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Infection and Immunity, November 2001, p. 6785-6795, Vol. 69, No. 11
0019-9567/01/$04.00+0 DOI: 10.1128/IAI.69.11.6785-6795.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
Type III Secretion-Dependent Cell Cycle Block Caused in HeLa
Cells by Enteropathogenic Escherichia coli
O103
Jean-Philippe
Nougayrède,*
Michèle
Boury,
Christian
Tasca,
Olivier
Marchès,
Alain
Milon,
Eric
Oswald, and
Jean
De
Rycke
UMR 960 de Microbiologie Moléculaire,
Institut National de la Recherche Agronomique-Ecole Nationale
Vétérinaire de Toulouse, 31076 Toulouse Cedex, France
Received 21 February 2001/Returned for modification 30 May
2001/Accepted 3 August 2001
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ABSTRACT |
Rabbit enteropathogenic Escherichia coli (EPEC) O103
induces in HeLa cells an irreversible cytopathic effect characterized by the recruitment of focal adhesions, formation of stress fibers, and
inhibition of cell proliferation. We have characterized the modalities
of the proliferation arrest and investigated its underlying mechanisms.
We found that HeLa cells that were exposed to the rabbit EPEC O103
strain E22 progressively accumulated at 4C DNA content and did
not enter mitosis. A significant proportion of the cells were able to
reinitiate DNA synthesis without division, leading to 8C DNA content.
This cell cycle inhibition by E22 was abrogated in mutants lacking
EspA, -B, and -D and was restored by transcomplementation. In
contrast, intimin and Tir mutants retained the antiproliferative
effect. The cell cycle arrest was not a direct consequence of the
formation of stress fibers, since their disruption by toxins during
exposure to E22 did not reverse the cell cycle inhibition. Likewise,
the cell cycle arrest was not dependent on the early tyrosine
dephosphorylation events triggered by E22 in the cells. Two key partner
effectors controlling entry into mitosis were also investigated: cyclin
B1 and the associated cyclin-dependent kinase 1 (Cdk1). Whereas cyclin
B1 was not detectably affected in E22-exposed cells, Cdk1 was
maintained in a tyrosine-phosphorylated inactive state and lost its
affinity for p13suc1-agarose beads. This
shows that Cdk1 is implicated in the G2/M arrest caused by
EPEC strain E22.
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INTRODUCTION |
Enteropathogenic Escherichia
coli (EPEC) constitutes a major cause of severe diarrheal disease
in infants of the developing world (33). EPEC bacteria
colonize the intestinal mucosa and produce specific
attaching-and-effacing (A/E) lesions on gut enterocytes, characterized
by intimate bacterial adhesion, formation of gross cytoskeletal
structures beneath intimately attached bacteria, and destruction of the
brush border microvilli (32). The intimate adhesion is
considered to play a central role in EPEC-mediated disease, but the
mechanisms by which EPEC causes diarrhea remains poorly characterized.
In the human reference EPEC strain E2348/69, the determinants of A/E
lesions are encoded within a 35-kb chromosomal pathogenicity island,
the locus of enterocyte effacement (LEE) (30). Similar pathogenicity islands are present in rabbit EPEC O103, in rabbit EPEC
O15 strain RDEC-1, in enterohemorrhagic E. coli, and in
other A/E pathogens (10, 14). The LEE encodes a type III
secretion system homologous to those found in other pathogens,
dedicated to the secretion and translocation of
pathogenicity-associated proteins (20, 28). At least five
proteins are secreted via this type III machinery, namely, EspA, -B,
-D, and -F and Tir (21-23, 27, 31). EspA forms appendages
that link the bacteria to target cells to allow the translocation of
EspB and Tir into host cells (23, 25, 49). Recent
experimental data suggest that EspB and EspD might be inserted in the
target cell membrane to function as translocators for effector proteins
(26, 46, 48, 49). In addition, EspB is found in the
cytoplasm of exposed cells, and when transiently expressed in cultured
cells it promotes actin rearrangements (44, 49). Once
inserted in the target cell membrane, Tir serves as a receptor for an
EPEC outer membrane protein, intimin (23, 40). This
interaction leads to the local rearrangement of the cytoskeleton
together with intimate adhesion of the bacterium on the host cell.
In addition to intimate adhesion, EPEC bacteria also modulate signaling
pathways within cultured cells. EPEC bacteria activate protein kinase C
and alter the phosphorylation state of several host proteins
(14). Tyrosine dephosphorylation of several unidentified host proteins was correlated with the inhibition of phagocytosis by
cultured macrophage cells (24, 15). Tyrosine
phosphorylation of phospholipase C-
1 and induction of inositol
triphosphate and Ca2+ fluxes have been described,
but increased intracellular Ca2+ is not required
for A/E lesion formation (14, 24). EPEC increases paracellular permeability and stimulates ion secretion (7, 41). The integration of the A/E lesion and host cell responses in the induction of diarrhea is not fully elucidated.
We have previously shown that rabbit EPEC O103, the rabbit EPEC O15
strain RDEC-1, and certain human clinical EPEC isolates, but not the
human reference EPEC strain E2348/69, trigger in HeLa cells an
irreversible cytopathic effect (CPE). The CPE is characterized by the
progressive recruitment of focal adhesions and assembly of stress
fibers (10, 35). The cytoskeletal alterations are associated with an arrest of cell proliferation, as assessed by the
inhibition of protein synthesis (10). The CPE is not
reproducible by using supernatants or concentrated sonicates of
CPE-positive EPEC strains, nor is it attributable to cytotoxic
necrotizing factor, a toxin known to also cause the irreversible
formation of actin stress fibers (10, 36). The triggering
of the cytoskeletal alterations depends on a functional EPEC type III
secretion machinery and requires EspA, -B, and -D but not Tir or
intimin (10, 29, 35). No single espA,
espB, or espD gene encodes the specific information needed to trigger the cytoskeletal rearrangements, since
each espA, espB, or espD mutant is
fully complemented by the corresponding esp gene cloned from
CPE-negative E2348/69 (35).
In the present study, we have investigated in more detail the arrest of
cell proliferation that is associated with the cytoskeletal rearrangements. We found that cells exposed to rabbit EPEC strain E22
irreversibly accumulated at 4C and 8C DNA content without entering
mitosis. This effect was not functionally related to cytoskeletal
rearrangement but was linked to the maintenance of the cyclin-dependent
kinase Cdk1, a key effector driving entry into mitosis, in a
premitotic, tyrosine-phosphorylated state.
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MATERIALS AND METHODS |
Bacteria and HeLa cell cultures.
EPEC strains and their
mutants are listed in Table 1. The E22
espA, espB, espD, tir, and eae mutants were shown
to be nonpolar and are described elsewhere (29, 35).
Before interaction with cell cultures, bacteria were grown at 37°C in
Penassay broth (Difco) supplemented with appropriate antibiotics. HeLa
cells (ATCC CCL2) were cultivated in Eagle's minimum essential medium
(MEM) supplemented with 10% fetal calf serum (FCS) (Gibco),
L-glutamine (200 mM), and gentamicin (40 µg/ml)
at 37°C in a 5% CO2 atmosphere.
Synchronization of HeLa cells at the G1/S border
was carried out with nonconfluent cell cultures
(106 cells in a 10-cm-diameter culture dish) by
the double thymidine block method, and synchronization in prometaphase
was achieved using nocodazole (100 nM for 16 h) (8).
Type 1 cytolethal distending toxin (CDT-I) was prepared and added to
the cells as described previously (8, 11). Labeling the
cells with 5-bromo-2'-deoxyuridine (BrdU) (5 µg/ml; Boehringer) was
achieved for 30 min or 6 h.
Interaction between HeLa cells and bacteria.
This assay was
described previously (10). Briefly, interactions were
carried out in MEM buffered with 25 mM HEPES supplemented with 5% FCS
and 1% mannose, with a starting inoculum of 103
bacteria per cell. At the end of the 4-h interaction period, the cells
were washed four to six times with Earle balanced saline solution and
fixed, or they were further incubated in MEM with 10% FCS and 200 µg
of gentamicin/ml for 24, 48, or 72 h.
For stress fiber inhibition experiments, cells were preincubated for
2 h in the interaction medium in the presence of 1 µg
of
purified epidermal cell differentiation inhibitor (EDIN) (kindly
provided by M. Sugai [43])/ml or a 1:100 dilution of a filtered
sonic
lysate of BL21(pDC3B) (a gift from P. Boquet) containing
the DC3B
chimeric toxin (
3). Bacteria were then added and left
in
contact with cells for 4 h as described above. Control cells
were
pretreated with a lysate of BL21 without the
plasmid.
For tyrosine phosphatase inhibition experiments, we used phenylarsine
oxide (PAO) (1 µM; Calbiochem) or pervanadate (PV).
PV was freshly
made by mixing hydrogen peroxide (1 µl of 30% stock)
with 25 µl of
500 mM sodium vanadate
(Na
3VO
4) (Sigma) in 424 µl
of phosphate-buffered saline (pH 7.4). The remaining hydrogen
peroxide was removed by treatment with catalase (100 µg/ml) (Sigma).
PV was added to the cells at a 1:1,000 dilution after 2 h of EPEC
infection. Control cells were pretreated with the solution lacking
sodium
vanadate.
The trypan blue uptake assay was performed as already described
(
9). The lactate dehydrogenase (LDH) release assay was
performed on HeLa cells in 96-well plates. After the interaction,
the
supernatant was collected and the LDH was quantified with
the
cytotoxicity kit from Roche Molecular Biochemicals, according
to the
manufacturer's
recommendations.
Fluorescence microscopy.
Microtubules were stained with rat
anti-
-tubulin (clone YL1/2; Sera-lab) and fluorescein isothiocyanate
(FITC)-conjugated rabbit anti-rat immunoglobulin G (IgG) antibodies
(Vector) as already described (8). DNA was stained with
diaminophenylindole (0.1 µg/ml; Molecular Probes). F-actin was
labeled with rhodamine-phalloidin according to the manufacturer's
instructions (Molecular Probes). Focal adhesions were demonstrated by
labeling vinculin with anti-vinculin mouse monoclonal antibodies (clone
VIN-11-5; Sigma) and FITC-conjugated anti-mouse IgG goat antiserum
(Immunotech) as previously described (10). Slides were
examined by fluorescence microscopy with a Leica microscope.
Flow cytometry analysis.
The flow cytometry analysis of DNA
and cyclin B1 content of HeLa cells was performed as described
previously (8). Briefly, cells were trypsinized, fixed in
70% ethanol, permeabilized with 0.25% Triton X-100, and incubated
with anti-cyclin B1 mouse monoclonal antibodies (clone GNS1;
Pharmingen) followed by FITC-conjugated goat anti-mouse IgG (Sigma).
Control experiments were achieved using an irrelevant isotypic mouse
IgG (Immunotech). In the final step, cells were suspended in a DNA
staining solution containing propidium iodide (10 µg/ml; Sigma) and
RNase (1 mg/ml; Sigma) in phosphate-buffered saline.
Incorporated BrdU was labeled according to a procedure previously
described (
12), including a thermal denaturation of DNA
at
100°C followed by indirect immunofluorescence using anti-BrdU
mouse
monoclonal antibodies (clone 3D4; Pharmingen) and FITC-conjugated
goat
anti-mouse IgG (Sigma). DNA staining was then performed as
described
above.
Flow cytometry analyses were performed on a FACScalibur flow cytometer
(Becton Dickinson), using the red (630 nm) emission
for DNA
quantification and green (530 nm) for BrdU and cyclin
B1
quantification. The data from at least 10
4 cells
were collected and analyzed using CellQuest and ModFit
softwares
(Becton Dickinson). Cell aggregates were identified
and removed from
analysis by
gating.
Western blotting analysis of phosphotyrosine proteins.
HeLa
cells lysis and immunoprecipitation of phosphotyrosine proteins were
carried out using Triton X-100 as described elsewhere (24). Protein samples were resolved by sodium dodecyl
sulfate-7% polyacrylamide gel electrophoresis (SDS-7% PAGE)
and blotted onto Immobilon-P membranes, and tyrosine-phosphorylated
proteins were revealed with antiphosphotyrosine monoclonal antibodies
(clone 4G10; Upstate Biotechnology) followed by secondary goat
anti-mouse IgG (Fab-specific)-peroxidase conjugate (Sigma) and then
developed with the ECL chemiluminescence detection system (Amersham).
Demonstration of Cdk1 in E22-exposed cells.
HeLa cells
(5 × 105) were lysed in 100 µl of Laemmli
buffer, and the samples (40 µg of proteins, from about
105 cells) were resolved by SDS-12% PAGE. Cdk1
was demonstrated by direct Western blotting using the PhosphoPlus
cdc2(Tyr15) antibody kit (New England Biolabs) following the
recommendations of the manufacturer. In other experiments, Cdk1 (Cdc2)
was affinity purified using yeast p13suc1 and
revealed as previously described (8, 45). Briefly, 2 × 106 cells were lysed in 300 µl of modified
RIPA buffer, and Cdk1 was purified from 200 µg of total proteins by
affinity to yeast recombinant p13suc1 -agarose
(Upstate Biotechnology). Samples were resolved by SDS-12% PAGE and
blotted onto Immobilon-P. The three isoforms of Cdk1 were demonstrated
with rabbit anti-Cdk1 antibodies (Gibco) followed by secondary goat
anti-rabbit IgG-peroxidase conjugate (Biosys). After stripping, the
slow-migrating tyrosine-phosphorylated isoform of Cdk1 was revealed
with 4G10 monoclonal antibodies as before.
Raw data of the blots were scanned with an Astra 1220S scanner (Umax),
and the protein amount in each revealed band was estimated
by
densitometry, using National Institutes of Health image software
(available at
http://rsb.info.nih.gov/nih-image/).
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RESULTS |
EPEC strain E22 triggers an irreversible inhibition of
mitosis
HeLa cells exposed to E22 for 4 h
were irreversibly impaired in their proliferation, as assessed by cell
counting (Fig. 1A). In contrast, cells
exposed to E2348/69 were inhibited for about 24 h, after which
their growth rate was similar to that of control cells (Fig. 1A).
Morphologically, cells exposed to E22 progressively swelled and
flattened, whereas cells exposed to E2348/69 behaved like control cells
(data not shown), in agreement with previous observations
(10).
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FIG. 1.
Demonstration of the irreversible arrest in HeLa cell
proliferation (A) and cell cycle perturbation (B) triggered by E22.
Cells were exposed for 4 h to E2348/69 or E22 or left uninfected,
and they were further cultivated for the indicated times. (A) Cell
proliferation after interaction. Cultures were fixed and stained with
Giemsa, and cells within random microscope fields were counted
(objective, ×20). Each point is the mean of four independent measures.
(B) Cell distribution according to DNA content, analyzed by flow
cytometry after staining of DNA with propidium iodide. The percentages
of cell populations are shown in each case.
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This irreversible arrest in cell proliferation indicated that the cell
cycle could be altered in a specific manner in E22-exposed
cells. We
thus analyzed the DNA content of cells exposed to E22
or E2348/69 by
flow cytometry. The cell cycle distribution of
cells exposed to
E2348/69 was similar to that of control cells
24 h (Fig.
1B) or 48 to 72 h after the interaction (not shown).
In contrast, cells
exposed to E22 progressively accumulated in
G
2/M
(4C DNA content), while the number of cells in
G
0/G
1 (2C
DNA content)
declined (Fig.
1B). In addition, a third peak at
8C DNA units was
visible 72 h after the infection with E22 (Fig.
1B).
The foregoing results strongly suggested that the cells exposed to E22
were prevented from entering mitosis. In order to substantiate
this
result, DNA and
-tubulin were stained in E2348/69- or E22-exposed
cells 24 h after the interaction. As shown by fluorescence
microscopy,
no figure of chromatin condensation (characteristic of
prophase)
or reorganization of microtubules into mitotic spindle was
observed
in E22-exposed cells (Fig.
2).
These cells appeared mononucleated,
and their nuclei were swollen (Fig.
2). In contrast, cells exposed
to E2348/69 were actively dividing,
showing typical mitotic spindle
and figures of chromatin condensation
(Fig.
2). For both E22-
and E2348/69-exposed cells, these observations
were confirmed
48 and 72 h after the interaction (not shown).
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FIG. 2.
Absence of mitotic figures in E22-exposed cells. Cells
were exposed for 4 h to E2348/69 or E22 and further cultivated for
24 h. DNA was stained with diaminophenylindole, and -tubulin
was labeled by FITC indirect immunofluorescence. The same fields were
photographed with a ×100 objective. Note the
increased nuclear size in E22-exposed cells, compared to
E2348/69-exposed cells, where figures of mitosis are visible
(arrows).
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E22-induced mitosis inhibition is EspA, -B, and -D dependent but
Tir and intimin independent.
Our previous works indicate that the
cytoskeletal rearrangement triggered by E22 in HeLa cells requires
EspA, -B, and -D but not intimin and Tir (29, 35). We
tested whether the antiproliferative effect of E22 follows the same
pattern. The DNA content of HeLa cells exposed to E22 mutant strains
was analyzed by flow cytometry 72 h after the interaction. Cells
exposed to either E22
Eae or E22Tir accumulated at 4C and 8C
DNA content, whereas cells exposed to the nonpolar E22EspA,
E22EspB, or E22EspD mutant displayed a cell cycle distribution
profile similar to that of uninfected control cells (Fig.
3). Cells exposed to each E22
esp mutant strain bearing in trans the
corresponding esp gene cloned from E2348/69 accumulated at
4C and 8C DNA content (Fig. 3). In conclusion, the mitosis inhibition
triggered by E22 was a process dependent on espA,
espB, and espD but independent of eae and
tir.
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FIG. 3.
Cell cycle patterns of HeLa cells 72 h after
interaction with E22 mutant strains. The cell cycle arrest
triggered by E22 required EspA, -B, and -D but neither
intimin nor Tir. Each esp mutant was fully complemented
by the corresponding esp gene cloned from E2348/69.
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Dissociation of mitosis inhibition from cytoskeletal
rearrangement.
As shown above, the cytoskeletal rearrangement and
the antiproliferative effect, both EspA, -B, and -D dependent and
Tir/intimin independent, were phenotypically linked. Moreover, cell
cycle perturbations may result from alterations of the cytoskeleton (2). We therefore reasoned that the cell cycle arrest
could be a functional consequence of the cytoskeletal rearrangement and
hence that the inhibition of stress fiber formation could possibly
prevent the block. Since the cytoskeletal rearrangements are
reminiscent of activated Rho (which plays a central role in stress
fiber and focal adhesion assembly [39]), we attempted to
inhibit stress fibers formation by inhibiting Rho before and during the
interaction. To do so, we used Clostridium botulinum exoenzyme C3 and Staphylococcus aureus EDIN, two toxins that
inhibit Rho. HeLa cells were pretreated for 2 h with either DC3B
(a fusion protein of C3 and the B fragment of diphtheria toxin
[3]) or purified EDIN (43), and then E22
was added and the interaction was prolonged for 4 h. After several
washes, the cells were further cultivated without toxins and bacteria.
Seventy-two hours after the interaction, cells exposed to E22 in
absence of toxins exhibited the cytoskeleton alterations, namely,
numerous stress fibers and clustered vinculin stretches (Fig.
4). In contrast, cells exposed to DC3B
(or EDIN) and E22 were larger, rounder, and contained many fewer stress
fibers, and vinculin was confined to the periphery of cells (Fig. 4 and
data not shown). In control experiments, we verified that actin fibers
were disrupted in HeLa cells treated with DC3B or EDIN at the
expiration of the interaction period and that removal of toxins from
the medium caused the recovery of actin fibers, vinculin structures,
and cell growth (Fig. 4 and data not shown). In addition, DC3B and EDIN
did not reduce HeLa cell viability (as assessed by the Trypan blue dye
exclusion method and LDH assay) and did not impair E22 growth and
adhesion (data not shown). The Rho inhibitors C3 and EDIN added before and during interaction therefore efficiently prevented, in an irreversible manner, the cytoskeletal rearrangement triggered by E22.
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FIG. 4.
Cytoskeletal rearrangement and cell distribution
according to DNA content of HeLa cells 72 h after exposition to
E22 in the presence or absence of the Rho inhibitor DC3B. HeLa cells
were pretreated for 2 h with DC3B, and then E22 was added and the
interaction was continued for 4 h. Control cells were treated with
DC3B but left uninfected. After several washes, the cells were
incubated for 72 h without bacteria and toxin. F-actin was stained
with rhodamine-phalloidin, and vinculin was labeled by FITC indirect
immunofluorescence. Corresponding cell distribution according to DNA
content was determined by flow cytometry.
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This long-term disruption of stress fibers, however, did not prevent
inhibition of mitosis. As shown by flow cytometry analysis,
cells
exposed to DC3B or EDIN and E22 and cultivated during 72
h
accumulated at 4C and 8C (46.3 and 36.3%, respectively), a profile
similar to that of cells exposed to E22 alone (43.3 and 36.5%
at 4C
and 8C, respectively) (Fig.
4 and data not shown). In contrast,
the
cell cycle distribution of cells exposed to DC3B or EDIN only
was
not significantly affected (Fig.
4 and data not shown). We
can conclude
that the antiproliferative effect was not functionally
linked to
cytoskeletal
rearrangement.
Dissociation of mitosis inhibition from early tyrosine
dephosphorylation events.
Tyrosine dephosphorylation of several
host cell proteins has been described as an early event induced by EPEC
strain E2348/69 (24). E22-exposed HeLa cells exhibited a
tyrosine dephosphorylation pattern similar to that induced by E2348/69,
as demonstrated by immunoprecipitation and direct Western blotting of
phosphotyrosine proteins (data not shown). Dephosphorylation events
together with the 85- to 90-kDa phosphorylated Tir protein were
detectable as early as 2 h after inoculation of cells with E22.
The espA, espB, and espD mutants did
not cause tyrosine dephosphorylation, which was restored after
complementation by the corresponding gene cloned from E2348/69. In
addition, eae and tir mutants induced a tyrosine dephosphorylation pattern similar to that in E22-exposed cells (data
not shown).
Tyrosine kinase inhibitors are known to induce cell cycle arrest in
several cell lines (
6,
17). To determine whether
the
cytoskeletal rearrangement and the mitosis inhibition were
dependent
upon early tyrosine dephosphorylation,PV or PAO was
used to inhibit
tyrosine phosphatases during the interaction period.
Cells were exposed
to E22 for 2 h, and then the drug was added
and the interaction
was continued for 2 h. The overall tyrosine
phosphorylation
profile was even increased in PV- or PAO-treated
cells compared to that
of control cells (not shown). Seventy-two
hours after the interaction,
cells exposed to E22 in the presence
of PAO or PV contained numerous
stress fibers (data not shown)
and a DNA content profile similar to
that of cells exposed to
E22 without the drugs (Fig.
5 and data not shown). Thus, the early
tyrosine dephosphorylation events that occurred in E22-exposed
cells
were not necessary to the triggering of the mitosis inhibition
and the
cytoskeletal rearrangement.
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FIG. 5.
Distribution of HeLa cells according to DNA content
72 h after the interaction in the presence or absence of the
tyrosine phosphatase inhibitor PV. Cells were infected with E22 for
2 h, PV was added, and the interaction was continued for 2 h.
After several washes, the cells were incubated for 72 h without
bacteria and PV, and then the cell distribution according to DNA
content was determined by flow cytometry.
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Installation and maintenance of the G2/M arrest in
E22-exposed cells.
With a view to investigating possible
alterations induced by E22 infection in the biology of cellular
effectors responsible for cell cycle progression, we analyzed more
closely the modalities of the cell cycle arrest. The 8C peak
demonstrated by cell cycle analysis indicates that cells blocked by
E22, although not able to undergo mitosis, were able to enter a new
round of DNA synthesis. In order to demonstrate DNA synthesis, HeLa
cells were treated with BrdU for 6 h starting 72 h after
initial exposure to E22 or E22EspB, and then DNA and BrdU contents
were quantified by flow cytometry. As shown in Fig.
6, 56.8 and 15.8% of E22EspB-exposed cells were in G0/G1 and
G2/M, respectively, whereas 8.4, 42.9, and 15.2%
of the cells exposed to E22 were identified in the
G0/G1, G2/M, and 8C populations, respectively. In
E22EspB-exposed cells, bivariate analysis showed that BrdU-labeled
cells were present in S, G2/M, and
G0/G1 populations (Fig. 6), which demonstrated progression into a new cycle. In contrast, cells exposed to E22, although unable to enter a new G1 phase, were
able to incorporate BrdU after G2/M phase, as
illustrated by the presence of labeled cells in the 8C population (Fig.
6).
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FIG. 6.
Determination of BrdU incorporation in E22EspB- and
E22-exposed cells by bivariate flow cytometry. Seventy-two hours after
exposition to bacteria, cells were treated for 6 h with BrdU (5 µg/ml). Incorporated BrdU was labeled by FITC indirect
immunofluorescence, and DNA was labeled with propidium iodide. Contour
maps of DNA red fluorescence versus FITC fluorescence are shown on the
upper row, and corresponding DNA frequency distributions are displayed
below.
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The foregoing results show that unsynchronized cells exposed to E22
progressively accumulated in G
2/M and 8C
populations.
To analyze more specifically the transition of cells
through S
to G
2 after the interaction, we exposed
cells synchronized at
the G
1/S border to E22 or
E22
EspB. Thirty minutes or 24 h after
the interaction period,
cells were labeled with BrdU during 30
min and then processed for
bivariate analysis by flow cytometry.
One hour after the end of the
interaction period (5 h after G
1/S
release),
81.3% of the E22
EspB-infected cells had transited in
S phase, as
demonstrated by BrdU incorporation and DNA content
(Fig.
7). At the same time, 74.2% of the
E22-infected cells were
also in S phase (Fig.
7). Twenty-four hours
after the interaction,
a majority of cells exposed to E22
EspB were
distributed in G
0/G
1 and S
phase (36.4 and 58.9%, respectively), which means that they
were
accomplishing a new cycle. In contrast, 70.5% of the cells
exposed to
E22 were in G
2/M, and 8.4% had greater than 4C
DNA
content (Fig.
7). In conclusion, cells exposed to E22 during S
phase accumulated in G
2/M, and some of them
rereplicated their
DNA without intervening mitosis.
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FIG. 7.
Determination of BrdU incorporation in synchronized
cells exposed to E22EspB or E22. HeLa cells were synchronized at the
G1/S border and exposed for 4 h to bacteria at the
time of release. Cells were treated for 30 min with BrdU (5 µg/ml) 5 or 24 h after release. Incorporated BrdU was labeled by FITC
indirect immunofluorescence, and DNA was labeled by propidium iodide.
Contour maps of DNA versus BrdU contents are on the upper row, and
corresponding DNA frequency distributions are displayed below.
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Expression of cyclin B1 in E22-exposed cells.
Cdks associated
with their regulatory units (cyclins) regulate progression through the
eukaryotic cell cycle. More specifically, cyclin B1 and Cdk1 control
entry into mitosis. The cellular concentration of cyclin B1 is an
immediate determinant of the transition from G2
to mitosis (34). To test whether cyclin B1 expression was affected by exposition to E22, cells synchronized in
G1/S were infected as before, and the cyclin B1
concentration as a function of DNA content was determined by bivariate
flow cytometry analysis. In cells exposed to E22EspB, cyclin B1
accumulated during S phase (7 h after G1/S
release) and reached a maximum 11 h after
G1/S release (Fig.
8), when the majority of cells were in
G2 and about 5% were in mitosis (not shown).
E22-exposed cells showed a similar cyclin B1 accumulation in S and
G2/M (Fig. 8). This indicated that cyclin B1
synthesis was not affected by exposition to E22 and prompted us to
investigate Cdk1.
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FIG. 8.
Evolution of cyclin B1 content in synchronized cells
exposed to E22 or E22EspB. HeLa cells were synchronized at the
G1/S border and exposed for 4 h to bacteria starting
at the time of release. The cells were harvested 7 and 11 h after
release and processed for bivariate flow cytometry analysis. Cyclin B1
was labeled by FITC indirect immunofluorescence, and DNA was labeled by
propidium iodide. Contour maps of cyclin B1 as a function of DNA
content are shown. The "windows" represent the level of nonspecific
fluorescence, i.e., fluorescence of the cells that were treated with
irrelevant isotypic IgG rather than antibodies against cyclin.
|
|
Cdk1 modification in E22-exposed cells.
Cdk1 is expressed at a
constant level over the different phases of the cell cycle, but its
phosphorylation level increases during interphase to reach a maximum in
G2. Initiation of mitosis is then triggered by
the activation of Cdk1, which results from dephosphorylation of the
Tyr-15 residue (34). The amount of Cdk1 and its tyrosine
phosphorylation status were determined in cells synchronized in
G1/S and exposed to bacteria as before. To
validate the method, we used cells arrested in prometaphase by
nocodazole (resulting in dephosphorylated active Cdk1) and cells
blocked in G2/M by treatment with CDT-I
(resulting in hyperphosphorylated inactive Cdk1 [8]). The three
isoforms of Cdk1 were demonstrated by direct Western blotting
using anti-Cdk1 antibody (Fig. 9A
and B), and after stripping of the membrane, antiphosphotyrosine
antibodies were used to confirm that the slow-migrating Cdk1
isoform was tyrosine phosphorylated (not shown). As expected, the
fast-migrating dephosphorylated isoform of Cdk1 was dominant in
nocodazole-treated cells, while in CDT-I-treated cells the
slow-migrating hyperphosphorylated isoform of Cdk1 was prevalent (Fig.
9A). In E22EspB-exposed cells, the concentration of the
hyperphosphorylated upper isoform of Cdk1 was maximum in
G2 phase (11-h time point) and was lowered 24 h after the interaction (Fig. 9A; densitometry data not shown), consistent with the fact that these cells were accomplishing a new
cycle (see Fig. 7). In E22-exposed cells, the concentration of the
three isoforms of Cdk1 was similar to that of E22EspB-exposed cells
at the 7- and 11-h time points, but the concentration of hyperphosphorylated slow-migrating band remained high at the 24-h time
point (Fig. 9A; densitometry data not shown), when about 70% of the
cells were at 4C DNA content (Fig. 7). Thus, the kinetic of the
accumulation of the cells at 4C DNA content was correlated to the
hyperphosphorylation status of Cdk1, suggesting that the G2/M arrest triggered by E22 is associated with
the prevention of Cdk1 dephosphorylation.
View larger version (51K):
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|
FIG. 9.
Demonstration of Cdk1 in E22- and E22EspB-exposed
cells. HeLa cells synchronized at the G1/S border (A and B)
or left unsynchronized (C) were exposed to bacteria for 4 h and
were harvested after 7, 11, and 24 h. (A) Cell lysates (40 µg of
proteins from 5 × 105 cells) were resolved by
SDS-PAGE, and the three isoforms of Cdk1 were revealed by Western
blotting. (B and C) Cdk1 was affinity-purified from cell lysates (200 µg of proteins from 2 × 106 cells) using
p13suc1-agarose beads. After SDS-PAGE, the three
isoforms of Cdk1 were revealed by Western blotting. Cells blocked in
prometaphase by nocodazole (dephosphorylated Cdk1) and blocked in
G2/M by CDT-I (hyperphosphorylated Cdk1) were used as
controls. The blots were stripped and reprobed with anti-Cdk1-Tyr15 or
anti-phosphotyrosine antibodies to confirm that the slow-migrating
isoform (noted by an arrow) was tyrosine phosphorylated (data not
shown).
|
|
p13
suc1, which binds Cdk1, is widely used as a
reagent for precipitating Cdk1 from all eukaryotes (
45).
With a view to substantiate
the foregoing result, Cdk1 was first
affinity purified from cell
lysates using
p13
suc1-agarose beads before revelation by
Western blotting. In E22
EspB-exposed
cells, the total amount of the
three isoforms of affinity-purified
Cdk1 appeared similar in S phase
and G
2 phase (11-h time point),
while the
hyperphosphorylated isoform increased to reach a maximum
in
G
2 (Fig.
9B). In comparison, in cells exposed to
E22, the total
amount of Cdk1 demonstrated by
p13
suc1 affinity was similar to that of
E22
EspB-exposed cells 7 h after
G
1/S
release but about four times less abundant 11 h after release
(Fig.
9B; densitometry data not shown). This reduction of Cdk1
affinity
to p13
suc1-agarose beads was also observed
24 h after the interaction of
E22 with unsynchronized cells (Fig.
9C). Taken together, these
results indicate that the
G
2/M arrest triggered by E22 is associated
with
the prevention of Cdk1 dephosphorylation and with the loss
of Cdk1
affinity to exogenous p13
suc1.
| |
DISCUSSION |
Main features of the cell cycle arrest.
This study sheds light
on the modalities of the arrest of HeLa cell proliferation following
exposure to strain E22 of the rabbit EPEC O103:H2 clonal group
(10). The cytostatic effect triggered by E22 can be
summarized as follows: cells progressively accumulate at 4C and 8C DNA
content and do not display signs of mitosis during the whole period of
observation, i.e., 72 h after the interaction. The kinetics of
cell cycle distribution could suggest that unsynchronized cells exposed
to E22 were arrested both in
G0/G1 and in
G2/M (Fig. 1B). However,
G0/G1 cells eventually transited to G2/M, which suggests that
G1 cells were delayed and not stopped. Moreover,
synchronized cells exposed in S phase accumulated in
G2/M without slowing down S-phase progression,
which shows that G2/M arrest was the major
feature of the cell cycle perturbation (Fig. 7). It should be noticed
that the capacity of a proportion of
G2/M-arrested cells to undergo a new round of DNA
synthesis might result from a partial release in the mechanisms leading to the G2/M arrest. This would give rise
to tetraploid (8C) mononucleated cells that are unable to
complete mitosis (Fig. 6). Such a phenomenon, called endoreduplication
(16), has been observed with cell lines exposed to
anticancer agents (47), the Simian virus 40 (42), or protein kinase inhibitors (17). We
should also note that the HeLa cell genetic background could have
influenced the occurrence of endoreduplication. Indeed, HeLa cells
poorly express the inhibitor of Cdks
p21WAF1/CIP1 (19), which has an
inhibitory effect on endoreduplication (47).
Bacterial effectors causing the G2/M arrest.
Certain traits of the cell cycle inhibition triggered by E22 are
strikingly similar to that reported for cells exposed to CDTs. These
toxins, which are produced by certain EPEC isolates (1),
were shown to cause cell and nuclear distension and induce a
G2/M block through the maintenance of Cdk1 in
hyperphosphorylated inactive state (8, 11). However, the
participation of a toxin homologous to a CDT in E22-induced cell cycle
arrest is unlikely, since no toxic activity could be detected in
sterile lysates or in supernatants of E22 cultures (10),
and we were unable to demonstrate homologous genes by degenerate PCR in
rabbit EPEC O103 (unpublished data). In addition, the reduced affinity
purification of Cdk1 by p13suc1 in E22-exposed
cells is not observed in CDT-treated cells (Fig. 9C) (8). Moreover, the
triggering of cytoskeletal rearrangements together with cell
proliferation arrest are dependent upon the type III secretion system
(10), while CDT toxins do not rely upon type III secretion
for delivery (38). We also demonstrate that the cell cycle
arrest triggered by E22 is EspA, -B, and -D dependent but Tir and
intimin independent (Fig. 3). Whether EspA, -B, and -D mediate
cytoskeleton alterations and mitosis inhibition directly as effector
proteins and/or indirectly as components of a translocation apparatus
remains to be determined. However, each espA,
espB, or espD mutant strain was
functionally complemented by the corresponding esp gene
cloned from the CPE-negative strain E2348/69, indicating that no single
espA, espB, or espD gene encodes the
information needed to confer the cytostatic capacity (Fig. 3) and the
cytoskeleton alteration (35). Recent data support the
notion that EspA, -B, and -D form a molecular syringe to allow the
injection of effector molecules into the host cells by EPEC (25,
26, 48, 49). From all these data, we can hypothesize that the
EPEC strain E22 produces at least one other factor that is specifically
involved in CPE. This factor could depend on secreted EspA, -B, and -D
for functionality and/or translocation. Alternatively, the Esps may
trigger the cytoskeletal rearrangements and/or the mitosis inhibition,
which are then altered by other factor(s) unique to each strain,
eventually leading to the CPE phenotype. For instance, the negative
strain E2348/69 may express an additional dominant determinant that
prevents triggering of CPE.
Uncoupling of cell cycle arrest from cytoskeletal alteration.
Correlation between the structure of the actin cytoskeleton and cell
cycle progression have been reported: endoreduplication may result from
alteration of the cytoskeleton (2), and the cytotoxic
necrotizing toxins induce the formation of multinucleated cells
containing numerous stress fibers and in parallel inhibit cell division
(36). However, the inhibition of mitosis observed in this
study is not likely to be a functional consequence of the cytoskeletal
rearrangement triggered by E22, since the use of EDIN or C3 chimeric
toxin DC3B efficiently prevented the multiplication of focal adhesions
and stress fibers without impairing the cell cycle arrest (Fig. 4).
Control cells treated with DC3B or EDIN alone showed a normal
cytoskeleton and cell cycle pattern 72 h after treatment (Fig. 4),
an observation consistent with the recently described reversal of C3
effects upon removal of the toxin from the medium (4). On
the other hand, the irreversible inhibition of stress fiber assembly by
DC3B in E22-exposed cells suggests that the small GTP-binding RhoA, the
main target of DC3B, is crucial in the transduction cascade leading to
the cytoskeleton rearrangement. Further works, for instance using Rho
mutant cell lines, are needed to substantiate this hypothesis.
Cell cycle arrest and tyrosine dephosphorylation.
Regulation
of tyrosine phosphorylation represents a governing mechanism in cell
proliferation (5). In certain cell systems, the protein
kinase inhibitor staurosporine impairs cytokinesis and induces a higher
DNA ploidy level (17). We therefore reasoned that the
triggering of the cell cycle arrest by E22 could be preceded by the
disruption of tyrosine phosphorylation events. E22 did induce an EspA,
-B, and -D-dependent tyrosine dephosphorylation of host
proteins. However, repressing the dephosphorylation induced by E22 with
pervanadate or phenylarsine oxide impaired neither the cell cycle
arrest nor the cytoskeletal rearrangement. In addition, the E22-induced
phosphorylation profile was similar to that induced by E2348/69, a
strain that is unable to trigger the cell cycle arrest. A recent work
shows that E2348/69-induced tyrosine dephosphorylation events are
linked to an antiphagocytic phenotype (15). Unpublished work done in our laboratory indicates that E22 also inhibits its entry
in HeLa cells, an inhibition that depends on EspA, -B, and -D and which
is impaired by pervanadate or phenylarsine oxide treatment.
Thus, the detectable tyrosine dephosphorylation events that take place
in the host cell following E22 exposition are related to an
antiphagocytic activity exerted by EPEC on target cells but not to
either cytoskeletal rearrangement or mitosis inhibition.
Implication of specific cellular effectors of the G2-M
transition.
To investigate further the possible mechanisms of the
G2/M arrest triggered by E22, we have analyzed
the behavior of the cyclin B1 and Cdk1, which form the complex
controlling the transition from G2 to mitosis. In
normal cells, cyclin B1 accumulates during S phase to reach a maximum
in late G2, whereas Cdk1 is present at a constant
level over the different phases of the cell cycle. Cdk1 activity is
downregulated by phosphorylation of Tyr-15 and Thr-14 residues, which
remain phosphorylated during interphase until onset of M phase
(34). The G2/M arrest triggered by
E22 could not be accounted for by a lack of cyclin B1 expression, since
cyclin B1 expression was not affected in synchronous cells exposed to
E22 (Fig. 8). On the other hand, we observed in E22-exposed synchronous
cells an accumulation of inactive Cdk1 phosphorylated on Tyr-15 (Fig.
9A), in association with the accumulation of the cells at 4C DNA
content (Fig. 7). Since Cdk1 dephosphorylation is a prerequisite for
its activation and entry into mitosis, the lack of Cdk1
dephosphorylation may account for the G2/M
arrest. A further clue to the determinism of the cell cycle arrest
triggered by E22 is provided by our observation that the
G2/M arrest was associated with a drastic
reduction of the level of Cdk1 affinity purified with
p13suc1-agarose beads (Fig. 9B and C).
p13suc1 is the founding member of the
cyclin-dependent kinase subunit (Cks) family of proteins that bind and
regulate Cdks, and it is widely used as a reagent for precipitating
Cdk's from all eukaryotes (45). We can hypothesize that
the binding of an endogenous Cks protein may have impaired binding of
Cdk1 to p13suc1-agarose beads. Indeed,
overexpression of Cks abolishes entry into mitosis and causes an
accumulation of inactive Cdk1 phosphorylated on Tyr-15 (13,
37). Alternatively, a putative Cdk1 alteration could alter
its affinity to p13suc1 and participate in the
cell cycle perturbation. The fact that certain cell cycle yeast
mutants, carrying temperature-sensitive Cdk alleles, show a decrease in
p13suc1-bound Cdk without change in overall Cdk
levels supports this idea (4a). The kinetics of association of Cdk1
with cyclin B1 and endogenous Cks together with their subcellular
localization should now be assessed in order to explain the defect of
exogenous p13suc1 affinity to Cdk1 and further
unravel the alteration of cell cycle machinery in E22-exposed cells.
Elucidation of the abnormal behavior of Cdk1 toward
p13suc1 may provide a clue on upstream signaling
events triggered upon E22 interaction and eventually preventing cell
entry into mitosis.
Concluding remarks.
The cell cycle arrest triggered by
E22 appears to be relevant to other CPE-positive strains of the rabbit
EPEC O103:H2 clonal group, rabbit EPEC O15 strain RDEC-1, and some
human clinical EPEC isolates (10), since they had a
similar effect on the HeLa cell cycle (data not shown). Is a modulation
of the eukaryotic cell cycle relevant in EPEC pathogenesis? A cell
cycle arrest of stem cells in the crypts of Lieberkhün, which
supply cells to intestinal villi, could reduce the shedding of
epithelia and therefore prolong the local existence of attached
bacteria. In addition, the ability to inhibit proliferation could
constitute a powerful weapon for immune evasion. There is emerging
evidence that a growing family of pathogenic bacteria can subvert the
eukaryotic cell cycle (18). Future work should hunt
for a putative mitosis-inhibiting factor translocated into host cells
by EPEC in an EspABD-dependent manner and should evaluate the
impact of such a cell cycle modulation activity on the natural history
of disease.
| |
ACKNOWLEDGMENTS |
We are indebted to M. Sugai for the kind gift of the purified
EDIN and to P. Boquet for the gift of the plasmid encoding DC3B. We
thank J. R. Seavitt, S. Boullier, and S. Pérès for
useful advice, C. Watrin for technical assistance, and E. Blank for
critical reading of the manuscript.
This work was supported by grants from the Région
Midi-Pyrénées, from INRA (AIP Microbiologie), and from the
DGER and by grant 1335 from the European Community Program FAIR.
J.-P.N. was a recipient of a scholarship from INRA and Biové
Company, and O.M. was a recipient of a scholarship from ENVT.
| |
FOOTNOTES |
*
Corresponding author. Present address: Division of
Infectious Diseases, University of Maryland at Baltimore, 10 S. Pine
St., Baltimore, MD 21201. Phone: (410) 706-7560. Fax: (410) 706-8700. E-mail: jnoug001{at}umaryland.edu.
Editor:
J. T. Barbieri
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Infection and Immunity, November 2001, p. 6785-6795, Vol. 69, No. 11
0019-9567/01/$04.00+0 DOI: 10.1128/IAI.69.11.6785-6795.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
