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J Biol Chem, Vol. 274, Issue 29, 20259-20264, July 16, 1999
From the We report the cloning, sequencing, and expression
of malK encoding the ATP-hydrolyzing subunit of the
maltose/trehalose transport system of the hyperthermophilic archaeon
Thermococcus litoralis. According to the deduced amino acid
sequence, MalK consists of 372 amino acids with a calculated molecular
weight of 41,787. It shows 47% identity with the MalK protein of
Escherichia coli and high sequence conservation in
important regions. C-terminal His-tagged MalK was purified. The soluble
protein appeared monomeric by molecular sieve chromatography and showed
ATPase activity. Enzymatic activity was highest at 80 °C with a
Km of 150 µM and a
Vmax of 0.55 µmol of ATP hydrolyzed/min/mg of
protein. ADP was not a substrate but a competitive inhibitor
(Ki 230 µM). GTP and CTP were also
hydrolyzed. ATPase activity was inhibited by
N-ethylmaleimide but not by vanadate. The strong homology
found between the components of this archaeal transport system and the
bacterial systems is evidence for the evolutionary conservation of the
ABC transporters in these two phylogenetic branches.
High affinity binding protein-dependent ABC
transporters were originally discovered in Gram-negative bacteria. They
consist of a binding protein as their major substrate recognition site, located in the periplasm, two hydrophobic membrane proteins forming the
translocation pore, and, peripherally associated with them at the inner
face of the membrane, two additional subunits. By ATP hydrolysis the
latter provide the energy for the accumulation of substrate (1). In the
case of the Escherichia coli maltose/maltodextrin transport
system, malE is the gene for the periplasmic-binding protein
(MBP or MalE),1 the membrane
components are encoded by genes malF and malG,
and the two ATP-hydrolyzing subunits, by malK. These genes
form a cluster on the E. coli chromosome where malE
malF malG constitute an operon that is oriented divergently to
malK (2). Binding protein-dependent
ABC transporters have also been found in thermophilic bacteria (3, 4).
Recently, we described an ABC transporter for maltose/trehalose in
the hyperthermophilic archaeon Thermococcus litoralis (5).
This transport system has several unusual properties. It shows an
extremely high affinity (Km of about 20 nM) at 85 °C, the optimum growth temperature of this
organism, and it recognizes with equal affinity its very different
substrates, maltose and trehalose, and is not inhibited by
maltodextrins. The soluble high affinity maltose/trehalose-binding
protein (TMBP) is anchored to the membrane by a lipid anchor.
malE, the gene encoding TMBP, is the first gene in an operon
with malF and malG as distal genes (6). Here we
report the molecular characterization of malK and the
biochemical properties of the encoded purified His-tagged protein.
Cloning of T. litoralis malK--
Chromosomal DNA was prepared
from T. litoralis by the method of Owen and Borman (7).
Because the trehalose/maltose system of T. litoralis is
nearly identical to that of Pyrococcus furiosus, we searched
the P. furiosus sequence data base at the Center of Marine
Biotechnology, University of Maryland Biotechnology Institute, for
homology to the E. coli malK gene. The open reading frame with the highest homology was chosen for the synthesis of primers for
amplification of the corresponding malK gene from T. litoralis. The two primers
(5'-GCCATGGCTGGTGTTAGGCTTGTA-3' and
5'-CTGGATCCCAATATTGCTTTTCCTGTG-3') contained the
endonuclease restriction sites for NcoI and BamHI (underlined), respectively. After digestion with the corresponding restriction enzyme, the fragment was ligated into plasmid pCS19 (obtained from C. Spiess). This plasmid is a derivative of pQE60 (a
his-tag vector from Qiagen) and contained the
lacIq gene ligated into the XbaI site
of pQE60. The resulting open reading frame (His6)MalK
carried a C-terminal extension of 10 amino acids: GSRSHHHHHH. The
resulting plasmid was named pGG100.
Purification of His6MalK--
E. coli
strain SF120 (8) was transformed with pGG100 selecting for ampicillin
resistance. The transformants were pooled and aliquoted, frozen in
liquid nitrogen, and stored at ATPase Assay and Analytical Techniques--
ATPase activity was
determined colorimetrically (9). 10 µg of MalK was added to 0.5 ml of
ATPase buffer (50 mM Tris-HCl, pH 7.5, 150 mM
NaCl, 5 mM MgCl2). The solution was heated to
80 °C, and the assay was initiated by adding ATP at 1 mM
final concentration. After 5 min, the reaction was stopped by freezing
in liquid nitrogen. After thawing, the amount of liberated
Pi was determined according to Chan et al. (9).
ATPase activity is given in units defined as the amount of enzyme
liberating 1 µmol of Pi/min under the assay conditions.
Protein determination was according to Bradford (10) with reagents from
Bio-Rad. SDS-polyacrylamide gel electrophoresis was according to
Laemmli (11).
Nucleotide Sequence Accession Number--
The sequence of
malK from T. litoralis (strain DSM 5473, maintained in the laboratory of Dr. H. Santos, Instituto de Tecnologia Química e Biol-gica, Universidade Nova de Lisboa) as shown in Fig. 1 has GenBankTM accession number AF121946. The sequence of
malK of T. litoralis strain DSM 5473 maintained
in the laboratory of Jocelyne DiRuggiero (Center of Marine
Biotechnology, University of Maryland, Baltimore, MD 21202) has the
accession number AF126010.
Preparation of Antibodies and Western Blot Analysis--
A
chicken was immunized five times with 100 µg of purified MalK. 14 days after the last immunization, antibodies were prepared from 10 eggs
(12). Western blot analysis was done as described previously (13, 14)
using the primary antibody (17 mg/ml) in a dilution of 1 to 10,000.
Cloning and Sequencing of the T. litoralis malK Gene--
The
previous analysis of T. litoralis DNA harboring the
malEFG cluster did not reveal the presence of
malK. Upstream of malEFG we found an apparently
unrelated gene (orf1) encoding a plant fructokinase homolog
(GenBankTM accession number AF096373) and downstream, two genes
(orf2 and orf3) with homology to a gene encoding
a sugar phosphorylase (synthase) (15) and to cymJ of Klebsiella oxytoca (16), respectively.
Progress in the P. furiosus sequencing
project2 revealed the
presence of two similar but distinct genes that were homologous to
E. coli malK. One of them was located close to the
previously identified malG gene, directly adjacent and
distal to cymJ. We realized that the mal gene
cluster as well as the adjacent genes of T. litoralis were
nearly identical to the corresponding cluster of P. furiosus. Primers designed from the P. furiosus malK
sequence were used to clone the T. litoralis malK gene,
using T. litoralis DNA provided by the laboratory of Helena
Santos (Instituto de Tecnologia Química e Biológica,
Universidade Nova de Lisboa). Dr. Santos obtained her T. litoralis strain DSM 5473 from the Deutsche Sammlung von
Mikroorganismen und Zellkultur GmbH (Braunschweig, Germany).
The polymerase chain reaction fragment was cloned into an expression
vector that attached a 10-amino acid extension containing 6 histidine
residues to the C terminus, resulting in plasmid pGG100. The
recombinant malK gene was sequenced, and the nucleotide and deduced amino acid sequence are shown in Fig.
1. The malK sequence has 30 base pair changes in comparison to the corresponding sequence of the
same T. litoralis strain DSM 5473, which is maintained in
the laboratory of J. DiRuggiero. This resulted in a difference of four
amino acids in the two MalK protein sequences. In contrast, comparison
of the malK sequence from T. litoralis
(maintained in the laboratory of J. DiRuggiero) to that of P. furiosus showed only an exchange of 7 base pairs resulting in two
altered amino acids. When the sequence of T. litoralis MalK
(maintained in the laboratory of H. Santos) was compared with the
corresponding sequence of P. furiosus, 37 base pair changes
were observed resulting in the exchange of 6 amino acids. The important
conclusion from this comparison is that T. litoralis and
P. furiosus do contain the nearly identical binding
protein-dependent trehalose/maltose ABC transport system.
Attempts to identify in T. litoralis a second and
nonidentical mal gene cluster that is present in P. furiosus did not yield any result.
Fig. 2 shows an alignment of T. litoralis MalK protein with MalK proteins from several bacteria
and a putative MalK protein from another archaeon (Pyrococcus
horikoshii). As expected, the degree of sequence identity is high
among the archaeal MalK proteins (80%), but surprisingly, it is also
very high with MalK proteins from both Gram-positive and -negative
bacteria ({sim]50%).
The conserved regions are clustered around the recognized functional
domains of MalK, i.e. Walker A and B motif and the ABC motif
LSGGQ (linker peptide) (17) as well as the recently recognized H motif
overlapping the switch region (18). The sequence homology is still
noticeable in the C-terminal half of the protein, which is lacking in
some ABC proteins. In contrast, sequence comparison of the T. litoralis MalEFG subunits with the corresponding bacterial proteins revealed only 25-35% identity (6).
The T. litoralis MalK sequence (from the laboratory of H. Santos) has 50 positively and 52 negatively charged amino acids (11 and
9 more than the E. coli sequence, respectively) of a total of 372 amino acids (371 amino acids in E. coli MalK). Also,
T. litoralis MalK contains 20 phenylalanines, which is 9 more than in E. coli, and 8 of these additional
phenylalanines are in the less conserved C-terminal portion.
Purification of Recombinant T. litoralis MalK--
Recombinant
MalK protein was purified from strain SF120, which lacks several
proteases (8). Strain SF120 was transformed with pGG100 and grown at
28 °C in rich medium (NZA) to an A578 of
about 1 before the expression of malK was induced with
isopropyl-1-thio-
After the last purification step (Fig. 3), the sample still contained
small amounts of a contaminating protein of about 29,000 daltons that
could not be removed. N-terminal amino acid sequencing of the
contaminant revealed that it contained a part of the MalK sequence
starting with methionine-178. Inspection of the upstream DNA sequence
suggested that this protein might originate from a second translational
start site. Apparently, restart from within an open reading frame of
DNA from hyperthermophilic archaea heterologously expressed in E. coli is not uncommon (20).
Biochemical Characterization of MalK--
The purified protein
showed ATPase activity. Fig. 4 shows that
the activity was highest at 80 °C but hardly measurable at room
temperature. Incubating the protein in buffer at 80 °C resulted in
loss of activity with a half-life time of 45 min. At 80 °C we
determined a pH optimum of 7.0 (Fig. 5),
a Km of 155 µM, and a
Vmax of 0.55 µmol of ATP hydrolyzed/min/mg of
protein (Fig. 6). ADP and ATP
It had been reported that the intrinsic tryptophan fluorescence of MalK
from S. typhimurium is quenched by ATP, indicating a
conformational change (22). We saw the same magnitude of an apparent
fluorescence quenching by ATP when using T. litoralis MalK.
However, we also observed this quenching with serum albumin and
conclude that ATP and other nucleotides generally interfere with
fluorescence measurement by a filter effect, reducing both excitation
and emission. Thus, we believe that the apparent reduction in
fluorescence by ATP cannot be taken as evidence for a protein conformational change.
Even though the protein has ATPase activity and showed a surprisingly
high sequence identity with E. coli MalK, the recombinant T. litoralis MalK was not able to complement a
malK mutant of E. coli for growth on maltose at
37 °C when expressed from the isopropyl-1-thio-
The malK gene from the T. litoralis strain
maintained in the laboratory of J. DiRuggiero has also been cloned and
overexpressed, and the protein was purified in the same manner as
described above. This protein showed the same biochemical
characteristics as the other MalK species. Thus, the difference in four
amino acids does not seem to have an effect on the activity of the protein.
Induction Pattern--
The purified His-tagged protein was used to
obtain polyclonal antibodies in chicken. This antiserum was able to
recognize MalK in extracts of T. litoralis. We tested the
amount of MalK in T. litoralis by Western blotting of
extracts from cells grown in peptone with and without the addition of
maltose, trehalose, and yeast extract. Fig.
7 shows that MalK was induced by maltose, trehalose, and yeast extract. The induction appeared less pronounced than the induction of the cognate TMBP and the corresponding transport activity in intact cells (Fig. 7) (6).
In this publication we describe the cloning of malK
from the hyperthermophilic archaeon T. litoralis, its
expression in E. coli, and the purification and biochemical
characterization of the recombinant protein. With the exception of
malK, the organization of the T. litoralis
trehalose/maltose transport operon malEFG (Fig. 1) is very
similar to that of E. coli and other bacterial binding
protein-dependent ABC transport systems (1). At present it
is unclear whether or not malK is expressed from a different promoter than malEFG. The Western blot analysis shown in
Fig. 6 suggests that malK is coregulated with
malEFG. The open reading frames orf3 and
malK are separated by only five nucleotides, indicating translational coupling of the two genes that might form an operon. 32 nucleotides upstream of the translational start of orf3 the sequence TTTTAAA points to the presence of an element identical with
the consensus sequence of archaeal promoters (Box A) (24).
The T. litoralis MalK protein exhibits an astonishingly high
sequence identity of 50% with the E. coli protein (25-27).
It is noteworthy that the T. litoralis protein has 23% more
positively and 17% more negatively charged amino acids than the
E. coli protein, which is in agreement with the notion that
ionic interactions are important for high thermostability (28). Even
the nonidentical part of T. litoralis MalK appears highly
homologous to the E. coli protein. Walker A and B motifs are
well conserved as is the intervening linker region LSGGQQ, the
established ABC signature (29). Purified His-tagged MalK heterologously
expressed in E. coli shows ATPase activity that is
comparable in its kinetic constants with the well studied MalK
protein from S. typhimurium (21).
E. coli MalK is known to be involved in the regulation of
mal gene expression. Several amino acids in its C-terminal
part define a domain responsible for this repressor function (23, 30).
Repression works via an interaction of MalK with the transcriptional activator MalT (31). None of the amino acids of E. coli MalK that supposedly participate in the MalK-MalT interaction are conserved in the T. litoralis MalK sequence.
At present it cannot be directly proven that the MalK protein, purified
and characterized in this publication, is really part of the
trehalose/maltose transport machinery. This can only be inferred from
the position of the malK gene next to the malEFG cluster and from the induction pattern. The two genes orf2
and orf3 that separate malEFG from
malK encode open reading frames with homology to a sugar
phosphorylase (synthase) (15) and a CymJ protein. Whereas the role (if
any) of orf2 in a (trehalose/maltose) transport gene cluster
is unclear, the presence of cymJ has been observed
previously in a gene cluster of Klebsiella oxytoca encoding a binding protein-dependent ABC transporter for cyclic
dextrins (16). The function of CymJ remains unknown.
There are more differences between the two T. litoralis malK
sequences than to the corresponding sequence from P. furiosus. This is probably due to mutations that accumulated over
the multiple cell generations. Because the two T. litoralis
strains have been maintained in different laboratories under different
conditions, it is not surprising that the mutations appear.
We found that the sequences of the mal genes and adjacent
genes in T. litoralis are nearly identical to those in the
P. furiosus genome. Interestingly, such a gene cluster has
not been found in the genome of the closely related archaeon P. horikoshii. There, the homologous malE malF malG orf2
and orf3 cluster is present but lacks the downstream
malK (32). Yet, this genome contains several genes encoding
ABC proteins with high homology to MalK from T. litoralis,
the one fitting best showing 80% sequence identity (cf.
Fig. 2). This raises the possibility not only of a gene transfer between P. furiosus and T. litoralis3 but also
between bacteria (likely Gram-positive bacteria (33)) and archaea (34).
Analysis of the many complete genomes that have been published in the
last few years has shown that in archaea most of the
information-processing genes (i.e. for replication, repair,
transcription, and translation) are more closely related to eukaryal
genes, whereas their metabolic genes are more closely related to
bacterial genes.
Nevertheless, binding protein-dependent transport systems
must have appeared early in evolution. A gene cluster supposedly encoding a maltose transport machinery also exists in T. maritima which, like T. litoralis in the archaea, is
one of the most deeply branched bacteria with a maximum growth
temperature of 90 °C (35).
We gratefully acknowledge the receipt of
plasmid pCS19 from Christoph Spiess.
*
This research was supported by grants from the Deutsche
Forschungsgemeinschaft, Forschergruppe, Struktur und Funktionssteuerung an zellulären Oberflächen (to W. B.), and by the
Department of Energy (DE-F902-92ER20083) (to J. DR.).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.
The nucleotide sequence(s) reported in this paper has been submitted to the GenBankTM/EMBL Data Bank with accession number(s) AF121946.
¶
To whom correspondence should be addressed: Tel.: 49 7531 88 2658; Fax: 49 7532 88 3356; E-mail:
winfried.boos@uni-konstanz.de.
2
R. Weiss, manuscript in preparation.
3
Flanked by inverted sequence elements in
P. furiosus, this gene cluster is evidence for a recent
horizontal gene transfer between two organisms (J. DiRuggiero, G. Greller, R. Horlacher, and W. Boos, manuscript in preparation.
The abbreviations used are:
MBP (or MalE), periplasmic-binding protein;
TMBP, maltose/trehalose-binding protein;
ATP
Molecular and Biochemical Analysis of MalK, the ATP-hydrolyzing
Subunit of the Trehalose/Maltose Transport System of the
Hyperthermophilic Archaeon Thermococcus litoralis*
,,¶
Department of Biology, University of
Konstanz, D-78457 Konstanz, Germany and § Center of Marine
Biotechnology, University of Maryland, Baltimore, Maryland 21202
ABSTRACT
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
MATERIALS AND METHODS
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
80 °C. These aliquots were used to
inoculate overnight cultures subsequently used for large scale
cultures. Cultivation was done in 6 liters of NZA medium (10 g NZ-amine
A (Sheffield Products Inc.), 5 g of yeast extract, and 7.5 g
of NaCl/liter) containing 200 mg of ampicillin/liter. After the culture
reached an optical density at 578 nm (A578) of
1, 0.1 mM
isopropyl-1-thio-
-D-galactopyranoside was added. 12 h later the culture was harvested by centrifugation. The pellet was
resuspended in 80 ml of buffer 1 (50 mM Tris-HCl, pH 7.5, containing 500 mM NaCl), ruptured in a French pressure cell
at 16,000 pounds/square inch, and centrifuged for 15 min at 19,000 × g. The supernatant was heated to 80 °C for 10 min. After centrifugation of the precipitated proteins (30 min at
19,000 × g), imidazol was added to the supernatant to
a final concentration of 20 mM. The solution was loaded
onto a Ni2+-nitrilotriacetic acid-agarose column (4-ml bed
volume) from Qiagen equilibrated with the same buffer. After washing
the column with 80 ml of buffer 1 (containing 20 mM
imidazol), MalK was eluted with buffer 1 containing 100 mM
imidazol. MalK-containing fractions (30 ml) were pooled and loaded onto
a Reactive Red agarose 120 (3000-CL) column from Sigma (bed volume, 8 ml) equilibrated with buffer 1. The column was washed with 5 bed
volumes of buffer 1. Elution of MalK was achieved by 50 mM
Tris-HCl, pH 7.5, containing 1 M NaCl. MalK-containing
fractions (30 ml) were pooled and dialyzed against 50 mM
Tris-HCl, pH 7.5, containing 150 mM NaCl. The enzyme was
stored at 4 °C without loss of activity.
RESULTS
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
View larger version (38K):
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Fig. 1.
Nucleotide sequence of malK
and deduced amino acid sequence of MalK from T. litoralis (strain DSM 5473). The top of the figure
indicates the gene cluster in which malK is located.
orf1 shows homology to a fructokinase (GenBankTM
accession number AF096373), orf2 to an enzyme resembling
sugar phosphorylase (15), and orf3 to CymJ, whose
gene lies within a cluster of genes encoding a cyclodextrin transport
system of K. oxitoca (16). Where the sequence is different
in the two isolates, the upper base corresponds to the strain
maintained in the laboratory of H. Santos, and the lower base (and
amino acid) corresponds to the strain maintained in the laboratory of
J. DiRuggiero. Numbering refers to the amino acid sequence.
View larger version (74K):
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Fig. 2.
Alignment of the amino acid sequences of MalK
from T. litoralis with MalK from several bacteria and
a putative MalK protein from the archaeon P. horikoshii. T.l., T. litoralis
(47% identity with E. coli MalK); ABC Pho, open
reading frame PH0194 in P. horikoshii (32) with highest
homology (80% identity) to T. litoralis MalK; MsmX
B.s., multiple sugar ABC transporter of Bacillus
subtilis (36), 53% identity with T. litoralis MalK;
MsmK S.m., multiple sugar ABC transporter of
Streptococcus mutans (37), 50% identity with T. litoralis MalK. Not shown in the figure, sequence identities with
the corresponding subunit of a glycerol 3-phosphate transport system
from E. coli (38) (49%) and a cyclodextrin transport system
in K. oxytoca (16) (50%) are equally high. Signature
sequences (Walker A and B motif) (39), the ABC motif LSGGQ (17), the
switch region (17) overlapping IYVTHD and the recently recognized H
region (18) are indicated. E. C., E. coli.
-D-galactopyranoside. Under these
conditions, MalK does not form inclusion bodies but remains as a
soluble protein in the cytoplasm. It was purified from the soluble
cellular extract by heat treatment (80 °C for 10 min),
Ni2+-nitrilotriacetic acid-agarose affinity chromatography,
and dye ligand chromatography on Red agarose. SDS-polyacrylamide gel
electrophoresis was used to follow the purification protocol (Fig.
3). The total yield of purified
recombinant MalK from a 6-liter culture was routinely between 40 and 60 mg. Molecular sieve chromatography gave no hint for multimerization.
MalK eluted as a symmetric peak with a calculated molecular weight of
40,000 (data not shown). Samples of MalK with and without ATP were
investigated by dynamic light scattering (19) at different temperatures
using a DynaPro mass spectrometry instrument. Values of mean particle
radius and estimated molecular weight were essentially identical for
both samples (data not shown).
View larger version (75K):
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Fig. 3.
Purification of MalK from T. litoralis. Shown is the analysis by SDS-polyacrylamide
gel electrophoresis of the different protein fractions during
purification. Lane 1, whole cells of the producer strain
grown in the absence of inducer; lane 2, whole cells of the
producer strain grown in the presence of inducer; lane 3,
crude extract; lane 4, crude extract after heating to
80 °C for 10 min; lane 5, after
Ni2+-nitrilotriacetic acid column; lane 6,
preparation after Red agarose; lane 7, molecular mass
standards in kDa.
S were
not substrates but competitive inhibitors for ATP hydrolysis
(Ki values of 230 µM). GTP and CTP were also hydrolyzed with Km values of 430 µM and 870 µM, and
Vmax values of 0.45 and 0.32 µmol/min/mg of
protein, respectively (Fig. 5). ATPase activity was inhibited by 10, 60, and 97% after incubating the enzyme with 10 µM, 100 µM, and 1 mM N-ethylmaleimide for
5 min. The additional presence of 1 mM ATP during
incubation largely prevented inactivation by 1 mM NEM (75%
remaining activity). In agreement with the property of MalK from
Salmonella typhimurium, ATPase activity was not inhibited by
10 mM vanadate (21).
View larger version (15K):
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Fig. 4.
ATPase activity of T. litoralis
MalK in dependence of temperature. The enzyme was heated for
5 min at the temperature indicated before addition of ATP. ATP
hydrolysis proceeded for 5 min. Specific activity is given in µmol of
ATP hydrolyzed/min/mg of protein.
View larger version (13K):
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Fig. 5.
pH dependence of the ATPase activity of
T. litoralis MalK measured at 80 °C. Specific
activity is given in µmol of ATP hydrolyzed/min/mg of protein.
View larger version (15K):
[in a new window]
Fig. 6.
Km and
Vmax determination of the ATPase activity
of T. litoralis MalK at 80 °C. ATPase activity
of T. litoralis MalK was determined at 80 °C at different
substrate concentrations. The data were plotted according to
Lineweaver-Burk. A Km of 155 µM and a
Vmax of 0.55 µmol of ATP hydrolyzed/min/mg of
protein was determined. Filled diamonds, ATP; filled
triangles, GTP; open triangles, CTP.
-D-galactopyranoside-induced plasmid
pGG100. It was also unable to affect mal gene expression as
does E. coli MalK when overproduced (23).
View larger version (14K):
[in a new window]
Fig. 7.
Induction pattern of TMBP and of MalK from
T. litoralis estimated by Western blotting. Equal
amounts of whole T. litoralis cells separated by
SDS-polyacrylamide gel electrophoresis. Antibodies raised against TMBP
(A) and against MalK (B) were used as primary
antibodies. The growth medium of the cultures was as follows:
lane 1, peptone; lane 2, peptone plus maltose;
lane 3, peptone plus trehalose; lane 4, peptone
plus yeast extract; lane 5, purified MalK and purified TMBP.
Panel A, antibodies against TMBP; panel B,
antibodies against MalK.
DISCUSSION
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
ACKNOWLEDGEMENT
FOOTNOTES
ABBREVIATIONS
S, adenosine 5'-O-(thiotriphosphate).
REFERENCES
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
1.
Boos, W.,
and Lucht, J. M.
(1996)
in
Escherichia coli and Salmonella typhimurium; Cellular and Molecular Biology
(Neidhardt, F. C.
, Curtiss, R.
, Ingraham, J. L.
, Lin, E. C. C.
, Low, K. B.
, Magasanik, B.
, Reznikoff, W. S.
, Riley, M.
, Schaechter, M.
, and Umbarger, H. E., eds), 2nd Ed., Vol. 1
, pp. 1175-1209, American Society of Microbiology, Washington, DC
2.
Boos, W.,
and Shuman, H. A.
(1998)
Microbiol. Mol. Biol. Rev.
62,
204-229 3.
Sahm, K.,
Matuschek, M.,
Müller, H.,
Mitchell, W. J.,
and Bahl, H.
(1996)
J. Bacteriol.
178,
1039-1046 4.
Herrmann, A.,
Schlösser, A.,
Schmid, R.,
and Schneider, E.
(1996)
Res. Microbiol.
147,
733-737[Medline]
[Order article via Infotrieve]
5.
Xavier, K. B.,
Martins, L. O.,
Peist, R.,
Kossmann, M.,
Boos, W.,
and Santos, H.
(1996)
J. Bacteriol.
178,
4773-4777 6.
Horlacher, R.,
Xavier, K. B.,
Santos, H.,
DiRuggiero, J.,
Kossmann, M.,
and Boos, W.
(1998)
J. Bacteriol.
180,
680-689 7.
Owen, R. J.,
and Borman, P.
(1987)
Nucleic Acids Res.
8,
3631
8.
Baneyx, F.,
and Georgiou, G.
(1991)
J. Bacteriol.
173,
2696-2703 9.
Chan, K.-M.,
Delfert, D.,
and Junger, K. D.
(1986)
Anal. Biochem.
157,
375-380[CrossRef][Medline]
[Order article via Infotrieve]
10.
Bradford, M. M.
(1976)
Anal. Biochem.
72,
248-254[CrossRef][Medline]
[Order article via Infotrieve]
11.
Laemmli, U. K.
(1970)
Nature
227,
680-685[CrossRef][Medline]
[Order article via Infotrieve]
12.
Polson, A.,
von Wechmar, M. B.,
and van Regenmortel, M. H.
(1980)
Immunol. Commun.
9,
475-493[Medline]
[Order article via Infotrieve]
13.
Harlow, E.,
and Lane, D.
(1988)
Antibodies: A Laboratory Manual
, Cold Spring Harbor Laboratory, Cold Spring Harbor, New York
14.
Towbin, H.,
Staehelin, T.,
and Gordon, J.
(1979)
Proc. Natl. Acad. Sci. U. S. A.
76,
4350-4354 15.
Saito, K.,
Yamazaki, H.,
Ohnishi, Y.,
Fujimoto, S.,
Takahashi, E.,
and Horinouchi, S.
(1998)
Appl. Microbiol. Biotechnol.
50,
193-198[CrossRef][Medline]
[Order article via Infotrieve]
16.
Pajatsch, M.,
Gerhart, M.,
Peist, R.,
Horlacher, R.,
Boos, W.,
and Böck, A.
(1998)
J. Bacteriol.
180,
2630-2635 17.
Schneider, E.,
and Hunke, S.
(1998)
FEMS Microbiol. Rev.
22,
1-20[CrossRef][Medline]
[Order article via Infotrieve]
18.
Linton, K. J.,
and Higgins, C. F.
(1998)
Mol. Microbiol.
28,
5-13[CrossRef][Medline]
[Order article via Infotrieve]
19.
Brown, R. G. W.,
Burnett, J. G.,
Mansbridge, J.,
and Moir, C. I.
(1990)
Appl. Optics
29,
4159-4169
20.
Hess, D.,
and Hensel, R.
(1996)
Gene
172,
121-124[CrossRef][Medline]
[Order article via Infotrieve]
21.
Morbach, S.,
Tebbe, S.,
and Schneider, E.
(1993)
J. Biol. Chem.
268,
18617-18621 22.
Schneider, E.,
Wilken, S.,
and Schmid, R.
(1994)
J. Biol. Chem.
269,
20456-20461 23.
Reyes, M.,
and Shuman, H. A.
(1988)
J. Bacteriol.
170,
4598-4602 24.
Thomm, M.
(1996)
FEMS Microbiol. Rev.
18,
159-171[CrossRef][Medline]
[Order article via Infotrieve]
25.
Shuman, H. A.,
and Silhavy, T. J.
(1981)
J. Biol. Chem.
256,
560-562 26.
Gilson, E.,
Nikaido, H.,
and Hofnung, M.
(1982)
Nucleic Acids Res.
10,
7449-7458 27.
Dahl, M. K.,
Francoz, E.,
Saurin, W.,
Boos, W.,
Manson, M. D.,
and Hofnung, M.
(1989)
Mol. Gen. Genet.
218,
199-207[CrossRef][Medline]
[Order article via Infotrieve]
28.
Vetriani, C.,
Maeder, D. L.,
Tolliday, N.,
Yip, K. S.-P.,
Stillman, T. J.,
Britton, K. L.,
Rice, D. W.,
Klump, H. H.,
and Robb, F. T.
(1998)
Proc. Natl. Acad. Sci. U. S. A.
95,
12300-12305 29.
Higgins, C. F.
(1995)
Cell
82,
693-696[CrossRef][Medline]
[Order article via Infotrieve]
30.
Kühnau, S.,
Reyes, M.,
Sievertsen, A.,
Shuman, H. A.,
and Boos, W.
(1991)
J. Bacteriol.
173,
2180-2186 31.
Panagiotidis, C. H.,
Boos, W.,
and Shuman, H. A.
(1998)
Mol. Microbiol.
30,
535-546[CrossRef][Medline]
[Order article via Infotrieve]
32.
Kawarabayasi, Y.,
Sawada, M.,
Horikawa, H.,
Haikawa, Y.,
Hino, Y.,
Yamamoto, S.,
Sekine, M.,
Baba, S.,
Kosugi, H.,
Hosoyama, A.,
Nagai, Y.,
Sakai, M.,
Ogura, K.,
Otsuka, R.,
Nakazawa, H.,
Takamiya, M.,
Ohfuku, Y.,
Funahashi, T.,
Tanaka, T.,
Kudoh, Y.,
Yamazaki, J.,
Kushida, N.,
Oguchi, A.,
Aoki, K.,
and Kikuchi, H.
(1998)
DNA Res.
5,
55-76[Abstract]
33.
Gupta, R. S.
(1998)
Microbiol. Mol. Biol. Rev.
62,
1435-1491 34.
Aravind, L.,
Tatusov, R. L.,
Wolf, Y. I.,
Walker, D. R.,
and Koonin, E. V.
(1988)
Trends Genet.
14,
442-444
35.
Liebl, W.,
Stemplinger, I.,
and Ruile, P.
(1997)
J. Bacteriol.
179,
941-948 36.
Yoshida, K.,
Shindo, K.,
Sano, H.,
Seki, S.,
Fujimura, M.,
Yanai, N.,
Miwa, Y.,
and Fujita, Y.
(1996)
Microbiology
142,
3113-3123 37.
Russell, R. R. B.,
Aduse-Opoku, J.,
Sutcliffe, I. C.,
Tao, L.,
and Ferretti, J. J.
(1992)
J. Biol. Chem.
267,
4631-4637 38.
Overduin, P.,
Boos, W.,
and Tommassen, J.
(1988)
Mol. Microbiol.
2,
767-775[CrossRef][Medline]
[Order article via Infotrieve]
39.
Walker, J. E.,
Saraste, M.,
Runswik, J. M.,
and Gay, N. J.
(1982)
EMBO J.
1,
945-951[Medline]
[Order article via Infotrieve]
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