(Received for publication, December 17, 1996, and in revised form, February 20, 1997)
From the Department of Biology, University of Konstanz, 78434 Konstanz, Germany
The pathway of trehalose utilization in
Escherichia coli is different at low and high osmolarity.
The low osmolarity system takes up trehalose as trehalose 6-phosphate
which is hydrolyzed to glucose and glucose 6-phosphate.
treB and treC, the genes for the enzymes
involved, form an operon that is controlled by TreR (encoded by
treR), the repressor of the system, for which trehalose 6-phosphate is the inducer. We have cloned and sequenced
treR. The protein contains 315 amino acids with a molecular
weight of 34,508. TreR was purified and shown to bind as a dimer
trehalose 6-phosphate and trehalose with a Kd of 10 and 280 µM, respectively. The conformations of the
protein differ from each other with either one or the other
substrate-bound. Protease treatment removed the DNA-binding domain from
the intact protein leaving the dimerization domain (a 29-kDa
carboxyl-terminal fragment) intact. Nuclease protection experiments
revealed a palindromic sequence located directly upstream of the 35
promoter sequence of treB that functions as the operator of
the system.
The nonreducing disaccharide trehalose
(-D-glucosyl-1
1-
-D-glucoside) is known
to maintain the fluidity of membranes under conditions of dryness and
desiccation (1) as well as to stabilize enzymes, foods,
pharmaceuticals, and cosmetics even at high temperatures (2).
Escherichia coli synthesizes trehalose when exposed to high
osmolarity (3-5). The synthesis of trehalose requires the enzymes
trehalose-6-phosphate synthase and trehalose-6-phosphate phosphatase,
encoded by otsA and otsB, respectively (6, 7). otsB and otsA form an operon (8) that is induced
at high osmolarity and during entry into stationary phase. The
induction is dependent on RpoS, which is the alternative
factor for
stationary phase (9). Trehalose itself is not involved in the
regulation of the operon. The accumulated trehalose is broken down to
glucose by the cytoplasmic trehalase (TreF) (10), ensuring a continuous turnover of the osmoprotectant.
E. coli is also able to use trehalose as the sole carbon source at low and high osmolarity. The problem of the simultaneous degradation and synthesis of trehalose at high osmolarity is solved by separating the two metabolic pathways. The synthesizing enzymes are located in the cytoplasm, and the degrading enzyme encoded by treA is located in the periplasm. TreA (11, 12) hydrolyzes trehalose to glucose, which is subsequently taken up by the enzyme II of the phosphotransferase system specific for glucose (13). Mutants lacking treA can no longer grow on trehalose as the sole carbon source at high osmolarity, but they still grow at low osmolarity (11). This is due to a second system for trehalose degradation that is only expressed at low osmolarity. This system is composed of a phosphotransferase system enzyme II specific for trehalose (EIICBTre encoded by treB), which together with EIIAGlc transports trehalose as trehalose 6-phosphate to the cytoplasm (13-15). The cytoplasmic trehalose-6-phosphate hydrolase (encoded by treC) splits the accumulating trehalose 6-phosphate to glucose and glucose 6-phosphate (16). treB and treC form an operon at 96.5 min on the chromosome with treB as the promoter-proximal gene (15). The treB/C operon is induced by trehalose 6-phosphate and dependent on the cAMP catabolite gene activation protein (CAP),1 therefore it is subject to glucose-mediated catabolite repression (13). Trehalose 6-phosphate is thus a central metabolite being the crossing point between the synthesizing and degradative pathways for trehalose. To prevent the cells from futile cycles a proper regulation of both pathways is necessary.
Recently, we have described an open reading frame directly upstream of
treB (with the same direction of transcription as the treB/C operon). This open reading frame, called
treR, encodes the regulator of the system (15). Here we
present the molecular characterization of treR and its
encoded protein TreR (the trehalose repressor). We show that TreR is
able to bind DNA at a palindromic sequence located upstream of the 35
region of the treB promoter. We show that TreR binds
trehalose 6-phosphate as well as trehalose but that only the binding of
trehalose 6-phosphate results in a reduction of the operator binding
affinity.
Bacterial strains used in this study are described in Table I. P1 transductions (17) were used for strain construction. Cultures were grown in Luria broth (LB). Growth was monitored by measuring the optical density at 578 nm (A578).
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Standard DNA methods were used
(18). Cloning of treR and construction of pRHo500 was
described previously (15). Digestion of pRHo500 with
SspI/PstI and cloning of the 1162-bp
treR-carrying fragment into pBR322 that was opened with the
same restriction enzymes yielded plasmid pRHo501. To obtain a fragment
containing the promoter of treR, plasmid pRHo500 was
digested with SspI/SmaI. The resulting 198-bp
fragment was ligated into promoter probe vector pTAC3575
(lacZ, phoA) (19) opened with SmaI,
yielding plasmid pTACptreR. The orientation of the insert
was confirmed by restriction analysis to be the promoter of
treR, which was controlling the transcription of
lacZ. To overexpress TreR, the coding sequence of
treR was amplified by polymerase chain reaction from plasmid
pRHo500 using two primers: treR NdeI, carrying a NdeI site at the ATG translation start (Fig. 1, Table II),
and treR EcoRI, downstream of the open reading frame (Fig.
1, Table II). The amplified DNA was digested with NdeI and
EcoRI and ligated into pCYTEXP1 digested with the same
enzymes, yielding plasmid pRHotreR. The cloned sequence was
verified by sequencing.
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The sequence of treR was determined from plasmid pRHo500 by the dideoxy chain termination method of Sanger et al. (20) with the modification of Biggin et al. (21) using customized sequencing primers 209/1-5 and 209/k from MWG (Gesellschaft für Angewandte Biotechnologie GmbH, Ebersberg, Germany) and the Sequenase kit version 2.0 (Amersham). The primer sequences are shown in Table II, and their positions are indicated in Fig. 1. [35S]dATP was purchased from Amersham International. Sequence reaction products were separated on a 4% sequencing gel containing urea according to the manufacturer's manual (Pharmacia Biotech Inc.). The DNA sequence and the deduced amino acid sequence were identical to another sequence submitted to GenBankTM later (accession number U14003[GenBank]) (22). Sequence homologies were found by querying the latest releases of all available data bases using the BLAST server at the National Center for Biotechnology, Bethesda, MD (23). Protein homology comparisons were done with MegAlign (DNA Star Inc.).
Determination of Transcriptional Start PointThe mRNA start point was mapped by the reverse transcriptase method of primer extension according to Ref. 24 using 20-50 µg of total cellular RNA and 5 pmol of primer 209/3 (Table II). The sequence reaction was done with the same primer.
Purification of TreRStrain SF120 (25) was transformed with plasmid pRHotreR and grown at 28 °C in 1 liter of LB containing ampicillin (100 µg/ml). Induction was done after reaching an A578 of 0.6 by shifting the culture quickly to 42 °C. The culture was further incubated for 3 h at 42 °C. The following procedures were all performed at 4 °C. After centrifugation for 15 min at 4,200 × g the culture was washed in 500 ml of buffer A (50 mM Tris-HCl, pH 7.5, 100 mM KCl, 10 mM MgCl2) and resuspended in 20 ml of the same buffer. The suspension was ruptured in a French pressure cell at 16,000 p.s.i. and centrifuged for 30 min at 36,000 × g. The nucleic acid remaining in the supernatant was precipitated by adding streptomycin sulfate to a final concentration of 2%. After 30 min of incubation the suspension was centrifuged at 36,000 × g for 30 min. The proteins of the supernatant were precipitated by the addition of ammonium sulfate to 30% saturation. After incubation for 30 min and centrifugation at 36,000 × g for 30 min, the ammonium sulfate concentration of the supernatant was elevated to 50% saturation. The protein pellet was harvested by centrifugation and resuspended in 20 ml of buffer A. The suspension was loaded onto a heparin-Sepharose column (Pharmacia) (15-ml bed volume, 3.5-cm diameter) equilibrated with buffer A. The flow rate was adjusted to 60 ml/h. After washing the column with 60 ml of buffer A, the protein was eluted in 140 ml of a linear gradient from 100 to 500 mM KCl in buffer A. The TreR-containing fractions were pooled. The protein was precipitated with 60% saturated ammonium sulfate and stored in precipitated form at 4 °C. During purification the different fractions were analyzed by SDS-PAGE using 15% polyacrylamide (26).
Gel Filtration of Purified TreR100 µl of TreR (0.5 mg/ml) in buffer A was applied on a Superdex 200 column (Pharmacia). Trehalose 6-phosphate or trehalose, when present, had a concentration of 10 mM. Elution was with the same buffer and done at a flow rate of 0.3 ml/h. The marker proteins chymotrypsin (25 kDa), ovalbumin (45 kDa), bovine serum albumin (66 kDa), and dimer of bovine serum albumin (132 kDa) were analyzed in separate runs using identical conditions. The molecular weights were plotted half-logarithmically against their elution volume forming a straight line from which the molecular weight of TreR was interpolated.
Proteolysis of TreR5 µg of TreR at 2 mg/ml was incubated at 37 °C with different concentrations of thermolysin in buffer A supplemented with 4 mM CaCl2. After 2 h an excess of EDTA (6 mM) was added, and the products were analyzed on a 15% SDS-PAGE gel (26).
Gel Retardation Assay4 µg of plasmid pRHo400 was digested with AvaI and NcoI. After heat inactivation of the enzymes, the restricted sites were filled up with 4 units of Klenow enzyme using 10 µCi of [35S]dATP and an excess of the other unlabeled nucleotides (2 mM each). After heat denaturation, the labeled DNA was diluted (1/100) and incubated with different concentrations of purified TreR in buffer A containing bovine serum albumin (0.1 mg/ml). As indicated, the sugars trehalose and trehalose 6-phosphate were added to a final concentration of 3 mM. The mixture was separated on a 4% acrylamide gel (18) and subjected to autoradiography.
DNase I Footprinting4 pmol of the primer treB
FP2 (Table II) were labeled with 10 units of T4 polynucleotide kinase
(New England Biolabs) using 5 µCi of [-32P]ATP
(Amersham). After labeling, the complete mixture was used to perform a
polymerase chain reaction together with unlabeled primer Foot1 (Table
II) and plasmid DNA as template. After precipitation with ethanol, the pellet was resuspended with water to a value of
50,000 cpm/µl. 2 µl of the labeled DNA was incubated with varying amounts of TreR in a total volume of 50 µl using buffer A containing bovine serum albumin (0.1 mg/ml) and 100 µg/ml poly(dI-dC)
(Pharmacia). Trehalose and trehalose 6-phosphate were added to a final
concentration of 1 mM. After an incubation of 10 min at
37 °C, 3 µl of DNase I (Boehringer Mannheim, 0.007 units/µl) was
added, and the reaction was performed at 37 °C for 3 min. It was
stopped by the addition of 50 µl of stop solution (600 mM
sodium acetate, pH 4.8, 20 mM EDTA). The DNA was
precipitated by the addition of 2 volumes of ethanol. The resulting
pellet was resuspended in 1 × sequencing stop solution (Amersham)
and analyzed on a sequencing gel. A sequencing reaction with the
corresponding primer was used to localize the resulting binding
site.
The DNA region upstream of treB
located on plasmid pRHo500 was sequenced on double-stranded DNA with
the dideoxy chain termination technique using the customized primers
indicated. The result is shown in Fig. 1. An open
reading frame was found starting with ATG at position 155 and ending
with the TGA stop codon at position 1100 of the sequence shown in Fig.
1. This open reading frame contains 945 bp encoding 315 amino acids
(molecular mass of 34,508 Da) that represent TreR. Upstream of the ATG
start codon we recognized sequences that are likely to function as 10
and
35 regions of a
70-dependent promoter.
Primer extension analysis was used to determine the transcriptional
start point (Fig. 2). Four closely spaced start points
were identified, and they are indicated in Fig. 1 together with their
corresponding
10 and
35 promoter region. Also shown in Fig. 1
downstream of the TGA stop codon of treR, a sequence was
found that could form a palindrome able to act as a potential
transcription termination signal (stem and loop structure). Comparison
of the deduced amino acid sequence of TreR with that of the LacI (27),
PurR (28), and other repressors of the LacI-GalR subfamily shows a high
degree of homology at the NH2-terminal part of the protein
sequence. This part is known to contain the helix-turn-helix
DNA-binding motif (Fig. 3). In the case of TreR the
recognition helix is KSTVSRVLN.
By cloning a 198-bp fragment containing the identified promoter of treR into a promoter probe vector with promoterless lacZ and phoA genes we obtained plasmid clones where lacZ was fused to a promoter within treR but oriented opposite to treR transcription (data not shown). Therefore, a second even stronger promoter than the identified treR promoter exists on this very short DNA fragment but with the opposite orientation. This finding is consistent with a report of an active lacZ fusion to this hypothetical promoter (29).
Purification of TreRE. coli strain SF120 (lacking
several proteases) was transformed with plasmid pRHotreR
carrying the treR gene behind the strong inducible promoter of pCYTEXP1. Growing in LB, the strain showed strong
expression of treR only after a temperature shift from 28 to
42 °C as demonstrated by SDS-PAGE (Fig. 4). After
harvesting the cells most of the overproduced protein appeared in the
soluble fraction (Fig. 4). TreR was purified by ammonium sulfate
precipitation (30-50% saturation) followed by chromatography through
a heparin-Sepharose column. Homogeneous TreR was eluted from the
heparin column at 320 mM KCl (Fig. 4). The yield from a
1-liter LB culture was routinely 70 mg of homogeneous protein. It was
stored in precipitated form (60% saturated ammonium sulfate) for
several months without loss of activity as measured by its ability to
bind substrate. Molecular sieve chromatography through Superdex 200 revealed that TreR behaves as a molecule with a molecular weight of
70,000. Therefore, TreR is a dimer of identical subunits. The dimeric
state of TreR was not changed in the presence of 10 mM
trehalose or 10 mM trehalose 6-phosphate, the inducer of
the system (data not shown).
TreR Binds Trehalose 6-Phosphate and Trehalose
Previously, we
had identified trehalose 6-phosphate as the inducer of the
treB/treC operon (30). Therefore, TreR should bind trehalose 6-phosphate. Using the intrinsic fluorescence of TreR we
found that the emission (excitation at 280 nm) changed in the presence
of trehalose 6-phosphate (Fig. 5A). The
reduction in the emission at 340 nm was used to measure binding of
trehalose 6-phosphate (Fig. 5B). Half-maximal saturation
identical with the Kd of binding occurred at 10 µM trehalose 6-phosphate. To our surprise, the addition
of trehalose also caused a change in the fluorescence emission of
the protein (Fig. 5A) with the half-maximal concentration
being 280 µM (Fig. 5B). Other sugars at 10 mM concentration such as glucose, maltose, and sucrose did not elicit changes in the emission spectrum (data not shown).
TreR Consists of at Least Two Domains
During purification of
TreR, particularly when purified from extracts of a strain not carrying
mutations in different proteases, the rapid formation of a proteolytic
breakdown product of 29 kDa was observed. This proteolytic fragment was
still able to dimerize (data not shown). During elution from
heparin-Sepharose, a heterodimer peak was visible consisting of an
intact monomer and a proteolyzed monomer (in the ratio of 1:1). This
heterodimer eluted at lower salt concentrations than the intact
homodimer (250 and 320 mM KCl, respectively) implicating a
lower binding affinity of this heterodimer toward heparin (data not
shown). By incubating the purified intact protein with thermolysin we
were able to produce the same proteolytic 29-kDa fragment of TreR (Fig.
6) even at a very low protease concentration (6 µg/ml;
Fig. 6, lane 2). The protease stability of the 29-kDa
fragment could be improved by incubation with 0.3 mM
trehalose 6-phosphate but not by trehalose (data not shown). The
stability of this fragment allowed the determination of its
amino-terminal sequence. The sequence obtained indicated the existence
of three different proteolytic fragments differing only in the last 3 or 6 amino-terminal amino acids (Fig. 7). Therefore, this region is likely to represent a linker between the
carboxyl-terminal dimerization domain and the amino-terminal
DNA-binding domain of the intact protein.
TreR Binds DNA Containing a Specific Palindromic Sequence
By
use of DNase I footprinting analysis we determined the sequence of the
DNA recognized and bound by TreR. Increasing amounts of TreR were
incubated with linear DNA carrying the promoter fragment of
treB/C prior to incubation with nuclease.
Depending on the concentration of TreR, a DNA segment with the centered
perfect palindromic sequence 5-CGGGAAC
GTTCCCG-3
was protected from DNase I (Fig. 8, lanes 1-8). At
concentrations of 1 nM TreR or lower no protection of the
DNA was visible and at 5 nM TreR protection was complete.
At the highest concentration used (250 nM), no unspecific binding of DNA was detectable. When trehalose 6-phosphate (1 mM) was added to the assay, the DNA-protecting ability of
TreR changed. No binding to DNA was obtained at low TreR concentrations
(5 nM). At higher concentrations (>50 nM), the
protein was able to bind to the same DNA sequence as in the absence of
the inducer (Fig. 8, lanes 9-15). The addition of trehalose
(1 mM) did not change the DNA binding ability of TreR (Fig.
8, lanes 16-22). The TreR binding site is located near the
hypothetical cAMP/CAP binding site and partially overlaps the
35
region of the major promoter of treB/C (Fig.
9). The topology of the DNA had no influence on the
results obtained since identical binding patterns were visible with
supercoiled DNA (data not shown). Similar results concerning the
binding of TreR to its operator were obtained by gel retardation assays
(data not shown).
In this paper, we describe the molecular and biochemical characterization of TreR, the regulatory protein of the treB/C operon of E. coli. treR had previously been identified by the phenotype of an insertion in this gene. treR mutants are constitutive in the expression of the treB/C operon and become repressed when treR is overexpressed on a multicopy plasmid (15). Therefore, TreR acts as the repressor of treB/C, the genes encoding the trehalose-utilizing enzymes. The detailed analysis of treR and its encoded protein TreR reported here firmly establishes the regulation of the metabolic pathway of trehalose utilization at low and high osmolarity.
TreR of E. coli and the very closely related bacterium Salmonella typhimurium (31) is homologous to other repressor proteins of the LacI-GalR family, but significant homology only exists in the amino-terminal part of the protein known to contain the helix-turn-helix motif for DNA binding (32).
By the use of substrate-dependent fluorescence quenching, we established that trehalose 6-phosphate is bound by TreR. Binding of this sugar phosphate not only causes a fluorescence quench but also a shift in the emission maximum, which is indicative of a conformational change of the protein upon binding substrate. By titration we calculated a Kd of 10 µM. This is significantly lower than the Km of TreC (6 mM) (16), which is the trehalose 6-phosphate-hydrolyzing enzyme. From the maximal rate of TreB-mediated transport in a fully induced strain and the capacity of TreC, we could estimate that the equilibrium concentration of internal trehalose 6-phosphate at saturating external trehalose concentration is about 0.6 mM (16). This is far above the limiting concentration for saturation of TreR thus ensuring full induction.
In the absence of trehalose 6-phosphate, TreR binds to DNA harboring
the control region of the treB/C operon. This can
be seen by gel shift as well as nuclease protection assays. The
analysis of the latter reveals the palindromic sequence
5-CGGGAAC
GTTCCCG-3
as the only TreR binding site of the operator
of the treB/C operon. Significantly, this
sequence contains a central CG which has been found in all operators of
the LacI family (33).
Müller-Hill and co-workers (34, 35) have proposed rules for the
interaction of the recognition helix of repressors with their cognate
operators. In particular, bases 4 and 5 of the symmetrical operator
sequence (counted from the center of symmetry toward the 5 direction)
only allow a narrow range of amino acid side chains in positions 1 and
2 of the recognition helix for effective repression. When the
lac operator sequence was mutated to carry GG at positions 4 and 5 the only amino acids tolerated for effective repression at
positions 1 and 2 of the equally mutated recognition helix were Lys for
position 1 and Ser for position 2 (34). Exactly this combination occurs
in the tre system for the operator (Fig. 8) and recognition
helix (Fig. 3). This finding lends further support to the validity of
rules in repressor-operator recognition.
The operator sequence partially overlaps the putative binding site for cAMP/CAP. One could therefore argue that the effective transcription of the operon is solely due to the activation by the cAMP·CAP complex, and the function of TreR is to prevent this activation. The TreR concentration needed to protect the operator-DNA from nuclease attack is at least 50 nM in the presence of 1 mM trehalose 6-phosphate versus 5 nM in its absence (Fig. 9). The presence of 1 mM trehalose neither affects the ability of TreR to protect the DNA from nuclease action nor its ability to elicit a gel retardation effect. As seen by footprint analysis, the protected DNA region is somewhat larger when TreR has bound trehalose 6-phosphate. This indicates a conformational change of the dimeric repressor protein resulting in an increased distance of its two DNA-binding motifs.
To our surprise, we found that TreR is also able to bind trehalose, although with a much higher Kd than it binds trehalose 6-phosphate (280 versus 10 µM). The Kd for binding trehalose is far lower than the measured concentration of this sugar when synthesized at high osmolarity (about 400 mM) (5) and therefore should be of physiological significance. The conformational change deduced from the fluorescence change was not the same as the one that is caused by binding trehalose 6-phosphate. Nevertheless, the addition of excess trehalose 6-phosphate to TreR that already contained bound trehalose lead to the typical spectrum seen in the presence of trehalose 6-phosphate only. This was also true for the addition of a large excess of trehalose to TreR that contained bound trehalose 6-phosphate. This indicates that both sugars bind competitively to the same site but their binding causes different conformations of the protein.
Because trehalose is synthesized internally at high osmolarity and
treB/C (the genes encoding the degradative
enzymes under TreR control) become uninducible under these conditions,
one may conclude that binding of trehalose could enhance the affinity of TreR for the operator. However, this is not the case. Yet, the
simple competition by the high trehalose concentration for the binding
of trehalose 6-phosphate to TreR will also slow down or even prevent
induction. Trehalose thus behaves as an anti-inducer of the
tre system. Similar observations have been made in the case
of the Lac repressor where it was found that sugars other than the
inducer isopropyl-1-thio--D-galactopyranoside, such as
o-nitrophenyl-
-D-fucoside or even glucose, in
high concentrations could compete with the binding of inducer but did
not elicit repression by themselves (36). Thus, the synthesis of
trehalose can cause the physiologically important uninducibility of the
treB/C operon independently of the enzymatic
activity of the trehalose 6-phosphate-degrading enzyme (OtsB) as we
have considered previously (30). Therefore, TreR is the major control
element to ensure the proper separation of the two crossing pathways of
synthesis and degradation of trehalose in E. coli.
The strong evidence of a promoter element divergent to the treR promoter opens the possibility of a treR specific antisense RNA pointing to an additional form of regulation. More studies are necessary to unravel this aspect.
Recently, the repressor for the genes encoding the trehalose-utilizing enzymes in Bacillus subtilis was described (37). These enzymes, enzyme IIBCTre and trehalose-6-phosphate hydrolase (38, 39), are homologous to the corresponding enzymes from E. coli. Surprisingly, this is not true for the repressor.
The biochemical analysis of TreR showed that the protein forms a dimer of two identical subunits irrespective of its bound ligand. Like in other repressors of this family, the dimerization domain was found to be localized in the carboxyl-terminal part of the protein whereas the DNA-binding domain is localized near the NH2 terminus. This was clear from the appearance of a stable 29-kDa degradation product that was either formed during the isolation from protease-containing extracts or by the addition of thermolysin to the purified protein (Figs. 4 and 6). The 29-kDa carboxyl-terminal dimerization domain was stable against further proteolysis. A very similar fragment lacking the first 60 NH2-terminal amino acids was produced by trypsin treatment of the Lac repressor retaining the tetramerization domain but lacking the operator binding activity (40) pointing once again to the close relationship of these two repressors.
Even though it belongs to the same family as the tetrameric LacI repressor, the TreR repressor only forms a dimer. This is due to the lack of the four-helix bundle oligomerization domain in TreR that is present at the extreme carboxyl terminus of the Lac repressor (41, 42).
Early on it had been proposed that the inducer-binding domain of repressors is homologous to the substrate binding cleft in the well studied sugar-binding proteins involved in transport and chemotaxis (43, 44). Indeed, the elucidation of the three-dimensional structure of the Lac repressor (42, 45) and the PurR repressor (33) has fully confirmed this concept. The determination of the crystal structure of the TreR repressor that is under way will add to our knowledge of the molecular properties of these interesting proteins.
The nucleotide sequence(s) reported in this paper has been submitted to the GenBankTM/EMBL Data Bank with accession number(s) U07790[GenBank].
We thank J. E. G. McCarthy for pCYTEXP1 and R. Hengge-Aronis for rpoS::Tn10.