Department of Molecular Genetics,
Biochemistry and Microbiology, University of Cincinnati College of
Medicine, Cincinnati, Ohio 45267-0524,1 and
Department of Microbiology and Immunology, East Carolina
University School of Medicine, Greenville, North Carolina
278582
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INTRODUCTION |
Pseudomonas aeruginosa is
a gram-negative bacillus that is virtually ubiquitous throughout
nature. It is also an opportunistic pathogen of humans, most notably
those who have cystic fibrosis or whose immune systems have been
compromised (e.g., as a result of burns or cancer chemotherapy)
(11, 16, 55). The organism has a remarkable capacity to
utilize a wide range of carbon sources for growth under a variety of
environmental conditions. Although tricarboxylic acid (TCA) cycle
intermediates such as succinate are preferentially utilized by P. aeruginosa, the organism readily catabolizes glucose. In contrast
to the facultative organism Escherichia coli, P. aeruginosa does not metabolize glucose via the Embden-Meyerhof pathway because it does not possess 6-phosphofructokinase
(36). Thus, the catabolism of glucose by P. aeruginosa requires its conversion to glyceraldehyde-3-phosphate
and pyruvate via the Enter-Doudoroff enzymes 6-phosphogluconate
dehydratase (Edd) and 2-keto-3-deoxy-6-phosphogluconate aldolase
(Eda) (36). Depending on the physiological conditions,
glucose is converted to 6-phosphogluconate by one of two routes, one of
which is oxidative and the other of which is phosphorylative. The
direct oxidative route involves oxidation of glucose to gluconate and
2-ketogluconate in the periplasm via membrane-bound glucose and
gluconate dehydrogenases (29). Recently both oxidative
routes have been shown to be physiologically significant with the
isolation of mutants blocked in either gluconate or 2-ketogluconate
utilization (67a). Alternatively, the phosphorylative route
involves uptake of glucose by an inducible transport system where, once
inside the organism, it is phosphorylated by glucokinase and next
converted to 6-phosphogluconate by glucose-6-phosphate dehydrogenase
(G6PDH; EC 1.1.1.49), the product of the zwf gene (29).
Interestingly, a zwf mutant of E. coli was
reported to be more sensitive to the redox-active, superoxide
(O2
)-generating agent methyl viologen
(paraquat) (19). It was then postulated by Liochev and
Fridovich (38) that this sensitivity was attributed to a
reduced level of NADPH, a cofactor necessary for the activity of
glutathione reductase (3) and alkylhydroperoxide reductase
(32), enzymes which combat paraquat-mediated oxidative stress.
In this study, we describe the cloning and characterization of the
zwf gene of P. aeruginosa PAO1. We demonstrate
that inactivation of the zwf gene does not allow mutant
organisms to grow on mannitol as the sole carbon source. In addition,
we demonstrate that the zwf gene is under tight control,
being highly transcribed in the presence of inducing agents such as
glycerol and glucose and weakly transcribed in the presence of the TCA
cycle intermediate succinate. In addition, we demonstrate that G6PDH
activity is important in resistance to the
O2-generating agent paraquat.
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MATERIALS AND METHODS |
Bacterial strains, plasmids, and media.
All P. aeruginosa and E. coli strains used in this study are
listed in Table 1 and were maintained on
Luria (L)-agar plates containing 10 g of tryptone, 5 g of
yeast extract, 5 g of NaCl, and 15 g of Bacto Agar per liter.
Frozen stocks were stored indefinitely at 
80°C in a 1:1 mixture of
25% glycerol and stationary-phase culture grown in L broth.
Growth conditions.
All bacteria were grown from
single-colony isolates in either L broth or a basal salts medium
(69) supplemented with 20 to 60 mM selected carbon sources.
Liquid cultures were grown at 37°C with shaking at 300 rpm or on a
roller wheel at 70 rpm unless otherwise indicated. Culture volumes were
1/10 of the total Erlenmeyer flask volume to ensure proper aeration.
All agar media were solidified with 1.5% Bacto Agar.
Cloning and sequence analysis of P. aeruginosa PAO1
zwf.
Steps involved in the cloning of the P. aeruginosa PAO1 zwf gene are described in Results. All
DNA sequencing was performed by the dideoxy method on double-stranded
DNA (Sequenase 2.0; U.S. Biochemical, Cleveland, Ohio). Sequence
obtained by this method was confirmed on both strands by using a PRISM
Dye Deoxy terminator cycle sequencing kit and analyzed on an ABI model
373A DNA sequencer. Additional DNA sequencing was provided by the
Biotechnology Program of the East Carolina University School of
Medicine. Oligonucleotides for DNA sequencing reactions and PCR
analysis were synthesized in the DNA Core Facilities, Department of
Molecular Genetics, Biochemistry and Microbiology, University of
Cincinnati College of Medicine, or were provided by the Biotechnology
Program, East Carolina School of Medicine. Sequence analysis was
performed with Sequencher 3.0 (Gene Codes Corp., Ann Arbor, Mich.),
MacVector 4.1.1 (Eastman Chemical Co., New Haven, Conn.), or Gene
Runner (Hastings Software, Inc.). Amino acid alignments were performed by using either the BLASTP program provided by the National Center for
Biotechnology Information (1) or the Align Plus 3 global alignment program (Sci-Ed Software, Durham, N.C.). Potential
transcription start sites were identified by using the Neural Network
Promoter Prediction program
(http://www-hgc.lbl.gov/projects/promoter.html [54]).
Manipulation of recombinant DNA.
Plasmid DNA was transformed
into either E. coli DH5
-MCR (Gibco-BRL, Gaithersburg,
Md.) or E. coli SM10 (63).
5-Bromo-4-chloro-3-indolyl-
-D-galactopyranoside (X-Gal;
40 µg/ml) was added to agar medium to detect the presence of insert
DNA via blue/white selection. Restriction endonucleases, alkaline
phosphatase, and T4 DNA ligase were used as specified by the vendor
(Gibco-BRL); Plasmid DNA was isolated on a small scale by the alkaline
lysis method described by Maniatis et al. (43) or on a large
scale by using a plasmid isolation kit (Qiagen). Restriction fragments
were recovered from agarose gels by using SeaPlaque low-melting-point
agarose (FMC BioProducts, Rockland, Maine).
Construction of the G6PDH overexpression vector, pJFM3.
PCR
primers ZWF-START (5'-GTAACAACACATGTCTGATGTCCGCGTTCT-3')
upstream of the P. aeruginosa zwf gene and KS
(5'-TCGAGGTCGACGGTATC-3') of pBluescript KS were used to
PCR amplify the zwf gene from pJFM1, and this fragment was
cloned into the EcoRV site of pBluescript KS. This
plasmid, designated pJFM2, was digested with AflIII and
EcoRI, and the resulting ~1.6-kb zwf fragment
was ligated into the NcoI/EcoRI-cut expression
vector pEX30 (61a), forming pJFM3. Plasmid pJFM3 was then
used for overproduction and purification of G6PDH as described below.
Purification of P. aeruginosa G6PDH.
Overproduction of G6PDH in P. aeruginosa PAO1 was
accomplished after the following steps. Bacteria harboring the
zwf overexpression vector pJFM3 were grown in 4 liters of L
broth containing carbenicillin (400 µg/ml) to an optical density at
600 nm (OD600) of 0.3. The synthesis of T7 polymerase was
then induced by the addition of 0.2 mM
isopropyl--D-thiogalactopyranoside (IPTG), and the
bacteria were allowed to grow for an additional 3 h at 37°C. The
bacteria were pelleted by centrifugation at 10,000 × g
for 15 min, washed in 0.9% saline, and resuspended in 50 mM Tris-HCl
(pH 7.8) containing mercaptoethanol (0.02%), lysozyme (0.02%), and
the protease inhibitors phenylmethylsulfonyl fluoride (0.5 mM),
leupeptin (0.5 µM), and pepstatin (0.5 µM). The suspension was
incubated on ice for 1 h and subjected to three freeze
(80°C)-thaw (37°C) cycles to aid in breakage of the cells and
further disrupted in a French pressure cell at 12,000 lb/in2 at 4°C. Unbroken cells and cell debris were
clarified by ultracentrifugation at 100,000 × g for
1 h at 4°C. The clarified extract was brought to 38% saturation
with ammonium sulfate and allowed to incubate at 4°C for 17 h,
and the precipitated protein was clarified by centrifugation at
10,000 × g for 20 min. The precipitate was dissolved in 20 mM potassium phosphate buffer (KPi), pH 6.8, and
dialyzed against six 1-liter changes of the same buffer at 4°C. This
solution was filtered through a 0.22-µm-pore-size filter (Nalgene)
and concentrated with an Amicon YM-100 membrane. The retentate,
containing G6PDH, was passed over a 2- by 18-cm DE-52 column (Whatman
International Ltd., Kent, England) and eluted with a 20 to 400 mM
gradient of KPi (pH 6.8). After concentration of the
G6PDH-containing fractions as described above, sample was loaded on a
1.5- by 6-cm hydroxyapatite column and eluted with a 20 to 150 mM
gradient of KPi. Finally, G6PDH was purified from two
smaller contaminating proteins by passage through a 3.5- by 100-cm
Bio-Gel 150 gel filtration column equilibrated with 20 mM
KPi (pH 6.8) at 4°C while maintaining a flow rate of 0.2 ml/min. Purified G6PDH was then stored on ice at 0°C.
Construction of a P. aeruginosa zwf mutant.
The
strategy for insertional mutagenesis of the zwf gene was
based on the sucrose counterselection technique (59). To
accomplish this, a ~1-kb PstI-BamHI fragment
from pJFM1 was ligated into pNOT19 (59), forming pJFM9. This
plasmid was linearized with HincII, a unique site within the
zwf gene, and ligated to a SmaI-cut ~850-bp
gentamicin resistance (Gmr) cassette from pUCGM
(60), creating pJFM10. This plasmid was linearized with
NotI and ligated to the 5.8-kb oriT
sacB-containing fragment of pMOB3 (59), creating
pJFM11. After biparental mating of E. coli SM10 harboring
pJFM11 and P. aeruginosa PAO1, plasmid integration into the
genome by homologous recombination was assessed by selection on
Pseudomonas isolation agar (PIA)-gentamicin plates. Isolated
Gmr colonies were picked and grown in L broth until mid-log
phase, and serial dilutions were plated on PIA-gentamicin plates
containing 5% sucrose. Candidate zwf mutants were confirmed
by Southern blot and G6PDH activity gel analyses.
Paraquat sensitivity assays.
Bacteria were grown for 17 h at 37°C under aerobic conditions in L broth without NaCl containing
400 µg of carbenicillin per ml and 0.2 mM IPTG. Aliquots (2.5 µl)
of these suspensions were added to 2.5 ml of the same medium containing
increasing concentrations of paraquat and incubated on a roller wheel
at 90 rpm for 17 h at 37°C. The final absorbance of the
appropriately diluted suspensions was recorded on a Beckman DU 20 (Fullerton, CA) spectrophotometer at 600 nm.
Cell extract preparation, nondenaturing gel electrophoresis, and
biochemical assays.
Cell extracts of mid-logarithmic-phase
organisms or overnight-grown bacteria were prepared from cultures
harvested by centrifugation at 10,000 × g for 10 min
at 4°C. Bacteria were washed twice in ice-cold 50 mM sodium phosphate
buffer (pH 7.0) and sonicated in an ice water bath for 10 s with a
model W-225 sonicator (Heat-Systems, Inc., Farmington, N.Y.) at setting
5. The sonicate was then clarified by centrifugation at 13,000 × g for 10 min at 4°C. Cell extract for native gel
electrophoresis was prepared as described above except that 50 mM
Tris-HCl (pH 7.8) was used as the diluent. G6PDH activity was monitored
by the production of NADPH at 340 nm in 1-ml reaction mixtures
containing 1 mM glucose-6-phosphate, 0.4 mM NADP+, and cell
extract, using a Beckman DUP spectrophotometer equipped with an NGI
(Elk Grove Village, Ill.) Servogor chart recorder unless otherwise
indicated. G6PDH activity staining in 7.5% nondenaturing gels was
performed with the same reagents as in the spectrophotometric assay
described above except for the addition of 0.16 mM phenazine methosulfate and 0.18 mM nitroblue tetrazolium (37).
Paraquat:NAD(P)H oxidoreductase activity was assayed by two methods.
The first involved following the oxidation of NADH or NADPH
spectrophotometrically at 340 nm (39). The second involved
activity staining in 10% nondenaturing gels soaked in a mixture of 50 mM Tris-HCl (pH 7.5), 4 mM paraquat, 1 mM nitroblue tetrazolium, and
either 0.2 mM NADH or NADPH (40). -Galactosidase assays
were performed on either chloroform-sodium dodecyl sulfate
(SDS)-treated bacteria or cell extracts, using
o-nitrophenyl--D-thiogalactopyranoside (ONPG) as the substrate; the results were expressed as international units
(micromoles of ONPG hydrolyzed/minute/milligram of protein), using a
millimolar extinction coefficient for ONPG of 3.1 (45). Catalase activity was monitored by following the decomposition of 18 mM
H2O2 at 240 nm (4, 6, 25).
Superoxide dismutase (SOD) activity was monitored by following the
autoxidation of pyrogallol at 320 nm (52), a modification of
the original method described by Marklund and Marklund (44).
Protein concentrations were estimated by the method of Bradford
(5), using bovine serum albumin fraction V (Sigma) as the
standard.
Nucleotide sequence accession number.
The sequence shown in
Fig. 1 has been assigned GenBank
accession no. AF029673.
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FIG. 1.
DNA sequence of the zwf gene of P. aeruginosa PAO1. Coding sequences are uppercase, noncoding
sequences are lowercase. The zwf coding sequence starts at
position 966. The putative ribosome binding (Shine-Dalgarno) sequence
is underlined prior to the ATG start codon. A predicted
 70-like promoter is bracketed, with the 35 and 10
regions underlined, and is based on the Neural Network Promoter
Prediction program (54). The asterisk indicates the
zwf stop codon.
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RESULTS |
DNA sequence analysis of the P. aeruginosa zwf
gene.
The P. aeruginosa PAO1 zwf gene was
initially cloned on an 11-kb BamHI fragment that also
contained the eda gene, encoding keto-3-deoxy-6-phosphogluconate aldolase (64). The
zwf gene was localized to a ~2.5-kb SacII
fragment. The predicted zwf gene product is 490 residues,
which could form a tetramer with an molecular mass of ~220 kDa (Fig.
1). A putative ribosome binding
(Shine-Dalgarno) site (GGttGG) was identified 9 bp upstream of the
zwf ATG start codon. The estimated size of the translated
G6PDH monomer was ~55.6 kDa, with a pI of 12.6.
Amino acid similarity with other G6PDH proteins.
The P. aeruginosa G6PDH was aligned with seven other G6PDH proteins
(identified by GenBank accession number and, in brackets, reference)
from E. coli (M55005 [57]),
Mycobacterium tuberculosis [unpublished]), (Z95844).
Chlamydia trachomatis (U83195 [unpublished]),
Haemophilus influenzae (U32737 or L42023 [15]), Erwinia chrysanthemi (X74866
[28]), Anabaena sp. strain PCC 7120 (U33282
[48]), and Synechococcus sp. strain PCC
7942 (U33285 or X64768 [58]), using the Align Plus 3 multiple protein alignment program (Fig.
2). The P. aeruginosa G6PDH
revealed the greatest identity with G6PDH proteins from E. chrysanthemi (55% identity) and E. coli (54%
identity). The weakest homology was demonstrated with the G6PDH
of H. influenzae (19% identity). The remaining G6PDH
proteins were >40% identical.
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FIG. 2.
Alignment of G6PDH proteins from various organisms.
G6PDH proteins were retrieved from GenBank and aligned by using the
global alignment program Align Plus 3. Abbreviations: PA, P. aeruginosa; ECO, E. coli; TB, M. tuberculosis; CHL, C. trachomatis; HAE, H. influenzae; ERW, E. chrysanthemi; ANA,
Anabaena sp.; SYN, Synechococcus sp. (B) Homology
blocks of each G6PDH protein.
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Construction of an isogenic zwf mutant of P. aeruginosa PAO1.
G6PDH-deficient P. aeruginosa
PAO1 strains called PFB103 (zwf-2) and PFB98
(zwf-1) were initially constructed by chemical mutagenesis
(50, 56). These strains are incapable of utilizing mannitol
as the sole carbon source and cannot catabolize glucose via the
phosphorylative pathway because of a deficiency in G6PDH activity
(50, 56). Here we elected to construct an isogenic zwf mutant of wild-type strain PAO1 containing a selectable
antibiotic resistance marker, the details of which are given in
Materials and Methods. Insertional inactivation of zwf was
first confirmed by Southern analysis on a sucroser
Gmr zwf mutant called PAO9010. Genomic DNA from
the wild-type strain and PAO9010 was cut with
PstI/BamHI, transferred to nitrocellulose, and
probed with a ~1-kb PstI-BamHI zwf
fragment. Insertional inactivation of the zwf gene was
confirmed by demonstration of a band of the predicted size (1.85 kb
[Fig. 3A, lane 2]) relative to
wild-type DNA (~1.0 kb [Fig. 3A, lane 1]). Insertional inactivation
of the zwf gene was also confirmed by monitoring G6PDH
activity in nondenaturing gels. Figure 3B (lane 2) demonstrates an
absence of G6PDH activity band in the mutant organism, while activity
is clearly evident in the wild-type strain (lane 1).
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FIG. 3.
Construction of a P. aeruginosa isogenic
zwf mutant PAO9010. (A) Genomic DNA was digested with
PstI and BamHI and transferred to nitrocellulose.
Southern blot analysis was performed with a 32P-labeled
1.0-kb PstI/BamHI zwf fragment. Lane
1, PAO1 (wild type); lane 2, PAO9010 (zwf mutant). (B) G6PDH
activity gel (7.5%) of cell extracts. Lane 1, PAO1 (wild type); lane
2, PAO9010 (zwf mutant).
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Transcription of the zwf gene and G6PDH activity are
maximal in logarithmic phase.
To examine the regulation of
zwf in P. aeruginosa, we used both
transcriptional and translational approaches. To monitor zwf transcription, a 1.7-kb PvuII zwf-containing
fragment from pJFM1 was cloned into the unique SmaI site in
pEX100T (62). This plasmid, pJFM4, was cut with
BamHI and ligated to a 4.0-kb BamHI-cut
promoterless lacZ-Gmr cassette from pZ1918G
(61a), resulting in either pJFM5 (sense orientation) or
pJFM6 (antisense orientation). These plasmids were conjugated into
P. aeruginosa PAO1 via biparental mating and selected on PIA
containing gentamicin (300 µg/ml). Genetic confirmation of the
zwf::lacZ-Gmr fusion mutant
strain PAO9011 was elucidated after sucrose counterselection (as
with strain PAO9010) and Southern analysis (data not shown). As shown
in Fig. 4A, zwf (sense)
transcription rose dramatically in early to mid-logarithmic phase,
followed by a marked drop in activity when the organisms entered late
log to stationary phase. Antisense transcriptional activity throughout
the entire growth phase was negligible (data not shown). G6PDH
enzymatic activity paralleled that of the zwf
transcriptional analysis in Fig. 4A, with activity rapidly rising in
the early stages of growth and falling markedly at the later stages
(Fig. 4B).
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FIG. 4.
Analysis of zwf transcription (A) and G6PDH
activity (B) throughout a normal aerobic growth phase. Wild-type
bacteria and strains PAO9011
(zwf::lacZ-Gmr, sense
orientation) and PAO9012
(zwf::lacZ-Gmr, antisense
orientation) were grown aerobically at 37°C in L broth. At intervals,
organisms were harvested and specific activities for -galactosidase
and G6PDH were measured.  , OD600;  , -galactosidase
specific activity of strain PAO9011;  , G6PDH activity.
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Effect of carbon source on zwf transcription.
G6PDH activity is induced when organisms are grown in minimal medium
supplemented with either glucose, gluconate, or glycerol, highly
reduced substrates. In pseudomonads, G6PDH activity is repressed by
organic acids via catabolite repression (39; for a
review, see reference 10), and this effect has been
assumed to be at the level of transcription. To test this
assumption, we elected to determine the level of zwf
transcription in
zwf::lacZ-Gmr fusion strain
PAO9011 (constructed above) grown in media containing a variety of
carbon sources. As shown in Fig. 5, there
is a broad range of transcriptional control of the zwf gene.
Growth on glycerol, gluconate, and glucose allowed for the highest
levels of zwf transcription. In contrast, growth on organic
acids reduced zwf transcription, with succinate and acetate
evoking the strongest catabolite repression.
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FIG. 5.
Effect of carbon source of zwf transcription.
P. aeruginosa PAO9011, with
zwf::lacZ integrated into the
chromosome (single copy), was grown aerobically at 37°C in minimal
medium containing various carbon sources: glycerol (40 mM), glucose (20 mM), gluconate (20 mM), lactate (40 mM), fumarate (30 mM), citrate (20 mM), succinate (30 mM), and acetate (60 mM). Cell suspensions were
assayed in early log phase for -galactosidase activity as previously
described (45).
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Purification of P. aeruginosa G6PDH and enzyme
kinetics.
To determine the kinetic parameters of the P. aeruginosa G6PDH, we purified G6PDH from wild-type bacteria
overexpressing the enzyme. We used a four-step procedure involving (i)
ammonium sulfate precipitation of cell extracts, (ii) DE-52 anion
exchange, (iii) hydroxyapatite chromatography, and (iv) Bio-Gel 150 gel
filtration. Figure 6 demonstrates the
stages of purification using SDS-polyacrylamide gel electrophoresis
(PAGE). Clearly, the most significant purification step was DE-52
anion-exchange chromatography (Fig. 6, lane 4). Some proteins which
bound to DE-52 did not bind to hydroxyapatite (Fig. 6, lane 5). The
smaller contaminating proteins still present after hydroxyapatite
chromatography were resolved easily with the Bio-Gel 150 matrix, while
G6PDH, because of its large size (estimated at ~220 kDa), eluted from
the column at the void volume (Fig. 6, lane 6). We obtained
approximately 500 µg of purified G6PDH, a small portion of which was
used for the kinetic analyses described below.
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FIG. 6.
Analysis of the purification of P. aeruginosa
PAO1 G6PDH by SDS-PAGE (10% gel). Lane 1, high-molecular-weight
protein standard; lane 2, crude cell extract (45 µg); lane 3, 50%
ammonium sulfate cut (30 µg); lane 4, DE-52 column eluate (10 µg);
lane 5, hydroxyapatite column eluate, (7 µg); lane 6, Bio-Gel 150 column eluate (2 µg); lane 7, low-molecular-weight protein
standard.
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Many G6PDH enzymes have been purified from organisms or tissues from
various phyla. Unlike the P. aeruginosa (35) and
several other bacterial G6PDH enzymes, however, many G6PDH enzymes
cannot use both NAD+ and NADP+ as cofactors for
enzyme activity. To determine the specificity of the P. aeruginosa G6PDH toward G6P, NAD+, and
NADP+, we performed a kinetic analysis using each compound.
Double-reciprocal Lineweaver-Burk plots of enzymatic activity as a
function of G6P, NAD+, and NADP+ concentration
are shown in Fig. 7. The estimated
Km values for G6P (with NADP+ as the
cofactor), NAD+, and NADP+ were 530, 333, and
57 µM, respectively. The specific activities for NAD+ and
NADP+ were calculated to be 176 and 69 µmol/min/mg.
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FIG. 7.
Estimation of Km for
glucose-6-phosphate (G6P; A), NAD+ (B), and
NADP+ (C) with purified P. aeruginosa G6PDH.
Rates were measured in terms of an increase in absorbance at 340 nm at
22°C. Initial rates as a function of either glucose-6-phosphate,
NAD+, or NADP+ are presented above on
reciprocal coordinates, using 4.2 nM purified P. aeruginosa
G6PDH.
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An absence of G6PDH confers enhanced sensitivity to paraquat.
The intracellular redox status of all living cells is governed in part
by the levels of NAD(P)+ relative to NAD(P)H. NADPH is an
essential cofactor for glutathione reductase (3) and
alkylhydroperoxide reductase (32), enzymes important in
combating oxidative stress (9). Since by-products of G6PDH
activity are NADH and NADPH, and reduced levels of these cofactors
would limit the efficacy of such enzymes, we predicted that a
zwf mutant would be more sensitive to paraquat. However, for
paraquat to cause oxidative stress, it must first be reduced, followed
by autoxidation of the paraquat monocation radical (PQ*) by oxygen,
creating O2. Paraquat reduction within E. coli
is catalyzed by three paraquat:NADPH oxidoreductases (39).
It would be predicted that the activity of such an enzyme(s) under
aerobic conditions would, in part, dictate susceptibility or resistance
to paraquat. Because the P. aeruginosa G6PDH enzyme also
generates NADH (35), it is possible that paraquat can also
be reduced by enzymes utilizing this cofactor that may not utilize
NADPH. To monitor the activities of NADH- and NADPH-dependent paraquat
oxidoreductases and to ensure that wild-type and zwf mutant
levels of these enzymes were similar, cell extracts of both strains
were subjected to nondenaturing PAGE followed by activity staining for
both enzymes. As shown in Fig. 8,
P. aeruginosa possesses both NADPH (Fig. 8A)- and NADH (Fig.
8B)-dependent paraquat oxidoreductases; there were two of the latter
and at least five of the former. The addition of PQ (lanes 5 to 8 in
Fig. 8A and B) triggered a 1.2-fold increase in oxidoreductase
activity, which was measured spectrophotometrically (data not shown).
Thus, based on the activity gel, spectrophotometric measurement, and
linear scanning densitometry (data not shown), we conclude that
wild-type and zwf mutant levels of both paraquat-reducing enzymes were similar. Furthermore, the activities of the important antioxidants SoD and catalase were identical in both wild-type and
zwf mutant organisms (data not shown).
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FIG. 8.
Analysis of wild-type and zwf mutant cell
extracts for paraquat:NADPH and paraquat:NADH oxidoreductase activity.
P. aeruginosa PAO1 and PAO9010 containing either pEX30
(vector control) or the zwf expression vector pJFM3 were
grown in L broth minus NaCl containing 400 µg of carbenicillin per ml
and 0.2 mM IPTG until mid-logarithmic phase (OD600 = 0.6),
and the culture was divided into two parts. One set was treated with
100 µM paraquat (PQ), and the other served as a control. These
suspensions were incubated aerobically for an additional hour at 37°C
prior to preparation of cell extracts. Extracts were separated by
nondenaturing PAGE on 7.5% polyacrylamide gels and stained for
paraquat:NADPH (A) and paraquat:NADH (B) oxidoreductase activities as
previously described (40). Lanes 1 through 4, mid-logarithmic-phase organisms; lanes 5 through 8, mid-logarithmic-phase organisms plus 100 µM paraquat for 1 h.
Lanes 1 and 5, PAO1(pEX30); lanes 2 and 6, PAO1(pJFM3); lanes 3 and 7, PAO1 zwf(pEX30); lanes 4 and 8, PAO1
zwf(pJFM3).
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Finally, to test whether a G6PDH deficiency increases the
susceptibility of P. aeruginosa to paraquat, wild-type and
zwf mutant strains containing the zwf
overexpression vector pJFM3 or the control vector pEX30 were grown in L
broth in the absence of NaCl and exposed to increasing concentrations
of paraquat. Our rationale for not supplementing L broth with NaCl in
this experiment is that NaCl has been shown to interfere with paraquat
for its receptor on the cell surface and thus restricts its antibiotic
efficacy (34). As shown in Fig.
9, wild-type organisms were resistant to
60 µM paraquat whereas the zwf mutant demonstrated
increased sensitivity at concentrations of 40 µM and greater. When
the zwf gene was provided in trans in both the
zwf mutant and wild-type strains, there was enhanced
resistance to paraquat which exceeded that of wild-type organisms.
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FIG. 9.
Effect of paraquat on growth of wild-type and
zwf mutant P. aeruginosa. P. aeruginosa PAO1 and
PAO9010 harboring either pEX30 (control vector) or pJFM3
(zwf overexpression plasmid) were grown in L broth (without
NaCl) containing 400 µg of carbenicillin per ml and 0.2 mM IPTG for
17 h at 37°C under aerobic conditions. Aliquots (2.5 µl) were
added to 2.5 ml of the same media containing increasing concentrations
of paraquat and incubated on a roller wheel at 90 rpm for 17 h at
37°C. The final OD600 nm was recorded. The data are
representative of four different experiments.  , PAO1(pEX30); ,
PAO9010(pEX30); , PAO1(pJFM3); , PAO9010(pJFM3).
|
|
| |
DISCUSSION |
P. aeruginosa is capable of utilizing myriad carbon
sources for growth. Although it prefers TCA cycle intermediates (e.g., succinate or citrate), it also readily metabolizes glucose. A key
enzyme involved in glucose metabolism is G6PDH, which converts glucose-6-phosphate to 6-phosphogluconate. 6-Phosphogluconate is
further metabolized by the obligatory Entner-Doudoroff pathway (29). In this study, we have cloned and characterized the
zwf gene encoding G6PDH to better understand the
physiological role of this enzyme in normal aerobic metabolism.
Regulation of the P. aeruginosa zwf gene was found to be
under tight transcriptional control. The transcription of
zwf, as well as G6PDH activity, was greatest during
mid-logarithmic phase and then rapidly decreased to basal levels. This
was not surprising since substrates triggering elevated zwf
transcription (e.g., glucose) are likely depleted once organisms begin
to enter the stationary phase (41). Furthermore, P. aeruginosa and other Pseudomonas species exhibit a
strong catabolite repression control (10, 42), and this
pattern of induction/repression is a hallmark of such an event.
Catabolite repression control of glucose-6-phosphate activity is
normally striking, as evidenced by an approximate 90 to 99% reduction
in activity when cells are grown on organic acids (66). We
observed a similarly wide range of transcriptional control for the
chromosomal zwf::lacZ fusion and now
conclude that catabolite repression control of the zwf gene
is at the level of transcription. Interestingly, when the
zwf::lacZ fusion was introduced on a
multicopy plasmid (pUCP22 at ~30 copies/cell [61b]), -galactosidase activity was reduced only ~50% during growth on organic acids compared to glucose, glycerol, or gluconate (data not
shown). This is strikingly similar to the HexC phenotype
(64), where a cloned promoter for the hex regulon
genes edd and gap is proposed to titrate a
hex regulon repressor, leading to increased basal activity
of all five hex regulon enzymatic activities (Zwf, Edd, Eda,
Gap, and Glk) (12, 64, 65). This result indicates the
presence of a Hex repressor binding site upstream of the zwf gene, for which there is in vitro evidence (51).
Unlike eukaryotic G6PDH enzymes, which can utilize only
NADP+ as a cofactor, many bacterial enzymes, including
those from Leuconostoc mesenteroides (13),
Acetobacter suboxydans (8), A. hansenii (53), Azotobacter vinelandii
(2), P. aeruginosa (this study and reference
35), P. fluorescens (37),
P. (Burkholderia) cepacia
(7), and P. multivorans (67), utilize
both NAD+ and NADP+. Of particular interest was
the remarkably low Km of the P. aeruginosa G6PDH for its substrate, glucose-6-phosphate (530 µM). Estimated Km values range from 2.3 to 2.7 mM for glucose-6-phosphate of purified or partially purified G6PDH
enzymes or the NAD+/NADP+-cofactored G6PDH from
the related organism P. fluorescens (37) to 5 mM
in the other related species P. multivorans (67)
and Burkholderia (formerly Pseudomonas)
cepacia (7). Furthermore, the cofactor
specificity for the P. aeruginosa G6PDH was nearly sixfold
greater for NADP+ (Km = 57 µM)
than for NAD+ (Km = 333 µM) but
the specific activity was greater with NAD (176 versus 69 U/mg). One
particular advantage for possessing an enzyme with such superb
efficiency is that the valuable cellular reducing equivalents NADH and
NADPH, by-products of G6PDH activity, are essential cofactors for
hundreds of enzymes involved in catabolic or anabolic processes and
cellular defense and could be produced in environments where glucose is
limiting.
The role of G6PDH in susceptibility to paraquat was also dissected.
Resistance to reactive oxygen intermediates in P. aeruginosa is governed in part by antioxidant enzymes, including iron- and manganese-cofactored SOD (21-26) and at least two heme
catalases (6, 21). One compound which exacerbates the
production of O2 and
H2O2 within aerobic bacteria is paraquat
(18, 20). In E. coli, transcriptional control of
the zwf gene is governed by the soxRS regulon
(for a review, see reference 14) and increased upon
exposure to paraquat (18, 33). It was postulated that an
increase in G6PDH activity is brought about because of the need for
NADPH, required as a cofactor for glutathione reductase (3)
and alkylhydroperoxide reductase (32) activities. The latter
enzymes are important in combating paraquat-mediated oxidative stress
(9). The sensitivity of our P. aeruginosa zwf
mutant to paraquat is consistent with an unpublished observation in
E. coli, where a zwf mutant demonstrated
increased sensitivity to both the related redox-active compound
menadione and H2O2 (17). Although
the enhanced sensitivity of our P. aeruginosa zwf mutant was
modest, enhanced resistance could be conferred by overexpression of
intracellular G6PDH (Fig. 9). Still, sensitivity to paraquat is likely
dependent on the presence or absence of multiple cellular factors, some
of which include SOD (24), catalase (6),
methionine sulfoxide reductase (46, 47), DNA repair systems
(30, 31), and various regulatory proteins (e.g., SoxRS
[14]).
Although the P. aeruginosa gor gene encoding glutathione
reductase has been cloned (49), no mutants are currently
available. Similarly, an ahp (alkylhydroperoxide reductase
[32]) homolog has not been identified in this
organism. It will be important to construct gor and, if
possible, ahp mutants of P. aeruginosa to
determine whether inactivation of these genes increases susceptibility to various forms of oxidative stress.
J.-F.M. and P.W.H. contributed equally to completion of this
project.
This work was supported in part by grant AI-32085 from the
National Institutes of Health (D.J.H.), Cystic Fibrosis grant
HASSET96PO (D.J.H.), and Departmental Start-Up Funds from the
Department of Molecular Genetics, Biochemistry and Microbiology,
University of Cincinnati College of Medicine.
Mary Beth Dail and Ann Covert-Rinaldi provided excellent technical
support for the subcloning and sequencing of the zwf gene.
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J. Bacteriol.
173:4700-4706[Abstract/Free Full Text].
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Abstract
Introduction
