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J Biol Chem, Vol. 274, Issue 36, 25398-25402, September 3, 1999
§,,
From the Department of Microbiology, College of
Medicine, Chungbuk National University, Chongju, 361-763 Korea and
the ¶ Department of Microbiology, Seoul National University,
Seoul, 151-742 Korea
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ABSTRACT |
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 TOP
 ABSTRACT
 INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
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Products of the pts operon of
Escherichia coli have multiple physiological roles such as
sugar transport, and the operon is controlled by two promoters, P0 and
P1. Expression of the pts P0 promoter that is increased
during growth in the presence of glucose is also activated by cAMP
receptor protein·cAMP. Based on the existence of a sequence that has
a high similarity with the known Mlc binding site in the promoter, the
effects of the Mlc protein on the pts P0 promoter
expression were studied. In vivo transcription assays using
wild type and mlc-negative E. coli strains
grown in the presence and absence of glucose indicate that Mlc
negatively regulates expression of the P0 promoter, and Mlc-dependent repression is relieved by glucose in the
growth medium. In vitro transcription assay using purified
recombinant Mlc showed that Mlc repressed transcription from the P0 but
did not affect the activity of the P1. DNase I footprinting experiments revealed that a Mlc binding site was located around +1 to +25 of the
promoter and that Mlc inhibited the binding of RNA polymerase to the P0
promoter. Cells overexpressing Mlc showed a very slow fermentation rate
compared with the wild type when grown in the presence of various
phosphoenolpyruvate-carbohydrate phosphotransferase system
sugars but few differences in the presence of
non-phosphoenolpyruvate-carbohydrate phosphotransferase system sugars
except maltose. These results suggest that the pts operon
is one of major targets for the negative regulation by Mlc, and thus
Mlc regulates the utilization of various sugars as well as glucose in
E. coli. The possibility that the inducer of Mlc may not be
sugar or its derivative but an unknown factor is proposed to explain
the Mlc induction mechanism by various sugars.
The phosphoenolpyruvate-carbohydrate phosphotransferase
system (PTS)1 catalyzes the
phosphorylation and transportation of a large number of its sugar
substrates (1). The phosphoryl group from phosphoenolpyruvate is
sequentially transferred to enzyme I, to HPr, to the sugar-specific enzyme II complex, and finally to the substrate as it is translocated across the membrane. The ptsH, ptsI, and crr
genes encoding HPr, enzyme I, and enzyme IIAGlc,
respectively, constitute the pts operon. The pts
operon is regulated in a complex fashion by P0 and P1, each of which
has two different transcription start sites depending on the
availability of CRP·cAMP and on the topology of DNA (2).
Transcription of the pts promoters increases in the presence
of CRP·cAMP as well as glucose in vivo (3, 4). The
glucose- and cAMP-mediated activations occur independently of each
other (2, 4, 5), even though glucose lowers the level of CRP and cAMP
in the cell (6). It has been known that the target promoter that is
activated when cells are grown in the presence of glucose is the P0
promoter, but the mechanism by which glucose activates the P0
transcription is not known. Transcription from the P0 is fully
activated only when cells grow in the presence of both glucose and
exogenous cAMP (2, 4, 7). The possibility of the presence of a
repressor that is sensitive to glucose has been suggested based on
these observations (7).
Mlc (making large colonies)
is a newly identified global regulator of carbohydrate metabolism
(8-11). The mlc gene was originally found to cause the
reduction of acetate accumulation when the overexpressing cells grow in
the presence of glucose (12). The mlc gene was also shown to
be identical with the previously characterized dgsA gene
(10, 13, 14). All genes that are so far known to be under the control
of Mlc are also regulated by CRP·cAMP. We noticed a sequence that has
a high homology with the known Mlc binding site between +1 and +25 of
the pts P0 promoter region (Fig. 1). In this study, a
procedure is described for purification of the active form of Mlc to
homogeneity, and the effects of Mlc on the expression of the
pts P0 promoter were studied to determine whether the
in vivo glucose effect on pts operon expression
is mediated by Mlc.
Materials--
Cyclic AMP was obtained from Sigma. RNA
polymerase and nucleotide triphosphates were purchased from Amersham
Pharmacia Biotech. The cycle sequencing kit was from Epicentre
Technologies (Madison, WI). [ Bacterial Strains--
SR702 (MC4100, suhX1) is a
derivative of MC4100 (araD139 Primer Extension--
Cells were grown in tryptone broth (1%
Bacto tryptone, 0.8% NaCl) with or without 0.2% glucose. Total
Escherichia coli RNA was purified using Trizol
reagent (Life Technologies, Inc.). RNA was resuspended in sterile
distilled water. Purified Construction of Expression Vector pNS100 and Overexpression
of Recombinant Mlc--
The DNA sequence from base 194 to 1490 of the
E. coli mlc gene (GenBankTM accession code
D32222) was amplified by polymerase chain reaction. The forward
polymerase chain reaction primer
(5'-GCGAAAATATAGGGAGTATCATATGGTTGC-3') contained
an engineered NdeI site (underlined) containing
the ATG start codon (boldface, the original GTG was changed
into ATG for better expression). The reverse polymerase chain reaction primer (5'-CTTTCCTGGCCCAAATTGGGATCCCGCAAA-3') contained an
engineered BamHI site (underlined) located 33 base pairs downstream from the TAA stop codon. The polymerase chain
reaction product was cloned into the NdeI and
BamHI cloning sites of the vector pRE1 (19), and the
sequence of the recombinant plasmid, pNS100, was verified by a cycle
sequencing kit. The pNS100 was electroporated with an E. coli pulser (Bio-Rad) into E. coli strain GI698. In plasmid pNS100, the mlc gene is under the control of the
strong Phenotype of E. coli Overexpressing Mlc--
Fermentation
properties of E. coli GI698 strains transformed with pNS100
or pRE1 were compared with that of the mlc-negative mutant
to check the effect of Mlc overexpression or deletion on the PTS
activity. These strains were grown in the synthetic medium supplemented
with ampicillin and then spotted onto MacConkey indicator plates
containing various sugars as carbon sources, and color development of
those colonies was observed. Four PTS sugars including glucose,
mannose, mannitol, and N-acetylglucosamine and four non-PTS sugars including lactose, maltose, melibiose, and sucrose were tested.
Purification of Mlc--
The cells containing overexpressed Mlc
were sonicated in glycine-NaOH buffer, pH 9.5, and the cell debris was
removed by ultracentrifugation at 100,000 × g for 90 min. The supernatant was loaded onto a fast protein liquid
chromatography Mono-Q 5/5 column equilibrated with glycine-NaOH buffer
(buffer G), pH 9.5, containing 1 mM DTT and 50 mM NaCl. The column was washed with 3 column volumes of
buffer G containing 1 mM DTT and 50 mM NaCl,
and then Mlc was eluted with a linear salt gradient (7 column volumes
of buffer G containing 50 mM NaCl to 7 column volumes of
buffer G containing 500 mM NaCl in the presence of 1 mM DTT). The elution of Mlc was monitored by
SDS-polyacrylamide gel electrophoresis, and the fractions containing substantial amounts of Mlc were pooled and concentrated in a 3 K
Macrosep centrifugal concentrator (Filtron). The concentrate was
chromatographed through a HiLoad 16/60 Superdex 75 prep grade column
(Amersham Pharmacia Biotech) using buffer G with 1 mM DTT and 50 mM NaCl as eluent. The fractions containing Mlc were
pooled and concentrated as described above.
In Vitro Transcription Assay--
Reactions were done as
described by Ryu and Garges (2) in a 25-µl volume containing the
following: 20 mM Tris acetate, pH 8.0, 3 mM
magnesium acetate, 200 mM potassium glutamate, 1 mM dithiothreitol, 1 mM ATP, 0.2 mM
GTP, 0.2 mM CTP, 0.02 mM UTP, 10 µCi of
[ DNase I Footprinting--
DNase I protection experiments were
done as described by Ryu et al. (7). Two nM DNA,
40 nM CRP, 200 ng of Mlc, and 100 µM cAMP
were mixed in transcription buffer in the combinations as indicated in
Fig. 5 and incubated at 37 °C for 10 min. RNA polymerase was added
and incubated for an additional 10 min at 37 °C before DNase I
treatment. The DNase I treatment was terminated by adding an equal
volume of 20 mM EDTA and heating at 85 °C for 3 min. The
DNase I-treated DNA was cleaned with a Wizard DNA cleanup kit (Promega,
Madison, WI), probed with 32P-end labeled primer using
Klenow polymerase, and analyzed on a 6% sequencing gel.
Mlc Is a Repressor of the pts P0 Promoter--
We have suggested
the presence of a repressor that is inducible by glucose in the
pts P0 promoter (2). The presence of a sequence that has a
high similarity with the known Mlc binding site (9, 10) at the
pts P0 promoter region prompted us to study the effect of
Mlc on the expression of the promoter (Fig. 1). We tested the effect of Mlc on
transcription of the P0 promoter in vivo by primer extension
assay of total RNA extracted from cells grown in the presence or
absence of glucose. The P0 transcription was stimulated by growth on
glucose in a wild type strain as expected (Fig.
2). In the absence of glucose, the
mlc-negative mutant showed a much higher transcription level
of the P0 promoter than the wild type strain, implying that Mlc
negatively regulates the expression of the P0 promoter in the wild type
(compare lanes 2 and 4 in Fig. 2). The level of
transcription from the P0 promoter of a mlc-negative mutant
grown without glucose (Fig. 2, lane 4) was even higher than
that of a wild type strain grown in the presence of glucose (Fig. 2,
lane 1). This is because the P0 is activated further by
CRP·cAMP in the absence of glucose in a mlc-negative mutant. In glucose-grown cultures, however, the mlc-negative
strain showed a similar expression level of P0 promoter with the wild type strain (compare lanes 1 and 3 of Fig. 2).
These results suggest that Mlc is a repressor of the pts P0
promoter, and Mlc-dependent repression is relieved by
glucose in the growth medium.
Purification of Mlc--
Mlc protein was purified to characterize
its effects on the pts P0 promoter further. Mlc could be
overproduced in E. coli strain GI698 containing pNS100 to
about 25% of the total cell protein after induction (Fig.
3). Even though a high level of expression of Mlc could be achieved using the system, the protein was
found in the insoluble fraction of the lysate (lanes 3 and 4 of Fig. 3). Various methods as suggested by Rudolph and
Lilie (21) were tried to increase the solubility of Mlc in the cell extract, and we found that Mlc was soluble in glycine-NaOH buffer, pH
9.5. Mlc was purified using a combination of anion-exchange and gel
filtration chromatography. The overall purification was 3.8-fold from
the crude extract to the final preparation (Table I). From 100 ml of culture (about 350 mg
of wet weight cell), a yield of 5.5 mg of approximately 95% pure Mlc
was obtained as judged by SDS-polyacrylamide gel electrophoresis (Fig.
3, lane 6). The final preparation was free of RNase activity
and was directly used for in vitro transcription
assay.
Effect of Mlc on the pts P0 Transcription in Vitro--
The effect
of Mlc on the P0 transcription was studied further by an in
vitro transcription assay using purified proteins. The supercoiled
pHX DNA containing both P0 and P1 promoters was used as a DNA template
(2). Mlc inhibited transcription from the P0 promoter but did not
affect transcription of the P1 promoter (Fig.
4A). The specificity of the
Mlc action on the P0 promoter was further demonstrated by the
consistent activity of the rep that is originated from the
plasmid origin of replication regardless of the presence of Mlc (Fig.
4A). The inhibitory effect of Mlc on the P0 promoter was
reduced in the presence of CRP·cAMP (compare lanes 1 and
3 in Fig. 4A), even though the influence of CRP·cAMP was
not significant.
Varying amounts of purified Mlc were added to the in vitro
transcription reactions to determine the kinetic behavior of the purified protein in the transcriptional regulation of the P0 promoter. Half repression by the recombinant Mlc, in the absence and presence of
CRP·cAMP, was obtainable with about 6 and 12 ng (Fig. 4B), respectively, showing that the stimulatory effect of the CRP·cAMP complex on P0 in the presence of Mlc was not significant, and Mlc is a
stronger regulator.
Binding of Mlc to the pts P0 Promoter Region--
We tested the
binding of Mlc on the P0 promoter region to determine the mechanism of
Mlc action. Binding of Mlc, CRP·cAMP, and RNA polymerase on the P0
promoter region was studied using a DNase I footprinting experiment.
Fig. 5 showed that Mlc bound to the P0
promoter region, and the binding of both Mlc and CRP·cAMP to the P0
promoter region was independent of each other (compare lanes
2, 3, and 7). DNase I footprinting results
(Fig. 5) confirmed the Mlc binding site around +1 to +25 of the P0
promoter as indicated by sequence comparison of the known Mlc binding
sites to the region. DNase I footprinting results also showed that the
binding of RNA polymerase to the P0 promoter region was inhibited in
the presence of Mlc (compare lanes 2, 4, and
5 in Fig. 5).
Phenotype of E. coli Overexpressing Mlc under Various Growth
Conditions--
The phenotype of E. coli overexpressing Mlc
was examined on MacConkey agar plates containing various PTS and
non-PTS sugar substrates. The overall colony size of GI698 harboring
pNS100 (containing the mlc gene) was larger than the strain
harboring a control vector, pRE1, regardless of the sugar substrates,
and colonies on plates containing readily fermentable sugars showed a
reddish purple color 6 h after spotting at 37 °C. When non-PTS sugars such as lactose, maltose, melibiose, and sucrose were used as
substrate, there were no remarkable differences between GI698 harboring
pNS100 and the strain containing pRE1 except for maltose (Table
II). When PTS sugars were included in
MacConkey plates, however, Mlc overexpression seriously retarded the
fermentation rate of those PTS sugars regardless of the sugar
substrates (Table II). Repressing activity of Mlc and derepression of
Mlc activity by readily fermentable sugar substrates have been shown
for several sugar-specific transporter genes and the pts
operon (8-10, 18). According to these observations, the wild type
cells grown in the presence of these sugar substrates should show the
similar fermentation rate compared with the mlc-negative
cells. When we compared fermentation patterns of the mlc
mutant and the wild type cells to the GI698 strain harboring pRE1 or
pNS100, the mlc-negative mutant showed no remarkable
difference in fermentation patterns with the wild type cells or the
GI698 strain harboring pRE1, as expected. These results imply that Mlc,
which mainly affects utilization of PTS sugars, is a global regulator
of carbohydrate metabolism.
Because of the multiple roles exerted by the gene products of the
pts operon (22, 23), the intricate regulation of expression of the operon is crucial for the survival of the organism. The expression level of pts gene products in E. coli
was reported to change 2- to 3-fold in response to the environmental
changes such as the availability of the sugar substrates and oxygen
(1). It has been known that the pts P0 promoter is activated
when cells are grown in the presence of glucose. Examination of the
pts P0 promoter region revealed a site that has a high
similarity to the sequence of the known Mlc binding sites. The
mlc encodes a 44-kDa protein, Mlc, that has been shown to
regulate the expression of ptsG encoding
IICBGlc, manXYZ encoding enzyme II of the
mannose PTS, malT encoding the activator of maltose regulon,
and mlc itself (8-10). Mlc is proposed to be a global
regulator of carbohydrate metabolism (8, 9).
Comparison of transcription from the pts P0 promoter in wild
type and mlc-negative mutant suggests that Mlc is a
repressor of the P0 promoter. The P0 promoter was activated in the wild type, whereas it was repressed in a mlc-negative mutant when
cells were grown in the presence of glucose (Fig. 2). The probable
reason for the reduction of the activity of the P0 promoter when the mlc-negative strain grows in the presence of glucose is that
the concentration of an activator of the P0 promoter, CRP·cAMP, was lowered in that condition (1, 6). These results also indicated that the
action of Mlc in the regulation of the pts operon is dominant over that of CRP·cAMP as proposed for the regulation of
ptsG expression by Mlc recently (9).
It has been suggested that the concentration of Mlc in E. coli is limiting (9). Expression of the gene is autoregulated (8),
and the translation efficiency of the mlc is low because the
translation initiation codon of the mlc is GTG (12). We cloned the mlc under the control of
The common feature of five operons (manXYZ, malT, mlc, ptsG, and
pts) identified as the Mlc regulon so far is that all of them have
at least one CRP·cAMP binding site as well as a Mlc binding site, and
thus they are under the dual regulation. This seems to be necessary for
the fine control of expression of these genes to respond to various
environmental conditions. It is interesting that E. coli
overexpressing Mlc showed the same phenotype (the cells having a very
slow fermentation rate) on N-acetylglucosamine and mannitol
indicator plates as on glucose and mannose plates (Table II). The
nagE gene of N-acetylglucosamine PTS and the
mtlA gene of mannitol PTS correspond to the ptsG
gene of glucose PTS and the manXYZ gene of mannose PTS in
that all of them encode the major sugar-specific transporters, enzyme
II. It is not known if Mlc is involved in the regulation of the
nagE and mtlA genes, even though positive
regulation of nagE by the CRP·cAMP complex was reported
recently (24). In any case, we can expect that Mlc regulates
utilization of many PTS sugars because it modulates the expression of
the pts that encodes general proteins for all PTSs, enzyme
I, and HPr. To serve as a common regulator of metabolism of many
sugars, Mlc should be induced by different kinds of sugar. The inducer
of Mlc has not been identified despite repeated attempts to identify
the inducer that affects the Mlc binding to its binding site by many
researchers (8, 9). We examined the possibility that the inducer
relieves repression by Mlc without affecting the binding of Mlc to its
binding site using in vitro transcription assay. However,
none of the sugars or their derivatives tested (glucose, glucose-6-P,
maltose, mannitol, mannose, xylose, melibiose, pyruvate,
N-acetylglucosamine, methyl
We are testing this possibility, and further work is needed to discover
the inducer of Mlc would be.
INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
EXPERIMENTAL PROCEDURES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
-32P]ATP and
[
-32P]UTP were from Amersham Pharmacia Biotech. Klenow
polymerase was from New England Biolabs, Inc. (Beverly, MA).
argF-lacU169rpsL150
thiA1 relA1 flbB5301 deoC1 ptsF25 rbsR) that expresses a high
level of GroEL because of an IS1 element inserted upstream
of the groE gene. It was constructed from KY1603 (15) by P1
transduction. The chaperonin GroEL protects RNA from nucleases (16) so
that the unstable mRNA from the P0 promoter (17) is stabilized in
suhX1 strain background because of a high level of GroEL.
SR703 (SR702, mlc) was constructed from CP1036 by P1 transduction. Glutamine at residue 369 of Mlc is replaced by a stop
codon (UAG) in CP1036 (18).
-32P-end labeled primer P11
(5'-GCCAGTTTTTAACAGACGCGACGCACGAAG-3') (7) was coprecipitated with 30 µg of total cell RNA, and the pellet was resuspended in 20 µl of
250 mM KCl, 2 mM Tris-HCl, pH 7.9, and 0.2 mM EDTA. Primer extension reactions were done as described
by Ryu and Garges (2).
PL promoter-cII ribosome binding site
combination. The cI repressor gene is under the control
of the trp promoter in GI698 (20). E. coli GI698
transformed with plasmid pNS100 was cultured at 30 °C in 200 ml of
synthetic medium (20) supplemented with 0.1 mg/ml ampicillin. When the
culture reached an A600 = 0.5, tryptophan (0.1 mg/ml) was added to induce the expression of Mlc. The cells harvested
20 h after induction were washed once with 20 mM
Tris-HCl, pH 7.5, containing 50 mM NaCl and stored at
20 °C.
-32P]UTP (800 Ci/mmol), 2 nM supercoiled
DNA template, 20 nM RNA polymerase holoenzyme, 100 µg/ml
bovine serum albumin, and 5% glycerol. Additional regulators such as
40 nM CRP, 100 µM cAMP, or 0-200 ng of Mlc
were added to the reaction as needed. All components except nucleotides
were incubated at 37 °C for 10 min. Transcriptions were started by
the addition of nucleotides and terminated after 10 min by the addition
of 25 µl of formamide loading buffer (80% formamide, 89 mM Tris base, 89 mM boric acid, 2 mM EDTA, 0.05% bromphenol blue, 0.05% xylene cyanol). RNA
was resolved by electrophoresis on an 8 M urea, 6%
polyacrylamide gel. The amounts of transcripts were measured using a
Molecular Imager system (Bio-Rad).
RESULTS
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
View larger version (14K):
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Fig. 1.
The locations of protein binding sites in the
P0 promoter of the pts operon. The nucleotide
sequence between 120 and +30 with respect to the transcription start
site of the P0 promoter is shown. The 10 and 35 region of the P0
promoter and the CRP binding site are underlined. The Mlc
binding sites are boxed. The sequence is identical to the
consensus Mlc binding sequence proposed by Kimata et al. (9)
with the exception of one nucleotide.
View larger version (50K):
[in a new window]
Fig. 2.
Effect of glucose on transcription from the
P0 promoter in the wild type (SR702) and mlc-negative
strain (SR703). Total RNA was isolated from cells grown in
tryptone broth with or without glucose. Primer extension analysis of 30 µg of total RNA/reaction was done as described under "Experimental
Procedures." WT, wild type.
View larger version (96K):
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Fig. 3.
Expression, solubilization and purification
of recombinant Mlc from E. coli. The recombinant
Mlc was overexpressed in E. coli GI698 containing pNS100.
Aliquots (20 µl) of bacterial cell lysates or purified Mlc were
subjected to SDS-polyacrylamide gel electrophoresis and stained with
Coomassie Blue. Lane M, prestained SDS-polyacrylamide gel
electrophoresis standards, low range (Bio-Rad); lane 1,
crude cell extract before induction; lane 2, crude cell
extract 20 h after induction of Mlc; lanes 3-5,
supernatants after centrifugation at 100,000 × g of
sonicated culture following suspension of cells in buffers 10 mM Na-acetate buffer with 50 mM NaCl (pH 4.5),
10 mM potassium phosphate buffer with 50 mM
NaCl (pH 7.0), and 10 mM glycine-NaOH buffer with 50 mM NaCl (pH 9.5) containing 1 mM DTT,
respectively; lane 6, 1 µg of purified Mlc, which is 44 kDa.
Purification of recombinant Mlc from E. coli GI698 containing pNS100
View larger version (16K):
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Fig. 4.
Effects of Mlc on the activity of the
pts promoter in vitro. The
supercoiled plasmid pHX, which has both P0 and P1 promoters, was used.
A, Mlc specifically inhibited the P0 promoter activity. A
185-base transcript from the P0 and 85- and 78-base transcripts from
the P1a and P1b promoters are shown as P0, P1a,
and P1b, respectively. The transcripts from plasmid origin
of replication (106/107 bases) are shown as rep.
B, effect of Mlc on the P0 promoter activity in the presence
(closed circle) and absence (open circle) of 40 nM of CRP·cAMP. 0, 6.3, 12.5, 25, 50, 100, and 200 ng of
Mlc were tested in each experiment.
View larger version (69K):
[in a new window]
Fig. 5.
DNase I protection of the pts P0 promoter region by Mlc, CRP·cAMP, and RNA polymerase.
The supercoiled DNA was treated with DNase I in the presence of various
combinations of proteins as indicated at the top. The
treated DNA was probed with a 32P-end labeled primer. The
same primer was used for sequencing the P0 promoter region. Numbering
is relative to the P0 transcription initiation site.
Fermentation patterns of E. coli strains transformed with pNS100 and
pRE1 on various sugar substrates
, no fermentation; +,
very slow fermentation; ++, slow fermentation; +++, moderate
fermentation; ++++, fast fermentation. The fermentation rate of SR702
and SR703 was similar to that of GI698/pRE1.
DISCUSSION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
PL and changed the GTG to ATG in our
expression vector pNS100 for better expression of the gene. We could
get more than 95% pure Mlc using a combination of ion-exchange and gel
filtration chromatography. This is the first report describing the
purification of Mlc. In vitro transcription assays with
purified Mlc clearly showed that Mlc specifically inhibited
transcription from the P0 promoter but had no effect on the P1 promoter
(Fig. 4A). CRP·cAMP reduced the action of Mlc a little but
could not prevent Mlc from inhibiting the P0 promoter. It is, however,
possible that the modest influence of CRP·cAMP on Mlc action revealed
by in vitro transcription assay can be significant in
vivo because Mlc concentration is limiting in E. coli
(9). In vitro transcription assay results together with the
in vivo Mlc effects on the pts P0 promoter
activity strongly demonstrated that Mlc was a repressor of the
pts P0 promoter that can be induced by glucose. We
identified one Mlc binding site centered at +13 of the promoter. The
sequence has high homology with the tentative consensus sequence of the
Mlc binding site as proposed by Kimata et al. (9) (Fig. 1).
The binding sites of CRP·cAMP and Mlc do not overlap and their
binding to the P0 promoter region was independent of each other as
expected from the previous finding that the glucose- and cAMP-mediated
activations of the pts promoter were independent of each
other (2). Mlc inhibited the P0 promoter activity by interfering with
the binding of RNA polymerase to the promoter (Fig. 5).
-D-thiogalactoside) showed any effect on the repression
by Mlc. These results suggest the possibility that the inducer of Mlc
may not be the sugar or its derivative. It has been known that
glucose-mediated activation of the pts operon is dependent
on the enzyme IICBGlc, which may act as a sensor protein
(25). In this view, Mlc can act as a response regulator whose activity
is modulated by enzyme IICBGlc. However, the possibility
that Mlc is phosphorylated by enzyme IICBGlc is low because
we could not get any evidence of phosphorylation of Mlc, even though we
tried several different approaches employing [32P]phosphoenolpyruvate or [-32P]ATP
mixed with purified Mlc in the presence and absence of E. coli cell-free extracts to phosphorylate Mlc (data not shown). These may imply that the activity of Mlc is modulated by interaction with an unknown factor probably through protein-protein interaction as
in the case of anti-
factors (26, 27). Glucose may affect the
interaction by changing the phosphorylation state of enzyme IICBGlc, and other sugars may also affect the interaction
through their own enzyme II. The unknown factor could be any one of PTS
proteins or an unknown novel factor yet to be identified.
| |
ACKNOWLEDGEMENTS |
|---|
We thank Drs. T. Yura and C. Park for providing strains and R. Labbe for reviewing the manuscript.
| |
FOOTNOTES |
|---|
* Financial support was received from the Korea Research Foundation made in the program year 1998.The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
§ Contributed equally to this work.
To whom correspondence should be addressed: Dept. of
Microbiology, Bldg. 150, Rm. 308, College of Medicine, Chungbuk
National University, Chongju, 361-763 Korea. Tel.: 82-431-273-3745;
Fax: 82-431-272-1603; E-mail: sryu@med.chungbuk.ac.kr.
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ABBREVIATIONS |
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The abbreviations used are: PTS, phosphoenolpyruvate-carbohydrate phosphotransferase system; CRP, cAMP receptor protein; DTT, dithiothreitol; HPr, histidine protein.
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REFERENCES |
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TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
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