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Journal of Bacteriology, May 2001, p. 2823-2833, Vol. 183, No. 9
0021-9193/01/$04.00+0 DOI: 10.1128/JB.183.9.2823-2833.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
Transcriptional Regulation of the orf19 Gene and the
tir-cesT-eae Operon of Enteropathogenic
Escherichia coli
Claudia
Sánchez-SanMartín,
Víctor H.
Bustamante,
Edmundo
Calva, and
José Luis
Puente*
Departamento de Microbiología
Molecular, Instituto de Biotecnología, Universidad Nacional
Autónoma de México, Cuernavaca, Morelos 62251, México
Received 22 August 2000/Accepted 19 February 2001
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ABSTRACT |
To establish an intimate interaction with the host epithelial cell
surface, enteropathogenic Escherichia coli (EPEC) produces Tir, a bacterial protein that upon translocation and insertion into the
epithelial cell membrane constitutes the receptor for intimin. The
tir gene is encoded by the locus for enterocyte effacement (LEE), where it is flanked upstream by orf19 and downstream
by the cesT and eae genes. With the use of a
series of cat transcriptional fusions and primer extension
analysis, we confirmed that tir, cesT, and eae
form the LEE5 operon, which is under the control of a
promoter located upstream from tir, and found that the
orf19 gene is transcribed as a monocistronic unit. We also
demonstrated that the LEE-encoded regulator Ler was required for
efficient activation of both the tir and the
orf19 promoters and that a sequence motif located between
positions 
204 and 157 was needed for the Ler-dependent activation
of the tir operon. Sequence elements located between
positions 204 and 97 were determined to be required for the
differential negative modulatory effects exerted by unknown regulatory
factors under specific growth conditions. Upon deletion of the upstream
sequences, the tir promoter was fully active even in the
absence of Ler, indicating that tir expression is subject to a repression mechanism that is counteracted by this regulatory protein. However, its full activation was still repressed by growth in
rich medium or at 25°C, suggesting that negative regulation also
occurs at or downstream of the promoter. Expression of
orf19, but not of the tir operon, became Ler
independent in an hns mutant strain, suggesting that Ler
overcomes the repression exerted by H-NS (histone-like nucleoid
structuring protein) on this gene.
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INTRODUCTION |
Enteropathogenic Escherichia
coli (EPEC) is a major cause of acute and persistent infantile
diarrhea and a leading cause of infant death in developing countries
(35, 43, 45). The interaction of EPEC with the host cell,
which has been the subject of several recent reports, has been divided
into three different stages characterized by two distinctive
phenotypes, localized adherence and the attaching-and-effacing (A/E)
lesion (reviewed in references 9, 11, 18, and 43). The
virulence determinants required for the induction of the A/E lesion in
EPEC are encoded in a 35.6-kb pathogenicity island, denoted LEE (for
locus of enterocyte effacement), which contains 41 predicted open
reading frames (16, 38, 39). Based on recent studies and
sequence analyses, most of the LEE-encoded genes have been divided into
three functional regions: the esc and sep genes,
which code for a type III secretion-translocation apparatus
(25); the tir, cesT, and eae genes,
coding for the proteins involved in intimate attachment (1, 14,
26, 28); and the esp genes, which encode effector
proteins that are involved in the formation of a translocon for
delivering effector molecules to the host cell (17, 29, 30, 32,
33, 51).
Recent studies have indicated that the LEE-encoded genes are organized
into five major operons (14, 41): the LEE1,
LEE2, and LEE3 operons, which contain the
esc and sep genes; the LEE4 operon,
which encodes secreted Esp proteins; and the tir, cesT, and
eae cluster, herein denoted LEE5. Ler acts as a
positive transcriptional regulator of the LEE2, LEE3, LEE4,
and LEE5 operons (5, 19, 41). Furthermore,
integration host factor (IHF) (19) and a quorum-sensing
autoinducer (LuxS) (47) are also required for efficient
activation of the LEE-encoded genes. In addition, it has been proposed
that Ler overcomes the negative regulation exerted by H-NS
(histone-like nucleoid structuring protein) on the expression of at
least the LEE2, LEE3, and LEE4 operons
(5).
We studied the transcriptional organization and regulation of the
orf19, tir, cesT, and eae genes of EPEC. The
tir gene codes for Tir (translocated intimin receptor),
which is transferred by the type III secretion system into host cells,
where it is phosphorylated and inserted into the host cell membrane
(28). Tir is the receptor for intimin, an
eae-encoded outer membrane protein necessary for intimate
attachment to epithelial cells (26). cesT,
previously known as orfU, codes for a chaperone that is
required for the stable secretion of Tir (1, 14). The
orf19 gene encodes a protein that exhibits similarity to
IpgB of Shigella flexneri (16) and to TrcA and
TrcP of EPEC (48, 50). In the present study we have
demonstrated that tir, cesT, and eae constitute
an operon and that orf19 is a monocistronic unit. We show
that transcription of the tir operon and the
orf19 gene requires Ler, which seems to overcome the
negative regulation exerted by a repressor protein that is also present
in E. coli K-12. In addition, we show that distinct
cis-acting elements are involved in negative and positive
regulation of tir expression by different regulatory
elements and environmental cues.
(A preliminary account of this work was presented at the 99th General
Meeting of the American Society for Microbiology, Chicago, Ill.,
30 May to 3 June 1999 [C. Sanchez-SanMartín, M. G. Sosa, V. H. Bustamante, E. Calva, and J. L. Puente, Abstr.
99th Gen. Meet. Am. Soc. Microbiol., abstr. B/D-227, p. 74, 1999].)
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MATERIALS AND METHODS |
Bacterial strains, plasmids, and growth conditions.
Strains
and plasmids used in this study are listed in Table
1. Overnight cultures were grown at
37°C in Luria-Bertani (LB) broth medium (46).
Dulbecco's modified Eagle's medium (DMEM) containing 0.45% (wt/vol)
glucose and L-glutamine (584 mg/l) without sodium pyruvate
(Gibco Life Technologies) and supplemented with pyridoxal (4 µg/ml)
was used for growth at 37°C. Where indicated, 20 mM ammonium sulfate
was added. An overnight LB culture was pelleted, and the bacteria were
resuspended in phosphate-buffered saline, pH 7.4, to an optical density
at 600 nm (OD600) of 1. Fifty milliliters of DMEM or LB was
inoculated with 1 ml of the bacterial phosphate-buffered saline
suspension and incubated in an orbital shaker water bath (Amerex
Instruments) at 200 rpm and various temperatures. When necessary,
antibiotics were added at the following concentrations: ampicillin, 100 µg/ml; nalidixic acid, 15 µg/ml, kanamycin, 40 µg/ml,
chloramphenicol, 50 µg/ml, gentamicin, 15 µg/ml; and tetracycline,
25 µg/ml. Samples were collected every hour, or when the cultures
reached OD600s of 0.8, 1.0, 1.2, and 1.4, to determine
chloramphenicol acetyltransferase (CAT) activity or for RNA extraction.
Molecular biology techniques.
DNA manipulations were
performed according to standard protocols (46).
Restriction and DNA-modifying enzymes were obtained from Boehringer
Mannheim, New England Biolabs, or Gibco BRL and used according to the
manufacturer's instructions. [
-32P]dCTP (3,000 Ci
mmol
1) was purchased from Amersham Corp. Oligonucleotides
were purchased from BioSynthesis or provided by the Oligonucleotide
Synthesis Facility at our institute. PCRs were performed in 100- or
50-µl volumes, with AmpliTaq (Perkin-Elmer) being used according to the manufacturer's instructions. Double-stranded DNA sequencing of the
plasmids generated in this work was carried out by the dideoxy-chain
termination procedure with a Thermo Sequenase cycle sequencing kit
according to the manufacturer's (Amersham) instructions.
Construction of cat transcriptional fusions.
PCR
fragments of different lengths that spanned the region between
orf19 and eae were amplified using as a template
chromosomal DNA from wild-type EPEC strain E2348/69. The forward and
reverse oligonucleotides were designed to introduce BamHI or
HindIII restriction sites, respectively (Table
2). The PCR-amplified fragments were digested with BamHI and HindIII and cloned
into pKK232-8, a vector, digested with the same enzymes, containing a
promoterless CAT gene (cat) (Pharmacia LKB Biotechnology).
Each ligation reaction product was electroporated into E. coli MC4100, after which ampicillin-resistant colonies were
selected. The resulting plasmids (Table 1) were sequenced to confirm
the fidelity of the PCR amplification and introduced into different
strains by electroporation, using a Gene Pulser apparatus (Bio-Rad) at
settings of 2.5 kV, 25 µF, and 200 
, or by CaCl2
transformation according to standard protocols (46).
Mutagenesis of the 10 promoter sequence.
Oligonucleotide
CAM10tirR plus pKKampi and oligonucleotide CAM10tirF plus pKKcat (Table
2) were used to amplify two fragments encompassing the tir
regulatory region contained in pTIREAE. Oligonucleotides CAM10tirR and
-F introduce a SacI restriction site that replaces the 10
promoter hexamer. Both fragments were digested with SacI and
with either BamHI (left fragment) or HindIII
(right fragment) and cloned into pKK232-8 digested with
BamHI and HindIII, creating pTIRCAM-10. The
insert in this plasmid was sequenced to verify that only the 10
hexamer sequence was modified.
RNA isolation and primer extension analysis.
Total bacterial
RNA from samples obtained from DMEM or LB cultures was isolated using a
commercial kit (RNeasy [Qiagen] or Boehringer Mannheim High Pure RNA
isolation kit). End-labeled oligonucleotides complementary to the 5'
end of the cat structural gene or the tir, cesT,
eae, or orf19 structural gene were used for primer
extension reactions as previously described (5, 37). The
extended products were purified with a Microcon-10 microconcentrator
(Amicon) and analyzed by electrophoresis in 8% polyacrylamide-urea
gels. Primer extension using a 16S rRNA-specific oligonucleotide was
included as a control to monitor RNA quality and loading concentration.
Sequence ladders were generated with the same primers and DNA of the
different pKK232-8 derivatives or plasmids carrying the genes being
studied in this work.
CAT assay.
The CAT assay was performed as described
previously (5, 37, 44).
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RESULTS |
Transcriptional organization of the orf19, tir,
cesT, and eae genes.
The start codon of
tir is located 326 bp downstream from the stop codon of
orf19, while the tir-cesT and cesT-eae
intergenic regions consist of 137 and 63 bp, respectively (Fig.
1). To confirm and further analyze the
transcriptional organization of the orf19, tir, cesT, and
eae genes and to identify intergenic regions with promoter
activity, a series of transcriptional fusions to the cat
reporter gene was constructed (Fig. 1). These plasmids were transformed
into EPEC wild-type strains E2348/69 and B171-8, and CAT activity
directed by each fusion was determined from samples collected from
cultures grown in DMEM at 37°C, conditions that induce expression of
different virulence factors in EPEC (5, 27, 37, 44). The
fusions carried by plasmids pTIR394, pTIREAE, and pTIREAE-DEL1, which
all contain the 5' upstream region of tir, expressed
significant levels of CAT (Fig. 1). In contrast, fusions pEAE1800,
pEAE1629, pEAE1422, and pEAE520, which contain different lengths of the
region upstream from the eae start codon but lack the
tir promoter region, expressed only background levels of CAT
activity (Fig. 1 and data not shown). These results confirmed that
tir, cesT, and eae constitute an operon that is
expressed under the control of a promoter located upstream of
tir and indicated that eae does not have an
independent promoter.
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FIG. 1.
tir, cesT, and eae constitute an
operon. (A) Schematic representation of the organization of the
orf19, tir, cesT, and eae genes and of the
transcriptional fusions constructed to study their regulation. The
horizontal arrows indicate the direction of transcription. Bent-tailed
arrows denote the transcriptional start sites identified in this work
(see the text). The sizes (in base pairs) of the intergenic regions are
shown below the thick horizontal line. Plasmid denominations are
indicated in the left-hand column below. The fragments cloned into the
promoterless cat gene vector pKK232-8 are denoted by solid
lines, and the cat gene is indicated by an open box at the
end of each fragment. The 10/SacI label indicates the presence of a
mutation that replaced the putative tir 10 promoter
hexamer by a SacI restriction site. The right-hand column
shows the CAT activity expressed by each fusion in EPEC E2348/69 grown
in DMEM at 37°C. The data obtained for EPEC B171-8 are not shown, for
simplicity, but rendered the same conclusions. The CAT specific
activity was determined from cells harvested at an OD600 of
1.4. The results reported are the averages ± standard deviations
of data from at least four different experiments.
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To confirm that the
eae gene is transcribed from the
tir promoter, the putative
10 hexamer (see below) was
replaced by the
CTCGAG sequence in pTIREAE, as described in
Materials and Methods,
generating pTIRCAM-10. As expected, this fusion
did not express
CAT (Fig.
1). Fusion plasmid pORF19, which contains 308 bp upstream
from the translational start codon of
orf19, was
active (Fig.
1), indicating that this gene is transcribed from its own
promoter.
A fusion containing just the
tir-cesT intergenic region
(pCEST) rendered activity levels that suggested the existence of an
additional active promoter for the
cesT gene (Fig.
1).
However,
fusions pEAE1800, pEAE1629, and pEAE1422, containing the
tir-cesT and
cesT-eae intergenic regions, were
inactive (Fig.
1), suggesting
a role for the
cesT-eae
intergenic region in terminating transcription
originating at the
cesT putative promoter. To further analyze
this possibility,
the
cesT-eae intergenic region was cloned into
pCEST to
generate plasmid pCEST-EXT-EAE (see Materials and Methods).
In this
case, no activity was detected (data not shown). When
this region was
deleted from the inactive fusions carried by plasmids
pEAE1629 and
pTIRCAM-10, thus recreating the pCEST fusion and
generating
pTIRCAM-10-DEL1 (which lacks a functional
tir promoter),
respectively, the
cesT transcriptional activity was
recovered
(Fig.
1).
Two transcriptional start sites were identified for the putative
cesT promoter when primer extension experiments were
performed
with total RNA of EPEC E2348/69 carrying either pCEST,
pEAE1629,
or pTIRCAM-10 fusions (Fig.
2C). These results confirmed the
existence
of active
cesT promoters in these fusions and
suggested that the
eae upstream region contains elements
involved in terminating
transcription originating from the
cesT promoter.
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FIG. 2.
Primer extension analysis of the tir, orf19,
and cesT promoter regions. (A) Total RNA was obtained from
culture samples of strains EPEC E2348/69 wild type (lane 1), JPN15
(pEAF cured) (lane 2), EPEC E2348/69 ler (lane 3), and
EPEC E2348/69ler carrying pKORF1 (lane 4) growing in DMEM
at 37°C (OD600 = 0.8). A primer specific for the
tir structural gene was used, and primer extension was
performed as described in Materials and Methods. A primer extension
assay using a primer specific for the 16S rRNA gene was performed as a
control. (B) Primer extension analysis was performed as described for
panel A but with a primer specific for the orf19 structural
gene. (C) Total RNA from EPEC E2348/69 carrying pCEST
(cesT-cat fusion) and a cat-specific primer were
used for primer extension reactions. The upper and bottom panels show
the two extended products. Lanes G, A, T, and C correspond to the DNA
sequence ladder obtained with the corresponding primer. The sequences
spanning the transcription start site are shown, and the transcription
start sites (in bold) are marked with arrows.
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Determination of the transcriptional start sites of the
orf19 and tir genes.
The potential
transcriptional activity from the 5' upstream regions of the four genes
considered for this study was tested by primer extension analysis (Fig.
2 and data not shown). A transcriptional start site corresponding to a
T residue was located 85 bp upstream from the translational start codon
of tir (Fig. 2A), one base further downstream from where it
was previously mapped (14).
Examination of the 5' upstream region revealed the presence of putative
35 (TTGCAT) and
10 (TTTATT) promoter
sequences (Fig.
3A). When the putative
10 promoter sequence was replaced by the
CTCGAG sequence,
fusions carrying this mutation became inactive
(Fig.
1), indicating
that this sequence motif was essential for
transcriptional activation
of the
tir operon. An additional transcriptional
start site
for
tir, corresponding to a T residue, was identified
24 bp
upstream from the first reported site (Fig.
2A); however,
the relevance
of this weaker potential promoter is unknown. A
transcriptional start
site was also identified for
orf19, on an
A residue located
133 bp upstream from its translational start
codon (Fig.
2B). Analysis
of its 5' upstream region revealed the
presence of putative
35
(TTGCAT) and
10 (ATAAAT) promoter sequences
(Fig.
3B). In contrast, no transcriptional start site was observed
for
the chromosomal
cesT and
eae genes under the
conditions tested.
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FIG. 3.
Nucleotide sequences of the orf19-tir (A),
rorf10-orf19 (r, reverse) (B), and
tir-cesT (C) intergenic regions. The transcriptional start
sites (+1) are indicated by the bent-tailed open-headed arrows. The
bent-tailed filled-head arrows indicate the 5' ends of the different
tir-cat fusions. The predicted 10 and 35 promoter
sequences are underlined. The sequences containing motifs potentially
involved in Ler activation and ammonium-dependent repression, in
negative regulation by an as-yet-unidentified repressor, and in
repression at high temperature are indicated by solid, broken, and
dotted underlines, respectively.
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Ler is required for transcriptional activation of tir
and orf19.
As described above, tir-cat
fusions were active in two different EPEC wild-type strains (Fig. 1).
However, when plasmid pTIR394, carrying the tir-cat fusion,
was transformed into E. coli MC4100 (a K-12 derivative
laboratory strain), its transcriptional activity was reduced (Fig.
4A), indicating that full expression of
the tir operon required a regulatory factor that was present
only in wild-type EPEC. To identify the activator(s) involved in
tir expression, we first examined the potential role of the
EAF plasmid by transforming pTIR394 into EPEC strains JPN15 and B171-10
(pEAF-minus derivatives of EPEC wild-type strains E2348/69 and B171-8,
respectively) (Table 1). Expression of the tir-cat fusion in
the plasmid-cured strains rendered levels of CAT activity similar to
those obtained in the wild-type strains (Fig. 4A and data not shown),
indicating that the transcriptional activation of tir was
independent of the EAF plasmid. This observation was confirmed by
determining that the transcriptional activities of the chromosomal
tir promoters of wild-type EPEC and its pEAF-minus
derivative were similar when compared by primer extension (Fig. 2A,
lanes 1 and 2).
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FIG. 4.
Expression of tir requires the Ler protein.
(A) The transcriptional activity directed by the tir-cat
fusion in pTIR394 and the bfpA-cat fusion contained in
pCAT232 was tested in EPEC strains E2348/69 (wild type), JPN15 (an
EAF-minus derivative), and ler (a ler in-frame
deletion mutant of E2348/69) carrying or not carrying pKORF1
(ler+), as well as in E. coli K-12
strain MC4100 (wild type) carrying or not carrying either pKORF1
(ler+) or pCS-TVW
(per/bfpTVW+). The CAT specific
activity was determined from cells grown in DMEM at 37°C and
harvested at an OD600 of 1.4. The data are the averages of
results from at least three different experiments. Error bars indicate
standard deviations. (B) Primer extension analysis of the
tir-cat fusion in pTIR394 was carried out with total RNA
extracted from samples obtained at an OD600 of 0.8 from the
cultures described above. The primer extension reactions were performed
as described in the legend to Fig. 2, using a primer specific for
cat. The arrow on the left indicates the transcriptional
start site of tir-cat.
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It has been shown that the product of the
ler gene
(previously known as
orf1) is a positive regulator of the
expression of
sepZ and
orf12, two genes also
located in the LEE (
5,
41).
This observation prompted us
to investigate the role of Ler in
tir expression by
performing primer extension experiments with
total RNA obtained from
DMEM cultures of an EPEC
ler strain which
carries an
in-frame deletion of
ler (
5). Expression of
tir was considerably reduced in this mutant, while
complementation
with
ler on a plasmid restored its
expression (Fig.
2A, lanes
3 and 4). In agreement with these results,
the activity directed
by the
tir-cat fusion (pTIR394) was
reduced about 10-fold in the
ler mutant strain, while its
activation was restored and enhanced
by supplementing
ler in
trans with plasmid pKORF1 (Fig.
4A). Furthermore,
activation
was restored in
E. coli MC4100 when supplemented with
pKORF1, but not with a plasmid carrying the entire
per locus
(pCS-TVW),
which, in contrast, complemented the expression of the
bfpA-cat fusion that was used as a control (Fig.
4A).
Consistent with these results, primer extension analysis revealed that
Ler-dependent activation of the
tir-cat fusion in pTIR394
was directed by the same putative promoter predicted for the wild-type
gene (Fig.
4B). Similar experiments, using the same set of strains
carrying the pORF19 fusion, revealed that
orf19 expression
also
required a functional
ler gene (Fig.
2B; see also Fig.
7A). Taken
together, these results indicated that Ler was required for
the
positive regulation of
tir and
orf19 expression.
Analysis of the tir promoter region.
To define the
minimal regulatory sequence required for tir expression, a
series of fusions containing segments of the tir 5' promoter
region ranging from 394 to 22 bp in length, with respect to the
transcriptional start site (Fig. 3 and
5), was constructed. Fusions containing
sequences up to position 204 (pTIR204) or longer were found to
express similar amounts of CAT in EPEC E2348/69 (Fig. 5A). However,
fusions to position 157 (pTIR157) or 122 (pTIR122) showed a
significant reduction of CAT activity compared with that obtained with
pTIR394 (Fig. 5A). Fusions containing up to position 97, 80, or
45 (pTIR97, pTIR80, and pTIR45, respectively) expressed a twofold
increase in CAT activity in comparison to that obtained with pTIR394
(Fig. 5A). As expected, a fusion containing up to position 22 which
lacks the putative 35 promoter hexamer did not express CAT.
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FIG. 5.
cis-acting elements involved in
tir expression. (A) Schematic representation of the
tir regulatory region and tir-cat fusions.
Numbering is relative to the transcription start site, which is
indicated by a bent-tailed arrow. Regions containing sequences
potentially involved in Ler-dependent activation (subdivided boxes) or
in negative regulation (shaded boxes) are indicated. EPEC strains
E2348/69 and E2348/69ler, as well as E. coli
MC4100, were transformed with different tir-cat fusions
contained in plasmids pTIR394, pTIR243, pTIR204, pTIR157, pTIR122,
pTIR97, pTIR80, pTIR45, and pTIR22. The resulting strains were grown in
DMEM at 37°C, and the CAT specific activity was determined from
samples obtained at an OD600 of 1.4. The plots of the
activities determined from samples obtained along the growth curve at
other OD600 values showed the same pattern. Values are the
averages of data from at least three different experiments; error bars
indicate standard deviations. (B) Total RNA was obtained from EPEC
E2348/69 carrying the tir-cat fusions in pTIR204, pTIR157,
pTIR80, and pTIR45, and primer extension assays were performed as
described in the legend to Fig. 2. The arrow on the left indicates the
transcriptional start site of the tir-cat fusions, which
corresponds to that identified for the wild-type gene.
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In the absence of Ler (in EPEC
ler or
E. coli
MC4100),
tir-cat fusions in pTIR394, pTIR243, and pTIR204
showed only background
levels of
tir promoter activity (Fig.
5A). In the absence of sequence
elements located between positions
157 and
97, activation of
the
tir promoter became Ler
independent (Fig.
5A). These results
suggested that Ler could interact
with a DNA sequence motif located
between positions
204 and
157 and
that this interaction overcame
the repressing effect exerted by a
negative regulatory factor,
also present in
E. coli
K-12, that interacts with sequence elements
located between positions
157 and
97. To rule out the possibility
that an additional promoter
was responsible for the Ler-independent
activity shown by the shorter
fusions, primer extension experiments
were performed with total RNA
obtained from culture samples of
strains EPEC E2348/69, EPEC
ler, and
E. coli MC4100 carrying
fusions
pTIR204, pTIR157, pTIR97, or pTIR45. The resulting primer
extension
products demonstrated that the transcriptional activity
observed for
these fusions was directed by the same promoter predicted
for the
wild-type gene (Fig.
5B and data not
shown).
H-NS represses the expression of orf19 but not
tir.
The experiments described above suggested that
the putative repressor for tir and orf19 was
conserved between EPEC and E. coli K-12. To identify
putative repressors, different E. coli K-12-derived strains
carrying mutations in well-characterized genes coding for global
regulators were transformed with fusion plasmids pORF19 and pTIR394.
Only background levels of CAT activity were obtained for both fusions
in strains carrying mutations in the genes coding for LRP
(leucine-responsive regulatory protein), IHF (integration host
factor), Fis (factor for inversion stimulation), StpA (suppressor of
td phenotype A), factor, FIS, StpA,
RpoN, RpoS, and OmpR as well as in their corresponding parental strains
(Table 1 and data not shown). In contrast, expression of the
orf19-cat fusion resulted in a 25-fold increase in CAT
activity in E. coli CSH56 hns (470 ± 36 CAT units [mean ± standard deviation]) in comparison with its
parental strain, CSH56 (18 ± 5 CAT units). Repression was restored when a plasmid carrying the hns gene was introduced
into CSH56 hns/pORF19 (11 ± 7 CAT units). The
absence of H-NS did not have any effect on expression of the
tir-cat fusion.
Regulation of tir and orf19 expression in
response to environmental conditions.
Expression and secretion of
different virulence factors in EPEC are optimal in tissue culture
medium (DMEM) at 37°C and are negatively regulated in response to
growth in a rich medium such as LB at temperatures above or below
37°C or in the presence of ammonium salts (4, 5, 27, 37,
44). To determine whether tir expression was
modulated by changing the growth conditions, EPEC E2348/69 carrying
plasmid pTIR394 was grown in DMEM at 37°C, in LB at 37°C, in DMEM
containing 20 mM ammonium sulfate at 37°C, and in DMEM at 25°C and
40°C, as described previously (44). tir
expression was significantly reduced by growth in LB or in DMEM
containing ammonium, as well as by growth at temperatures above or
below 37°C (Fig. 6).
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FIG. 6.
Effect of the growth medium, the presence of ammonium,
and temperature on tir expression. EPEC E2348/69 derivatives
carrying the tir-cat fusions described in the legend to Fig.
5 were grown at 37°C in DMEM, DMEM plus 20 mM ammonium sulfate, or LB
(A) or in DMEM at 37, 25, or 40°C (B). CAT specific activities from
samples obtained at an OD600 of 1.4 were determined and
plotted. The plots of the activities determined from samples obtained
along the growth curve at other OD600 values showed the
same pattern. Values are the averages of data from at least three
different experiments; error bars indicate standard deviations.
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When the same experiment was carried out with EPEC E2348/69 carrying
the shorter
tir-cat transcriptional fusions, it was observed
that growth in LB (Fig.
6A) and in DMEM at 25°C (Fig.
6B) resulted
in
negative modulation of the expression of all the active fusions
(pTIR243 to pTIR45). This indicated that repression under these
conditions acts on or downstream of the promoter. In contrast,
the
repression mediated by the presence of ammonium or by growth
at 40°C
was observed only for fusions containing the sequence
between positions
204 and
157 (Fig.
6A) or between positions
157 and
122 (Fig.
6B), respectively. These observations suggested
that
tir
expression is subjected to different levels of negative
regulation,
probably involving one or more factors that act on
different
segments of the
tir regulatory region. In addition,
CAT
activity assays of samples obtained from cultures of EPEC
E2348/69/pORF19 grown under the conditions described
above revealed
that expression of
orf19 is regulated
coordinately with the expression
of the
tir operon (Fig.
7B) and suggested that Orf19 plays an
important role in EPEC pathogenesis.
View larger version (35K):
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|
FIG. 7.
Regulation of orf19. (A) Expression of
orf19 requires the Ler protein. The transcriptional activity
directed by the orf19-cat fusion in pORF19 was tested in
different strains as described in the legend to Fig. 4A. (B) Effect of
the growth medium, the presence of ammonium, and temperature on
orf19 expression. EPEC E2348/69 carrying the
orf19-cat fusion (pORF19) was grown under different
conditions to determine CAT activity, as described in the legend to
Fig. 6.
|
|
| |
DISCUSSION |
In this work, we studied the regulation of the
tir-cesT-eae operon (henceforth referred as the
LEE5 operon), whose expression is directed by a promoter
located upstream of the tir gene (Fig. 1 to 3). Recently, it
was reported that these genes are expressed in the same transcript,
which initiates 86 nucleotides (nt) upstream of the tir
start codon (14), one base upstream from where the transcriptional start site was determined to be located (Fig. 3A). The
existence of an eae transcriptional start site located inside the structural cesT gene was previously proposed
(21). However, neither fusions carrying different
fragments of the eae upstream region (pEAE1800, pEAE1629,
pEAE1422, and pEAE520) nor a tir-eae-cat fusion (pTIRCAM-10)
carrying a mutation in the 10 tir promoter sequence
demonstrated promoter activity (Fig. 1). Different attempts to define a
transcriptional start site for eae by primer extension
rendered only a variable ladder of undefined reverse transcription
products (data not shown). We cannot rule out the possibility that
additional promoters allow the differential expression of the
components of the LEE5 operon under different conditions.
However, our initial data suggest that the observed eae
primer extension products could be the result of posttranscriptional mRNA processing events.
A transcriptional start site for cesT has been reported
(14). Consistent with this observation,
cesT-cat fusions carrying sequences of the upstream region
of cesT without the tir promoter (pCEST and
pTIRCAM-10-DEL1) directed the expression of significant levels of CAT
activity (Fig. 1). Primer extension experiments with the
cat-specific primer revealed two different transcriptional start sites (Fig. 2C). The first transcriptional start site was located
15 nt upstream of the cesT start codon and allowed the prediction of a good putative 10 (TATTAT) promoter
sequence and a poor 35 (TGGGTA) hexamer. The sequence
preceding the second start site did not show any homology with known
promoter sequences (Fig. 3C). Because of its weak activity, we were
unable to detect primer extension products derived from the transcript
of the chromosomal cesT gene. This Ler-independent promoter
activity does not seem to read through the eae gene, since
the presence of the cesT-eae intergenic region rendered
fusions inactive (compare pTIRCAM-10 with pTIRCAM-10-DEL1 and pEAE1422
with pCEST [Fig. 1]). These results suggest that
Ptir-initiated transcription may be
antiterminated while PcesT-initiated
transcription is not. Further detailed analysis is required to
establish the significance of these observations; however, it is
tempting to speculate that the independent expression of
cesT may ensure the presence of the chaperone when Tir is
translated or that CesT has additional, as-yet-undefined functions.
Two major mechanisms regulate virulence gene expression in EPEC
(5, 15, 19, 21, 41, 49). One involves a classical activator (PerA/BfpT) that is fully required for the activation of the
bfpA and perA (bfpT) promoters
(37, 49). per is also proposed to be involved
in the modulation of eae expression (21), protein secretion (27), the down-regulation of intimin
during A/E adhesion (31), and the direct activation of the
LEE1 operon, which encodes the ler gene
(41). The other involves an antagonist protein (Ler)
(19, 41, 47) that is required to overcome the repression
exerted by negative regulators on the expression of several LEE-encoded
genes, which is directed by promoters that in the absence of upstream
regulatory elements are constitutively expressed (5). Ler
seems to act as a master key which modulates the expression of
different virulence factors that allow the intimate colonization of the
proximal small intestine and the generation of A/E lesions by EPEC.
Based on these observations, we analyzed the role of the ler
and per (bfpTVW)-encoded products in
LEE5 and orf19 expression. Ler was needed for the
efficient expression of both the LEE5 operon and the
orf19 gene (Fig. 2 and 4 and data not shown). In contrast,
wild-type EPEC, its EAF-cured derivative, and a per mutant
strain did not show significant differences in their expression (Fig. 2
and 4 and data not shown). Hence, the LEE5 operon and the
orf19 gene are part of the Ler regulon.
Deletion analysis of the LEE5 upstream regulatory region
indicated that nucleotides up to position 45, which include only the
tir promoter, were sufficient for maximal activation even in
the absence of Ler (Fig. 5). Full activation was maintained with
sequences up to position 97, but not with sequences up to position
122 or 157, which sustained low levels of activation. This
suggested that a sequence motif involved in negative regulation is
located upstream of position 97 and that the negative regulator was
conserved in nonpathogenic E. coli strains. Fusions up to position 204 or longer were activated in a Ler-dependent manner but
only reached intermediate levels of activity with respect to those
directed by the shorter fusions (Fig. 5). This established that
sequences between positions 204 and 157 were necessary for
Ler-dependent activation of the LEE5 promoter, which was
still modulated by a putative negative regulator that probably
interacts with the region between positions 157 and 97.
Ler shows amino acid similarity to the DNA-binding global
transcriptional regulator H-NS and its paralogue, StpA (12, 16, 41). The H-NS protein has been implicated in the negative
regulation of several virulence factors and housekeeping genes
(2). Considering its similarity to H-NS, it is likely that
Ler binds DNA sequences between positions 204 and 157. The H-NS
protein is involved in the negative regulation of the LEE2
and LEE3 operons (5) and the orf19
gene but not LEE5 expression (see Results). Ler might
overcome the repression exerted by H-NS or an unknown factor by
directly or indirectly (e.g., changing the DNA topology) interfering with its binding. However, further work is required to distinguish between these and other possibilities.
Environmental conditions regulate the expression of several virulence
factors in different bacteria, such as Vibrio cholerae, Shigella spp., Yersinia spp., and pathogenic E. coli strains (10, 24, 40). In EPEC, the expression of
virulence factors is also regulated in response to culture conditions
that mimic in vivo regulatory signals (5, 27, 37, 44). We
found that distinct regulatory sequences in the LEE5
promoter region are involved in the regulatory response to these
conditions (Fig. 6). Negative regulation by growth in rich medium or at
temperatures below 37°C involves factors that act directly on the
promoter (Fig. 6). The repression mechanism mediated by temperatures
above 37°C and by the presence of ammonium in the culture medium is
dependent on sequences located upstream from the putative promoter,
between positions 157 and 122 and positions 204 and 157,
respectively (Fig. 6). These motifs overlap with the sequence
presumably required for negative regulation by an unknown factor and
the putative Ler-binding region, respectively (Fig. 3A), suggesting the
existence of different regulatory mechanisms that probably involve
additional trans-acting factors. Neither ammonium nor high
temperature is a common regulatory signal for the regulation of
virulence factors. However, both can be found during transit along the
intestinal lumen, and they may represent signals indicating harmful or
inappropriate niches for colonization (13, 44).
| |
ACKNOWLEDGMENTS |
We particularly thank Susana López, Mario Rocha,
Joaquín Sánchez, and Y. Martínez-Laguna for helpful
discussions. We also thank Martha G. Sosa, Francisco Santana, and
Alejandra Vázquez for technical assistance.
C.S.-S. was supported by a Ph.D. fellowship from the Consejo Nacional
de Ciencia y Tecnología (CONACYT), México (no. 91904), and
from the Universidad Nacional Autónoma de México. This
research was supported by grants from the Consejo Nacional de Ciencia y Tecnología, México (CONACyT 27831-N), and from the
Universidad Nacional Autónoma de México (DGAPA IN206594).
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Departamento de
Microbiología Molecular, Instituto de Biotecnología,
Universidad Nacional Autónoma de México, Apdo. Postal
510-3, Cuernavaca, Morelos 62251, México. Phone: (52) 73 291 621. Fax: (52) 73 138 673. E-mail:
puente{at}ibt.unam.mx.
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Journal of Bacteriology, May 2001, p. 2823-2833, Vol. 183, No. 9
0021-9193/01/$04.00+0 DOI: 10.1128/JB.183.9.2823-2833.2001
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Abstract
Introduction
