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Journal of Bacteriology, June 2001, p. 3336-3344, Vol. 183, No. 11
0021-9193/01/$04.00+0 DOI: 10.1128/JB.183.11.3336-3344.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
Reverse Genetics of Escherichia coli
Glycerol Kinase Allosteric Regulation and Glucose Control of Glycerol
Utilization In Vivo
C. Kay
Holtman,1
Aaron C.
Pawlyk,1
Norman D.
Meadow,2 and
Donald W.
Pettigrew1,*
Department of Biochemistry and Biophysics,
Program in Microbial Genetics and Genomics, and Center for Advanced
Biomolecular Research, Texas A&M University, College Station, Texas
77843-2128,1 and Department of Biology
and McCollum-Pratt Institute, The Johns Hopkins University, Baltimore,
Maryland 212182
Received 21 September 2000/Accepted 8 March 2001
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ABSTRACT |
Reverse genetics is used to evaluate the roles in vivo of
allosteric regulation of Escherichia coli glycerol
kinase by the glucose-specific phosphocarrier of the
phosphoenolpyruvate:glycose phosphotransferase system,
IIAGlc (formerly known as IIIglc), and by
fructose 1,6-bisphosphate. Roles have been postulated for these
allosteric effectors in glucose control of both glycerol utilization
and expression of the glpK gene. Genetics methods based
on homologous recombination are used to place glpK
alleles with known specific mutations into the chromosomal context of the glpK gene in three different genetic backgrounds.
The alleles encode glycerol kinases with normal catalytic properties
and specific alterations of allosteric regulatory properties, as
determined by in vitro characterization of the purified enzymes. The
E. coli strains with these alleles display the glycerol
kinase regulatory phenotypes that are expected on the basis of the in
vitro characterizations. Strains with different glpR
alleles are used to assess the relationships between allosteric
regulation of glycerol kinase and specific repression in glucose
control of the expression of the glpK gene. Results of
these studies show that glucose control of glycerol utilization and
glycerol kinase expression is not affected by the loss of
IIAGlc inhibition of glycerol kinase. In contrast, fructose
1,6-bisphosphate inhibition of glycerol kinase is the dominant
allosteric control mechanism, and glucose is unable to control glycerol
utilization in its absence. Specific repression is not required for
glucose control of glycerol utilization, and the relative roles of
various mechanisms for glucose control (catabolite repression, specific repression, and inducer exclusion) are different for glycerol utilization than for lactose utilization.
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INTRODUCTION |
In Escherichia coli,
glucose controls utilization of several other carbon sources, including
lactose, melibiose, maltose, and glycerol (14, 27, 29, 30,
32). Effects of glucose on the expression of genes needed for
metabolism of other sugars, e.g., lactose, formed the foundation for
much of the initial understanding of molecular genetic control
mechanisms. Glucose effects were found to involve both positive and
negative control aspects. At the level of transcriptional control,
these two opposing aspects for expression of the lac operon
are mediated by the cyclic AMP (cAMP)-cAMP receptor protein complex
(for catabolite repression) and by the lac repressor (for
specific repression), respectively. The specific repression is
relieved by binding of an inducer. Subsequent studies have revealed
that glucose acts to modulate the level of cAMP and the level of the
inducer. These controls are exerted by two different forms of
IIAGlc, the glucose-specific phosphocarrier of
the phosphoenolpyruvate:glycose phosphotransferase system (PTS). The
form of IIAGlc that is phosphorylated at an
active-site histidine residue participates in the increase of cAMP by
activation of adenylate cyclase, and the form of
IIAGlc that is unphosphorylated binds to lactose
permease and prevents lactose uptake. Because the latter process
prevents uptake of the inducer, this mechanism is termed inducer
exclusion. IIAGlc-dependent PTS-mediated inducer
exclusion is an important regulatory concept that unifies several
aspects of genetic, allosteric, and metabolic controls. The finding of
both positive and negative control mechanisms raises the issue of their
relative roles in glucose control. In the case of the lac
operon, recent studies show that specific repression coupled to inducer
exclusion is the dominant mechanism for glucose control of lactose
utilization (6, 11, 36). In lacI strains,
glucose control is abolished, which is seen as loss of the repression
of 
-galactosidase and elimination of the plateau during diauxic
growth on glucose-lactose (11). A similar phenotype is
seen for strain PPA586, an MG1655 derivative with
lacY(S209I), in which the lactose permease is thought to be
resistant to IIAGlc inhibition (6, 8,
33).
Glycerol kinase (EC 2.7.1.30; ATP-glycerol 3-phosphotransferase) is a
component of a regulatory network in E. coli by which glucose and other carbon sources control the utilization of glycerol and the gene expression that is needed for glycerol metabolism (14, 27, 29, 32). The proteins involved in glycerol
metabolism are encoded by the elements of the glp regulon,
which displays a complex genetic structure (3, 5, 37, 39).
It contains five operons, which are located at three different
chromosomal loci. Glucose modulation of glycerol utilization involves
both regulation of transcription and posttranslational control of
glycerol kinase catalytic activity. Control of transcription of the
regulon elements is analogous to the lac operon and involves
both positive control by cAMP-cAMP receptor protein and negative
control by a specific repressor that is encoded by the glpR
gene. DNA-binding sites for the specific repressor in the
glpFKX operon have been identified both in the 5' upstream
region and internally within the glpK coding sequence
(37). The inducer for expression of the glp
elements is sn-glycerol 3-phosphate
(15), which is both the product of the reaction that is
catalyzed by glycerol kinase during glycerol catabolism and an
important metabolite in phospholipid biosynthesis under all growth
conditions. The catalytic activity of glycerol kinase is controlled
posttranslationally by the allosteric inhibitors fructose
1,6-bisphosphate (FBP) and IIAGlc (19, 26,
42). These allosteric effectors display V-system regulation (19, 23) that allows efficient control that is not dependent on changes in the concentrations of the substrates. The
unusual existence of two very different allosteric effectors that are
involved in glucose control has been noted and postulated to be the
basis for the extreme effectiveness of glucose in preventing glycerol
consumption (14).
Several years ago, Zwaig and Lin identified the mutant E. coli strain 43 on the basis of its loss of glucose control of
glycerol utilization (42). They showed that the glycerol
kinase from strain 43 had lost sensitivity to inhibition by FBP; the
role of IIAGlc was unknown at that time. We
isolated the glpK22 allele from strain 43 and showed that it
contains a mutation that results in a single amino acid substitution in
glycerol kinase, G-304-S (21). The variant enzyme encoded
by the glpK22 allele was purified and characterized. It was
found to show greatly reduced sensitivity to FBP inhibition, in
agreement with the earlier work, and to show weak activation by
IIAGlc with greatly reduced apparent affinity for
binding IIAGlc. Thus, this variant glycerol
kinase has lost sensitivity to inhibition by both allosteric effectors.
This finding raises the question of the relative roles of the
regulation by each glycerol kinase allosteric effector in glucose
inhibition of glycerol utilization. Results of a study with
Salmonella suggest that both allosteric inhibitors may be
required for glucose control in that organism (19).
In other investigations of the novel allosteric regulation of glycerol
kinase, we identified, purified, and characterized in vitro variant
enzymes that are insensitive to one of the allosteric inhibitors while
retaining normal sensitivity to the other inhibitor as well as normal
catalytic behavior. Glycerol kinase A-65-T is not sensitive to
inhibition by FBP but displays normal regulation by
IIAGlc and normal catalytic properties
(16). Glycerol kinase T-477-N is not sensitive to
inhibition by IIAGlc but displays normal
regulation by FBP and normal catalytic properties (see below). These
variants provide the basis for reverse genetic investigations of the
quantitative contributions of each of the allosteric inhibitors to
glucose inhibition of glycerol utilization and control of expression of
the glp regulon in vivo.
Because of the complex genetic structure of the glp regulon
and the many-faceted control network, it is necessary to place the
glpK alleles encoding the variant enzymes into the normal chromosomal context. This report describes the construction and characterization of strains with chromosomal glpK alleles.
Three different genetic backgrounds were utilized for the
constructions. Initially, strain DG1 was used, because it is a
glpK (16) strain, to facilitate the
constructions. Unexpectedly, however, strain DG1 and its derivatives
were found to carry the glpR208 allele (9).
This allele is functionally identical to the glpR2 allele, and these strains were used here as GlpR
strains. Strain MC4100 was used as a glpR+
strain because other investigators have performed extensive studies of
the glp operator structures and transcriptional control in this strain and some of its derivatives (13, 38, 40).
Strain MG1655 was used as a second glpR+
strain because it is a prototrophic strain and has been used as the
background for extensive investigations of the mechanisms of glucose
control of how other carbon sources are used (6, 7). The
effects of the specific alterations in glycerol kinase allosteric
regulatory properties on diauxic growth on glucose-glycerol, glycerol
utilization, and levels of glycerol kinase specific activity are
described. The results reveal that, in E. coli, FBP
inhibition of glycerol kinase is quantitatively dominant in glucose
control of glycerol utilization, which is independent of inducer
exclusion mediated by specific repression.
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MATERIALS AND METHODS |
Materials.
Chemicals and enzymes were purchased from Sigma
Chemical Co. (St. Louis, Mo.) unless otherwise indicated. Purified
IIAGlc was generously provided by Saul Roseman,
Department of Biology, Johns Hopkins University, Baltimore, Md.
Strains and culture methods.
Biological materials that were
used in these studies are listed in Table
1. All strains were grown in
Luria-Bertani (LB) medium or minimal M9 (18) medium with
carbohydrate added as indicated. MacConkey glycerol agar was prepared
according to the instructions of the manufacturer (Difco). Antibiotics
were added when indicated to obtain final concentrations of 75 µg/ml
for ampicillin, 8 µg/ml for tetracycline, 200 µg/ml for
streptomycin, and 40 µg/ml for kanamycin.
Enzyme assays and protein determinations.
Glycerol kinase
enzyme activity was measured by using the continuous ADP-coupled
spectrophotometric assay at pH 7.0 and 25°C (24). Other
additions are as indicated in the tables and figures. One unit of
glycerol kinase catalyzes the formation of 1 µmol of ADP per min in
this assay. For studies with purified glycerol kinase, the enzyme
concentration was determined from the
A280 (16) and varied from
0.1 to 0.5 µg/ml. Kinetic data were analyzed for initial-velocity or
inhibition parameters as previously described (23). For
studies with cellular extracts, the protein concentration was
determined using the Bio-Rad assay with bovine serum albumin as a standard.
glpK alleles.
Alleles that encode the A-65-T
(glpK203) and G-304-S (glpK22) glycerol kinases
were derivatives of plasmid pHG165 (35) and have been
described previously (16, 21). The allele for the T-477-N
glycerol kinase (glpK204) was constructed by using the Kunkel method of site-directed mutagenesis, as described previously for
the construction of other site-directed variants of glycerol kinase
(23). The variant enzyme was purified to >95%
homogeneity and characterized in vitro by using previously described
protocols (23). The catalytic properties that are reported
are the average of three experiments using enzyme purified from two
independent isolates of the variant enzyme. No significant differences
were found in the properties of the different isolates.
Integration of variant genes into the genome.
The
glpK alleles were moved from the pHG165-derived plasmids
into the chromosome of strain KH10 by conjugation. Strain KH5, transformed with a plasmid carrying the glpK allele, was
mated with strain KH10 (18). Exconjugants with a
functional glpK gene were selected on minimal-glycerol
plates with streptomycin. Individual colonies were purified on
selection medium several times. Purified colonies were screened on LB
and LB-AMP plates to identify AMPs
exconjugants to ensure loss of the plasmid. AMPs
exconjugants were plated on MacConkey glycerol agar to screen for those
able to ferment glycerol, i.e., those putatively bearing a chromosomal
copy of a functional allele. Strains bearing mutations in
glpK were identified by determining the glycerol kinase
regulatory phenotype with enzyme activity and inhibition assays of cell
extracts prepared as follows. AMPs colonies that
fermented glycerol on MacConkey glycerol agar were grown overnight in 2 ml of LB, 1.5 ml of the culture was transferred to a microcentrifuge
tube, and the cells were pelleted by microcentrifugation. The cell
pellet was resuspended in the same volume of standard buffer (0.1 M
triethanolamine HCl, 2 mM glycerol, 1 mM EDTA, 1 mM
-mercaptoethanol, adjusted to pH 7.0 at room temperature by using
NaOH) and disrupted by sonication. Cellular debris was removed using
centrifugation, and the supernatant was transferred to a new tube.
Glycerol kinase activity and the total protein concentration of the
extract were determined as described above. The reported specific
activities were corrected for glycerol-independent ATPase activity in
the cellular extracts by subtracting the rate obtained in assays of
extracts from glpK strains. The correction was 0.1 to 0.3 U/mg for different strains and growth conditions. Extracts were diluted
at least 50-fold into the assays, thus reducing the glycerol
concentration from the extract to a negligible level. Glycerol kinase
activity in the solution was then dependent on addition of glycerol to
the assay. The same reaction rate was observed for the respective
glpK strains and for the
glpK+ strains assayed without added glycerol.
Strains derived by this procedure carry
glpK alleles in the
chromosome in a
glpR208 background and have a tetracycline
marker
near the
glpK gene. This marker was used for
P1 transduction (
18)
with
P1
vir to move the
glpK alleles into
the MC4100 and MG1655
genetic backgrounds. Transductants were selected
on LB-tetracycline
plates and screened on MacConkey glycerol agar to
confirm the
presence of glycerol kinase activity. The glycerol kinase
regulatory
phenotypes of these strains were determined as described
above
after overnight growth in minimal-glycerol (0.2%)
medium.
Diauxic growth curves.
Strains were incubated at 37°C
overnight in 4 ml of M9 minimal-glucose (0.2%) medium. Three
milliliters of the overnight culture was transferred to a sterile
microcentrifuge tube, and the cells were collected by centrifugation.
The cell pellet was resuspended in 1 ml of 1× M9 salts and washed. The
washed cells were resuspended in 1 ml of 1× M9 salts, and the optical
density at 600 nm (OD600) was determined.
Aliquots of these cells were used to inoculate 80 ml of M9 medium
containing either 2.5 mM glucose or 2.5 mM glucose plus 5 mM glycerol
to an OD600 of ~0.02. Growth at 37°C in a
rotary shaker (250 rpm) was monitored by determining the OD600. Periodically,
5-ml aliquots were removed from the growing culture and placed on ice.
Cells and medium were separated by centrifugation. The cells were
resuspended in 1 ml of standard buffer and disrupted with sonication.
After clarification by centrifugation, the resulting cellular extracts
were assayed for glycerol kinase activity and protein concentration.
The concentration of glycerol in the medium was determined by using
end-point assays with glycerol kinase in the ADP-coupled assay. The
concentration of glucose was determined at the Texas Veterinary Medical
Diagnostic Laboratory using endpoint assays with hexokinase and
glucose-6-phosphate dehydrogenase in a Hitachi 911 analyzer.
Sedimentation velocity experiments.
Glycerol kinases and
IIAGlc.were exhaustively dialyzed in the same
beaker against 0.1 M triethanolamine-HCl (pH 7.0), which also contained
2 mM glycerol, 1 mM -mercaptoethanol, and 10 µM
ZnCl2. Protein samples were diluted with filtered
dialysate to 0.3 mg of glycerol kinase per ml (5 µM [subunits]) and
to 0.54 mg of IIAGlc per ml (30 µM) when
present. All samples were clarified by centrifugation prior to
ultracentrifugation and then loaded into cells assembled with
12-mm-optical-pathlength double-sector Epon charcoal-filled centerpieces and sapphire windows. Approximately 0.2 ml of sample and
0.25 ml of buffer were loaded into the sample and reference channels,
respectively. Samples were run in a Beckman model XL-A analytical
ultracentrifuge at 35,000 rpm and 25°C for 90 min. Scans were
performed at 280 nm and collected without pausing, allowing 4 min to
elapse between scans. Because IIAGlc lacks
tryptophans or tyrosines (31), it is transparent at the 280-nm wavelength. Each run was conducted either with all cells containing glycerol kinase or with all cells containing glycerol kinase
and IIAGlc, giving three independent
measurements. Data were analyzed using the SVEDBERG program (version
6.38) from J. Philo (25).
Rescue of growth in lactose medium.
Strains were grown to
saturation at 30°C in 5 ml of M9 minimal-glucose (0.2%) medium with
ampicillin for plasmid-harboring strains. Cells from 3 ml of the
cultures were collected by centrifugation in a sterile tube, then
washed and resuspended in 1× M9 medium, and the
OD600 was determined. Aliquots of these cells
were used to inoculate 25 ml of prewarmed M9 minimal-lactose (0.2%)
medium with ampicillin when appropriate, at an
OD600 of 0.025. Cells were incubated in a rotary
shaker (250 rpm) at 42°C, and the OD600 was
determined to monitor growth.
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RESULTS AND DISCUSSION |
Construction and characterization of allosteric regulatory variant
glycerol kinase T-477-N.
Two of the allosteric variant glycerol
kinases used in these studies, A-65-T and G-304-S, were described
previously, and their catalytic and regulatory properties have been
determined by in vitro studies with the purified enzymes (16,
21). The T-477-N glycerol kinase was constructed, purified, and
characterized as described in Materials and Methods. The substituted
amino acid position is in the IIAGlc binding site
on glycerol kinase and is >25 Å from the active site and >65 Å from
the FBP-binding site (10, 20). Examination of the
structure of the glycerol kinase-IIAGlc complex
suggests that the variant T-477-N enzyme will prevent IIAGlc binding because of increased side-chain
volume and polarity; the methyl group of T-477 is in a nonpolar
environment. Previous work has shown that the catalytic activity of
glycerol kinase is reduced by substitutions to negatively charged amino
acid side chains in this region (4), so the neutral polar
amino acid asparagine was used for substitution of T-477.
Initial-velocity studies of the substrate dependence of the catalytic
properties of the T-477-N variant enzyme yielded the following kinetic
parameters for this enzyme: Vmax,
13 ± 2 U/mg; KATP, 7 ± 2 µM; Kgol, 6 ± 3 µM; and
KiATP, 53 ± 45 µM. The values
of these parameters were not significantly different from those
obtained for the normal enzyme: Vmax,
15 ± 1 U/mg; KATP, 9 ± 2 µM; Kgol, 5 ± 2 µM;
KiATP, 54 ± 23 µM. The
kinetic properties showed apparent negative cooperativity with respect
to ATP that was similar to the response obtained for the normal
enzyme, showing that this aspect of the regulatory behavior of the
enzyme was not altered qualitatively by the substitution.
Effects of the substitution on allosteric regulation by FBP and
IIA
Glc were assessed by initial-velocity studies.
In assays at pH 7.0,
25°C, and 0.4 µg of glycerol kinase per ml,
FBP inhibition showed
positive cooperativity and yielded the following
parameters for
the T-477-N glycerol kinase:
Imax, 89 ± 1%; Hill coefficient
(n
H),
1.8 ± 0.1; and
Kapp, 0.3 ± 0.02 mM. The values
were not significantly
different from the parameters obtained for the
normal enzyme:
Imax, 93 ± 1%;
n
H, 1.7 ± 0.1;
Kapp, 0.26 ± 0.02 mM. Figure
1 shows
IIA
Glc
inhibition for normal and T-477-N glycerol kinases. The highest
concentration of IIA
Glc that was used
corresponded approximately to the total concentration
of
IIA
Glc (phosphorylated and unphosphorylated)
estimated to occur in vivo
(
27). Inhibition parameters of
the normal glycerol kinase agreed
with previous results
(
23). Because of the small extent of inhibition
of the
T-477-N glycerol kinase, the fitting algorithm could not
estimate both
Imax and
Kapp; consequently, the value for
Imax was fixed at the value obtained
for normal glycerol kinase. The
resultant fit to the data obtained for
the T-477-N glycerol kinase
showed that the substitution decreased the
apparent affinity for
IIA
Glc binding by about
400-fold if the substitution did not affect
the extent of inhibition.
This result is consistent with the expected
effect of increasing the
size and polarity of the amino acid at
this position, on the basis of
the crystal structure of the complex
of IIA
Glc
with the normal glycerol kinase (
10).
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FIG. 1.
Effect of the T-477-N substitution on IIAGlc
inhibition of glycerol kinase. Initial velocities of glycerol kinase
catalyzed reactions were determined at pH 7.0 and 25°C as described
in Materials and Methods. The points show the data that were obtained
for the normal or T-477-N glycerol kinase and the lines show the fits
of the data to the following equation:
where SA is specific activity,
Imax is the maximum extent of
inhibition and Kapp is the apparent
dissociation constant for IIAGlc binding to
glycerol kinase. The fits yield the following parameters for normal
glycerol kinase: Imax, 96 ± 1%;
Kapp, 0.95 ± 0.06 µM. Those
for T-477-N glycerol kinase are as follows:
Imax, 96% (fixed);
Kapp, 370 ± 70 µM. Conditions:
2 mM glycerol, 2.5 mM ATP, 0.1 mM ZnCl2, and
IIAGlc as indicated on the x axis.
Enzyme concentration, 0.5 µg/ml. WT, wild type.
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We utilized two methods to examine binding of
IIA
Glc to the T-477-N variant glycerol kinase. In
the first method, sedimentation
velocity measurements were performed as
described in Materials
and Methods to assess formation of a complex
between IIA
Glc and glycerol kinase. For the
normal glycerol kinase, the apparent
sedimentation coefficient was
increased from 11 ± 0.06 S to 13.3
± 0.06 S when 30 µM
IIA
Glc was added to the ultracentrifuge cell.
This concentration of
IIA
Glc showed saturation
behavior for inhibition of normal glycerol
kinase in kinetics assays
(Fig.
1), and the increased value of
the sedimentation coefficient with
IIA
Glc indicated its binding to glycerol kinase.
The sedimentation coefficient
of the T-477-N variant glycerol kinase in
the absence of IIA
Glc was 10.6 ± 0.1 S and
was 10.5 ± 0.06 S with 30 µM IIA
Glc
included in the cell. Thus, addition of IIA
Glc
did not alter the sedimentation coefficient of the T-477-N variant,
indicating that IIA
Glc does not bind to this
variant under these conditions. We estimated
that this result indicates
a reduction of at least 200-fold for
the IIA
Glc
binding affinity for the variant relative to the normal glycerol
kinase. This result is consistent with that from the inhibition
kinetics studies and supports the assumption that was made in
fitting
the inhibition data, namely that the substitution decreases
the binding
affinity but does not alter the extent of
inhibition.
The second method provided a measure of IIA
Glc
binding to glycerol kinase in vivo. Strain AP110 did not grow on
lactose at the
restrictive temperature (42°C). This is believed to be
a consequence
of the
ts variant enzyme I in this strain
(
12), resulting in
inability of the PTS to phosphorylate
IIA
Glc to relieve its inhibition of the lactose
permease. Figure
2 shows
that growth of
AP110 cells on lactose could be rescued by transformation
with the
plasmid pCJ102, which constitutively expresses the normal
glycerol
kinase (
22). Growth of cells that harbor the plasmid
vector pBR322 alone was not rescued. In contrast, growth of cells
that
express the T-477-N variant glycerol kinase from the same
plasmid was
not rescued significantly in the same time period.
Analogous results
were obtained on minimal-lactose plates on which
just-visible colonies
appeared after 5 days of growth at the restrictive
temperature for
AP110 cells in which the T-477-N variant glycerol
kinase was expressed.
Cells that contained the vector alone showed
no growth after 5 days,
and cells in which the normal glycerol
kinase was overexpressed
produced large colonies after 2 days.
Addition of exogenous glycerol
was not required for these rescue
experiments, and the expression of
the glycerol kinases did not
affect discernibly the growth rate of the
strains on minimal glucose
(0.1%) plates at the permissive temperature
(30°C). The absence
of an effect on the rate of growth on glucose is
consistent with
simulations indicating that the amount of
IIA
Glc greatly exceeds the amount required for
growth (
28). Rescue
of growth on lactose by overexpression
of normal glycerol kinase
is consistent with binding of the glycerol
kinase to the unphosphorylated
form of IIA
Glc,
thus titrating the inhibitor away from the lactose permease
and
allowing entry of lactose into the cell. Both of the glycerol
kinases
were greatly overexpressed constitutively from the pBR322
construct,
and the specific activity in crude extracts was the
same for the normal
and T-477-N glycerol kinases: 10 U/mg for
liquid cultures that were
grown overnight at 42°C in LB. Thus,
the lack of efficient rescue by
the variant glycerol kinase was
not due to differences in the level of
expression or protein stability.
The very high level of glycerol kinase
may account for the binding
of IIA
Glc in the
absence of added glycerol; alternatively, ATP or
sn-glycerol
3-phosphate binding to the glycerol kinase may promote
IIA
Glc binding. The level of specific activity
was >10-fold higher than
the level observed for expression from the
chromosome during growth
on glycerol (see below); yet, no effective
rescue was observed
with the T-477-N variant glycerol kinase, leading
to the expectation
that the level of binding to
IIA
Glc was even lower at one-tenth the glycerol
kinase concentration.
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FIG. 2.
Glycerol kinase-dependent rescue of growth on lactose.
Cells of strain AP110 that harbor plasmids with different
glpK alleles were inoculated into minimal-lactose medium
and incubated with shaking at 42°C. Growth was monitored by
determining the OD600.  , pCJ102 (normal glycerol
kinase);  , pBR322 (vector);  , pCJ102-T477N (T-477-N glycerol
kinase).
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Results of the sedimentation velocity experiments and the in vivo
rescue experiments indicated that the binding of
IIA
Glc to the T-477-N variant glycerol kinase is
very weak relative
to the normal glycerol kinase. Thus, the T-477-N
substitution
practically abolished binding and inhibition by
IIA
Glc at these concentrations, and the T-477-N
glycerol kinase provided
the desired altered allosteric regulatory
phenotype of greatly
reduced inhibition by IIA
Glc
with no significant change for the catalytic or other regulatory
properties of the
enzyme.
Construction and characterization of mutant strains with
chromosomal alleles for allosteric regulatory variant glycerol
kinases.
Strains with chromosomal glpK alleles that
encode the allosteric regulatory variants of glycerol kinase, T-477-N,
A-65-T, and G-304-S, were constructed in the three genetic backgrounds as described under Materials and Methods. The glycerol kinase regulatory phenotype of each strain was verified by assays of enzyme
activity in cell extracts. Results of those assays are summarized in
Table 2. In each case, the allosteric
regulatory phenotype was the same as that observed for the respective
purified glycerol kinase. The extract from the strain with the normal
glycerol kinase displayed inhibition of glycerol kinase by both FBP and IIAGlc (K+ glycerol kinase)
that, with the putative glycerol kinase A-65-T, showed inhibition by
IIAGlc but was insensitive to FBP
(Ki glycerol kinase); that, with the putative
glycerol kinase T-477-N, showed inhibition by FBP but was resistant to
IIAGlc inhibition (Kr
glycerol kinase); and that with the putative glycerol kinase G-304-S
was insensitive to FBP and resistant to IIAGlc
inhibition (Ki,r glycerol kinase). The
designations of the regulatory defect (Ki,
Kr) follow earlier nomenclature
(19). The same results were obtained for all three genetic
backgrounds.
Growth rates and glycerol kinase specific activity after overnight
growth in minimal glucose, minimal glycerol, and LB media
were
determined for all of the strains. Differences were seen
for growth
rates of strains KH11, MC4100, and MG1655 in each of
the different
media (data not shown). However, in strains with
variants of glycerol
kinase, the growth rate was sensitive to
the allosteric regulatory
phenotype of glycerol kinase only for
cells expressing
K
i or K
i,r glycerol
kinase, for which the growth rate in glycerol was increased
in all
genetic backgrounds. Strains with K
i or
K
i,r glycerol kinase also showed a strong
fermentation phenotype on
MacConkey glycerol agar in all genetic
backgrounds. This phenotype
was displayed as a large red disk in the
agar surrounding the
colonies and was seen for both plasmid-borne and
chromosomal copies
of these alleles. The phenotype has segregated with
the mutations
following conjugation or transduction in all the strains
that
have been examined. Strains with K
r glycerol
kinase showed a normal fermentation
phenotype.
Table
3 shows the specific activity of
glycerol kinase in extracts prepared after overnight growth in several
media. In glucose-grown
cells, the apparent levels of enzyme activity
were not significantly
different from the apparent activity obtained
for the respective
glpK strains. This apparent activity
was not dependent on addition
of glycerol to the assay and thus
reflected sources of ADP other
than glycerol kinase. The basal level of
glycerol kinase specific
activity in glucose-grown cells was too low to
be measured by
using the ADP-coupled assay (<0.1 U/mg). Glycerol
kinase enzyme
activity was repressed by glucose in both
glpR208 and
glpR+ strains, in
agreement with an earlier report (
41).
The level of enzyme activity of glycerol kinase in cells that were
grown on glycerol showed little dependence on the glycerol
3-phosphate
repressor phenotype; the levels were the same for
KH11, MC4100, and
MG1655. However, the expression level did depend
on the glycerol kinase
regulatory phenotype. The level was reduced
in strains with
K
i or K
i,r glycerol kinases
but not in strains with K
+ or
K
r glycerol kinases. Despite this lower level of
glycerol kinase
activity, the strains with K
i or
K
i,r glycerol kinases grew more rapidly on
glycerol and displayed
the enhanced glycerol fermentation phenotype on
MacConkey glycerol
plates.
In LB, the glycerol kinase specific activity level showed little
dependence on the glycerol kinase regulatory phenotype but
was
dependent on the glycerol 3-phosphate repressor phenotype.
In the
glpR208 strains, high levels of glycerol kinase specific
activity were obtained. The levels of specific activity were
considerably
reduced for the
glpR+ strains
and were not significantly above the apparent level observed
for the
respective
glpK strains. The low levels of expression
of
the K
i or K
i,r glycerol
kinases in minimal glycerol medium did not appear to
be related to
instability of the enzymes or inherent differences
in expressibility
because the same high level of specific activity
was seen for the
normal and variant glycerol kinases in the
glpR208 genetic
background during growth on
LB.
The
glpK22 allele was used in these experiments to verify
that the effects of K
i,r glycerol kinase on
glucose control were not changed by the different
genetic backgrounds
used here relative to the initial report of
those effects
(
41). The properties of the strains which expressed
this
variant that were constructed in this work, including the
reduced level
of glycerol kinase specific activity following growth
in minimal
glycerol and the
glpR allele dependence of the level
of
glycerol kinase specific activity during growth on LB, agree
with those
properties described in the earlier work. Diauxic growth
curves (data
not shown) also agreed with earlier work: a normal
plateau for a
glpR+ strain and elimination of the
plateau in a
glpR strain. Thus,
the effects of the
glpK22 allele on mechanisms of glucose control
in strains
used here were not distinguishable from the effects
that were observed
earlier in a different strain, and the present
strains provided
suitable genetic backgrounds for assessing the
contribution of each of
the glycerol kinase allosteric control
mechanisms to regulation of
glycerol
metabolism.
Roles of glycerol kinase allosteric regulation in glucose control
of glycerol utilization and glycerol kinase expression.
The
fundamental observation of glucose control of utilization of other
carbon sources is diauxic growth, which is exhibited as a biphasic
growth curve. Figure 3A displays growth
curves obtained in minimal medium with 2.5 mM glucose plus 5 mM
glycerol for strain MC4100. This growth showed the expected two phases,
which are separated by a plateau. Figure 3A also shows the basis for
the diauxic growth. During the first phase, glucose is utilized while glycerol utilization is inhibited. During the second growth phase, which occurred after the glucose was consumed, glycerol was utilized. Figure 3B shows that the level of glycerol kinase specific activity was
barely detectable during the first phase and was induced to higher
levels for the phase of glycerol utilization. Thus, glucose prevented
both utilization of glycerol and expression of glycerol kinase.
View larger version (21K):
[in this window]
[in a new window]
|
FIG. 3.
Roles of glycerol kinase allosteric regulation in
diauxic growth, glucose-glycerol utilization, and expression of
glycerol kinase in the MC4100 genetic background. Cultures were
prepared as described in Materials and Methods. (A) Filled symbols show
growth of strains 34 (R+/Ki) (), 24 (R+/Kr) ( ), and MC4100
(R+/K+) (), which were measured as the
change in OD600 following inoculation. Open symbols
connected by dashed lines show the concentration of glucose, and open
symbols connected by solid lines show the concentration of glycerol in
the medium. (B) Specific activity (S.A.) of glycerol kinase. ,
MC4100 (R+/K+); , strain 34 (R+/Ki); , strain 24 (R+/Kr).
|
|
The consequences of the specific changes in the allosteric regulatory
properties of glycerol kinase for glucose control of
glycerol
utilization in derivatives of strain MC4100 also are
shown in Fig.
3A
and B. The curves for strain 24 (R
+/K
r) were practically
identical to those obtained for strain MC4100
(R
+/K
+). Thus, loss of
IIA
Glc inhibition of glycerol kinase, i.e.,
inducer exclusion, did not
affect the diauxic growth, glycerol
utilization, or expression
of glycerol kinase under these conditions.
In contrast, the curves
obtained for strain 34 (R
+/K
i) differed greatly
from those of strain MC4100. Loss of FBP inhibition
of glycerol kinase
affected all three aspects of glucose control:
(i) the plateau in the
growth curve was eliminated, (ii) glycerol
was consumed throughout the
growth and the rate of glucose utilization
during the first phase was
reduced, and (iii) glycerol kinase
specific activity remained at a low
level throughout the growth.
Thus, FBP inhibition was the
quantitatively dominant allosteric
regulatory mechanism for control of
glycerol kinase in vivo in
E. coli. A dominant role for FBP
inhibition was consistent with
the observation that 16 of 18 glycerol-specific revertants of
a
ptsI strain expressed
glycerol kinase that was no longer inhibited
by FBP (
2).
For the other two genetic backgrounds, the effects
of the altered
glycerol kinase allosteric regulatory properties
on the diauxic growth
curves, carbon source utilization, and glycerol
kinase specific
activity were the same as those shown for the
MC4100 genetic background
(data not shown). Thus, the role of
allosteric regulation of glycerol
kinase was not dependent on
the genetic
background.
For each of the strains described here, growth rates and glycerol
kinase specific activities in minimal glucose (2.5 mM) medium
alone and
the first phase in minimal glucose (2.5 mM) plus glycerol
(5 mM) medium
were indistinguishable (data not shown). Thus, growth
on glucose was
not affected by the different glycerol kinase regulatory
phenotypes,
suggesting that the PTS was not altered. The behaviors
of strains
MG1655 and KH52 with respect to growth rates, diauxic
growth, and
glycerol kinase specific activities were identical;
thus the presence
of the Tn
10 element did not affect the properties
of the
strains under these
conditions.
The unexpected lack of effect of loss of IIA
Glc
inhibition of glycerol kinase, i.e., inducer exclusion, on glucose
control of
glycerol utilization raises questions about the role of
specific
repression by the glycerol phosphate repressor. We showed
previously
that glucose represses expression of glycerol kinase in
glpR strains,
including strain KH11, during growth on
glucose plus glycerol
(
9). Figure
4 compares diauxic growth curves and
glycerol utilization
for strains KH11
(R
/K
+) and MC4100
(R
+/K
+). Diauxic growth and
glycerol kinase specific activities in strains
with the
glpR2 or
glpR208 allele are indistinguishable
from those
of
glpR strains, indicating that these alleles
encode nonfunctional
repressors (
9). The results (Fig.
4)
show that glucose control
of glycerol utilization during the first
phase of growth also
was not dependent on a functional glycerol
phosphate repressor.
View larger version (23K):
[in this window]
[in a new window]
|
FIG. 4.
Growth and glucose and glycerol utilization in the
glpR208 and glpR+
genetic backgrounds. Cultures were prepared as described in Materials
and Methods. The filled symbols show growth measured as the change in
OD600 following inoculation. Open symbols connected by
dashed lines show the concentration of glucose, and open symbols
connected by solid lines show the concentration of glycerol in the
medium.  /, MC4100 (R+/K+);  /, KH11
(R/K+).
|
|
In all three genetic backgrounds, strains that expressed
FBP-insensitive glycerol kinase showed loss of glucose control of
glycerol utilization, diauxic growth, and glycerol kinase expression.
The behavior of these strains during growth on glycerol was very
similar to that of
lacI (
11) or
lacY(S209I) (
6,
8,
33)
strains during growth on
lactose. Allosteric inhibition of glycerol
kinase by
IIA
Glc alone provided no discernible glucose
control in the FBP-insensitive
glycerol kinase strains described here.
The low level of glycerol
kinase in these strains might be expected to
contribute to loss
of IIA
Glc inhibition by
favoring dissociation of the glycerol
kinase-IIA
Glc complex. However, the initial
identification of FBP-insensitive
glycerol kinase was based on a screen
for loss of glucose control
of glycerol utilization, and the enzyme was
expressed at higher
levels from a plasmid-borne copy of the
glpK203 allele lacking
the upstream genetic control elements
(
16). Cells that expressed
the normal glycerol kinase from
the same plasmid background showed
glucose control at the higher level
of expression. Glucose control
was abolished for the strain with
FBP-insensitive glycerol kinase
at even the higher level of expression,
which suggests that the
absence of effective
IIA
Glc control observed here was not due to the
lower level of expression
of the chromosomal copy of the
glpK203 allele. The absence of
effective
IIA
Glc control in strains with FBP-insensitive
glycerol kinase could
reflect synergy in the binding of FBP and
IIA
Glc, in which FBP enhances the binding of
IIA
Glc. However, results of isothermal titration
calorimetry experiments
are consistent with independent binding of
these allosteric effectors
to the normal glycerol kinase in vitro (I. Luque, D. W. Pettigrew,
and E. Freire, unpublished
data).
In contrast to the complete loss of glucose control of glycerol
utilization that is associated with the FBP-insensitive glycerol
kinase, changes in glucose control are not associated with the
IIA
Glc-resistant glycerol kinase under these
conditions. All of the
strains with the
IIA
Glc-resistant glycerol kinase show diauxic
growth curves, inhibition
of glycerol utilization, and repression of
glycerol kinase specific
activity that are not discernibly different
from those responses
in strains with the normal glycerol kinase.
Glucose control of
glycerol utilization and repression of glycerol
kinase activity
also are not dependent on a functional glycerol
3-phosphate repressor,
i.e., specific repression. The lack of
dependence of glucose control
on IIA
Glc
inhibition of glycerol kinase is completely consistent with the
lack of
dependence on specific repression. Independence from specific
repression is implicit in the earlier publications in which the
glpK22 (
42) and
glpK203
(
16) alleles were identified; in both
cases,
glpR strains were used, and the
glpR
glpK+ control strains showed normal glucose
control. The consequences
of this observation for PTS regulation of
carbon source utilization
appear to have been unrecognized previously.
The lack of dependence
of glucose control of glycerol utilization on
specific repression
suggests that cAMP-dependent catabolite repression
may be the
dominant mechanism of glucose repression of glycerol kinase
activity
levels during diauxic growth. Thus, the mechanisms by which
glucose
controls glycerol utilization by
E. coli differ
significantly
from those by which it controls lactose utilization
(
6,
11,
36). The differences in the relative roles of
catabolite repression,
specific repression, and inducer exclusion in
regulation of use
of these two carbon sources may reflect the
differences in genetic
structure (operon versus regulon) and/or the
differences with
respect to the nature of the inducer (unusual
disaccharide versus
normal metabolite in lipid
metabolism).
| |
ACKNOWLEDGMENTS |
This work was supported by grants from the National Institutes of
Health (GM-49992 and GM-38759) and by the Texas Agricultural Experiment
Station (grant H-6559). A.C.P. was supported in part by NIH
Chemistry/Biology Interface Training grant T32-GM08523.
We thank Ry Young for strains and Donna Barker, Audra Boettcher, and
Geneva Sampson for expert technical assistance.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Biochemistry and Biophysics, Texas A&M University, 2128 TAMU, College Station, TX 77843-2128. Phone: (979) 845-9621. Fax: (979) 845-9274. E-mail: dpettigrew{at}tamu.edu.
| |
REFERENCES |
| 1.
|
Baldwin, T. O.,
T. Berends,
T. A. Bunch,
T. F. Holzman,
S. K. Rausch,
L. Shamansky,
M. L. Treat, and M. M. Ziegler.
1984.
Cloning of the luciferase structural genes from Vibrio harveyi and expression of bioluminescence in Escherichia coli.
Biochemistry
23:3663-3667[CrossRef][Medline].
|
| 2.
|
Berman, M., and E. C. C. Lin.
1971.
Glycerol-specific revertants of a phosphoenolpyruvate phosphotransferase mutant: suppression by the desensitization of glycerol kinase to feedback inhibition.
J. Bacteriol.
105:113-120[Abstract/Free Full Text].
|
| 3.
|
Donahue, J. L.,
J. L. Bownas,
W. G. Niehaus, and T. J. Larson.
2000.
Purification and characterization of glpX-encoded fructose 1,6-bisphosphatase, a new enzyme of the glycerol 3-phosphate regulon of Escherichia coli.
J. Bacteriol.
182:5624-5627[Abstract/Free Full Text].
|
| 4.
|
Feese, D. M.,
H. R. Faber,
C. E. Bystrom,
D. W. Pettigrew, and S. J. Remington.
1998.
Glycerol kinase from Escherichia coli and an Ala65 Thr mutant the crystal structures reveal conformational changes with implications for allosteric regulation.
Structure
6:1407-1418[Medline].
|
| 5.
|
Gralla, J. D., and J. Collado-Vides.
1996.
Organization and function of transcription regulatory elements, p. 1232-1245.
In
F. C. Neidhardt (ed.), Escherichia coli and Salmonella: cellular and molecular biology, 2nd ed., vol. 1. ASM Press, Washington, D.C.
|
| 6.
|
Hogema, B. M.,
J. C. Arents,
R. Bader,
K. Eijkemans,
T. Inada,
H. Aiba, and P. W. Postma.
1998.
Inducer exclusion by glucose 6-phosphate in Escherichia coli.
Mol. Microbiol.
28:755-765[CrossRef][Medline].
|
| 7.
|
Hogema, B. M.,
J. C. Arents,
R. Bader,
K. Eijkemans,
H. Yoshida,
H. Takahashi,
H. Alba, and P. W. Postma.
1998.
Inducer exclusion in Escherichia coli by non-PTS substratesthe role of the PEP to pyruvate ratio in determining the phosphorylation state of enzyme IIAGlc.
Mol. Microbiol.
30:487-498[CrossRef][Medline].
|
| 8.
|
Hogema, B. M.,
J. C. Arents,
R. Bader, and P. W. Postma.
1999.
Autoregulation of lactose uptake through the LacY permease by enzyme IIAGlc of the PTS in Escherichia coli K-12.
Mol. Microbiol.
31:1825-1833[CrossRef][Medline].
|
| 9.
|
Holtman, C. K.,
R. Thurlkill, and D. W. Pettigrew.
2001.
Unexpected presence of defective glpR alleles in various strains of Escherichia coli.
J. Bacteriol.
183:1459-1461[Abstract/Free Full Text].
|
| 10.
|
Hurley, J. H.,
H. R. Faber,
D. Worthylake,
N. D. Meadow,
S. Roseman,
D. W. Pettigrew, and S. J. Remington.
1993.
Structure of the regulatory complex of Escherichia coli IIIglc with glycerol kinase.
Science
259:673-677[Abstract/Free Full Text].
|
| 11.
|
Inada, T.,
K. Kimata, and H. Aiba.
1996.
Mechanism responsible for glucose-lactose diauxie in Escherichia coli: challenge to the cAMP model.
Genes Cells
1:293-301[Abstract].
|
| 12.
|
Jones-Mortimer, M. C., and H. L. Kornberg.
1974.
Genetic control of inducer exclusion by Escherichia coli.
FEBS Lett.
48:93-95[CrossRef][Medline].
|
| 13.
|
Larson, T. J.,
J. S. Cantwell, and A. T. van Loo-Bhattacharya.
1992.
Interaction at a distance between multiple operators controls the adjacent, divergently transcribed glpTQ-glpACB operons of Escherichia coli K-12.
J. Biol. Chem.
267:6114-6121[Abstract/Free Full Text].
|
| 14.
|
Lin, E. C. C.
1996.
Dissimilatory pathways for sugars, polyols, and carboxylates, p. 307-342.
In
F. C. Neidhardt (ed.), Escherichia coli and Salmonella: cellular and molecular biology, 2nd ed., vol. 1. ASM Press, Washington, D.C.
|
| 15.
|
Lin, E. C. C.
1976.
Glycerol dissimilation and its regulation in bacteria.
Annu. Rev. Microbiol.
30:535-578[CrossRef][Medline].
|
| 16.
|
Liu, W. Z.,
R. Faber,
M. Feese,
S. J. Remington, and D. W. Pettigrew.
1994.
Escherichia coli glycerol kinase: role of a tetramer interface in regulation by fructose 1,6-bisphosphate and phosphotransferase system regulatory protein IIIglc.
Biochemistry
33:10120-10126[CrossRef][Medline].
|
| 17.
|
Messing, J.
1979.
A multipurpose cloning system based on the single-stranded DNA bacteriophage M13. Recombinant DNA technical bulletin. NIH publication no. 79-99, vol. 2. , p. 43-48.
National Institutes of Health, Bethesda, Md.
|
| 18.
|
Miller, J. H.
1972.
Experiments in molecular genetics.
Cold Spring Harbor Laboratory, Cold Spring Harbor, N.Y.
|
| 19.
|
Novotny, J. M.,
W. L. Frederickson,
E. B. Waygood, and M. H. Saier, Jr.
1985.
Allosteric regulation of glycerol kinase by enzyme IIIglc of the phosphotransferase system in Escherichia coli and Salmonella typhimurium.
J. Bacteriol.
162:810-816[Abstract/Free Full Text].
|
| 20.
|
Ormo, M.,
C. E. Bystrom, and S. J. Remington.
1998.
Crystal structure of a complex of Escherichia coli glycerol kinase and an allosteric effector fructose 1,6-bisphosphate.
Biochemistry
37:16565-16572[CrossRef][Medline].
|
| 21.
|
Pettigrew, D. W.,
W. Z. Liu,
C. Holmes,
N. D. Meadow, and S. Roseman.
1996.
A single amino acid change in Escherichia coli glycerol kinase abolishes glucose control of glycerol utilization in vivo.
J. Bacteriol.
178:2846-2852[Abstract/Free Full Text].
|
| 22.
|
Pettigrew, D. W.,
D.-P. Ma,
C. A. Conrad, and J. R. Johnson.
1988.
Escherichia coli glycerol kinase. Cloning and sequencing of the glpK gene and the primary structure of the enzyme.
J. Biol. Chem.
263:135-139[Abstract/Free Full Text].
|
| 23.
|
Pettigrew, D. W.,
N. D. Meadow,
S. Roseman, and S. J. Remington.
1998.
Cation-promoted association of Escherichia coli phosphocarrier protein IIAGlc with regulatory target protein glycerol kinasesubstitutions of a zinc(II) ligand and implications for inducer exclusion.
Biochemistry
37:4875-4883[CrossRef][Medline].
|
| 24.
|
Pettigrew, D. W.,
G. B. Smith,
K. P. Thomas, and D. C. Dodds.
1998.
Conserved active site aspartates and domain-domain interactions in regulatory properties of the sugar kinase superfamily.
Arch. Biochem. Biophys.
349:236-245[CrossRef][Medline].
|
| 25.
|
Philo, J. S.
1997.
An improved function for fitting sedimentation velocity data for low-molecular-weight solutes.
Biophys. J.
72:435-444[Medline].
|
| 26.
|
Postma, P. W.,
W. Epstein,
A. R. J. Schuitema, and S. O. Nelson.
1984.
Interaction between IIIGlc of the phosphoenolpyruvate:sugar phosphotransferase system and glycerol kinase of Salmonella typhimurium.
J. Bacteriol.
158:351-353[Abstract/Free Full Text].
|
| 27.
|
Postma, P. W.,
J. W. Lengeler, and G. R. Jacobson.
1993.
Phosphoenolpyruvate:carbohydrate phosphotransferase systems of bacteria.
Microbiol. Rev.
57:543-594[Abstract/Free Full Text].
|
| 28.
|
Rohwer, J. M.,
J.-H. S. Hofmeyr, and P. W. Postma.
1998.
Retro-regulation of the bacterial phosphotransferase system: a kinetic model, p. 340-344.
In
C. Larsson, I.-L. Påhlman, and L. Gustafsson (ed.), Biothermokinetics in the post genomic era. Proceedings of the 8th International Meeting on BioThermoKinetics Göteborg University, Göteborg, Sweden.
|
| 29.
|
Roseman, S.
1994.
The bacterial phosphoenolpyruvate:glycose phosphotransferase system, p. 151-160.
In
A. Torriani-Gorini, E. Yagil, and S. Silver (ed.), Phosphate in microorganisms: cellular and molecular biology. ASM Press, Washington, D.C.
|
| 30.
|
Roseman, S., and N. D. Meadow.
1990.
Signal transduction by the bacterial phosphotransferase system. Diauxie and the crr gene.
J. Biol. Chem.
265:2993-2996[Free Full Text].
|
| 31.
|
Saffen, D. W.,
K. A. Presper,
T. L. Doering, and S. Roseman.
1987.
Sugar transport by the bacterial phosphotransferase system. Molecular cloning and structural analysis of the Escherichia coli ptsH, ptsI, and crr genes.
J. Biol. Chem.
262:16241-16253[Abstract/Free Full Text].
|
| 32.
|
Saier, M. H., Jr.
1989.
Protein phosphorylation and allosteric control of inducer exclusion and catabolite repression by the bacterial phosphoenolpyruvate:sugar phosphotransferase system.
Microbiol. Rev.
53:109-120[Abstract/Free Full Text].
|
| 33.
|
Saier, M. H., Jr.,
H. Straud,
L. S. Massman,
J. J. Judice,
M. J. Newman, and B. U. Feucht.
1978.
Permease-specific mutations in Salmonella typhimurium and Escherichia coli that release the glycerol, maltose, melibiose, and lactose transport systems from regulation by the phosphoenolpyruvate:sugar phosphotransferase system.
J. Bacteriol.
133:1358-1367[Abstract/Free Full Text].
|
| 34.
|
Singer, M.,
T. A. Baker,
G. Schnitzler,
S. M. Deischel,
M. Goel,
W. Dove,
K. J. Jaacks,
A. D. Grossman,
J. W. Erickson, and C. A. Gross.
1989.
A collection of strains containing genetically linked alternating antibiotic resistance elements for genetic mapping of Escherichia coli.
Microbiol. Rev.
53:1-24[Abstract/Free Full Text].
|
| 35.
|
Stewart, G. A. B.,
S. Lubinsky-Mink,
C. G. Jackson,
A. Cassel, and J. Kuhn.
1986.
pHG165: a pBR322 copy number derivative of pUC8 for cloning and expression.
Plasmid
15:172-181[CrossRef][Medline].
|
| 36.
|
Stulke, J., and W. Hillen.
1999.
Carbon catabolite repression in bacteria.
Curr. Opin. Microbiol.
2:195-201[CrossRef][Medline].
|
| 37.
|
Weissenborn, D. L.,
N. Wittekindt, and T. J. Larson.
1992.
Structure and regulation of the glpFK operon encoding glycerol diffusion facilitator and glycerol kinase of Escherichia coli K-12.
J. Biol. Chem.
267:6122-6131[Abstract/Free Full Text].
|
| 38.
|
Yang, B.,
S. G. Gerhardt, and T. J. Larson.
1997.
Action at a distance for glp repressor control of glpTQ transcription in Escherichia coli K-12.
Mol. Microbiol.
24:511-521[CrossRef][Medline].
|
| 39.
|
Yang, B., and T. J. Larson.
1998.
Multiple promoters are responsible for transcription of the glpEGR operon of Escherichia coli K-12.
Biochim. Biophys. Acta
1396:114-126[Medline].
|
| 40.
|
Zhao, N.,
W. Oh,
D. Trybul,
K. S. Thrasher,
T. J. Kingsbury, and T. J. Larson.
1994.
Characterization of the interaction of the glp repressor of Escherichia coli K-12 with single and tandem glp operator variants.
J. Bacteriol.
176:2393-2397[Abstract/Free Full Text].
|
| 41.
|
Zwaig, N.,
W. S. Kistler, and E. C. C. Lin.
1970.
Glycerol kinase, the pacemaker for the dissimilation of glycerol in Escherichia coli.
J. Bacteriol.
102:753-759[Abstract/Free Full Text].
|
| 42.
|
Zwaig, N., and E. C. C. Lin.
1966.
Feedback inhibition of glycerol kinase, a catabolic enzyme in Escherichia coli.
Science
153:755-757[Abstract/Free Full Text].
|
Journal of Bacteriology, June 2001, p. 3336-3344, Vol. 183, No. 11
0021-9193/01/$04.00+0 DOI: 10.1128/JB.183.11.3336-3344.2001
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-
Sutrina, S. L., Alleyne, L., Hoyte, K., Blenman, M.
(2002). Effect of replacing the general energy-coupling proteins of the PEP:sugar phosphotransferase system of Salmonella typhimurium with their fructose-inducible counterparts on utilization of the PTS sugar glucitol. Microbiology
148: 3857-3864
[Abstract]
[Full Text]
-
Pawlyk, A. C., Pettigrew, D. W.
(2002). Transplanting allosteric control of enzyme activity by protein-protein interactions: Coupling a regulatory site to the conserved catalytic core. Proc. Natl. Acad. Sci. USA
99: 11115-11120
[Abstract]
[Full Text]
-
Eppler, T., Postma, P., Schutz, A., Volker, U., Boos, W.
(2002). Glycerol-3-Phosphate-Induced Catabolite Repression in Escherichia coli. J. Bacteriol.
184: 3044-3052
[Abstract]
[Full Text]
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Abstract
Introduction
![<UP>SA,</UP>%=100−[I<SUB><UP>max</UP></SUB>·(<UP>IIA<SUP>Glc</SUP></UP>)]/(K<SUB><UP>app</UP></SUB>+(<UP>IIA<SUP>Glc</SUP></UP>)],](/content/vol183/issue11/fulltext/3336/img001.gif)
