (VCAM-1) (13). Rickettsia
rickettsii infection of EC stimulates these cells to produce
interleukin-1
(IL-1) (29). Rickettsia conorii infection of EC has also been demonstrated to enhance the
expression of the adhesive molecules E-selectin, ICAM-1, and VCAM-1
(7). Active invasion of R. conorii was also
required for production of IL-6 and IL-8 from cultured human EC
(12). Likewise, active invasion of epithelial cells by
several microorganisms has been demonstrated to modulate endogenous
cytokine production (1, 4). Aihara et al. (1)
found that only viable Helicobacter pylori in direct contact
with gastric epithelial cells induces IL-8 formation. Killed bacteria,
culture supernatants, and juxtaposition of a cell-impermeable barrier
between the epithelial cells and bacteria abrogated the effect. Recent
studies indicate that invasion of epithelial cells by P. gingivalis results in the inhibition of IL-8 secretion
(4). Thus, growing evidence suggests an important role for
direct bacteria cell interactions for the modulation of expression of
cell adhesion molecules and cytokines.
Several reports have described an association between periodontal
disease and coronary artery disease. These include case control studies
which demonstrated significant associations after correction for
cholesterol, smoking, hypertension, social class, and body mass index
(2, 10, 18, 19). Infection with P. gingivalis and
the biological consequences for increased risk for cardiovascular
disease have recently received considerable attention (10).
P. gingivalis infection can cause local inflammation which
leads to ulceration of the gingivae and local vascular changes which
increase the incidence and the severity of transient bacteremias when
the gingivae are traumatized. Procedures such as dental extraction, periodontal surgery, tooth scaling, and even tooth brushing can lead to
the presence of oral bacteria in circulating blood (3). The
gingival sulcus is believed to be the most likely area of entry of oral
bacteria into the bloodstream, and the integrity of the basement
membrane of the oral mucosa, and particularly the gingival sulcus, is
paramount in the protection of patients at risk for cardiovascular
disease (3). The results presented here indicate that
P. gingivalis can actively invade and multiply within EC,
indicating that P. gingivalis has evolved mechanisms for
survival and replication within vascular EC. Injured or activated EC
(during infection) may show various artherogenic properties, including
increased procoagulant activity, secretion of vasoactive and
inflammatory mediators, and expression of adhesion molecules. E-selectin, ICAM-1, and VCAM-1 have been detected in atherosclerotic areas of human arteries (25), and inflammatory cells are
abundant at these sites. Studies are currently under way in our
laboratory to examine the regulation of adhesion molecule expression as
well as the cytokine production in response to P. gingivalis
invasion of EC. Invasion of vascular and heart EC by P. gingivalis after entry into the bloodstream may contribute to the
pathology of cardiovascular disease.
| |
ACKNOWLEDGMENTS |
This work was supported by Research Centers for Minority
Institutions (RCMI) grant RR/AI03034 and by DE9161 from the National Institutes of Health.
The authors would like to thank Lawrence Brako for the electron
microscopy, Aurellia James for the illustrations, and Yvonne Powers for
typing the manuscript. We also acknowledge Hakim Sojar and Robert
J. Genco for stimulating discussions regarding this work.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Medicine, Section of Infectious Diseases, Boston University School of Medicine, 774 Albany St., Boston, MA 02118. Phone: (617) 414-5282. Fax:
(617) 414-5280. E-mail: caroline.genco{at}bmc.org.
Editor:
J. R. McGhee
| |
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Infection and Immunity, November 1998, p. 5337-5343, Vol. 66, No. 11
0019-9567/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
