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Journal of Bacteriology, January 2001, p. 520-527, Vol. 183, No. 2
0021-9193/01/$04.00+0 DOI: 10.1128/JB.183.2.520-527.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
Negative Control of rpoS Expression
by Phosphoenolpyruvate:Carbohydrate Phosphotransferase System in
Escherichia coli
Chiharu
Ueguchi,1,2,*
Naoko
Misonou,2 and
Takeshi
Mizuno2
Bioscience Center1 and
School of Agriculture,2 Nagoya
University, Chikusa-ku, Nagoya 464-8601, Japan
Received 26 July 2000/Accepted 30 October 2000
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ABSTRACT |
The 
S (or 38) subunit of RNA
polymerase, encoded by the rpoS gene, is a crucial
regulator in the transcriptional control of a set of genes under
stressful conditions, such as nutrient starvation. The expression of
rpoS is regulated in a complex manner at the levels of
transcription, translation, and stability of the product. Although a
number of factors involved in the regulation of rpoS expression have been identified, the underlying molecular mechanisms are not fully understood. In this study, we identified the Crr (or
EIIAGlc) protein as a novel factor that plays an important
role not only in the transcriptional control but also in the
translational control of rpoS expression. Crr is an
important component in glucose uptake through the well-characterized
phosphoenolpyruvate:carbohydrate phosphotransferase system. The results
of a series of genetic analyses revealed that Crr negatively controls
rpoS translation and transcription. The observed
transcriptional control by Crr appears to be mediated by cyclic AMP.
However, it was found that Crr negatively controls rpoS
translation rather directly. These results suggest a possible linkage
between the control of rpoS expression and carbon metabolism.
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INTRODUCTION |
When Escherichia coli
cells are exposed to several stressful conditions preventing rapid
growth, such as nutrient starvation, the expression of a set of genes
is induced to allow the cells to survive under the harsh conditions
(8). The S (or
38) subunit of RNA polymerase, encoded by the
rpoS gene, has been shown to function as a central regulator
in the transcriptional control of such genes (11). Since
the gene expression is, at least, mainly dependent on the cellular
S content, it is important to determine how
S content is regulated during cell growth.
rpoS expression is severely repressed at the logarithmic
growth phase, while it is induced during entry into the stationary phase (5, 23). The regulation is conducted in a complex
manner at the levels of transcription, translation, and stability of S (10). Recent extensive studies
have revealed that several proteinaceous factors as well as small
molecules are involved in the regulation. rpoS transcription
was proposed to be negatively regulated by a cyclic AMP (cAMP) receptor
protein-cAMP complex, based on the fact that
S is significantly accumulated in the
cells of cya and crp mutants (9,
10). Posttranscriptional mechanisms also, and more
importantly under certain conditions, determine the cellular
S content. It has been revealed that an
RNA-binding protein, HF-I, encoded by the hfq gene, and a
nucleoid protein, H-NS, are involved in rpoS translation
positively and negatively, respectively (1, 15, 27). In
rapidly growing cells, S is markedly unstable,
being degraded by an ATP-dependent protease complex, ClpPX
(18). This rapid turnover requires the functions of both
H-NS and RssB (or SprE) (1, 14, 17, 27), the latter
protein belonging to the response regulator family in a two-component
signal transduction system. Although the genes involved in the
regulation of rpoS expression have been identified to some extent, the underlying molecular mechanisms remain to be elucidated. The questions of how cells sense the external and internal growth conditions and how such signals are transduced in the cells and then
regulate rpoS expression through the factors described above have not been answered, in spite of their biological significance.
In this study, we identified the Crr protein as a novel factor that is
crucial for the translational as well as transcriptional control of
rpoS expression. The Crr protein (or
EIIAGlc) is an important component in glucose
uptake in the phosphoenolpyruvate:carbohydrate phosphotransferase
system (PEP:PTS) (16). In this system, the phosphate group
of PEP is transferred through successive phosphorelay reactions
involving enzyme I (EI), histidine protein (HPr), and glucose-specific
enzyme II (EIIGlc), and then extracellular
glucose is phosphorylated by EIIGlc concomitantly
with its uptake. Crr is a cytoplasmic component of
EIIGlc and is known to be crucial not only for
glucose uptake but also for the regulation of several cellular
functions in carbon metabolism, such as inducer exclusion and
modulation of adenylate cyclase activity. We first isolated an E. coli mutant in which the expression of rpoS is
derepressed even at the logarithmic growth phase. The following genetic
analyses revealed that the function of the crr gene is
impaired by a transposon insertion in the mutant, suggesting that Crr
is deeply involved in the negative control of rpoS
expression. In this case, the phosphorylation of Crr is also crucial in
glucose uptake. Crr appears to be involved in both the translational
and the transcriptional control of rpoS expression. We will
discuss the underlying molecular mechanisms and the physiological role of Crr in the control of rpoS.
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MATERIALS AND METHODS |
Bacterial strains and growth conditions.
The bacterial
strains used in this study are listed in Table
1. They are all derivatives of MC4100
(2). Several mutant strains were constructed by P1
transduction (13). Cells were grown at 37°C mainly in
Luria broth (13). An overnight culture was inoculated into
fresh medium, and cells were grown until logarithmic phase, whereupon
the culture was appropriately diluted with fresh medium and further
grown (see Fig. 2) and then used for all experiments at the
mid-logarithmic phase. Antibiotics were added as necessary.
Construction of rpoS-lacZ fusion genes.
rpoS-lacZ fusion genes were constructed essentially by the
method of Hirano et al. (6). The rpoS-lacZ
operon fusion was constructed as follows. A 1.6-kb
ClaI-DraI fragment encompassing rpoS
promoters was purified from pKTF101 (22). After treatment with T4 DNA polymerase, the resultant fragment was inserted into the
previously blunt-ended HindIII site of pMS434HS. An
E. coli strain harboring 
pF13 was transformed with the
resultant plasmid carrying the rpoS-lacZ operon fusion, and
a lambda phage lysate was prepared from the transformant by UV
irradiation. MC4100 was infected with the phage lysate, and then
lysogens were selected from blue plaques on plates containing
5-bromo-4-chloro-3-indolyl-
-D-galactopyranoside (X-Gal) as candidates carrying the fusion gene on the chromosome. The
lysogens thus purified were further scored for the
Lac+ phenotype, and then one such lysogen,
named CH11, was used in this study.
rpoS-lacZ PF977 was constructed as follows. A 2.4-kb
ClaI-
Eco47III fragment encompassing the
rpoS gene lacking the C-terminal
portion, as well as the
promoter region, was first purified from
pKTF101 (
22).
After treatment with T4 DNA polymerase, the fragment
was inserted into
the
HincII site of pUC119 (
25) to construct
the
rpoS-lacZ
protein fusion. From the resultant plasmid, a
2.6-kb
HindIII-
BglI fragment encompassing the
protein fusion was purified
by partial digestion with
BglI
(the
BglI site is located within
lacZ), and
then the fragment was inserted between the
HindIII
and
BglI sites of pMS434HS (the
BglI site corresponds
to the identical
site of the
rpoS-lacZ protein fusion) to
yield pCU71. The resultant
rpoS-lacZ protein fusion,
including the N-terminal 325 codons
of the
rpoS open reading
frame, was named PF977 and subsequently
transferred to the chromosome
of MC4100, as described above.
rpoS-lacZ PF212 was
constructed by means of the same procedures except that
a 1.6-kb
ClaI-
HincII fragment encompassing the N-terminal
70 codons
of the
rpoS open reading frame as well as the
promoter region
was used for the
construction.
The
katE-lacZ operon fusion was constructed as for the
rpoS-lacZ operon fusion, except that a 1.25-kb
HindIII-
PstI fragment
encompassing the
katE promoter was
used.
Transposon insertion mutagenesis.
Transposon insertion using
mini-Tn10cam was carried out essentially according to the
method of Kleckner et al. (7). Cells of MC4100 were grown
in Luria broth at 37°C to the mid-logarithmic phase. A portion of the
culture was infected with a lambda phage lysate of NK1324 and then
plated onto a Luria agar plate containing 25 µg of chloramphenicol
per ml. Chloramphenicol-resistant (Cmr)
transductants were pooled and infected with the P1vir phage to prepare a P1 phage lysate. The resultant phage lysate was stored and
used for P1 transduction.
Assaying of -galactosidase activity.
Assaying of
-galactosidase activity was carried out by the method of Miller
(13).
Immunoblotting analysis.
Total cellular proteins were
prepared by precipitation with trichloroacetic acid (final
concentration, 5%) and then collected by centrifugation. After a wash
with ice-cold acetone, the precipitate was dissolved in 1% (wt/vol)
sodium dodecyl sulfate (SDS)-50 mM Tris-HCl (pH 8)-1 mM EDTA buffer.
The protein concentration was accurately determined for each sample
using a Micro BCA protein assay reagent kit (Pierce Chemical Co.,
Rockford, Ill.). Appropriate amounts of total cellular proteins
were separated by SDS-polyacrylamide gel electrophoresis, followed by
immunoblotting with anti-S and anti-CbpA
polyclonal antisera.
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RESULTS |
Isolation of transposon-insertional mutations that result in
derepression of rpoS
To monitor
rpoS expression appropriately in different genetic
backgrounds, in this study we constructed three types of
rpoS-lacZ fusion genes on the chromosome (Fig.
1). An rpoS-lacZ operon
(transcriptional) fusion contains only the rpoS promoter
region, fused to the lacZ gene, so it can be used to
monitor the transcriptional control of rpoS. Two protein
(translational) fusion genes, named PF212 and PF977, were also
constructed. Note that these fusions include the N-terminal 70 and 325 codons of the rpoS open reading frame, respectively. The
former contains a cis-acting element required for
translational control in addition to the rpoS promoter
region, whereas the latter contains all regulatory elements required
for rpoS control at the levels of transcription,
translation, and stability of the gene product (15). These
two protein fusions, PF212 and PF977, were used appropriately to
evaluate the translational efficiency and overall output of
rpoS expression, respectively.
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FIG. 1.
Schematic representation of a set of
rpoS-lacZ fusion genes used in this study. The
rpoS operon is diagrammed at the top. The
rpoS open reading frame is indicated. P, promoter of
rpoS. cis-acting elements required for
translational control and turnover control and restriction sites used
for the construction of the rpoS-lacZ fusion genes are
indicated. The structures of three types of rpoS-lacZ
fusion genes are diagrammed below.
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Using PF977 as a monitoring probe, an attempt was first made to isolate
mutants exhibiting derepressed expression for
rpoS in order
to identify a novel factor(s) involved in the regulatory
mechanism for
rpoS expression. PF977 should be advantageous for
comprehensively isolating mutants affecting
rpoS expression
at
any regulatory step(s). Indeed, on tetrazolium-lactose plates
(
19), the wild-type strain carrying PF977 on the
chromosome
gives red colonies (indicating low
-galactosidase
activity),
whereas the
hns::
neo
derivative, in which
rpoS expression is known
to be
derepressed, gives white ones (indicating high
-galactosidase
activity). Thus, mutants exhibiting derepressed expression of
rpoS should give white or pink colonies on
tetrazolium-lactose
plates due to the enhanced
-galactosidase
activity.
Cells of CU263, carrying PF977 on the chromosome, were mutagenized by
random insertion of mini-Tn
10cam carrying a
Cm
r marker (
7). From among ~7 × 10
4 Cm
r transductants,
we selected 20 white or pink colonies on tetrazolium-lactose
plates
containing chloramphenicol. The following immunoblotting
analysis
revealed that 2 of these 20 mutants significantly accumulated
S in their cells even at the logarithmic
phase, whereas in the
remaining 18 mutants the
S content showed only a three- to fourfold
induction compared to
that in the parental wild-type strain at the
logarithmic phase.
These two mutants were genetically purified by
repeated P1 transduction
into the fresh CU263 background and designated
CU328 and CU329.
In this study, we focus our attention on the latter
mutant, CU329,
to investigate the underlying regulatory mechanism for
rpoS expression
(the former mutant will be dealt with
elsewhere).
S is accumulated in CU329 even at the logarithmic
phase.
To clarify the phenotype more precisely, we monitored the
expression of PF977 in CU329 by measuring -galactosidase activity during cell growth. Cells were grown at 37°C in Luria broth, and -galactosidase activity was measured at appropriate intervals. The
expression of PF977 in the wild-type background decreased once after
inoculation of an overnight culture and then increased concomitantly
with cell growth, reaching the maximum level at the onset of the
stationary phase (Fig. 2A and B). PF977
expression in CU329 was found to be ~20-fold higher than that in
wild-type cells only around the logarithmic phase (Fig. 2A and B). This kinetic profile was similar to that observed for a
clpX::kan mutant (data not shown), in
which S is known to be accumulated
(18). Immunoblotting analysis also confirmed this
particular phenotype; that is, S content
increased approximately 10- to 20-fold in CU329 around the logarithmic
phase (Fig. 2C). These results indicated that rpoS
expression in CU329 is indeed derepressed even at the logarithmic phase. It should be noted that the accumulation of CU329 at the logarithmic phase was less significant, i.e., three- to fourfold accumulation, when cells were grown in M9 synthetic medium (data not
shown). The following analyses were thus carried out using Luria broth
exclusively as the culture medium.
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FIG. 2.
Expression of rpoS during cell growth.
Strains CU263 (open circles) and CU329 (closed circles), each carrying
rpoS-lacZ PF977, were grown at 37°C in Luria broth.
Both cell growth (A) and -galactosidase activity expressed by PF977
(B) were measured. Protein samples were prepared at the indicated time
points in panel A, and then each 20 µg of total proteins was
subjected to immunoblotting with anti-S antiserum (C).
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The crr gene is involved in the control of
rpoS expression.
To clarify the gene disrupted by
the mini-Tn10cam insertion in CU329, we first cloned a DNA
segment encompassing the insertion from the chromosomal DNA using the
cam (Cmr) gene of the transposon as a
selective marker. The following DNA sequencing of the flanking region
of the cam gene revealed that the transposon is inserted
just within the crr gene encoding the A subunit of
glucose-specific enzyme II (EIIAGlc). The
insertion point is the 95th codon of the open reading frame consisting of 169 codons. We thus named the relevant insertional mutation crr2-3::mini-Tn10cam. To
further confirm that the crr mutation indeed affects
rpoS expression, we constructed a derivative of CU263, named
CU330, carrying a well-characterized
crr::kan mutation (21).
The resultant strain also exhibited both enhanced expression of PF977
and accumulation of S at the mid-logarithmic
phase (Fig. 3A; compare vector controls). In addition, the wild-type crr gene was able to complement
the mutational phenotype in CU330 with regard to both the enhanced expression of PF977 and the accumulation of S
(Fig. 3A). Thus, we concluded that the crr gene product
somehow negatively controls rpoS expression at the
logarithmic phase.
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FIG. 3.
Phosphorylation of Crr is crucial for
rpoS regulation. (A) Complementation assay of the
crr::kan mutant. Strains CU263
(wild type) and CU330
(crr::kan) carrying plasmid
pTSV28 (vector [vec.]), pSTCRR
(crr+), or pST172
(crrH90Q) were grown at 37°C in Luria broth
supplemented with 25 µg of chloramphenicol per ml. At the
mid-logarithmic phase, -galactosidase activity (upper panel) and
S content (lower panel) were measured. (B) Effect of the
ptsHI or ptsG mutation on
rpoS expression. Strains CU344 (wild type
[WT*]), CU345 ( ptsHI), CU263 (wild
type), and CU348 (ptsG::Tn5)
were grown at 37°C in Luria broth. Note that CU344 and CU345
carry the nupC510::Tn10 allele,
which was used as a selectable marker to construct the
ptsHI mutant. At the mid-logarithmic phase,
-galactosidase activity expressed by PF977 (upper panel) and
S content (lower panel) were measured. -Galactosidase
activity data are means with standard deviations for four independent
assays. Each 20 µg of total proteins was used for immunoblotting.
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Phosphorylation of the Crr protein is crucial for negative
regulation of rpoS expression.
The Crr protein
(EIIAGlc) plays an important role in glucose
uptake through the PEP:PTS system (16). In this system,
the phosphate group of PEP is transferred to glucose through successive
phosphorelay reactions involving enzyme I (EI), histidine protein
(HPr), and glucose-specific enzyme II (EIIGlc).
Extracellular glucose is transported into cells through a coupled phosphorylation reaction catalyzed by EIIGlc. To
determine whether the phosphorylation of Crr is crucial for the
negative regulation of rpoS expression, we carried out the following two lines of experiments. First, we examined the
complementation ability of a mutant crr gene
(crrH90Q), in which the phosphorylated His residue is
replaced by Gln so that the mutant Crr protein is no longer
phosphorylated (21). The introduction of the
crrH90Q allele into CU330 failed to fully complement the
mutational phenotype of CU330, although both the expression of PF977
and the cellular content of S decreased
slightly (Fig. 3A). Second, we examined whether a certain lesion of
ptsHI affects rpoS expression. Since the
phosphorylation of Crr is dependent on both EI and HPr, which are
encoded by the ptsI and ptsH genes, respectively,
the Crr protein cannot be phosphorylated in ptsHI mutant
cells (16). Both the expression of PF977 and the
S content appeared to increase in the
ptsHI mutant cells (Fig. 3B, left pair). This result also
supported the view that the phosphorylation of Crr is important for
regulation of rpoS expression. These lines of evidence
demonstrated that the phosphorylation of the Crr protein is crucial for
the negative regulation of rpoS expression.
Since during glucose uptake the function of the Crr protein
(EIIA
Glc) is coupled to
EIICB
Glc, which is encoded by the
ptsG
gene (
16), both subunits of EII
Glc
could be required for the negative regulation of
rpoS
expression.
To examine this possibility,
rpoS expression in
a
ptsG mutant
was investigated. Neither the
expression of PF977 nor the
S content were
ever increased by the
ptsG::
kan
mutation, and instead,
both were reduced twofold (Fig.
3B; right pair),
indicating that
only the A subunit, i.e., not the CB subunit, of
EII
Glc is involved in the negative regulation of
rpoS expression.
S accumulated due to the crr mutation
is transcriptionally active.
Since S
positively controls the expression of a set of genes whose functions
are induced under certain harsh conditions, it is important to
determine whether the S accumulated in the
crr mutant is transcriptionally active or not. In the
crr::kan background, we thus examined
the expression of the katE and cbpA genes, whose
transcription is known to be dependent on the
S function (12, 26). A set of
strains (Fig. 3A) carrying a katE-lacZ operon fusion on the
chromosome was constructed, and katE-lacZ expression was
measured at the logarithmic phase. The results show that
katE promoter activity was increased fivefold by the
crr::kan mutation (Fig.
4A). The wild-type crr gene
was able to complement this particular phenotype, but the
crrH90Q allele was not. cbpA expression was also
induced by the crr::kan mutation (Fig.
4B). Thus, these results of immunoblotting analysis of the CbpA protein
essentially led to the same conclusion; that is, the
S accumulated in the crr mutant
cells indeed has the ability to allow the transcription of its target
genes.
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FIG. 4.
Expression of katE and
cbpA in the
crr::kan mutant. (A) Strains
CH12 (wild type [WT], katE-lacZ) and NM5
(crr::kan
katE-lacZ), each harboring plasmids as described for
Fig. 3A, were grown at 37°C in Luria broth supplemented with
chloramphenicol (25 µg/ml). At the mid-logarithmic phase,
-galactosidase activity expressed by the katE-lacZ
operon fusion was measured. The data are means with standard deviations
for four independent assays. (B) A set of transformants as described
for Fig. 3A was grown at 37°C in Luria broth supplemented with 25 µg of chloramphenicol per ml. Immunoblotting with anti-CbpA antiserum
was carried out as described for Fig. 3A.
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The crr mutation affects rpoS
expression at the level of transcription.
rpoS
expression is regulated at the levels of transcription, translation,
and stability of the protein (10). Which step(s) does Crr
negatively regulate? To answer this question, we examined the
phenotypic effects of the crr mutation on three types of
rpoS-lacZ fusion genes: operon fusion, PF212, and PF977. As
mentioned above (Fig. 1), PF212 allows the monitoring of the effects of
certain mutations on translational efficiency, other than the
stabilization of S. Indeed, the expression of
PF212 was affected by the hfq1::
mutation
(24) but not by the
clpX::kan or
rssB::kan mutation (data not shown).
While the crr::kan mutation affected
the rpoS promoter activity slightly (twofold or less), it
significantly induced expression of PF212 (fivefold) as well as that of
PF977 (eightfold) (Fig. 5A). The
half-life of S in the crr mutant,
as determined by immunoblotting analysis of chloramphenicol-treated
cells, was approximately 2.5 min, which is quite similar to that
observed for wild-type cells (Fig. 5B). Moreover, the
crr::kan rssB::cam
double mutant showed higher S content than
that in either single mutant (Fig. 5C), suggesting that the
crr::kan mutation does not affect the
stability of S. Thus, Crr seems to be partly
involved in the negative regulation of rpoS expression at
the level of its transcription. However, it should be noted that
phosphorylated Crr is able to activate the enzymatic activity of
adenylate cyclase and that the cellular concentration of cAMP is
positively controlled by Crr (16). Therefore, the effect
of the crr mutation on rpoS transcription described above is not surprising, since the cAMP receptor protein-cAMP complex has been shown to negatively regulate rpoS
transcription in vivo (9, 10). To confirm such an indirect
effect of the crr mutation on rpoS transcription
through adenylate cyclase activity, we examined the effect of the
addition of cAMP on the derepressed expression of rpoS in
the crr mutant. Cells harboring the rpoS-lacZ operon fusion were grown in Luria broth in either the absence or the
presence of 5 mM cAMP, and then -galactosidase activity was measured
at the mid-logarithmic phase. As shown in Fig.
6, the expression of the operon fusion
was completely restored to the wild-type level in both the
crr and the cya backgrounds by the addition of
cAMP. This indicated that the effect of the crr mutation on
rpoS transcription is rather indirect due to modulation of
adenylate cyclase activity.
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FIG. 5.
(A) Effect of the
crr::kan mutation on a set of
rpoS-lacZ fusion genes. Strains carrying the three types
of rpoS-lacZ genes described for Fig. 1 in either
crr+ (+) or
crr::kan ( ) background were
grown at 37°C in Luria broth. At the mid-logarithmic phase,
-galactosidase activity was measured. The data are means with
standard deviations for four independent assays. OF, operon fusion. (B)
Effect of the crr::kan mutation
on the half-life of S. Strains CU263 (wild type; open
circles) and CU330 (crr::kan;
closed circles) were grown at 37°C in Luria broth. At the
mid-logarithmic phase, cells were treated with 25 µg of
chloramphenicol per ml. At the indicated intervals, cells were
harvested and subjected to immunoblotting using anti-S
antiserum. The amount of S was expressed relative to
that determined for the sample at time zero. (C) Cellular
S content in the
crr::kan
rssB::cam double mutant. Strains
carrying the indicated mutations were grown at 37°C in Luria broth.
At the mid-logarithmic phase, cells were harvested and subjected to
immunoblotting using anti-S antiserum. WT, wild type.
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FIG. 6.
Effect of cAMP on rpoS transcription.
Strains CH11 (wild type [WT]), NM7
(crr::kan), and NM25
(cya::kan), each carrying the
rpoS-lacZ operon fusion (OF), were grown at 37°C in
Luria broth either in the absence () or the presence (+) of 5 mM
cAMP. At the mid-logarithmic phase, -galactosidase activity
expressed by the rpoS-lacZ operon fusion was measured.
The data are means with standard deviations for four independent
assays.
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Phosphorylated Crr is involved in translational control of
rpoS
We next examined whether Crr is involved in
rpoS translation indirectly through modulation of the
cellular concentration of cAMP. CU330 cells were grown in Luria broth
at 37°C in either the presence or the absence of 5 mM cAMP, and then
S content was determined by immunoblotting analysis. As
shown in Fig. 7A, S
content decreased only slightly (~10% or less) in the
crr mutant upon the addition of cAMP. In contrast, the
S content of the
cya::kan mutant decreased to
the normal level upon the addition of cAMP. Moreover, expression of
PF212 in the crr::kan
background only slightly decreased upon the addition of cAMP, whereas
that in the cya::kan background
clearly decreased to the normal level (Fig. 7B). These results strongly
suggested that Crr is involved in rpoS translation
rather directly or, at least, not via the modulation of
adenylate cyclase activity.
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FIG. 7.
The phosphorylated Crr is involved in
rpoS translation. (A) Effect of cAMP on cellular
S content. Strains CU263 (wild type [WT]), CU330
(crr::kan), and NM23
(cya::kan) were grown at 37°C
in Luria broth in either the absence () or the presence (+) of 5 mM
cAMP. At the mid-logarithmic phase, total protein samples were prepared
and each 20 µg was subjected to immunoblotting with
anti-S antiserum. (B) Effect of the addition of cAMP on
rpoS-lacZ PF212 expression. Strains CU264 (wild type),
NM9 (crr::kan), and NM24
(cya::kan), each carrying
rpoS-lacZ PF212, were grown, and then -galactosidase
activity expressed by rpoS-lacZ PF212 was measured. The
data are means with standard deviations for four independent assays.
(C) Strains CU263 (wild type) and CU330
(crr::kan) harboring plasmid
pTSV28 (vector [vec.]), pSTCRR (crr+), or
pST172 (crrH90Q) were grown at 37°C in Luria broth
supplemented with 25 µg of chloramphenicol per ml in either the
absence () or the presence (+) of 5 mM cAMP. At the mid-logarithmic
phase, S content was measured by immunoblotting.
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We further addressed the issue of whether the translational control of
rpoS requires the phosphorylation of Crr. The strains
harboring
crr plasmids described in the legend to Fig.
3
were
grown in the presence of 5 mM cAMP, and then
S contents were determined by immunoblotting.
It should be noted
that with the addition of cAMP one is able
only to estimate precisely
the effect of a mutation on
translational control by eliminating
the effect on transcriptional
control. As shown in Fig.
7C, the
crrH90Q allele was unable
to complement the mutational phenotype
of CU330. The slight reduction
in
S content, as shown in Fig.
3A, would be
due to the overproduction
of the mutated Crr by the multicopy plasmid.
The results demonstrated
that the phosphorylation of Crr is crucial for
translational control
of
rpoS.
Epistasis analysis with the hfq mutation.
The
results described above suggested that Crr is involved in translational
regulation of S. It was reported that an
RNA-binding protein, HF-I, the hfq gene product, is required
for rpoS translation (15). We thus finally examined the genetic relationship between the hfq and
crr genes with respect to rpoS translation. A set
of strains carrying the hfq1:: and/or
crr2-3::mini-Tn10cam mutations were
constructed, and the expression of PF212 was measured. The expression
of PF212 in the hfq1:: background was
apparently lower than that in wild-type cells, a finding which is in
good agreement with the previous report (15), whereas that
in the crr2-3::mini-Tn10cam background was fivefold higher. In hfq crr double-mutant cells, the
-galactosidase activity was slightly lower than that in wild-type
cells and similar to that in the hfq single mutant
(Fig. 8). This particular phenotype was
also confirmed by immunoblotting (Fig. 8). There are two possible explanations. First, the hfq mutation is epistatic to the
crr mutation because the strong effect of the crr
mutation was diminished. Second, the two gene products act
independently because the phenotype exhibited by the double mutant was
similar to that of the wild-type strain. It is difficult to determine
which explanation is correct.
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|
FIG. 8.
Effect of an hfq mutation on
rpoS expression in crr background.
Strains CU264 (wild type [WT]), NM20
(crr2-3::mini-Tn10cam), NM11
(hfq1::), and NM21
(crr2-3::mini-Tn10cam
hfq1::), each carrying rpoS-lacZ
PF212 on the chromosome, were grown at 37°C in Luria broth. At
the mid-logarithmic phase, -galactosidase activity expressed by
rpoS-lacZ PF212 (upper panel) and S
content (lower panel) were measured. -Galactosidase activity data
are means with standard deviations for four independent assays.
|
|
| |
DISCUSSION |
In this study, we demonstrated that Crr negatively controls
rpoS expression. The crr mutation affects
rpoS expression mainly at the level of translation rather
than that of transcription, since the addition of cAMP did not
drastically affect the S content of the
crr mutant even while rpoS transcription was
decreased to the wild-type level (Fig. 6 and 7). Although Crr has been
shown to be able to modulate several cellular functions in carbon
metabolism, such as inducer exclusion and adenylate cyclase activity,
this is the first evidence that Crr participates in the translational process.
How does Crr negatively control rpoS translation? Two
proteins, HF-I and H-NS, have previously been reported to be factors involved in the translational control of S
(1, 15, 27). HF-I is required for efficient
rpoS translation, probably through melting of the preformed
complex secondary structure of rpoS mRNA inhibiting the
translation (3, 15). H-NS is, instead, a negative
regulator of rpoS translation (1, 27), and we
have no information as to the underlying molecular mechanism. One
possible explanation is that Crr covalently modifies HF-I to modulate
its function, although no modification of HF-I has been reported.
Alternatively, Crr may somehow prevent the formation of the
translational initiation complex required for rpoS
translation. Since Crr is known to interact with many other proteins,
such as sugar transporters and adenylate cyclase, in carbon metabolism, it is likely that Crr is also able to interact with the translational machinery or HF-I. In this regard, it is notable that ribosomal protein
S7 has a consensus sequence implicated in the interaction with Crr
(20). Crr may repress rpoS translation by
modulating the function of S7, since S7 is known to repress its own
translation through direct binding to mRNA (4). Of course,
more complicated explanations cannot be excluded at present. In any
event, further extensive genetic and biochemical analyses are necessary
to clarify how Crr negatively regulates rpoS translation.
The phosphorylation of Crr appears to be important for the negative
control of rpoS translation (Fig. 3 and 7). Since
phosphorylated Crr is produced during successive phosphorelay reactions
in PEP:PTS, not only Crr but also the overall system is apparently
important for the control. The fact that the system absolutely depends
on PEP, an important intermediate in carbon metabolism, leads us to the
attractive idea that PEP:PTS regulates rpoS expression by
monitoring the amounts of available nutrients throughout cell growth.
However, this possibility seems unlikely because the phosphorylation state of Crr did not drastically fluctuate with the growth phase but
rather with the amount of extracellular glucose. Indeed,
S content in wild-type cells was not affected
significantly by the addition of glucose (data not shown), which is
known to dramatically decrease the levels of phosphorelated
species of Crr (21). Therefore, alternatively, the
intactness of PEP:PTS may be crucial for maintaining a lower level of
rpoS expression. To ensure rapid proliferation at the
logarithmic growth phase, the cells require a large amount of energy
and several metabolic intermediates. In this situation, efficient
transport of extracellular carbohydrates into cells by means of PEP:PTS
should be necessary. When PEP:PTS is impaired by certain mutations, the
cells may be unable to satisfy the requirement for adaptation to rapid
growth conditions and subsequently rpoS expression is
induced. If this is the case, the effect of the crr mutation
on rpoS expression should be more significant under conditions permitting a higher growth rate, a hypothesis which is consistent with our observation that the effect of the
crr mutation in a rich medium was stronger than that in a
synthetic medium.
rpoS expression is enhanced when cells enter conditions
preventing efficient proliferation, such as nutrient starvation, high osmolarity, and low pH, while it is repressed at the fast-growth logarithmic phase. Many proteinaceous factors involved in regulation of
rpoS expression have been identified, and all of them except HF-I were found to negatively control rpoS expression (see
the introduction), suggesting that the control of rpoS
expression is achieved mainly through negative regulation at the
logarithmic phase. When the growth conditions are sufficient for rapid
proliferation, these negative regulators are activated by individual
signals and subsequently repress rpoS expression at the
transcription, translation, or protein stabilization step. If
the growth conditions are not appropriate for rapid proliferation, a
part of the negative regulatory mechanism may be unable to work well,
resulting in derepressed expression of rpoS to some extent.
The intactness of PEP:PTS may be recognized by cells as one of such
cues for repression of rpoS expression.
| |
ACKNOWLEDGMENTS |
We are grateful to H. Aiba (Nagoya University) for the kind gifts
of mutant strains and plasmids of PEP:PTS and the helpful discussion.
We also thank A. Ishihama (National Institute of Genetics) and M. Kitagawa (Nara Institute of Science and Technology) for providing the
hfq1:: and
clpX::kan mutants,
respectively. We also thank C. Seto for her technical assistance (i.e.,
construction of the rpoS-lacZ operon fusion and
katE-lacZ fusion).
This work was supported by a grant from the Ministry of Education,
Science and Culture of Japan.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Bioscience
Center, Nagoya University, Chikusa-ku, Nagoya 464-8601, Japan. Phone:
(81)-52-789-5512. Fax: (81)-52-789-5214. E-mail:
cueguchi{at}nuagr1.agr.nagoya-u.ac.jp.
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Journal of Bacteriology, January 2001, p. 520-527, Vol. 183, No. 2
0021-9193/01/$04.00+0 DOI: 10.1128/JB.183.2.520-527.2001
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Abstract
Introduction
