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Previous Article | Next Article 
Infection and Immunity, August 2000, p. 4531-4538, Vol. 68, No. 8
0019-9567/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
Differential Modulation and Subsequent Blockade of
Mitogenic Signaling and Cell Cycle Progression by Pasteurella
multocida Toxin
Brenda A.
Wilson,*
Lyaylya R.
Aminova,
Virgilio G.
Ponferrada, and
Mengfei
Ho
Department of Microbiology, University of
Illinois at Urbana-Champaign, Urbana, Illinois 61801
Received 29 February 2000/Returned for modification 19 April
2000/Accepted 30 April 2000
 |
ABSTRACT |
The intracellularly acting protein toxin of Pasteurella
multocida (PMT) causes numerous effects in cells, including
activation of inositol 1,4,5-trisphosphate (IP3) signaling,
Ca2+ mobilization, protein phosphorylation,
morphological changes, and DNA synthesis. The direct
intracellular target of PMT responsible for activation of the
IP3 pathway is the Gq/11
-protein, which stimulates phospholipase C (PLC) 
1. The relationship between PMT-mediated activation of the Gq/11-PLC-IP3
pathway and its ability to promote mitogenesis and cellular
proliferation is not clear. PMT stimulation of p42/p44
mitogen-activated protein kinase occurs upstream via
Gq/11-dependent transactivation of the epidermal growth
factor receptor. We have further characterized the effects of PMT on
the downstream mitogenic response and cell cycle progression in Swiss
3T3 and Vero cells. PMT treatment caused dramatic morphological changes
in both cell lines. In Vero cells, limited multinucleation, nuclear
fragmentation, and disruption of cytokinesis were also observed;
however, a strong mitogenic response occurred only with Swiss 3T3
cells. Significantly, this mitogenic response was not sustained. Cell
cycle analysis revealed that after the initial mitogenic response to
PMT, both cell types subsequently arrested primarily in G1
and became unresponsive to further PMT treatment. In Swiss 3T3 cells,
PMT induced up-regulation of c-Myc; cyclins D1, D2, D3, and E; p21;
PCNA; and the Rb proteins, p107 and p130. In Vero cells, PMT failed to
up-regulate PCNA and cyclins D3 and E. We also found that the initial
PMT-mediated up-regulation of several of these signaling proteins was
not sustained, supporting the subsequent cell cycle arrest. The
consequences of PMT entry thus depend on the differential regulation of
signaling pathways within different cell types.
| |
INTRODUCTION |
The protein toxin from
Pasteurella multocida (PMT) is the primary etiological agent
of progressive atrophic rhinitis (11), and purified PMT
experimentally induces all of the major symptoms of atrophic rhinitis
in animals (2, 23). PMT appears to bind to and enter
mammalian cells via receptor-mediated endocytosis (30, 33),
although the details of this process are still unclear. In fibroblasts
and osteoblasts, PMT acts intracellularly to enhance inositolphospholipid hydrolysis (25, 26), mobilize
intracellular Ca2+ pools (40), increase protein
phosphorylation (41), stimulate cytoskeletal changes such as
stress fiber formation and focal adhesion assembly (5, 21),
and initiate DNA synthesis (33). In contrast to the case for
fibroblast cells, PMT exerts cytotoxic or cytopathic effects on Vero
cells (2, 28), embryonic bovine lung cells (34),
and canine osteosarcoma cells (30).
PMT exerts its effects on these cellular processes by acting on the
free, monomeric subunit of the Gq/11 family of
heterotrimeric G-proteins (46), which stimulates
phospholipase C (PLC) 1 to hydrolyze phosphatidylinositol
4,5-bisphosphate to inositol 1,4,5-trisphosphate (IP3) and
diacylglycerol. Accordingly, the release of these second messengers
stimulates Ca2+ mobilization and activates protein kinase
C-dependent phosphorylation. Recent evidence demonstrated that
PMT-mediated stimulation of the mitogen-activated protein kinase (MAPK)
pathway occurs via Gq/11-dependent transactivation of the
epidermal growth factor receptor (38). G-protein-coupled
receptors have been found to activate mitogenic signaling pathways and
cellular proliferation by a number of diverse mechanisms (3, 13,
14, 18, 36), which are largely dependent upon cell type. Since
PMT mediates its effects via regulation of the Gq/11
protein, the different effects observed for PMT on fibroblastic cells
compared to other cell types might be due to differential modulation of
Gq/11-dependent mitogenic signaling pathways in these cells.
In this study, we have compared PMT-mediated morphological changes,
mitogenic signaling, and cell cycle progression in Swiss 3T3 and Vero
cells under both confluent, quiescent conditions and subconfluent,
proliferative conditions. The effect of recombinant PMT (rPMT) on
cellular proliferation and cell cycle progression was characterized by
cell numbers, DNA synthesis, and flow cytometry analysis. We also
examined the effect of rPMT on the regulation of a number of key
mitogenic signaling and cell cycle markers. Our results indicate that
rPMT differentially modulates cellular responses in different cell
types, resulting in different cellular consequences. In addition, in
contrast to the long-lasting morphological changes, the initial
mitogenic response to rPMT is not sustained, and further treatment with
rPMT does not reinitiate mitogenesis.
| |
MATERIALS AND METHODS |
Materials.
rPMT was cloned, expressed, and purified as
previously described (45). African green monkey kidney
(Vero) cells (CCL-81) and Swiss 3T3 murine fibroblast cells (CCL-92)
were obtained from the American Type Culture Collection.
[3H]-thymidine was obtained from Amersham Life Science.
Fluorescein isothiocyanate (FITC)-conjugated phalloidin,
4,6-diamidino-2-phenylindole (DAPI), Triton X-100, and goat anti-rabbit
immunoglobulin G (IgG)-alkaline phosphatase conjugate (A3687) were
purchased from Sigma. Rabbit polyclonal antibodies to c-Myc (sc-764),
cyclin D2 (sc-754), Rb/p107 (sc-318), and Rb/p130 (sc-317); mouse
monoclonal antibodies to cyclin D1 (sc-8396), cyclin D3 (sc-6283), PCNA
(sc-56), and p21 (sc-6246); goat polyclonal antibodies to cyclin E
(sc-481-G) and -actin (sc-1616); and rabbit anti-goat
IgG-horseradish peroxidase (HRP) conjugate (sc-2033), were obtained
from Santa Cruz Biotechnology. Rabbit polyclonal antibodies to p42/p44
MAPK (9102S), phospho-p42/p44 MAPK (9101S), p38 MAPK (9211S), and
phospho-p38 MAPK (9211S), as well as goat anti-rabbit IgG-HRP
conjugate (7071-1), were obtained from New England Biolabs. Goat
anti-mouse IgG-HRP conjugate (170-6520) and goat anti-rabbit IgG-HRP
conjugate (170-6518) were obtained from Bio-Rad. Tissue culture media,
sera, antibiotics, and PCR primers and reagents were purchased from
Gibco/BRL. All other reagents were of the highest quality commercially available.
Subconfluent cell culture assays.
Vero cells were maintained
at 37°C and 10% carbon dioxide in Dulbecco's minimum essential
medium (DMEM) supplemented with 10% heat-inactivated fetal bovine
serum (FBS) (pH 7.4) and containing 100 U of penicillin G per ml and
100 µg streptomycin per ml. Swiss 3T3 cells were maintained at 37°C
and 10% carbon dioxide in DMEM supplemented with 15% heat-inactivated
calf serum (CS) (pH 7.4) and containing 100 U of penicillin G per ml
and 100 µg of streptomycin per ml. Cells were plated onto 12-well
plates (Falcon) at a density of 4 × 104 cells per
well for Vero cells and at 2 × 104 cells per well for
Swiss 3T3 cells. Prior to application, rPMT was added to the cell
culture medium at a final concentration of 200 ng/ml and the
toxin-containing medium was filter sterilized. Heat-inactivated toxin
was prepared by heating rPMT at 70°C for 45 min and was similarly
added to the medium at the same concentration as the active toxin.
After 18 h, the medium containing no toxin, heat-inactivated
toxin, or toxin was added to the cells. For each time point, cells were
analyzed for cell number and [3H]thymidine incorporation
and were visualized using phase-contrast microscopy for toxin-induced
morphological changes with an Olympus IX-70 inverted microscope. Images
of photomicrographs were obtained using a ScanJet 3C scanner
(Hewlett-Packard) with DeskScan II (Hewlett-Packard) image acquisition
software. The micrographs were produced using Adobe Photoshop 4.0.1 on
a Macintosh G3 computer.
Confluent cell culture assays.
Vero and Swiss 3T3 cells were
maintained as described above. Cells were plated onto 12-well plates
(Falcon) at a density of 4 × 104 cells per well for
Vero cells and at 2 × 104 cells per well for Swiss
3T3 cells. The cell culture medium was changed 1 day after plating.
Vero cells were allowed to reach confluency 5 days after plating, and
then the medium was changed to DMEM-1% FBS (pH 7.4) containing
antibiotics. Swiss 3T3 cells were allowed to reach confluency 5 days
after plating, and then the medium was changed to DMEM-1% CS (pH 7.4)
containing antibiotics. Two days after quiescence with low-serum
medium, medium containing no toxin, heat-inactivated rPMT, or rPMT, was
added to the confluent cultures as described above. The culture medium
was changed daily with DMEM-1% FBS (pH 7.4) containing antibiotics
for the Vero cells and with DMEM-1% CS (pH 7.4) containing
antibiotics for the Swiss 3T3 cells. For each time point, cells were
analyzed for cell number and [3H]thymidine incorporation
and were visualized for toxin-induced morphological changes using an
Olympus IX-70 inverted microscope. Images and graphics were generated
as described above.
Determination of [3H]thymidine incorporation.
In the subconfluent cell culture assays, at each time point, the cells
were exposed to DMEM-Waymouth medium (1:1) (pH 7.4) containing
[3H]thymidine (0.5 µCi/ml). After 2 h of exposure
to this medium at 37°C and 10% CO2, the medium was
removed and the cells were washed twice with phosphate-buffered saline
(PBS), trypsinized, and resuspended in 1 ml of PBS. The resuspended
cells were centrifuged, the PBS was removed, and the cells were
resuspended in 1 ml of cold 5% trichloroacetic acid (TCA) and then
centrifuged to collect the TCA-precipitable material. The TCA was
removed, the cells were washed with 1 ml of cold 100% ethanol, and the
pellets were solubilized in 1 ml of 0.1 M NaOH plus 2%
Na2CO3. The amount of radiolabel incorporation
was determined by adding 4 ml of ScintiVerse (Fisher) scintillation
cocktail to 500 µl of the solubilized cell sample and counting on a
Packard Tri-Carb 2300TR liquid scintillation analyzer. Data were
plotted using Cricket Graph III (Computer Associates).
Determination of cell number.
In both the subconfluent and
confluent cell culture assays, at each time point, the medium was
removed and the cells were washed twice with PBS and trypsinized. The
cells were then resuspended in 1 ml of PBS for subconfluent cells and
in 2 ml of PBS for confluent cells. The resuspended cells were counted
using a hemocytometer. For each experiment, cells in four samples were
counted from each well to obtain the mean for each data point. Data
were plotted as described above.
Fluorescence staining of rPMT-treated Swiss 3T3 and Vero
cells.
Cells were plated at low density (2 × 104
cells/mL for Swiss 3T3 cells or 4 × 104 cells/ml for
Vero cells) on glass chamber slides (Lab-Tek) in 2 ml of DMEM (pH 7.4)
supplemented with antibiotics and 10% FBS for Vero cells or 10% CS
for Swiss 3T3 cells. The cells were incubated at 37°C for 18 to
24 h to allow adherence to the matrix. The medium was changed and
replaced with medium containing no toxin or rPMT at 200 ng/ml, and the
cells were incubated for 2 h at 37°C and 10% CO2.
The cells were washed with PBS, fixed with 3.7% formaldehyde in PBS
for 30 min, washed with PBS, permeabilized with 0.5% Triton X-100 in
PBS, washed with PBS, incubated for 40 min at room temperature with
FITC-conjugated phalloidin (50 µg/ml) (Sigma) and DAPI (2 µg/ml)
(Sigma) in PBS, washed twice with PBS, and mounted in glycerol-PBS (3:1). The cells were visualized by phase-contrast and fluorescence microscopy using an Olympus IX-70 inverted microscope equipped with
U-MWB and U-MWU fluorescence cubes for observing FITC and DAPI,
respectively, and with a digital camera connected to a Power Macintosh
7600 computer. Images were captured with National Institutes of Health
Image 1.61 image acquisition and analysis software. The micrographs
were produced as described above.
Flow cytometry analysis.
Cells in six-well plates were
treated as described above. At the specified times, the cells were
washed with PBS and lysed in either 1 ml (for subconfluent cells) or 2 ml (for confluent cells) of hypotonic staining buffer (0.1% sodium
citrate containing 0.3% Triton X-100, 0.1 mg of propidium iodide per
ml, and 20 µg of RNase A per ml). The samples were kept in the dark
at 4°C for no more than 1 h prior to analysis. The stained
nuclei were analyzed using an EPICS-XL flow cytometer (Coulter). For
each sample, data from at least 10,000 events were collected and
analyzed using ModFit cell cycle analysis and modeling software
(Verity). The data shown are representative of at least three separate experiments.
Preparation of Swiss 3T3 and Vero cell lysates.
Whole-cell
lysates were prepared from cells treated with or without toxin under
the indicated conditions and at the indicated times. Monolayers on
six-well plates were washed with ice-cold PBS containing protease
inhibitors (1 µg each of pepstatin A, leupeptin, and aprotinin per
ml; 1 mM benzamidine, 0.25 mM phenylmethylsulfonyl fluoride; 2 mM
sodium vanadate; 50 mM sodium fluoride; and 2 mM EGTA), and cells were
lysed in 100 µl (for Swiss 3T3 cells) or 400 µl (for Vero cells) of
lysis buffer (62.5 mM Tris-HCl [pH 6.8] containing 2% sodium dodecyl
sulfate, 10% glycerol, 50 mM dithiothreitol, 0.1% bromophenol blue,
and protease inhibitors). The cells were scraped from each well, and
the contents were transferred into 1.5-ml centrifuge tubes. Each tube
was heated at 100°C for 5 min and then immersed in a water bath
sonicator for 5 min. Cellular proteins, approximately 20 µg of total
protein per lane, were resolved via sodium dodecyl
sulfate-polyacrylamide gel electrophoresis, and the protein bands were
transferred to nitrocellulose membranes for detection of protein
expression levels by Western immunoblot analysis using appropriate
primary antibodies, following by the appropriate HRP-conjugated
anti-IgG secondary antibodies. Membranes were treated with
chemiluminescence reagent according to the protocol of the manufacturer
(New England Biolabs). Quantitation of scanned images of X-ray film
exposed to the membranes was performed using National Institutes of
Health Image 1.61, and graphics were generated as described above.
After quantitation of phosphorylation of MAPK proteins using
anti-phospho-p42/p44 MAPK antibodies, the membranes were stripped and
reprobed using anti-p42/p44 MAPK antibodies to confirm equal loading of
MAPK proteins. All immunoblots were also reprobed with anti--actin
antibodies as control for protein loading.
Statistical analysis.
Data for thymidine incorporation and
cell numbers are presented as the means and standard errors from
replicate experiments, where N denotes the number of
experiments performed for each data point and n denotes the
number of replicate wells used. The significance of differences between
control and rPMT-treated cells was analyzed by two-way analysis of
variance with replication using the Microsoft Excel program and is
presented as the P value between two series of measurements.
| |
RESULTS |
Effect of rPMT on confluent, quiescent cells.
We have
previously reported the effects of rPMT on confluent, quiescent
monolayers of Swiss 3T3 and Vero cells (45). In those
studies, we observed that rPMT-treated Swiss 3T3 cells did not form a
monolayer characteristic of untreated fibroblasts and instead
proliferated into a dense monolayer, which eventually formed foci or
dense cell clusters. We also found in those earlier studies that
confluent, quiescent Vero cells treated with rPMT rapidly underwent
drastic morphological changes and developed foci. When we subsequently
examined the effect of rPMT on cell numbers in these two cell lines, we
found that the rPMT-induced increase in cell density of Swiss 3T3
monolayers was accompanied by a two- to threefold increase in cell
number over the course of 6 to 7 days (Fig.
1A). In contrast, the dramatic
morphological changes in Vero cells were not accompanied by changes in
cell numbers (Fig. 1B).
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FIG. 1.
Effects of rPMT on confluent, quiescent Swiss 3T3 and
Vero cells. Time courses of relative cell numbers for confluent Swiss
3T3 cells (N = 3; n = 1, 1, and 1;
P = 0.0005) (A) and Vero cells (N = 2;
n = 1 and 1; P = 0.95) (B) are shown.
Open squares, untreated controls; open circles, cells treated with
rPMT; closed circles, cells treated with heat-inactivated rPMT.
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Effect of rPMT on subconfluent, proliferating cells.
Since
rPMT did not appear to have a significant effect on proliferation in
confluent Vero cells, we next examined whether rPMT might influence the
rate of proliferation in subconfluent cells under normal serum
conditions. Subconfluent, proliferating cultures of Swiss 3T3 and Vero
cells treated with rPMT underwent marked morphological changes within 1 day, as observed by phase-contrast microscopy (Fig.
2, upper panels A, D, G, and J). The
initial stages were characterized by rounding up of individual cells
and cytoplasmic retraction. Once the cells began to reach confluence, the Vero cell monolayer developed foci or patches of dense cell clusters surrounded by enlarged cells (Fig. 2K). This uneven
distribution of the monolayer progressed (Fig. 2L) and eventually
(after 6 to 7 days) resulted in rolling up and detachment of the
monolayer as rolled sheets from the matrix (data not shown). This
phenomenon is consistent with the reported "cytopathic" or
"cytotoxic" effect of PMT on Vero cells (2, 28),
although these detached cells remained viable by trypan blue dye
exclusion assay (data not shown). For earlier time points, detached
cells were included in the cell counts.
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FIG. 2.
Effects of rPMT on subconfluent, proliferating Swiss 3T3
and Vero cells. (Top panels) Representative phase-contrast micrographs
of confluent Swiss 3T3 cells treated without (A to C) or with (D to F)
rPMT for 18 h (A and D), 96 h (B and E), and 144 h (C
and F) and of Vero cells treated without (G to I) or with (J to L) rPMT
for 18 h (G and J), 96 h (H and K), and 144 h (I and L)
under conditions as described in Materials and Methods. (Bottom panels)
Time courses of relative rate of [3H]thymidine
incorporation into DNA for subconfluent Swiss 3T3 cells
(N = 3; n = 2, 2, and 2; and
P = 0.004) (A) and Vero cells (N = 3;
n = 1, 2, and 2; and P = 0.45) (C) and
relative cell numbers for Swiss 3T3 cells (N = 2;
n = 1 and 1; and P = 0.007) (B) and
Vero cells (N = 3; n = 1, 1, and 1; and
P = 0.63) (D). Open squares, untreated controls; open
circles, cells treated with rPMT; closed circles, cells treated with
heat-inactivated rPMT.
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The rPMT-treated Swiss 3T3 cells first reached confluence in an
apparently normal manner and then formed a dense monolayer (Fig. 2E).
The dense monolayer subsequently developed foci and exhibited a
transformed phenotype with loss of adherence of the cells to the matrix
(Fig. 2F), but the monolayer did not detach in sheets from the matrix
as was observed in the case of the Vero cells. Again, the detached
cells remained viable as assayed by trypan blue dye exclusion (data not
shown). For earlier time points, detached cells were included in the
cell counts.
rPMT prolonged DNA synthesis in subconfluent Swiss 3T3 cells and caused
them to reach a higher density at confluence than untreated cells, as
evidenced by the rate of tritiated thymidine incorporation into DNA
(Fig. 2, lower panel A) and cell numbers (Fig. 2, lower panel B).
Interestingly, there was a decrease in both the rate of DNA synthesis
and cell numbers observed at later time points after day 3, indicating
that the initial increased mitogenic and proliferative activity was not
sustained. Similarly, there was a decrease in the rate of tritiated
thymidine incorporation in control and rPMT-treated Vero cells after
day 3 (Fig. 2, lower panel C), but unlike the case for Swiss 3T3 cells,
no significant differences in tritiated thymidine incorporation (Fig.
2, lower panel C) or overall cell numbers (Fig. 2, lower panel D) were observed between rPMT-treated cells and controls. This lack of rPMT-induced mitogenic response in Vero cells is in contrast to the
pronounced morphological effect observed throughout the time course of
the experiment.
Effect of rPMT on cell cytoskeletal organization.
Fluorescence
staining of actin was performed to visualize the effect of rPMT on the
organization of actin microfilaments in subconfluent, proliferating
Swiss 3T3 and Vero cells. In the untreated Swiss 3T3 cells, actin
staining was primarily diffused around the perinuclear region and
throughout the cytoplasm (Fig. 3A). Since
the cells were proliferating, actin fibers were visible to some extent
in many cells, particularly in those that were in the process of
dividing. In rPMT-treated Swiss 3T3 cells, prominent actin fibers were
visible throughout the cytoplasm in most of the cells after 2 h of
exposure (Fig. 3B to D). Strong staining of stress fibers was not
observed to any significant extent at 30 min but began to appear at
1 h and persisted for more than 24 h (not shown). These
findings are consistent with previous reports on PMT-treated Swiss 3T3
cells (21, 33).
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FIG. 3.
Effects of rPMT on actin cytoskeletal organization and
nucleation of Swiss 3T3 and Vero cells. Shown are representative
phase-contrast, FITC-conjugated-phalloidin-stained fluorescence
micrographs and DAPI-stained fluorescence micrographs of Swiss 3T3 and
Vero cells treated with rPMT (200 ng/ml) under subconfluent,
proliferative conditions as described in Materials and Methods. (A to
D) Swiss 3T3 cells; (E to H) Vero cells; (A and E) controls without
rPMT treatment; (B to D and F to H) cells treated with rPMT for 2 h. Within each panel phase-contrast (top), FITC-phalloidin-stained
(middle), and DAPI-stained (bottom) micrographs are shown. Arrows
indicate multinucleation or nuclear fragmentation.
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Vero cells treated with rPMT did not exhibit the prominent stress
fibers as observed in Swiss 3T3 cells, but some cells showed evidence
of disruption of cytoskeletal organization by 2 h of toxin
exposure (Fig. 3E to H). We observed a limited amount of bi- and
multinucleation (Fig. 3F to H), nuclear fragmentation (Fig. 3G), and
disruption of cytokinesis (Fig. 3H, right panel), which has not
previously been reported. These aberrant cells, making up about 10% of
the total at 2 h, were rarely observed after longer treatment with
toxin (not shown). By 18 h none were observed, and instead most
appeared rounded and less adherent to the matrix by that point (Fig.
2J).
Effect of rPMT on cell cycle progression.
To determine if rPMT
could initiate cell cycle progression in Vero cells similar to that
seen with Swiss 3T3 cells, we compared the effects of rPMT on cell
cycle progression in Swiss 3T3 and Vero cells using flow cytometry.
Confluent, quiescent Swiss 3T3 and Vero cells, in the presence of 1%
serum (Figs. 4 and
5) or 5%
serum (data not shown), were found predominantly in the
G0/G1 phase of the cell cycle, with 85 to 90%
in G0/G1 for Swiss 3T3 cells (Fig. 4A and B)
and 90 to 95% for Vero cells (Fig. 5A and B). After 1 day of toxin
exposure, both Swiss and Vero cells were induced by rPMT treatment to
progress through the cell cycle, with 40 to 45% of the cells (Fig. 4C
and 5C, respectively) found in S phase. However, after 3 to 4 days,
most of the cells were again found in G0/G1
(Figs. 4D and 5D), with the percentage returning to near the levels of
controls by day 5. Under subconfluent conditions, there was no
significant difference observed between controls and toxin-treated
cells in the percentage of cells progressing through the cell cycle,
with both treated and untreated Swiss 3T3 and Vero cells eventually
arresting in G0/G1 by day 6 to 7 (data not
shown). These results suggest that while there is a clear mitogenic
response to rPMT in both cells, exposure to rPMT for 1 day does not
allow for sustained cell cycle progression in either of these cell
types, with both cell types subsequently arresting predominantly in
G0/G1.
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FIG. 4.
Effect of rPMT on cell cycle progression in confluent
Swiss 3T3 cells. (Left) Representative DNA histograms from time courses
of untreated (A and B) or rPMT-treated (C and D) confluent Swiss 3T3
cells from day 1 (A and C) and day 4 (B and D). (Right) Summary of the
percentages of control (top) or rPMT-treated (bottom) cells found in
G0/G1, S, and G2/M phases of the
cell cycle during the time course, determined as described in Materials
and Methods.
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FIG. 5.
Effect of rPMT on cell cycle progression in confluent
Vero cells. (Left) Representative DNA histograms from time courses of
untreated (A and B) or rPMT-treated (C and D) confluent Vero cells from
day 1 (A and C) and day 4 (B and D). (Right) Summary of the percentages
of control (top) or rPMT-treated (bottom) cells found in
G0/G1, S, and G2/M phases of the
cell cycle, determined as described in Materials and Methods.
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Effect of rPMT on mitogenic signaling and cell cycle proteins.
To determine at what point in the cell cycle rPMT exerts its effects,
we assessed the effect of rPMT on the expression of a number of cell
cycle markers involved in progression from G0 through
G1 and into S phase. These markers included the MAPKs, the
D and E cyclins, p21, PCNA, c-Myc, and the Rb proteins (p107 and p130).
The levels of these proteins and their phosphorylation states have been
shown to vary as cells progress through the cell cycle (19, 31,
39, 43).
As confluent Swiss 3T3 cells reached quiescence over the course of 3 days, the expression levels of the D and E cyclins, p21, PCNA, c-Myc,
and Rb/p107 declined to undetectable levels (Fig. 6, left panels). During this time, the
phosphorylation of p42/p44 MAPK also decreased, and the Rb/p130 protein
was present in a hypophosphorylated state. These results are consistent
with previous reports for the behavior of these proteins in normal,
quiescent fibroblastic cells. Treatment with rPMT resulted in a
pronounced up-regulation in the expression levels of the cyclins D1,
D2, D3, and E, p21, PCNA, c-Myc, and Rb/p107 and increased protein phosphorylation of p42/p44 MAPK and Rb/p130, which was sustained through day 2. However, by day 3 the protein expression levels of
cyclin D3 were markedly reduced and cyclin D1 levels were undetectable. Expression levels of PCNA, cyclins D2 and E, and Rb/p107, while continuing to remain relatively high, began to decline slightly by day
3. Only c-Myc and p21 protein levels remained high. Phosphorylation levels of p42/p44 MAPK also declined by day 3, but the
hyperphosphorylated state of Rb/p130 continued.
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FIG. 6.
Effect of rPMT on expression profiles of mitogenic
signaling and cell cycle markers. Shown are representative Western
blots of cell lysates from time courses of untreated or rPMT-treated
confluent Swiss 3T3 (left panels) and Vero (right panels) cells,
prepared as described in Materials and Methods. Antibodies against
signaling and cell cycle proteins that were used for immunoblotting are
indicated to the left. Approximately 20 µg of total protein was used
per lane. Antibodies against -actin were used as an internal control
for protein content.
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In Vero cells, a somewhat different expression pattern was observed
(Fig. 6, right panels). No detectable expression of cyclin D1 or E was
observed in confluent, quiescent Vero cells. Cyclins D2 and D3, p21,
PCNA, and c-Myc were all expressed at a low, constitutive level in
these cells. rPMT treatment caused a sustained up-regulation of cyclin
D2, p21, Rb/p107, and particularly c-Myc. rPMT also caused a transient
up-regulation of the expression of cyclin D1 by day 1, which declined
again by day 2. However, unlike the case for cyclin D1, rPMT had no
effect on the expression of cyclin E in confluent Vero cells. When we
compared the expression of cyclin E in subconfluent, proliferating
cells with its expression in confluent, quiescent Vero cells, we found
that cyclin E was expressed only prior to confluence (Fig.
7). Thus, the results suggest that rPMT
treatment was not sufficient to up-regulate cyclin E expression in
confluent Vero cells. rPMT treatment also had no effect on the
expression levels of PCNA. Interestingly, rPMT treatment caused a
down-regulation in cyclin D3 expression to undetectable levels by day
1. Phosphorylation of p42/p44 MAPK was increased by rPMT treatment
during days 1 and 2 but declined again by day 3. Rb/p130, on the other
hand, was hyperphosphorylated in response to rPMT and remained so
through day 3.
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FIG. 7.
Cyclin E expression in Vero cells. Shown is a
representative Western blot indicating cyclin E expression levels in
cell lysates from subconfluent, proliferating (lane 1) and confluent,
quiescent (lane 2) Vero cells, prepared as described in Materials and
Methods. Approximately 20 µg of total protein were used per lane.
Antibodies against -actin were used as an internal control for
protein content.
|
|
Effect of multiple treatments with rPMT on cell cycle
progression.
To determine if rPMT could restimulate the cells to
initiate cell cycle progression, we examined the effect of additional treatment with rPMT on day 5 after the first exposure in confluent Swiss 3T3 cells (Fig. 8) and Vero cells
(Fig. 9). After 5 days under confluent,
low-serum conditions, Swiss 3T3 cells responded dramatically to rPMT
treatment (compare Fig. 8A and B). In contrast, under similar
conditions, Vero cells showed little or no cell cycle progression
(compare Fig. 9A and B), despite pronounced morphological changes. In
both cell lines, treatment with rPMT at day 0 resulted in cell cycle
reentry, with subsequent arrest predominantly at
G0/G1 by day 5 (Fig. 8C and 9C). A second
addition of rPMT had no effect on the percentage of cells in
G0/G1 or S and G2/M phases (Figs.
8D and 9D), indicating that after the first treatment, subsequent
treatments with rPMT failed to stimulate cell cycle progression.
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FIG. 8.
Effect of multiple rPMT treatments on Swiss 3T3 cell
cycle progression. Shown are representative DNA histograms of confluent
Swiss 3T3 cells, indicating the effect of multiple rPMT treatments. (A)
Untreated control cells analyzed on day 5. (B) Cells treated with rPMT
on day 5 and analyzed on day 6. (C) Cells treated with rPMT on day 0 and analyzed on day 5. (D) Cells treated with rPMT on day 0 and again
on day 5 and analyzed on day 6. The percentages of cells found in
G0/G1, S, and G2/M phases of the
cell cycle, determined as described in Materials and Methods, are also
shown.
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|
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FIG. 9.
Effect of multiple rPMT treatments on Vero cell cycle
progression. Shown are representative DNA histograms of confluent Vero
cells, indicating the effect of multiple rPMT treatments. (A) Untreated
control cells analyzed on day 5. (B) Cells treated with rPMT on day 5 and analyzed on day 6. (C) Cells treated with rPMT on day 0 and
analyzed on day 5. (D) Cells treated with rPMT on day 0 and again on
day 5 and analyzed on day 6. The percentages of cells found in
G0/G1, S, and G2/M phases of the
cell cycle, determined as described in Materials and Methods, are also
shown.
|
|
| |
DISCUSSION |
rPMT is known to induce cellular proliferation in confluent,
quiescent fibroblastic cells and markedly increases the total amount of
tritiated thymidine incorporation into DNA over a period of 40 h
(33). rPMT also induces striking changes in the morphology of other cells, including confluent Vero cells and embryonic bovine lung cells, which has been reported as a "cytotoxic" or
"cytopathic" effect (2, 28, 34). rPMT has also been
reported to induce anchorage-independent cell growth of fibroblasts
(16), as evidenced by colony formation in soft agar,
suggesting that rPMT has the ability to promote a transformed
phenotype. Consistent with these reports, we found that confluent,
quiescent Swiss 3T3 cells treated with rPMT formed dense monolayers,
concomitant with an overall two- to threefold increase in cell number
over a period of 4 to 6 days. More convincingly, we found that
subconfluent, proliferating Swiss 3T3 cells treated with rPMT first
formed a confluent monolayer but then underwent drastic morphological
changes, along with enhanced DNA synthesis, increased cell numbers,
rounding up, and decreased adherence. Interestingly, the rPMT-induced
increase in the rate of DNA synthesis, while prolonged over that of
untreated cells, was not sustained and declined after day 3. Likewise,
while the overall cell numbers were doubled over those of untreated
cells, there was no further increase in cell numbers after day 4. Detachment from the cell matrix did not account for this lack of
increase in cell numbers, since detached cells remained viable and were included in the counting.
Consistent with earlier reports on Swiss 3T3 cells (5, 21),
rPMT caused rearrangement of the more diffuse actin cytoskeleton into
numerous, prominent stress fibers, which were significant by 2 h
of toxin exposure. These stress fibers were rarely seen at 30 min but
were first evident by 1 h and persisted for more than 24 h.
We also observed a limited amount (1 to 2%) of bi- and multinucleation
in the Swiss 3T3 cells. This effect has not been previously reported by
others and is most likely due to the proliferative conditions under
which we conducted our experiments, since the other investigators had
used exclusively quiescent cells in their studies (5, 21).
Vero cells underwent dramatic morphological changes in response to rPMT
treatment under confluent, quiescent conditions, as well as under
subconfluent, proliferative conditions. The morphological response to
toxin was much more rapid and pronounced under both conditions for Vero
cells than for Swiss 3T3 cells. We observed no evidence of cytotoxicity
or cell death under our conditions, although the observed morphological
effects are consistent with the "cytotoxic" effects described in
earlier reports of the changes observed for toxin-treated confluent,
quiescent Vero cells (2, 28, 34). However, rPMT had no
apparent effect on mitogenesis or proliferation in Vero cells, as
evidenced by the lack of a significant increase in thymidine
incorporation into DNA or cell numbers, compared to untreated cells.
Cell cycle analysis indicated that a portion of the Vero cells could be
stimulated to enter G1 and S phases with up to 10% of the
cells undergoing multinucleation or DNA fragmentation, but this
response was not sustained, and most cells subsequently arrested in
G1.
Proliferating Vero cells treated with rPMT showed significant
cytoskeletal rearrangement but did not form prominent stress fibers
similar to those of Swiss 3T3 cells. Instead, at early times within 1 to 2 h of toxin exposure, a portion of the cells appeared to be
bi- and multinucleated, while others had evidence of interference with
cytokinesis, as well as nuclear fragmentation. The Vero cells appeared
to have a greater tendency to form bi- or multinuclear and
nuclear-fragmented cells than the Swiss 3T3 cells, with the incidence
being about 10% of the cell population. The aberrant Vero cells became
less evident at later times, probably due to subsequent cell death, and
were no longer present at 18 h; instead, by that time most of the
cells appeared viable but more rounded.
The cellular effects we observed for rPMT are similar to those observed
for two other related toxins, the cytotoxic necrotizing factors (CNF1
and CNF2) of Escherichia coli (6, 27) and the dermonecrotic toxin (DNT) of Bordetella species (32,
44). Although there is no significant sequence similarity between
PMT and DNT, PMT does share about 30% homology in the N-terminal 500 amino acids with the CNFs (6, 24, 27), and there is a
100-amino-acid region of significant homology between the CNFs and DNT
near their C termini (44). All of these toxins have a
mitogenic effect (increased DNA synthesis) on quiescent cells. rPMT has
both a mitogenic effect and a proliferative effect (reference 33 and this study), whereas DNT and the CNFs cause primarily bi- and multinucleation (17, 22, 27, 32). We have now shown that rPMT is also capable of eliciting bi- and multinucleation in cells that
are proliferating (up to ~10%), albeit to a lesser extent than DNT
and the CNFs, which can induce multinucleation in up to 90% of the
cells by 2 to 3 days (7, 35).
Like PMT, DNT and the CNFs also induce actin stress fiber formation
(8, 17, 22). The known target proteins modified by DNT and
the CNFs are the Rho GTPases (9, 10, 17, 35), which are
involved in regulating the actin cytoskeleton, the assembly of actin
stress fibers and focal adhesions, cell motility, and cytokinesis.
Whether PMT is also able to directly modify the Rho proteins is
unclear, but we have not been able to demonstrate a similar
rPMT-mediated deamidase modification of Rho as that reported for DNT
and the CNFs (B. A. Wilson and Q. Yin, unpublished results). On
the other hand, we have shown that the primary intracellular target of
rPMT that activates the PLC-IP3 pathway is the
Gq protein (38, 46). Unlike PMT, DNT and the
CNFs do not activate the IP3 pathway in Swiss 3T3 cells
(22). This suggests that DNT and the CNFs do not act on the
Gq protein or PLC and that the mechanism by which PMT
mediates mitogenesis and cytoskeletal rearrangement in cells is
different from that of the other toxins.
Our results suggest that rPMT has a greater effect on the cytoskeletal
organization in Vero cells than in Swiss 3T3 cells but has a greater
initial effect on DNA synthesis in Swiss 3T3 cells than in Vero cells.
Cell cycle analysis indicated that PMT treatment induced both cell
types to reinitiate cell cycle progression, albeit to a lesser extent
in Vero cells. However, both cell types subsequently returned to and
remained in the G0/G1 phase thereafter, despite
additional treatment with rPMT. In fact, rPMT was able to stimulate
cell cycle progression only in Vero cells that were not yet confluent;
once they reached full confluence, rPMT had no further influence on
mitogenesis or cell cycle progression. This transient mitogenic
response, which is followed by cell cycle arrest, is in contrast to
previous reports, which suggested that rPMT treatment caused a
sustained and irreversible mitogenic response in fibroblasts (16,
33). Our results instead suggest that the initial mitogenic
response to rPMT was not sustained and that cells thereafter arrest and
become unresponsive to further treatment with rPMT.
Since the method employed for cell cycle analysis did not allow us to
discriminate between the G0 and G1 phase, we
wanted to determine whether cells had indeed progressed through the
cell cycle at early times after treatment (days 1 to 2) and then had arrested in G0 or G1. We also wanted to
determine at what point in the cell cycle PMT was exerting its effects
and what might be the difference between Swiss 3T3 and Vero cells that
could account for the observed differences. To achieve this, we
assessed the effect of rPMT on the expression of a number of cell cycle markers. Specifically, we focused on events associated with the transition from G0 to G1; through early-, mid-,
and late-G1 phases; and into early S phase of the cell
cycle. The key proteins that regulate cell cycle progression through
these early phases include the MAPKs, the D and E cyclins, p21, PCNA,
c-Myc, and the Rb proteins (p110, p107, and p130) (19, 31, 39,
43).
Dephosphorylated Rb proteins sequester E2F transcription factors that
are required for progression into and through S phase (19).
Rb proteins are hypophosphorylated in G0 and are
progressively phosphorylated as cells progress through G1,
finally reaching a hyperphosphorylated state at the G1/S
border (39, 43). Hypophosphorylated Rb/p130 maintains cells
in G0, and its phosphorylation, in particular, plays an
important role in allowing the transition from G0 to early
G1 (4, 15, 43). The observed
hyperphosphorylation of p130 by rPMT indicated that rPMT induced cells
to exit G0 and enter the G1 phase of the cell
cycle, and the continued presence of hyperphosphorylated p130 suggested
that cells did not later exit the cell cycle into G0.
Members of the cyclin D family form complexes with Cdk4/6 or Cdk2,
PCNA, and p21, which then causes Rb inactivation via phosphorylation and release of E2F proteins (43). Normally, expression of
cyclins D1 and D2, as well as p21 and PCNA, begins early in
G1 near the G0-to-G1 transition
(29, 31, 39). Cyclins D3 and E are synthesized later in
G1 (4, 15, 31), with maximal accumulation of
cyclin E occurring with cell entry into S phase. Both p21 and PCNA play critical roles in regulating transition through early to
mid-G1. Low levels of p21 promote Rb phosphorylation,
whereas subsequent high levels of p21 inhibit Rb phosphorylation. The
release of E2F drives cell cycle progression by inducing expression of
enzymes required for DNA synthesis, cyclin E, and c-Myc, which are
required for driving cells through G1 and into S phase
(37, 39).
rPMT treatment clearly up-regulated the expression of each of the D and
E cyclins in Swiss 3T3 cells, confirming that rPMT induces cell cycle
reentry from G0 into G1 and progression through G1 and into S. Coupled with the concomitant increase in
p21, PCNA, p107, and c-Myc levels, and p130 hyperphosphorylation, along
with the flow cytometry results, this strongly supports an initial rPMT-induced mitogenic response. Thus, rPMT-treated Swiss 3T3 cells
were stimulated enough to progress through the cell cycle for at least
one or two complete rounds, accounting for the two- to threefold
increase in cell numbers. However, the subsequent decline in cyclin,
PCNA, and p107 levels and the return to control percentages of cells in
G1, S, and G2/M indicate that this initial response is not sustained and that thereafter, the cells again arrested
in G1 and became unresponsive to further rPMT treatment. Based on the expression profiles, rPMT-treated cells appear to arrest
primarily in mid- to late G1, since cyclin D2 and E and hyperphosphorylated Rb/p130 levels continued to remain relatively high.
In contrast to the case for Swiss 3T3 cells, there was a low, basal
level of PCNA and c-Myc expression in confluent Vero cells but no
expression of cyclin E. rPMT up-regulated cyclin D1 and D2, p21, p107,
and particularly c-Myc protein levels but did not up-regulate the
expression of PCNA or cyclins D3 and E. PCNA was initially identified
as a marker for proliferating cells in S phase (1, 20).
However, PCNA has been shown more recently to be a critical component
of cyclin D2 and D3 complexes with Cdks that regulate cell transition
through early to mid-G1 phase (39, 42). PCNA
expression normally begins to increase during early to
mid-G1 phase and continues to increase in amount throughout the cell cycle, remaining high in proliferating cells (12,
42). Failure to produce adequate quantities of PCNA would result
in a cell cycle block in mid- or late G1 phase. In
addition, rPMT's failure to up-regulate cyclins D3 and E in Vero
cells, both of which are critical for driving cells from G1
into S phase (4, 15, 31), would likewise result in a cell
cycle block in late G1, despite relatively high levels of
c-Myc and hyperphosphorylated p130. Such a cell cycle arrest is
consistent with our observations for Vero cells, where despite a
pronounced morphological response, we observed no significant increase
in cell number or continued cell cycle progression.
Study of the mechanism of action of bacterial toxins has significantly
contributed to our understanding of how these protein toxins mediate
their pathogenic effects on host cells and has provided a wealth of
information about the roles of heterotrimeric G proteins in cellular
signaling. Our data suggest that rPMT utilizes Gq/11
proteins to differentially modulate mitogenic and cytoskeletal signaling pathways in host cells. The mitogenic response in fibroblast cells is thought to be a downstream event of Gq/11
activation by rPMT (26, 38, 46). Recent evidence suggests
that stimulation of the p42/p44 MAPK pathway by rPMT occurs upstream
via Gq/11-dependent transactivation of the epidermal growth
factor receptor, which is not protein kinase C dependent
(38). We have now shown that the rPMT-mediated mitogenic
response is dependent on the differential regulation of downstream
signaling proteins involved in cell cycle progression. This finding
points to an important pathogenic consequence of toxins during
bacterial infection, i.e., the potential for differential cellular
outcome due to their action on different target cells.
We have also shown that the initial rPMT-mediated mitogenic response is
not sustained. After 2 to 3 days, cells arrest in mid- to late
G1 phase of the cell cycle and become insensitive to
further treatment with rPMT. This finding is in keeping with our
earlier observations that rPMT only transiently activates the
Gq/11 protein (46), which is then followed by
irreversible inactivation and uncoupling of the signaling pathway. This
finding further suggests that the initial enhanced modulation of
mitogenic signaling pathways by rPMT-mediated activation of
Gq/11-protein is followed by a subsequent, irreversible
shutdown of the pathway that is no longer responsive to further
stimulation by rPMT.
| |
ACKNOWLEDGMENTS |
This work was supported by grants NIH/NIAID AI38396 and USDA/NRI
1999-02295 (to B.A.W.).
We thank Barbara Hull and Nancy Bigley for helpful discussions, Gary
Durack for assistance with cell cycle analysis, and Brian Ho for
assistance with photomicrographic imaging.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Microbiology, University of Illinois at Urbana-Champaign, Urbana, IL 61801. Phone: (217) 244-9631. Fax: (217) 244-6697. E-mail:
bawilson{at}life.uiuc.edu.
Editor:
J. T. Barbieri
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Infection and Immunity, August 2000, p. 4531-4538, Vol. 68, No. 8
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Copyright © 2000, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
