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Previous Article | Next Article 
Infect Immun, February 1998, p. 696-702, Vol. 66, No. 2
0019-9567/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
Filamentous Actin Disruption and Diminished
Inositol Phosphate Response in Gingival Fibroblasts Caused by
Treponema denticola
Po Fong
Yang,
Meja
Song,
David A.
Grove, and
Richard P.
Ellen*
Faculty of Dentistry, University of Toronto,
Toronto, Ontario, Canada M5G 1G6
Received 28 July 1997/Returned for modification 21 October
1997/Accepted 17 November 1997
 |
ABSTRACT |
Previous reports have shown that Treponema denticola
causes rearrangement of filamentous actin (F-actin) in human gingival fibroblasts (HGF). The purpose of this investigation was to determine the effect of T. denticola on the generation of inositol
phosphates (IPs) in relation to a time course for F-actin disruption in
HGF. Cultured HGF were exposed to washed cells of T. denticola ATCC 35405 for 140 min. Changes in the fluorescence
intensity of rhodamine-phalloidin-labeled F-actin in serial optical
sections of single HGF were quantified by confocal microscopy image
analysis. The percentage of cells with stress fiber disruption was also
determined by fluorescence microscopy. Challenge with T. denticola caused a significant reduction in F-actin within the
first hour, especially at the expense of F-actin in the ventral third
of the cells, and a significant increase in the percentage of HGF with
altered stress fiber patterns. Significant concentration-dependent
disruption of stress fibers was also caused by HGF exposure to a Triton
X-100 extract of T. denticola outer membrane (OM). IPs were
measured by a radiotracer assay based on the incorporation of
myo-[3H]inositol into IPs in HGF incubated
with LiCl to inhibit endogenous phosphatases. HGF challenge with
several strains of T. denticola and the OM extract of
T. denticola ATCC 35405 resulted in a diminished accumulation of radiolabeled IPs relative to both 15 and 1% fetal bovine serum, which served as strongly positive and background control
agonists, respectively. The significantly diminished IP response to
T. denticola ATCC 35405 occurred within 60 min, concomitant with significant reduction of total F-actin and disruption of stress
fibers. Pretreatment with the proteinase inhibitor phenylmethylsulfonyl fluoride, which had previously been found to block T. denticola's degradation of endogenous fibronectin and detachment
of HGF from the extracellular matrix, had little effect on F-actin
stress fiber disruption and the IP response. Therefore, in addition to its major surface chymotrypsin-like properties, T. denticola expresses cytopathogenic activities that diminish the
generation of IPs during the time course associated with significant
cytoskeletal disruption in fibroblasts.
| |
INTRODUCTION |
Treponemes are usually among the
most prevalent bacteria in the microbiota of periodontal pockets
adjacent to inflamed and progressively deteriorating tissues.
Treponema denticola, which is the most thoroughly
characterized oral spirochete, produces several types of factors that
may contribute to its virulence, including outer sheath-associated
peptidases, chymotrypsin-like and trypsin-like proteinases, hemolytic
and hemagglutinating activity, adhesins that bind to a variety of
matrix proteins and host cells, and an outer sheath protein with
pore-forming activity (6, 8, 13, 19, 20, 21, 27, 28, 29, 30,
45). Within the subgingival periodontal environment, T. denticola and other treponemes are most often concentrated among
motile species at the mucosal interface. They have access for direct
contact with sulcular and junctional epithelium, and they have been
documented to penetrate the gingival connective tissue in acute disease
(26, 34). Thus, the treponemes, their metabolites, and the
constituents of their shedding outer sheath have the opportunity for
direct interactions with cellular membranes of stromal cells as well as
inflammatory cells in the gingival tissues.
We and others have documented cytopathic effects of T. denticola on the cytoskeleton of cultured gingival fibroblasts and epithelial cells (2, 11, 14, 43). Although T. denticola rarely invades intracellularly and is not immediately
cytotoxic, its adhesion to host cells perturbs filamentous actin
(F-actin), causing its rearrangement and the downstream effects of
cellular rounding, membrane blebbing, and subsequent detachment from
the substratum (2, 44). These profound effects on the
cytoskeleton of gingival fibroblasts would be expected to alter their
locomotion and phagocytosis of collagen, which are actin-dependent
functions important for physiological tissue remodelling and
periodontal wound repair. Cytopathic activities of T. denticola are also associated with perturbation of cytoskeletal
functions such as volume regulation, maintenance of cell-cell
junctional integrity, and barrier function of cultured oral epithelial
cells (11, 43). As physiological actin turnover depends on
complex transmembrane and intracellular communication pathways, our
laboratory set out to determine the upstream signalling events crucial
for the cytopathological perturbation of F-actin by T. denticola.
Homeostasis of actin in mammalian cells is known to depend on the local
concentrations of polyphosphoinositides and cytosolic calcium (23,
41). The relationship of Ca2+ transients to
phosphoinositides is linked further in that metabolites of the inositol
phosphate (IP) pathway of phospholipase C-catalyzed phosphatidylinositol-4,5-bisphosphate metabolism, especially
inositol-1,4,5-trisphosphate (IP3), stimulate release of
Ca2+ from intracellular stores (4, 10, 33). Some
pathogenic bacteria which parasitize humans have evolved virulence
factors to exploit these host cell signalling pathways (16,
39). For example, enteroinvasive and diarrheagenic pathogens have
been shown to stimulate increases in intracellular IPs and
Ca2+ concomitant with accumulation of F-actin and
associated cytoskeletal proteins adjacent to their point of adhesion to
the host cell membrane or surrounding bacteria which are internalized
(3, 12, 17, 18, 25, 35, 38). In contrast, contact with the
periodontal pathogen T. denticola apparently leads to a
decrease of F-actin in cultured fibroblasts and epithelial cells, and
neither the adherent bacteria nor the infrequent bacteria which have
been detected in an intracellular position have been found in
conjunction with localized accumulations of specific host cell
cytoskeletal proteins (11, 14, 43). The purpose of this
investigation was to determine the effect of T. denticola on
cellular accumulation of IPs, the calcium-mobilizing arm of the
cytoskeleton-regulating phosphoinositide signalling pathway, in human
gingival fibroblasts (HGF). We have also conducted a more precisely
timed determination of localized F-actin depolymerization than we
reported previously (2), so that changes in IPs and other
second messengers may be related temporally to T. denticola
perturbation of actin.
| |
MATERIALS AND METHODS |
Treponemal cultures and cultural conditions.
Stock cultures
of T. denticola ATCC 35405 (type strain), originally
provided by W. J. Loesche, University of Michigan, and ATCC 35404, ATCC 33520, e, and e', provided by E. C. S. Chan, McGill
University, were maintained and grown for experiments in a complex
spirochete broth medium containing brain heart infusion, tryptic
peptone, yeast extract, and volatile fatty acids and supplemented with
2.0% rabbit serum as previously described (7). Strains ATCC
35405, e, and e' have been shown to induce actin rearrangement and
detachment of cultured HGF from the substratum (2).
Treponema vincentii ATCC 35580 and Treponema
socranskii ATCC 35536 were obtained from the American Type Culture
Collection and maintained similarly. Cells were grown at 37°C and
subcultured weekly in an anaerobic chamber (Coy Laboratory Products,
Ann Arbor, Mich.) in an atmosphere of 80% N2, 10%
CO2, and 10% H2 (Canox, Toronto, Ontario,
Canada). For experiments in which bacterial suspensions were used to
challenge gingival fibroblasts, 3-day, stationary-phase cultures were
harvested by centrifugation at 12,000 × g for 6 min
and washed twice in 0.01 M phosphate-buffered saline at pH 7.2 (PBS)
prior to resuspension in a CO2-independent tissue culture medium.
T. denticola OM preparation.
Spirochete medium
was inoculated with a 3-day culture of T. denticola ATCC
35405 at a ratio of 30:1 (fresh medium to inoculum) and incubated at
37°C for 4 days. Bacteria were harvested by centrifugation at
12,000 × g for 15 min at 4°C and washed twice in
PBS. The pellet was weighed, dispersed uniformly, and resuspended at
1.0 g (wet weight) per 10 ml of PBS containing 10 mM
MgCl2. A modification of the detergent extraction method of
Penn et al. (5, 31) was used for the initial extraction.
Triton X-100 (Surfact-Amps X-100; Pierce, Rockford, Ill.) was added to
a final concentration of 0.2% (vol/vol). The suspension was incubated
with constant mixing at 37°C for 30 min and then repeatedly
centrifuged at 12,000 × g for 6 min until no visible
pellet remained. The clear supernatant was dialyzed (molecular mass
cutoff, 50 kDa; Spectra/Por, Spectrum, Houston, Tex.) against deionized
H2O at 4°C for several days until precipitates formed.
The contents of the dialysis tubing were centrifuged at 25,000 × g for 45 min. The pellet was resuspended in deionized
H2O to the predialysis volume and stored at 
70°C. The
dry weight of a lyophilized aliquot of the outer membrane (OM) extract
was determined so that the actin-perturbing activity of the extract
could be compared with that of whole T. denticola cells on a
dry weight basis. Aliquots were also run by standard sodium dodecyl
sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) using a 12%
acrylamide gel and silver stain to compare the migration of OM
polypeptides qualitatively with migration patterns of polypeptides from
whole cells that had been boiled in SDS for 10 min.
T. denticola cell suspensions and the OM extract were tested
for peptidase activity by using the chromogenic peptides
N-succinyl-L-alanyl-L-alanyl-L-prolyl-L-phenylalanine-p-nitroanilide (SAAPNA) and
N-benzoyl-DL-arginine-p-nitroanilide
(BAPNA; Sigma) (15). Whole T. denticola cells at
the concentration used for the assays described below had the
equivalent SAAPNA-degrading activity of 0.2 µg of chymotrypsin per ml
and BAPNA-degrading activity of 0.04 µg of trypsin per ml. The
undiluted OM extract contained SAAPNA-degrading activity equivalent to
4.0 µg of chymotrypsin per ml and no detectable BAPNA-degrading
activity.
Gingival fibroblast cultures.
HGF cell cultures were
established from primary human tissue explants as described previously
(1). The cells were cultured in alpha minimal essential
medium (
MEM) containing 400 U of penicillin G per ml and 10%
(vol/vol) heat-inactivated fetal bovine serum (FBS; BioWhittaker,
Walkersville, Md.) and maintained at 37°C in a humidified atmosphere
of 95% air and 5% CO2. The fibroblasts were subcultured
weekly and were used for experiments between passages 14 and 25.
Bacterial perturbation of F-actin in HGF.
Two assays were
used in time course experiments to measure the degree of actin
perturbation in HGF challenged by type strain ATCC 35405 whole cell or
OM extract suspensions.
(i) Stress fiber assay.
HGF in confluent monolayers were
trypsinized, washed in PBS, and adjusted to a density of
105 cells/ml in MEM containing penicillin G and FBS. The
cell suspensions were distributed at 1.0 ml/well in 24-well dishes
(Corning Glass Works), each containing one sterilized, circular glass
coverslip (no. 1, 12-mm diameter; Fisher Scientific). The HGF were
incubated at 37°C in a 5% CO2 atmosphere for 3 h to
allow spreading, and they were nonconfluent for the bacterial challenge
experiments. Prior to the addition of bacteria, each well was washed
once with CO2-independent medium (CIM; Gibco). The
treponemes were washed, resuspended in serum-free CIM to a cell density
of 2 × 109 bacteria/ml, and added to the wells
containing the coverslips at 1.0 ml/well in duplicate. Control wells
received CIM without bacteria. The dishes were incubated at 37°C. In
a time course experiment of 140 min, coverslips were selected at 20-min
intervals and the HGF were fixed in 1.0 ml of 3.75% (vol/vol)
formaldehyde in PBS. The coverslips were then washed with PBS, and the
HGF were permeabilized and labeled for F-actin.
The permeabilizing and labeling solution contained rhodamine-phalloidin
(Molecular Probes, Eugene, Oreg.), 0.6 U/ml in 0.1% (vol/vol) Nonidet
P-40 (Sigma) in PBS. Five hundred microliters was added per well, and
the dishes were incubated at room temperature for 30 min. The
coverslips were washed twice in deionized water and mounted on glass
slides with an antifade mounting medium containing 0.1% (wt/vol)
p-phenylenediamine, 10% (vol/vol) 0.01 M PBS (pH 7.4), and
90% (vol/vol) glycerol, adjusted to pH 8.0 with 0.5 M
carbonate-bicarbonate buffer. Single HGF were examined by fluorescence microscopy at a magnification of ×400, using a Leitz Dialux microscope equipped with a Leitz numerical-aperture 1.30, 160/0.17 objective lens,
and epifluorescence with an N2 filter block (excitation filter, 530 to
560 nm; suppression filter, 580 nm) for red fluorescence. Two hundred
HGF on duplicate coverslips were scored dichotomously according to
preset criteria for presenting either a normal or altered stress fiber
pattern, and the outcome was expressed as the percentage of cells with
altered stress fibers. HGF scored as normal had stress fibers that were
abundant in quantity, evenly and brightly fluorescent, long, mostly
straight, and detected in well-spread cells. In contrast, HGF scored as
altered had stress fibers that were reduced in quantity or absent
entirely, fragmented and unevenly fluorescent, and found in cells with
retraction of cytoplasmic processes. The samples were coded to obscure
their identity. Statistical significance between experimental and
control groups at each time point and within-group differences between time points was determined by chi-square analysis.
(ii) Confocal microscopy.
The degree of fluorescence in
optical sections of control and T. denticola ATCC
35405-challenged HGF was measured by confocal microscopy. The HGF were
prepared as for the stress fiber assay. The confocal laser scanning
microscope (Leica Lasertechnik GmbH, Heidelberg, Germany) was set with
an argon ion laser of 488/514-nm emission, BP568 laser filter, RSP
488/568 beam splitter, pinhole setting at 40, and offset at 30.
Fluorescence intensity of rhodamine-phalloidin-labeled F-actin was
recorded in serial 1-µm optical sections in the x-y plane
at a magnification of ×400 from the dorsal to the ventral (substratum)
surface. Thirty cells per group per time point were examined, and
fluorescence intensity per section was recorded. The total fluorescence
intensity in an individual cell was calculated as the sum of
fluorescence in all its optical sections, and the mean fluorescence per
cell was derived for the 30 cells counted per time period per
experimental group. As exposure to T. denticola caused many
of the HGF to undergo progressive changes in shape, including cellular
rounding and increased height, the number of optical sections for
complete coverage of each single cell was determined, and the sections
were categorized into thirds by cell height. The mean fluorescence per
ventral, middle, and dorsal third for the 30 cells per group was
calculated. For statistical analysis, significant differences in mean
fluorescence between experimental groups at each time period and
within-group differences at various time periods were determined by
Student's t test.
A comparison of whole T. denticola cells and OM extract for
actin-perturbing activity was determined in 90-min assays using the
stress fiber assay. The effect of inhibiting the proteolytic activity
of the bacteria and OM extracts was also tested. They were pretreated
with phenylmethylsulfonyl fluoride (PMSF) at 170 µg/ml, which we had
shown previously to inhibit T. denticola's fibronectin-degrading activity and detachment of HGF from the extracellular matrix (15).
IP assay.
IPs generated during the experimental time course
were measured by a modification of the radiotracer assays of
Ruschkowski et al. (38) and Dean and Beaven (9).
HGF in confluent monolayers were harvested by trypsinization and
resuspended in MEM with 10% FBS to a density of 2 × 105 cells/ml. The cell suspensions were dispensed (2.5 ml
in 60- by 15-mm petri dishes [Falcon]) and incubated at 37°C to
allow spreading. After 2 h, each petri dish was washed twice with
warm PBS, and 2.0 ml of MEM containing penicillin G and 1%
(vol/vol) FBS was added. One hundred microliters of 1/10-concentrated
myo-[3H]inositol (1.0 mCi/ml; Amersham,
Arlington Heights, Ill.) in 10% (vol/vol) ethanol was added to each
dish. The dishes were incubated for at least 18 h, the culture
fluids were removed, and the dishes were washed once with warm
serum-free CIM. Two milliliters of CIM containing 1.0% (vol/vol) FBS
and 10 mM LiCl was added, and the dishes were incubated for 15 min at
37°C in air. The LiCl inhibits endogenous phosphatases and thereby
allows the accumulation of 3H-labeled intermediates in the
IP pathway.
Three-day cultures of treponemes were harvested by centrifugation,
washed once in CIM, and resuspended in CIM containing 1.0% (vol/vol)
FBS and 10 mM LiCl to a density of 2 × 109
bacteria/ml. Three milliliters of the bacterial suspension was added to
each culture dish in the experimental groups. Positive control dishes,
for which substantial increases in accumulated 3H-labeled
IP intermediates would be anticipated received 3.0 ml of CIM containing
15% (vol/vol) FBS and LiCl, and the background control dishes received
3.0 ml of CIM containing 1.0% (vol/vol) FBS and LiCl as specified by
Ruschkowski et al. (38). In some experiments ATP, 100 µM
in CIM containing 1.0% FBS, was used as the positive agonist.
Duplicate dishes per treatment group were analyzed for total IPs
immediately and following a 60-min period. The reactions were
terminated by removal of the medium and one wash with ice-cold PBS.
Cells in each dish were harvested into 1.0 ml of ice-cold PBS and
collected into screw-capped polypropylene tubes. Four milliliters
methanol-chloroform (2:1) solution was added to each tube, mixed, and
allowed to react at ambient temperature for at least 30 min. Then a
mixture of 0.125 ml of 0.5 M EDTA (pH 8.0), 1.2 ml of chloroform, and
1.0 ml of deionized H2O was added. The mixtures were
vortexed and then centrifuged at 500 × g for 8 min. The aqueous phase, which contained the water-soluble IPs, was collected
and passed through a Dowex AG 1-X8 anion-exchange resin column (formate
form resin and Poly-Prep chromatography columns; Bio-Rad) followed by a
wash of 5.0 ml of deionized H2O. The IPs were eluted with a
5.0-ml solution containing 0.1 M formic acid and 1.0 M ammonium
formate. A 300-µl aliquot of each sample was added to 5.0 ml of
scintillation fluid (Ecolume; ICN, Costa Mesa, Calif.), and the
radioactivity (counts/minute) was measured in the tritium channel
(RackBeta scintillation counter; LKB-Wallac).
Procedural controls included (i) omission of the LiCl, which would be
expected to reduce the amount of accumulated IPs, and (ii) testing the
effects of 0.05% ethanol, the solvent for the myo-inositol,
in the IP assay. HGF incubated as usual with either 1.0 or 15% FBS and
with 10.0 mM LiCl led to an increase in radiolabeled IPs of 125 and
240%, respectively, over 60 min. In contrast, parallel samples for
which LiCl was deleted yielded negligible radiolabeled IPs at both the
beginning of the assay (10 and 14% of the 1.0% FBS-LiCl and 15%
FBS-LiCl controls, respectively) and at 60 min (6 and 7% of the
controls). These results verified that incubation of HGF with LiCl
indeed allowed the accumulation of radiolabeled inositols. Ethanol at
its assay concentration led to an insignificant change in accumulated
IPs over 60 min.
IP assays were also run with T. denticola cells pretreated
with either PMSF or
N--p-tosyl-L-lysine chloromethyl
ketone (TLCK; Sigma) at 150 µg/ml, as described previously
(2). At least two independent experiments were conducted for
each condition tested.
For IP assays in which OM extract of T. denticola ATCC 35405 was substituted for the whole bacteria, the OM extract was serially diluted 1/4 to 1/16 in CIM containing 1.0% FBS, and 3.0 ml of the
suspension was added to each dish. The effect of pretreatment of the OM
extract with PMSF was also determined.
| |
RESULTS |
Time course for F-actin depolymerization.
Rhodamine-phalloidin
fluorescence intensity was used as a measure of F-actin concentration
in optical sections analyzed by confocal microscopy. The mean
fluorescence per cell was significantly less for T. denticola ATCC 35405-challenged HGF than for control HGF by 60 min
and all subsequent time periods ([2.15 ± 0.24] × 106 [mean ± standard error of mean] for T. denticola and [3.32 ± 0.34] × 106 for control
at 60 min; P < 0.01 [Fig.
1]). To analyze changes in
rhodamine-phalloidin fluorescence in optical sections by confocal microscopy, the HGF were arbitrarily divided into thirds from their
ventral to their dorsal surface. The mean fluorescence intensity, representing the mean concentration of F-actin, was greatest in the
ventral third of the cells (Fig. 1), where the cytoskeleton interfaces
via integral membrane proteins with the extracellular substratum. At
the beginning of the experiment, a mean of 71.6% of the total cellular
fluorescence was attributable to the ventral, 22.7% was attributable
to the middle, and 5.7% was attributable to the dorsal one-third of
optical sections for the T. denticola-challenged HGF (Fig.
1). Over the time course of exposure to T. denticola ATCC
35405, total cellular fluorescence decreased by 52% (P < 0.001), and the greatest proportional change came at the expense of
F-actin in the ventral one-third, where the fluorescence intensity decreased by 34% from the initial level. In contrast, neither the mean
total fluorescence intensity per cell nor the proportional distribution
of fluorescence among grouped optical sections of control HGF changed
significantly during the time course.
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FIG. 1.
Histogram of fluorescence intensity of
rhodamine-phalloidin-labeled F-actin in HGF during a 140-min time
course, analyzed by confocal microscopy. There was significant
depolymerization of F-actin in the T. denticola ATCC
35405-challenged HGF (left graph) in comparison with the control HGF
(right graph). The degree of diminished fluorescence in T. denticola-challenged cells was significant at 60 min
(P < 0.01). Much of the decrease was proportionately
at the expense of F-actin in the ventral third of the cells (black).
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Changes in whole-cell F-actin determined by the frequency of HGF with
altered stress fiber patterns and by fluorescence intensity measured in
optical sections by confocal microscopy were in close agreement. Normal
stress fiber pattern and distribution were increasingly altered with
time in T. denticola ATCC 35405-challenged HGF (Fig. 2). By 140 min, 90% of the HGF were
found to have an altered stress fiber pattern, compared with 35% for
the control HGF. A significant difference between the frequency of
altered stress fibers in the T. denticola-challenged and
control HGF was reached by 60 min (P < 0.001).
Regression analysis was used to determine the correlation between data
sets when changes in actin were determined by calculating the mean
fluorescence per cell detected by confocal microscopy and by
calculating the mean percentage of cells with disrupted stress fibers
by the dichotomous fluorescence microscopy assay at six points in the
time course. The correlation coefficient for the two outcomes (labeled
F-actin per cell versus percentage of cells with abnormal stress
fibers) was 0.89 (P < 0.01).
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FIG. 2.
Histogram illustrating disruption of F-actin in T. denticola-treated HGF expressed as the percentage of HGF with an
altered stress fiber pattern (left graph) compared with the stable
stress fiber pattern in control HGF (right graph). The difference
between T. denticola-challenged and control HGF was
significant at 60 min (P < 0.001). These data were
from the same set of 30 cells analyzed by confocal microscopy in Fig.
1, illustrating the inverse relationship of total F-actin measured by
confocal microscopy and percentage of HGF with altered stress fibers.
Replicate experiments with 200 HGF per group yielded almost identical
distribution of data (not shown).
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The dichotomous stress fiber assay was also used to compare the degree
of cytoskeletal disruption by whole cells and OM extract of T. denticola ATCC 35405. The percentage of HGF with altered stress
fibers increased with increasing concentration of both bacterial cells
and OM extract (Fig. 3). The effect of
the OM extract was greater on a dry weight basis. T. denticola cells were pretreated with proteinase inhibitors PMSF
and TLCK to determine whether cell-associated proteinases could account
for stress fiber disruption. Neither inhibitor reduced the percentage
of HGF with altered stress fibers compared with untreated control and
sham-treated (centrifuged) T. denticola cells (Fig.
4).
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FIG. 3.
Comparison of filamentous actin disruption (mean ± standard deviation) in HGF challenged with different concentrations of
whole cells of T. denticola ATCC 35405 ( ) and OM extract
( ). The dry weight for the OM and the dry weight for the T. denticola cells were equivalent at each optical density (OD) point
shown on the x axis.
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FIG. 4.
Histogram of data (mean ± standard deviation)
examining the effects of proteinase inhibitors on the disruption of
stress fibers by T. denticola. Disruption of filamentous
actin in T. denticola-treated HGF was not affected by
pretreatment with PMSF or TLCK. CIM, HGF challenged with bacterium-free
CIM; Td, HGF challenged with T. denticola ATCC 35405;
Td-Sham, HGF challenged with T. denticola cells incubated in
proteinase inhibitor-free buffer and centrifuged identically to samples
containing PMSF and TLCK, which is the appropriate control for the
inhibitor-containing samples.
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IPs in HGF challenged with T. denticola cells.
The
effect of T. denticola ATCC 35405 cells on IPs recovered in
the extracts of HGF was measured over 60 min relative to the effect of
a background (1.0% FBS) and a strongly positive control (15% FBS).
Any manipulation of LiCl-treated HGF, even just by washing them, caused
an increase in accumulated IPs. Values for IPs recovered from HGF at
the first experimental sample varied, and IPs from HGF incubated with
the 1.0% FBS background control increased with time. Therefore,
following the procedure of Ruschkowski et al. (38), we
adopted the 1.0% FBS control for the standard comparison. Considering
data from independent experiments which included T. denticola-treated, 1.0% FBS standard, and 15% FBS positive
control groups (n = 11), the increase in radiolabeled IP for the 1.0% FBS background control was 212.3% ± 14.4%
(mean ± standard error of mean; range, 107.8 to 287.6%;
P < 0.01 comparing the 60-min sample with the initial
sample). Challenge by T. denticola diminished IP
accumulation as evidenced by the consistently lower and insignificant
percent increase in concentration of radiolabeled IPs in T. denticola-treated HGF in the presence of 1.0% FBS (mean, 143.1% ± 13.9%; range, 64.7 to 210.4%; P > 0.05 comparing
60-min and initial samples) (Tables
1 and 2).
The increase in 3H-labeled IPs for 15% FBS was usually
severalfold greater on each assay occasion (mean, 416.3% ± 49.1%;
range, 245.5 to 837.9%; P < 0.001 comparing 60-min
and initial samples). By 60 min, the mean IP concentrations for the 15 and 1.0% FBS controls were significantly different from one another
(P < 0.01), showing that the IP pathway of the HGF
would indeed respond maximally to a strongly positive agonist. Although
initially similar (P > 0.10), the mean IP
concentration in the T. denticola-treated HGF was
significantly lower than that for both FBS controls by 60 min
(P < 0.02).
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FIG. 5.
Qualitative comparison by SDS-PAGE of T. denticola ATCC 35405 whole cells (lane 1), OM extract run at the
same time (lane 2), and repeat of the OM extract run in a different gel
to resolve mid-range bands more clearly (lane 3). The positions of
molecular size standards (broad-range SDS-PAGE standards; Bio-Rad) are
shown in kilodaltons at the left. Conditions were as follows: Washed
T. denticola suspensions (optical density of 1.2 at 550 nm)
from 3-day cultures or undiluted OM extract were mixed 1:1 with sample
buffer (0.25 M Tris-HCl [pH 6.8], 20% glycerol, 4.6% SDS, 0.02%
bromophenol blue, 10%  -mercaptoethanol) and boiled for 10 min; 25 µl was added to each lane of a 1-mm-thick Ready Gel (Bio-Rad) with a
4% stacking gel and 12% resolving gel. Electrophoresis was run in a
Mini-Protean II cell (Bio-Rad). Whole cells and OM extract had several
bands in common.
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Attempts to determine whether T. denticola could suppress
the great increase in IPs in response to 15% FBS yielded inconsistent results. As a high concentration of serum contains a complex of potentially confounding agonists for stimulating the IP pathway, we
tested the effect of T. denticola ATCC 35405 on the response of HGF to ATP in 1.0% FBS. ATP is known to cause increased IP reactions, and our concurrent study found that T. denticola
OM decreased Ca2+ responses of HGF to exogenous ATP
(24). ATP stimulated a 320% increase in radiolabeled IPs
over 60 min (average of duplicates). When T. denticola and
ATP were added simultaneously, there was a small reduction seen as a
236% increase in the accumulation of IPs (data not shown).
Preincubation of HGF with T. denticola for 30 min prior to
addition of ATP (90-min experiment) led to a 60-min increase in IPs of
163%, compared with 282% for ATP alone (Table 1; average of
quadruplicates), an approximately 40% reduction in IP response.
IPs in HGF challenged with OM extract.
The OM extract prepared
from T. denticola ATCC 35405 contained several polypeptides
comparable in size to those of a boiled extract of the whole bacteria
(Fig. 5). The OM extract yielded a concentration-dependent reduction in
labeled IPs relative to the 1.0% FBS background control (Table 1).
Only at 1/16 dilution was the low level increase in radiolabeled IPs
for the OM extract plus 1.0% FBS comparable to that for the 1.0% FBS
alone. Whole cells of T. denticola ATCC 35405 and the OM
extract were pretreated with PMSF or TLCK prior to the assay to
determine their effects on diminished IP generation. Neither proteinase
inhibitor had an effect on the reduction in the yield of radiolabeled
IPs when HGF were incubated with 1.0% FBS and whole cells of T. denticola ATCC 35405 (Table 1). Likewise, there was little
difference in the relative concentrations of radiolabeled IPs between
HGF exposed to 1.0% FBS and PMSF-pretreated or untreated OM extract
(Table 1).
IPs in HGF challenged with additional strains of T. denticola and other treponemes.
Additional strains of
T. denticola and two strains of other oral treponemes were
tested to determine whether the IP results could be generalized beyond
ATCC 35405. The percent increase in 3H-labeled IPs over the
60-min incubation period was lower for all samples containing either
T. denticola, T. vincentii, or T. socranskii cells and 1.0% FBS than that found for the
bacterium-free 1.0% FBS control (Table 2). At 60 min, the total pool
of radiolabeled IPs was approximately three- to fourfold higher in HGF
treated with the 15% FBS control in these experiments, showing that
different strains of T. denticola are clearly unable to
stimulate the IP pathway and that the diminished IP response is not
limited to this species.
| |
DISCUSSION |
Upon exposure to T. denticola strains, cultured HGF
undergo profound actin rearrangement and perturbation of some related signalling pathways prior to and concomitant with the downstream effects of cell rounding and detachment from the extracellular matrix.
By establishing a time course for stress fiber disruption and
localization of F-actin depolymerization, this investigation provides
the opportunity to relate fluctuations in some second messengers to
actin rearrangement, at least temporally. The use of confocal
microscopy to quantify fluorescence intensity in optical sections of
individual HGF detected a significant decrease in whole cell F-actin
and a temporally related proportional shift in F-actin from the ventral
third to the middle, presumably perinuclear third, of the cells. The
decrease in ventral third actin is consistent with our finding
perturbed stress fibers in nearly all the HGF by the end of the assay
period, and it probably accounts for the strong agreement between the
two assays which we have used to quantify outcomes of actin integrity.
The quantitative method used in a previous study from our laboratory
had actually characterized the actin rearrangement as an initial
increase in total fluorescence (2). By using microscopic
spectrofluorimetry to measure emissions in a fixed area of an HGF
monolayer rather than in optical sections of single cells, the
substantial diminution of fluorescence intensity in the cell periphery
was probably masked by the more intense emissions of bright
fluorescence that condensed around the nuclei of cells in the selected
window (2). In the present study, diminished IP yield, as
reflected in the inability of T. denticola-challenged HGF to
respond even to the level of the background 1.0% FBS-stimulated HGF,
was apparent concomitant with the detection of significant differences
in total F-actin and stress fiber integrity between control and
T. denticola-treated cells. Both actin and IPs were affected
significantly within 60 min of challenge. Thus, some of the inhibitory
effects of T. denticola on the IP response probably preceded
the more downstream rearrangement of cytoskeletal proteins that
normally maintain cellular structure, and they certainly preceded
significant detachment of HGF from the substratum, which we had found
to occur after the first hour (2).
IPs, calcium, and actin assembly.
Phosphoinositides and their
products of catalysis by phospholipase C, the IPs, are significant for
maintaining homeostasis of cortical F-actin near the plasma membrane of
fibroblasts and other mammalian cells (23, 41). A locally
elevated concentration of phosphatidylinositol-4,5-bisphosphate, the
precursor of IP3, is thought to promote the uncapping of
the barbed ends of actin filaments and the release of actin monomers
from actin-sequestering proteins, which would favor F-actin assembly
(41). Exposure of HGF to T. denticola caused
depolymerization of the F-actin network and disruption of stress
fibers. Thus, the concomitant, diminished activity in the IP pathway
that we observed may be a reflection of either (i) bacterial inhibition
of the normal recycling and phosphorylation of polyphosphoinositides,
leading to impaired F-actin polymerization or its actual
depolymerization, (ii) lack of or altered agonists for phospholipase C
receptor activation, or (iii) bacterial inhibition of phospholipase C
activity. Although this investigation did not address these mechanisms, our finding of low IP yields within 1 h and even more rapid
effects on calcium transients (24) suggests that T. denticola OM components act directly at the external surface of
the HGF plasma membrane. Since T. denticola ATCC 35405, ATCC
35404, and ATCC 33520 are known to produce their own phospholipase C
(40), it is evident from our data that their potential
exogenous catalysis of membrane polyphosphoinositides is not realized
under conditions of treponemal challenge in intact HGF.
Cytoskeletal disruption and a weak IP response to T. denticola are activities apparently opposite those reported for
several pathogenic enteric species. Some enteropathogens stimulate
F-actin polymerization as a critical step in signalling their own
uptake into host cells, and others stimulate the accumulation of
F-actin immediately adjacent to the area of intimate adhesion to
membrane receptors on host cells (12, 16, 17, 35). Increases
in both total IPs (18, 38) and specifically IP3
(12) follow exposure of epithelial cells to enteric
pathogens. The method used by us to quantify IPs in comparison to a
1.0% FBS background control was the same as that used to demonstrate
increased IP fluxes associated with host cell invasion by
Salmonella typhimurium (38). Therefore, our
affirmation that T. denticola either suppressed or at least
did not stimulate increases in IP concentrations in the period leading
up to F-actin disruption was not unexpected. Our finding a reduced but
still rather robust IP response in ATP-stimulated HGF that had been
pretreated with T. denticola suggests that T. denticola does not totally block crucial steps in the pathway.
Elevated intracellular calcium ion concentration
[Ca2+]i generally opposes the effects of
polyphosphoinositides on actin assembly by promoting the capping of
actin's barbed ends and activating actin-severing proteins, which
would tend to promote actin depolymerization (23, 41). We
have recently found that T. denticola OM causes an immediate
but short-lived increase in the frequency of spontaneous calcium
oscillations (24), corresponding to a time early in the
period when IP yields are apparently low. This combination of early
effects would be consistent with the concept that a bacterially induced
imbalance in second messengers established a permissive intracellular
environment for the disruption of F-actin in stress fibers and the
generalized decrease in phalloidin-stained F-actin in the cell. The
complete blockade of calcium oscillations, which occurred later in the
time course (24), would be consistent with the rearrangement
of F-actin into a brightly staining perinuclear array. We stress,
however, that the possible relationships between IP concentration,
[Ca2+]i fluctuations, and F-actin location
and integrity are limited to interpretation of temporal, not
mechanistic, data. Moreover, actin assembly is thought to be sensitive
to fluctuations in the concentration of signalling messengers in
discrete microenvironments, and our assays for IPs and
[Ca2+]i analyzed either whole cells or pools
of cells.
The IP and calcium signalling pathways are interrelated. One of the
major activities of IPs is to mobilize calcium from intracellular stores, leading to a transient increase in
[Ca2+]i (10, 33). This
relationship has been cited as an explanation for the significantly
increased [Ca2+]i in host cells exposed to
enteric pathogens (12, 16, 22). In contrast, exposure of HGF
to OM extracts of T. denticola causes depletion of
intracellular calcium, possibly by affecting calcium release-activated
channels, which serve as a source of calcium replenishment for HGF
(24). The OM extract significantly reduced [Ca2+]i transients in response to both
thapsigargin and ATP, two reagents that mobilize calcium from internal
stores (24). In addition to these effects on resting cells,
OM extract greatly reduced membrane stretch-activated
[Ca2+]i transients, which rely in part on
calcium-activated internal calcium release in HGF (1).
Partial characterization of treponemal IP-suppressive
activity.
Several components of the outer sheath of T. denticola have the potential to initiate perturbation of actin.
For example, we have shown that the chymotrypsin-like activity of
T. denticola degrades endogenous fibronectin on the surface
of HGF and that PMSF blocks this activity as well as the downstream
effect of HGF detachment from the substratum (2, 15). This
enzyme also contributes to cytoskeletal rearrangement, disruption of
tight junctions, and loss of barrier function in oral epithelial cells (43). Therefore, there is considerable evidence supporting
the hypothesis that the major outer sheath chymotrypsin-like
proteinase, originally isolated and characterized by Uitto et al.
(42), may be significant for disrupting physiologic
signalling pathways involving the extracellular matrix.
This study of IP responses and our concurrent investigation of calcium
fluctuations in HGF (24) do not support a direct relationship of these second messengers to the chymotrypsin-like activity of treponemes. PMSF inhibited neither stress fiber disruption, the IP pathway effects (this study), nor the inhibition of
mechanosensitive calcium flux by T. denticola
(24). Moreover, OM extract diluted 1/16 failed to diminish
the yield of IPs even though its SAAPNA-degrading activity was higher
than that of T. denticola cells at the concentration which
caused actin perturbation and a diminished IP response. Therefore, it
is unlikely that the diminished IP response in this study was due to
proteolysis of serum-containing agonists or receptors. To the contrary,
these findings suggest that the immediate, direct effects on
intracellular signalling pathways may be triggered by T. denticola outer sheath components independent of the proteolytic activities which contribute to degradation of extracellular matrix and
cellular detachment from the substratum. Despite its inhibition of
plasma membrane fibronectin degradation, PMSF did not diminish the
adhesion of T. denticola cells to the HGF (15).
Perhaps one or several of T. denticola's adhesins which are
distinct from the catalytic site of the chymotrypsin-like proteinase will be found to block the generation of second messengers which regulate actin or other cytoskeletal proteins. For example, the well-studied pathogens in the genus Yersinia express a
functionally conserved, outer membrane and secretory protein (Yop)
cascade which is activated by contact with host cells (32,
37). YopE is a cytotoxin which blocks actin assembly upon
translocation into target cells (36), and other Yops
probably perturb actin by dephosphorylating proteins required for
physiologic signalling (16, 32). Following this analogy, it
is feasible that T. denticola proteins which impact on actin
assembly in HGF include more than the OM proteins which obviously have
direct actin-perturbing activity in our studies. Therefore, future
studies should seek to identify individual T. denticola
surface and secretory proteins which contribute to host cell contact
linked with actin perturbation and to determine the specific mechanisms
by which they affect actin-regulating intracellular messengers,
including IPs.
| |
ACKNOWLEDGMENTS |
This study was supported by grant MT-5619, a maintenance grant
for confocal microscopy, and a dental fellowship to P.F.Y. from the
Medical Research Council of Canada.
We thank C. A. G. McCulloch for generous use of his
laboratory facilities and for valuable discussions.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: University of
Toronto, Faculty of Dentistry, 124 Edward St., Toronto, Ontario, Canada M5G 1G6. Phone: (416) 979-4917, ext. 4456. Fax: (416) 979-4936. E-mail:
rellen{at}dental.utoronto.ca.
Editor: J. R. McGhee
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Infect Immun, February 1998, p. 696-702, Vol. 66, No. 2
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Top
Abstract
Introduction
