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Previous Article | Next Article 
Infect Immun, April 1998, p. 1688-1696, Vol. 66, No. 4
0019-9567/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
Divergent Signal Transduction Responses to
Infection with Attaching and Effacing Escherichia coli
Arif
Ismaili,1,2
Elaine
McWhirter,2,3
Michelle Y. C.
Handelsman,2,3
James L.
Brunton,2,3 and
Philip M.
Sherman1,2,4,*
Division of Gastroenterology and Nutrition,
Research Institute, The Hospital for Sick
Children,1
Samuel Lunenfeld Research
Institute, Mount Sinai Hospital,3 and
Departments of Pediatrics4 and
Molecular and Medical Genetics,2
University of Toronto, Toronto, Ontario, Canada
Received 3 July 1997/Returned for modification 9 September
1997/Accepted 9 January 1998
 |
ABSTRACT |
Shiga toxin-producing Escherichia coli (STEC) O157:H7
is an attaching and effacing pathogen that causes hemorrhagic colitis and the hemolytic-uremic syndrome. Although this organism causes adhesion pedestals, the cellular signals responsible for the formation of these lesions have not been clearly defined. We have shown previously that STEC O157:H7 does not induce detectable tyrosine phosphorylation of host cell proteins upon binding to eukaryotic cells
and is not internalized into nonphagocytic epithelial cells. In the
present study, tyrosine-phosphorylated proteins were detected under
adherent STEC O157:H7 when coincubated with the non-intimately adhering, intimin-deficient, enteropathogenic E. coli
(EPEC) strain CVD206. The ability to be internalized into epithelial
cells was also conferred on STEC O157:H7 when coincubated with CVD206
([158 ± 21] % of control). Neither the ability to rearrange
phosphotyrosine proteins nor that to be internalized into epithelial
cells was evident following coincubation with another STEC O157:H7
strain or with the nonsignaling espB mutant of EPEC.
E. coli JM101(pMH34/pSSS1C), which overproduces
surface-localized O157 intimin, also rearranged tyrosine-phosphorylated
and cytoskeletal proteins when coincubated with CVD206. In contrast,
JM101(pMH34/pSSS1C) demonstrated rearrangement of cytoskeletal
proteins, but not tyrosine-phosphorylated proteins, when
coincubated with intimin-deficient STEC (strains CL8KO1 and CL15).
These findings indicate that STEC O157:H7 forms adhesion pedestals by
mechanisms that are distinct from those in attaching and effacing EPEC.
Taken together, these findings point to diverging signal transduction
responses to infection with attaching and effacing bacterial
enteropathogens.
| |
INTRODUCTION |
Shiga toxin-producing
Escherichia coli (STEC) O157:H7 causes watery diarrhea and
hemorrhagic colitis and leads to systemic complications including
hemolytic-uremic syndrome and thrombotic thrombocytopenic purpura in
humans (28, 35). STEC of serogroups O157 and O26 is
often referred to as enterohemorrhagic E. coli, with
STEC of the serotype O157:H7 being most commonly identified in
association with human disease (28).
Most STEC strains belong to a family of gastrointestinal bacteria
referred to as attaching and effacing (AE) pathogens (28, 35). Phenotypically, an AE lesion is characterized by localized destruction of apical microvilli followed by intimate adhesion of
bacteria to the cell plasma membrane (23). At sites of
bacterial attachment underneath the host plasma membrane, there is a
rearrangement of cytoskeletal proteins including F-actin and
-actinin (16).
The formation of AE lesions by STEC is dependent on the presence of a
chromosomal gene, called E. coli attaching and effacing (or
eae, formerly eaeA) gene, in the infecting
bacterium (3, 38). The eae gene of STEC
O157:H7 encodes a 97-kDa outer membrane protein, intimin
(24). In vivo studies with a newborn piglet model of
infection have shown that STEC strains carrying mutations of
eae are unable to attach intimately to host epithelial cells and do not induce F-actin rearrangement (8).
A 35-kb pathogenicity island, termed locus for enterocyte effacement,
comprising virulence genes mediating both signal transduction responses
and the formation of AE lesions, has been identified in both STEC and
the related toxin-negative enteropathogen, enteropathogenic E. coli (EPEC) (25). This virulence cassette encodes
proteins (EspA and EspB) (17, 20) mediating signaling
responses in EPEC (13, 21) and the proteins responsible for
their secretion via the type III secretion pathway
(17). Proteins homologous to EspA and EspB of EPEC
have been identified in culture supernatants of some STEC
strains (12, 18). However, AE STEC strains of multiple
serotypes, including O157:H7, isolated from calves with diarrhea do not consistently test positive for the presence of the
espB gene (37).
Although STEC and EPEC share key virulence determinants, there also
exist differences between the two groups of enteric pathogens. For example, whereas EPEC strains are considered to be invasive organisms (2, 6), STEC O157:H7 strains are not
internalized into nonphagocytic cells (6, 26, 34). We have
also reported previously that STEC O157:H7 does not induce a
detectable rearrangement of eukaryotic tyrosine-phosphorylated
proteins (15). In the present study, we show that the
ability of STEC O157:H7 to rearrange phosphotyrosine proteins
in infected eukaryotic cells can be induced when it is coincubated with
a non-intimately adhering EPEC mutant, strain CVD206. The
internalization of STEC O157:H7 by host epithelial cells was also
significantly enhanced in the presence of CVD206. We also provide
direct evidence to show that cytoskeletal rearrangement in cells
infected with STEC O157:H7 occurs independently of phosphotyrosine protein response. These findings point to distinct mechanisms of signal
transduction induced in response to infection by AE bacterial
enteropathogens.
| |
MATERIALS AND METHODS |
Bacteria and growth conditions.
The bacterial strains
employed in this study are listed in Table
1. The bacteria were grown in static
nonaerated Penassay (Difco Laboratories, Detroit, Mich.) broth cultures
overnight at 37°C. Strains bearing the plasmids pMH34 and pSSS1C were
grown in Penassay broth supplemented with carbenicillin (150 µg/ml) and chloramphenicol (30 µg/ml), respectively (4). EPEC
strain E2348/69 was a kind donation of E. Boedeker (University of
Maryland, Baltimore). EPEC strains CVD206 and UMD864 and
enteroaggregative E. coli strain 17-2 were kindly provided
by J. B. Kaper (University of Maryland, Baltimore). STEC strains
CL8, CL15, and CL56 were donated by M. A. Karmali (The Hospital
for Sick Children, Toronto, Ontario, Canada).
A 3.5-kb XhoII fragment of pGB19 (a plasmid containing the
eae gene of STEC O157:H7 strain CL8
[3]) was cloned into the BamHI site of
pTRC99A, where expression is under the control of the trc
promoter (27). This plasmid, designated pMH34, was then transformed into E. coli JM101 by standard techniques
(33). A second recombinant strain was constructed by
transforming the diffuse adhesin plasmid pSSS1C (4) (kindly
provided by J. R. Cantey, Medical University of South Carolina,
Charleston) into E. coli JM101. Plasmids pMH34 and pSSS1C
were also cotransformed into E. coli JM101. All plasmid
transformations were carried out by standard techniques
(33).
Eukaryotic cell culture.
The human epithelial tissue culture
cell line HEp-2 (ATCC CCL23; American Type Culture Collection,
Rockville, Md.) and the human ileocecal adenocarcinoma cell line HCT-8
(ATCC CCL244) were employed in this study. HEp-2 cells were grown
in minimum essential medium (Life Technologies, Grand Island, N.Y.)
supplemented with 15% fetal calf serum (Cansera International Inc.,
Rexdale, Ontario, Canada). HCT-8 cells were cultivated in RPMI medium
supplemented with 10% fetal calf serum at 37°C in 5%
CO2. Both media also contained 0.5% glutamine, 0.1%
sodium bicarbonate, 2% penicillin-streptomycin, and 1% amphotericin B
(all from Life Technologies).
Immunofluorescence detection of phosphotyrosine and -actinin
proteins.
Tyrosine-phosphorylated and -actinin proteins were
detected in infected HEp-2 cells, as described previously (15,
16). Briefly, a subconfluent monolayer of HEp-2 cells was
infected with approximately 5 × 107 bacteria for
3 h at 37°C in antibiotic-free minimum essential medium. In
coinfection studies to detect phosphotyrosine and -actinin proteins,
equal amounts of the two strains, as determined by optical density at
600 nm, were added in each experiment. The cells were then washed free
of nonadherent bacteria and either fixed in 2% paraformaldehyde for 15 min and permeabilized with 0.1% Triton X-100 for 5 min at 25°C for
the phosphotyrosine assay or fixed in 100% methanol for 10 min for the
-actinin assay. The detection of phosphotyrosine and -actinin
proteins was performed by staining cells with murine monoclonal
antiphosphotyrosine 4G10 (Upstate Biotechnology Inc., Lake Placid,
N.Y.) and anti--actinin (Sigma Chemical Co., St. Louis, Mo.)
antibodies, respectively, for 1 h at 37°C. Phosphotyrosine
protein localization was confirmed by using two additional murine
monoclonal antiphosphotyrosine antibodies, PY-7E1 and PY-1B2 (both from
Zymed Laboratories Inc., South San Francisco, Calif.). After washings,
the cells were stained with fluorescein isothiocyanate
(FITC)-conjugated goat anti-murine antibody (Jackson ImmunoResearch
Laboratories Inc., West Grove, Pa.) for 1 h at 37°C.
In double immunolabeling experiments, isotype-specific secondary
antibodies conjugated to either FITC or lissamine rhodamine sulfonyl
chloride were employed (Jackson). Foci of intense fluorescence, corresponding to the presence of phosphotyrosine and -actinin proteins in infected HEp-2 cells, were detected underneath adherent bacteria by alternating phase-contrast and epifluorescence microscopy.
Fluorescent actin staining (FAS).
HCT-8 cells were infected
with approximately 2 × 107 recombinant E. coli [strain JM101(pMH34/pSSS1C), JM101(pMH34), or
JM101(pSSS1C)] bacteria for 2 h at 37°C alone or in
combination with either EPEC strain CVD206 or STEC O157:H7 strain
CL8KO1. The assay was then performed as described previously (5,
22). Briefly, cells were washed free of nonadherent bacteria,
fixed in 3% formalin, and permeabilized with 0.1% Triton X-100.
Following washes with phosphate-buffered saline, tissue culture cells
were incubated with FITC-phalloidin (Sigma) at a concentration of 5 µg/ml for 30 min to detect F-actin (27). In the case of
coinfection with bacterial strains, prior to being stained for F-actin,
fixed and washed HCT-8 cells were incubated with rabbit anti-O127
(Centers for Disease Control and Prevention, Atlanta, Ga.) or rabbit
anti-O157 (Difco) antisera, followed by staining with goat anti-rabbit
antibody conjugated to rhodamine (Jackson). The cells were then
examined by fluorescence microscopy, as described above.
Transmission electron microscopy.
HCT-8 epithelial
monolayers were grown in 75-cm3 tissue culture flasks
(Becton Dickinson, Plymouth, England) and infected with approximately
5 × 108 CVD206 cells for 2 h at 37°C.
Following washes, the cells were infected for 1 h with
JM101(pMH34/pSSS1C). After the monolayer was washed five times with
phosphate-buffered saline, the cells were gently scraped with a rubber
policeman. Cells were then fixed with 2% glutaraldehyde in 0.1 M
cacodylate buffer and postfixed in osmium tetroxide. Samples were then
dehydrated through a series of graded ethanol washes, embedded in Spur
epoxy resin, and stained with uranyl acetate and lead citrate. The
grids were then examined under a Philips 300 transmission electron
microscope (Philips Electronic Instruments, Mahwah, N.J.) for the
presence of AE pedestals.
Bacterial adhesion and gentamicin internalization assays.
HEp-2 cells were grown in 12-well tissue culture plates (Costar,
Cambridge, Mass.) to confluence and then infected in antibiotic-free medium with approximately 109 bacteria in 0.01 ml of broth
for 3 h at 37°C. In coinfection experiments, equal amounts
(approximately 109 cells) of the two strains were incubated
with HEp-2 cells for 3 h at 37°C. After the HEp-2 cells
were washed to remove nonadherent bacteria, cells with adherent
bacteria were detached from the culture plates by incubation with
0.25% trypsin (Life Technologies) for 10 min at 37°C. After
centrifugation and lysis of HEp-2 cells in distilled water
containing 0.1% bovine serum albumin, serial 10-fold dilutions were
plated onto rhamnose MacConkey agar plates and incubated for 16 h
at 37°C to determine viable bacterial CFU. The rhamnose MacConkey
agar allows for the differentiation of colonies formed by STEC
O157:H7 strain CL56 (negative after 16 h) from the colonies of
all other strains employed in the coinfection experiments (positive
after 16 h).
The gentamicin internalization assay was performed exactly like the
adhesion assay until after nonadherent bacteria were washed off. Prior
to trypsinization, the cells were incubated in the presence of
gentamicin (Schering Canada, Pointe-Claire, Quebec, Canada) at a
concentration of 100 µg/ml for 90 min. The assay was then completed
as described above.
Statistical analysis.
Results are presented as means ± standard errors of the means. Statistical significance between two
groups of data was tested by using the nonpaired Student t
test. A p value of <0.05 was considered significant.
| |
RESULTS |
Induction of the rearrangement of phosphotyrosine proteins in
STEC-infected HEp-2 cells by EPEC mutant strain CVD206.
The results of bacterial coinfection experiments to detect
phosphotyrosine proteins are summarized in Table
2. Infection of HEp-2 cells with
either STEC O157:H7 strain CL56 or EPEC strain CVD206 alone did not
lead to an organized rearrangement of phosphotyrosine proteins (data
not shown). However, when CL56 was used for coinfection with CVD206
there was an accumulation of phosphotyrosine proteins in the eukaryotic
cell underneath the adherent bacteria (Fig. 1A and
B). Similar accumulation of
tyrosine-phosphorylated proteins was also detected with a second STEC
O157:H7 isolate, strain CL8, when used for coinfection with CVD206
(Table 2). In contrast, when CVD206 was used for coinfection with the
eae insertional-inactivation mutant of CL8, strain CL8KO1,
rearrangement of phosphotyrosine proteins was not detected (Fig. 1C and
D). These findings indicate that, in the coinfection model system
employed, the phosphotyrosine proteins detected by fluorescence
microscopy are present underneath the adherent wild-type STEC
O157:H7 with functional intimin and not under the eae
deletion mutant (i.e., strain CVD206).
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FIG. 1.
Phase-contrast (A, C, and E) and immunofluorescence (B,
D, and F) detection of phosphotyrosine proteins in HEp-2 cells
following coinfection with STEC O157:H7 strain CL56 plus EPEC
strain CVD206 (A and B), STEC O157:H7 strain CL8KO1 plus EPEC
strain CVD206 (C and D), and STEC O157:H7 strain CL56 plus EPEC
strain UMD864 (E and F). Coinfection by STEC O157:H7 with CVD206
resulted in an accumulation of host phosphotyrosine proteins
corresponding to sites of bacterial adhesion (A and B). In contrast,
UMD864 did not induce detectable phosphotyrosine signaling in
STEC-infected cells (E and F). The absence of phosphotyrosine proteins
in a coinfection by intimin-deficient STEC O157:H7 strain CL8KO1
and CVD206 (C and D) confirmed that the phosphotyrosine proteins
detected were underneath adherent STEC O157:H7 and not the
coinfecting strain CVD206. Approximate original magnification,
×1,000.
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The induction of phosphotyrosine protein rearrangement was specific to
coinfection with strain CVD206 because incubation of wild-type STEC
O157:H7 strains CL8 and CL56 with either another STEC O157:H7
strain or the nonsignaling espB mutant of EPEC, strain UMD864, did not lead to the rearrangement of phosphotyrosine proteins (Fig. 1E and F). Similarly, incubation of STEC O157:H7 strains with
a laboratory E. coli strain, HB101, also showed no induction of tyrosine-phosphorylated proteins (Table 2). In contrast, when UMD864
was coincubated with strain CVD206, foci of tyrosine-phosphorylated proteins were detected (Table 2).
Internalization of STEC is enhanced by coinfection with EPEC strain
CVD206.
Figure 2 shows the results
of bacterial coinfection experiments for the internalization of STEC
O157:H7 strain CL56. When HEp-2 cells were coinfected with STEC
O157:H7 strain CL56 and EPEC strain CVD206, there was a significant
increase ([158 ± 21] %; P < 0.05) in the
internalization of CL56 compared to that when HEp-2 cells were
infected alone. Enhancement of invasion was a specific response due to
CVD206 since coinfection with either UMD864 or HB101 did not lead to an
increase in the internalization of STEC. While CVD206 enhanced the
ability of STEC O157:H7 to be internalized, the opposite was not
the case. That is, strain CVD206 was internalized to the same levels
whether it was used for infection alone or in the presence of STEC
O157:H7 strain CL56.
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FIG. 2.
Effect of bacterial coinfection on the ability of STEC
O157:H7 strain CL56 to be internalized into HEp-2 cells. The
colonies of STEC strain CL56 are negative (white) on rhamnose MacConkey
agar after 16 h of incubation while the colonies formed by each of
the other strains are positive (pink) in the same time period, thereby
allowing the differentiation of STEC O157:H7 strain CL56 from each
of the other strains. Coincubation of CL56 and CVD206 resulted in an
increase in internalization of STEC O157:H7 strain CL56 into
HEp-2 cells ([158 ± 21]% of control; t test,
P < 0.05 [*]), but there was no increase in the
internalization of EPEC strain CVD206 (P > 0.05). The
increased internalization was specifically due to strain CVD206 since
neither UMD864 nor HB101 enhanced the invasion phenotype of STEC
O157:H7 strain CL56.
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To determine whether the observed increase in internalization of STEC
O157:H7 upon coincubation with CVD206 was due to an increase in the
adherence of the strain to HEp-2 cells, quantitative adhesion
assays were performed in conjunction with an invasion assay. Figure
3 shows that with coinfection there was a
significant increase in the binding of STEC O157:H7 strain CL56 to
HEp-2 cells, whereas there was no effect on the adhesion properties
of CVD206. These findings suggest that the increase in internalization
of O157:H7 observed upon coinfection with CVD206 was due to an
upregulation in the adhesion of STEC O157:H7 to eukaryotic cells.
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FIG. 3.
Effects of coinfection by STEC O157:H7 strain CL56
and the eae-deficient EPEC strain CVD206 on adhesion (open
bars) and internalization (solid bars) into HEp-2 cells. The
strains were distinguished by their differential responses on rhamnose
MacConkey agar after 16 h of incubation. An increase in the
internalization of CL56 corresponded to an increase in the ability of
the organism to adhere to the tissue culture epithelial cells. In
contrast, coinfection did not increase the adhesion and internalization
properties of CVD206. *, P < 0.05.
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Intimin expressed by a laboratory E. coli strain,
JM101(pMH34/pSSS1C), rearranges both cytoskeletal proteins and
phosphotyrosine proteins when the strain is coincubated with EPEC.
Laboratory E. coli strains overexpressing
intiminO157 were then examined for their ability to
rearrange cytoskeletal elements when coincubated with CVD206.
Rearrangements of F-actin and -actinin were assessed on HCT-8 and
HEp-2 cells, respectively. Coincubation of JM101(pMH34/pSSS1C)
with CVD206 resulted in a positive FAS response after 2 h of
infection of HCT-8 cells, which is observed as organized fluorescence
outlining the shape of the bacterium in the form of a "tram line"
(Fig. 4A and B). In contrast, the FAS
pattern due to CVD206 was unorganized and shadowy in appearance (Fig.
4A), signifying its nonintimate attachment to epithelial cells.
Furthermore, the bacteria that resulted in an organized tram line of
fluorescence (Fig. 4A) were not detected when strain CVD206 was labeled
with anti-O127 immune serum followed by staining with a
rhodamine-conjugated secondary antibody (Fig. 4C). These findings
demonstrate that the FAS lesions were due to JM101(pMH34/pSSS1C) and not to CVD206. Neither JM101(pMH34/pSSS1C) nor JM101(pMH34) incubated alone on HCT-8 cells for 3 h resulted in a positive FAS response (data not shown). Coincubation of CVD206 with
JM101(pSSS1C) also did not result in detectable FAS lesions (data
not shown). These findings indicate that the positive FAS response was
specific to the highly adherent recombinant strain expressing intimin
encoded by the plasmid pMH34.
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FIG. 4.
Immunofluorescence (A) and phase-contrast (B)
micrographs of JM101(pMH34/pSSS1C) used for coinfection with EPEC
strain CVD206 on HCT-8 cells showing a characteristic FAS response
(long black arrow in panel A). The FAS response is represented as an
organized tram line of fluorescence while the response due to CVD206
(also seen in panel A and labeled with white arrows) is unorganized and
shadowy in appearance. The black arrow in panel A points to a
representative tram line of FAS response which is not labeled in panel
C, in which CVD206 cells are labeled with an anti-O127 serum (white
arrows). This result indicated that the FAS lesion is underneath
JM101(pMH34/pSSS1C) and not CVD206. The EPEC strain CVD206 is also
recognized by its capacity to form the microcolonies characteristic of
localized adherence (white arrows in panel B). In contrast, E. coli
JM101(pMH34/pSSS1C) containing the diffuse fimbrial adhesin
attaches with the appearance of a single bacterium (black arrow in
panel B). Approximate original magnification, ×1,000.
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Transmission electron microscopy confirmed the formation of
electron-dense adhesion pedestals in tissue culture cells infected for
1 h with JM101(pMH34/pSSS1C) following preincubation with CVD206 for 2 h (Fig. 5A). These
pedestals were not observed when either of the two bacterial strains
was used alone to infect HCT-8 cells (Fig. 5B and C).
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FIG. 5.
Transmission electron microscopy showing AE lesions
(arrows) formed by JM101(pMH34/pSSS1C) following preincubation with
CVD206 on HCT-8 cells (A). When either CVD206 (B) or
JM101(pMH34/pSSS1C) (C) was incubated on the tissue culture cells
alone, AE lesions were not formed. Approximate original magnification,
×11,000.
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JM101(pMH34/pSSS1C) also rearranged -actinin in HEp-2 cells
when coincubated with CVD206 for 3 h (Fig. 6A and
B). Neither CVD206 nor
JM101(pMH34/pSSS1C) alone induced an organized accumulation of
-actinin when incubated on HEp-2 cells (data not shown). In summary, the results demonstrate that EPEC strain CVD206 is able to mediate the formation of AE lesions by JM101(pMH34/pSSS1C) overexpressing intiminO157.
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FIG. 6.
Phase-contrast (A and C) and immunofluorescence (B and
D) detection of -actinin (A and B) and phosphotyrosine (C and D)
proteins in HEp-2 cells coinfected with JM101(pMH34/pSSS1C) and
EPEC strain CVD206. Distinct foci of fluorescence corresponding to
-actinin and tyrosine-phosphorylated protein rearrangement (arrows)
were seen only when the cells were infected with both
JM101(pMH34/pSSS1C) and CVD206. Approximate original magnification,
×1,000.
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Coincubation of JM101(pMH34/pSSS1C) with strain CVD206
on HEp-2 cells resulted also in the rearrangement of
tyrosine-phosphorylated proteins under JM101(pMH34/pSSS1C) (Fig. 6C
and D). The rearrangement of phosphotyrosine proteins was not evident
if the transformed strain was coincubated with the nonsignaling
espB mutant of EPEC, strain UMD864 (data not shown). This
finding suggests that the induction of tyrosine phosphorylation
response was due specifically to the signaling activity of CVD206.
Intimin expressed by JM101(pMH34/pSSS1C) rearranges
cytoskeletal elements, but not phosphotyrosine proteins, when
coincubated with STEC.
Since both EPEC and STEC are able to form
AE lesions, it was hypothesized that STEC O157:H7 can also induce
the rearrangement of cytoskeletal proteins under
JM101(pMH34/pSSS1C). Preincubation of HCT-8 cells for 2 h with
the STEC O157:H7 eae insertional-inactivation mutant,
strain CL8KO1, resulted in FAS lesions after 1 h of infection with
JM101(pMH34/pSSS1C) (Table 3). In
contrast, diarrheagenic enteroaggregative E. coli strain
17-2 and laboratory E. coli strains (HB101 and JM101) did
not result in a positive FAS response when used for coinfection with
JM101(pMH34/pSSS1C) (data not shown).
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TABLE 3.
Effect of coincubating EPEC and STEC on the rearrangement
of phosphotyrosine and cytoskeletal proteins (F-actin and
-actinin) by the intimin-overproducing E. coli
strain JM101(pMH34/pSSS1C)
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Rearrangement of -actinin was detected in HEp-2 cells when
JM101(pMH34/pSSS1C) was coincubated with two different STEC
intimin-deficient strains, CL8KO1 (serotype O157:H7) and CL15
(serotype O113:H21) (Fig. 7A and B).
Strains CL8KO1 and CL15 incubated alone on HEp-2 cells did not
reorganize -actinin proteins (Table 3).
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FIG. 7.
Phase-contrast (A and C) and immunofluorescence (B and
D) detection of -actinin (A and B) and phosphotyrosine (C and D)
proteins in HEp-2 cells coinfected with JM101(pMH34/pSSS1C) and
STEC intimin-negative strain CL15 (serotype O113:H21). Numerous foci of
fluorescence corresponding to -actinin rearrangement were seen
(arrow in panel B). In contrast, no detectable accumulation of
tyrosine-phosphorylated proteins was observed. Approximate original
magnification, ×1,000.
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In contrast to their ability to mediate the reorganization of F-actin
and -actinin, STEC strains CL8KO1 and CL15 failed to induce
detectable tyrosine-phosphorylated proteins following coincubation with
JM101(pMH34/pSSS1C) (Fig. 7C and D). Therefore, while STEC can
mediate the rearrangement of cytoskeletal elements when incubated with
a laboratory E. coli strain expressing intimin, in contrast to EPEC, STEC O157:H7 and STEC O113:H21 do not induce the
rearrangement of phosphotyrosine proteins.
STEC induces the rearrangement of cytoskeletal elements
independently of tyrosine phosphorylation.
Simultaneous detection
of -actinin and phosphotyrosine proteins in HEp-2 cells infected
with STEC O157:H7 strain CL56 showed the rearrangement of
-actinin in the absence of phosphotyrosine proteins (data not
shown). In contrast, EPEC strain E2348/69 showed rearrangement of both
phosphotyrosine proteins and -actinin at sites of bacterial
attachment (data not shown). These results indicate that the
rearrangement of cytoskeletal elements, including -actinin, can
occur in STEC O157:H7-infected cells in the absence of detectable
tyrosine phosphorylation.
| |
DISCUSSION |
STEC strains of multiple serotypes (including O157:H7) induce
the activation of intracellular second messenger molecules, including
inositol triphosphate and intracellular calcium, in infected eukaryotic
cells in tissue culture (15). Many STEC strains are also
able to induce AE lesions consisting of cytoskeletal elements,
including F-actin and -actinin, in infected host epithelial cells
(10, 26). When examined by indirect immunofluorescence microscopy, STEC O157:H7 strains do not induce the tyrosine
phosphorylation of host cell proteins (15) that is evident
following EPEC infection (30).
In this study, we have shown that, by infecting tissue culture cells
with both an EPEC eae-deficient mutant (strain CVD206) and
an O157:H7 strain, the rearrangement of phosphotyrosine proteins could then be detected in the AE lesions underneath adherent STEC O157:H7. The accumulation of tyrosine-phosphorylated proteins was
underneath STEC O157:H7, and not CVD206, because the latter strain
lacks the functional outer membrane protein, intimin, required for
reorganizing cytoskeletal and phosphotyrosine elements (30). The finding that an eae mutant of STEC (strain CL8KO1)
employed in a coinfection experiment with CVD206 did not lead to the
organized accumulation of tyrosine-phosphorylated proteins also
indicates that the proteins detected are underneath adherent
STEC O157:H7 and not CVD206. Neither the espB
mutant, strain UMD864, nor the laboratory E. coli strain was
able to induce tyrosine-phosphorylated proteins under adherent
wild-type STEC O157:H7. The tyrosine phosphorylation observed under
the adherent STEC did not occur when a STEC O157:H7 counterpart of
CVD206, strain CL8KO1, was used in the coinfection experiments.
It has not been possible to induce the phosphotyrosine response or
upregulate internalization properties of STEC O157:H7 by using
concentrated supernatants prepared from wild-type EPEC. Kenny and
Finlay (20) have also reported that soluble EPEC-secreted proteins alone do not induce tyrosine phosphorylation of eukaryotic cells. Filtered bacterial sonicates and outer membrane preparations of
EPEC also fail to mediate phosphotyrosine responses in HEp-2 cells
infected with STEC. Taken together, these findings indicate that
contact of the intact bacterium likely is required for the induction of
signal transduction responses. It is also possible that the signaling
proteins have a short half-life, thereby requiring the presence of
actively secreting bacteria (27). These observations are
comparable to those described for Yersinia species in which the action of YopE on host cells is contact dependent (32).
Rosenshine et al. (30) showed that the ability of EPEC
strain E2348/69 to induce internalization into nonphagocytic cells is
dependent on the prior phosphorylation of host cell proteins at
tyrosine residues. Mutants unable to induce tyrosine phosphorylation of
host cell proteins do not invade the cytosol of eukaryotic cells
(30). STEC O157:H7 strains are normally considered to be
noninvasive (6, 26, 34). As a result, we speculated that
STEC O157:H7 strains are not internalized because they do not
induce tyrosine phosphorylation of eukaryotic proteins. Therefore, the
internalization of STEC O157:H7 following coincubation with CVD206
was determined. Coinfection with CVD206 led to an increase in the
internalization of STEC O157:H7 into HEp-2 cells. Similar to
the phosphotyrosine responses, increases in internalization were
specifically related to factors provided by strain CVD206 because
coinfection with either the espB mutant or a laboratory E. coli strain did not mediate an increase in the
internalization of STEC O157:H7 into tissue culture cells. The
upregulation in internalization of STEC O157:H7 was not simply a
nonspecific effect of bacterial coinfection since an increase in the
internalization of CVD206 did not occur. The upregulation of
internalization observed with STEC O157:H7 in this study is
comparable to previous findings with EPEC in which the invasion of
mutants deficient in a secreted protein, either EspA or EspB, is
enhanced upon coinfection with the eae deletion mutant
CVD206 (13, 21).
Although there is no detectable difference in the secretion of EspA and
EspB proteins by the STEC strains employed in this study, including
serotype O113:H21 strain CL15 (14a), it is possible, of
course, that the proteins secreted by STEC have different structural or
functional properties than EspA and EspB derived from EPEC. Indeed,
Ebel et al. (12) reported the presence of a stretch of 18 amino acids in the N terminus of EspB derived from EPEC which is not
highly conserved in the EspB of STEC of serogroup O26. Furthermore,
this amino acid sequence is similar to that present in internalin A, an
outer membrane protein essential for the invasion of Listeria
monocytogenes in vitro (14). More recently, Abe et al.
(1) reported that EspBs of RDEC-1 and STEC (serogroups O157 and O26) have conserved deletions in the C terminus, which are not
found in the EspB of EPEC O127. Furthermore, the ability of RDEC-1 to
be internalized into HeLa cells was enhanced when it harbored a plasmid
carrying the espB gene derived from EPEC (1). In
the present study, we have shown that STEC O157:H7 can also be
induced to be internalized into HEp-2 cells when coincubated with
an EPEC strain capable of secreting a wild-type EspB protein.
The increase in internalization observed for STEC O157:H7 strain
CL56 was the result of a corresponding increase in the adhesion of this
strain upon coincubation with CVD206. This contrasts with the findings
in previous studies with EPEC mutants in which the lack of
internalization could not be accounted for by changes in bacterial
adhesion (21).
In this study, we also have shown that a laboratory E. coli
strain bearing the cloned STEC O157:H7 intimin gene,
JM101(pMH34/pSSS1C), is able to induce AE lesions in HEp-2
cells when they are coinfected with CVD206. Thus,
intiminO157 specified by the plasmid pMH34 is fully
functional for the formation of AE lesions if accessory signals are
provided. This finding indicates that intimin does not require specific
intracellular activation, processing, or other bacterial membrane
proteins in order to reorganize underlying cytoskeletal elements
(27). This conclusion is in agreement with the previous
results showing that JM101 containing the eae gene from EPEC
is able to cause cytoskeletal rearrangement only if preinduced by
CVD206 (31). In addition, the recombinant strain is able to
rearrange phosphotyrosine proteins when coincubated with CVD206.
We also show, for the first time, that STEC strains are able to induce
rearrangement of cytoskeletal proteins in cells infected with
recombinant strain JM101(pMH34/pSSS1C). In contrast to induction of
cytoskeletal assembly, however, STEC strains of serotypes O157:H7 and O113:H21 fail to induce detectable rearrangement of phosphotyrosine proteins. Therefore, while the signaling for cytoskeletal elements provided by STEC is functionally homologous to that provided by EPEC,
it likely does not occur via a protein tyrosine kinase-mediated pathway.
By employing double immunofluorescence labeling techniques in the
present study, we have confirmed and extended earlier findings indicating that rearrangements of cytoskeletal proteins, including F-actin and -actinin, occur independently of detectable
tyrosine-phosphorylated proteins in STEC O157:H7-infected eukaryotic
cells. These results are in agreement with a recent report by
Rabinowitz et al. (29) showing AE lesion formation by an
EPEC strain in the absence of detectable tyrosine-phosphorylated
proteins. In addition, this strain also failed to secrete into culture
supernatants detectable levels of the proteins currently implicated in
the generation of signal transduction responses to EPEC infection,
including EspA and EspB (29). Taken together, these
findings indicate that the rearrangement of cytoskeletal proteins
following STEC O157:H7 infection can occur by novel signal
transduction mechanisms that are not dependent upon prior
phosphorylation of host cell proteins at tyrosine residues. This
contrasts with a proposed model for signal transduction by EPEC in
which the cytoskeletal rearrangement is dependent on the upstream
activation of host protein tyrosine kinases (31). Therefore,
these findings suggest that STEC O157:H7 induces cytoskeletal
reorganization and the formation of AE lesions by signal transduction
mechanisms that are distinct from those that have been described to
date with AE EPEC strains.
| |
ACKNOWLEDGMENTS |
A.I. is the recipient of an Ontario Graduate Scholarship. This
work was supported by grants from the Medical Research Council of
Canada and an A. C. Finkelstein award.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Division of
Gastroenterology and Nutrition (Room 8411), The Hospital for Sick
Children, 555 University Ave., Toronto, Ontario, Canada M5G 1X8. Phone: (416) 813-6185. Fax: (416) 813-6531. E-mail:
sherman{at}sickkids.on.ca.
Editor: P. E. Orndorff
| |
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Infect Immun, April 1998, p. 1688-1696, Vol. 66, No. 4
0019-9567/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
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Top
Abstract
Introduction
