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Journal of Bacteriology, November 2001, p. 6509-6516, Vol. 183, No. 22
0021-9193/01/$04.00+0 DOI: 10.1128/JB.183.22.6509-6516.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
Identification of the Structural Gene for the
TDP-Fuc4NAc:Lipid II Fuc4NAc Transferase Involved in Synthesis of
Enterobacterial Common Antigen in Escherichia coli
K-12
Arifur
Rahman,
Kathleen
Barr, and
Paul D.
Rick*
Department of Microbiology and Immunology,
Uniformed Services University of the Health Sciences, Bethesda,
Maryland 20814-4799
Received 22 May 2001/Accepted 14 August 2001
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ABSTRACT |
The polysaccharide chains of enterobacterial common antigen (ECA)
are comprised of the trisaccharide repeat unit Fuc4NAc-ManNAcA-GlcNAc, where Fuc4NAc is 4-acetamido-4,6-dideoxy-D-galactose,
ManNAcA is N-acetyl-D-mannosaminuronic acid,
and GlcNAc is N-acetyl-D-glucosamine. Individual trisaccharide repeat units are assembled as
undecaprenyl-linked intermediates in a sequence of reactions that
culminate in the transfer of Fuc4NAc from TDP-Fuc4NAc to
ManNAcA-GlcNAc-pyrophosphorylundecaprenol (lipid II) to yield
Fuc4NAc-ManNAcA-GlcNAc-pyrophosphorylundecaprenol (lipid III), the
donor of trisaccharide repeat units for ECA polysaccharide chain
elongation. Most of the genes known to be involved in ECA assembly are
located in the wec gene cluster located at ca. 85.4 min
on the Escherichia coli chromosome. The available data
suggest that the structural gene for the TDP-Fuc4NAc:lipid II Fuc4NAc transferase also resides in the wec gene cluster;
however, the location of this gene has not been unequivocally defined.
Previous characterization of the nucleotide sequence of the
wec gene cluster in the region between
o416 and wecG revealed that it contained three open reading frames: o74, o204, and
o450. In contrast, the results of experiments described
in the current investigation revealed that it contains only two open
reading frames, o359 and o450. Mutants of
E. coli possessing null mutations in o359
were unable to synthesize ECA, and they accumulated lipid II. In
addition, the in vitro incorporation of [3H]FucNAc from
TDP-[3H]Fuc4NAc into lipid II was not observed in
reaction mixtures using cell extracts obtained from these mutants as a
source of enzyme. The ECA-negative phenotype of these mutants was
complemented by plasmid constructs containing the wild-type
o359 allele, and Fuc4NAc transferase activity was
demonstrated by using cell extracts obtained from the complemented
mutants. Furthermore, partially purified o359 gene
product, expressed as recombinant C-terminal His-tagged protein, was
able to catalyze the in vitro transfer of [3H]Fuc4NAc
from TDP-[3H]Fuc4NAc to lipid II. Our data support the
conclusion that o359 of the wec gene
cluster of E. coli is the structural gene for the
TDP-Fuc4NAc:lipid II Fuc4NAc transferase involved in the synthesis ECA
trisaccharide repeat units.
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INTRODUCTION |
Enterobacterial common antigen
(ECA) is a glycolipid found in the outer leaflet of the outer membrane
of all gram-negative enteric bacteria (12, 15, 19, 27).
The component sugars of the ECA polysaccharide are
N-acetyl-D-glucosamine (GlcNAc), N-acetyl-D-mannosaminuronic acid
(ManNAcA), and
4-acetamido-4,6-dideoxy-D-galactose (Fuc4NAc).
These amino sugars are linked to one another to yield polysaccharide
chains comprised of trisaccharide repeat units with the following
structure:
3)-
-D-Fuc4NAc-(14)-
-D-ManNAcA-(14)--D-GlcNAc-(1 (14, 16, 27). The linear trisaccharide repeat units of ECA are assembled as undecaprenyl-linked intermediates in a
stepwise sequence of reactions that are initiated by the
transfer of GlcNAc 1-P from UDP-GlcNAc to undecaprenylphosphate
(Und-P) to yield Und-PP-GlcNAc (lipid I) (Fig.
1) (4, 26, 27). Subsequent steps involve the incorporation of ManNAcA and Fuc4NAc to yield ManNAcA-GlcNAc-PP-Und (lipid II) and Fuc4NAc-ManNAcA-GlcNAc-PP-Und (lipid III), respectively (3). Lipid III molecules are
then presumably translocated across the cytoplasmic membrane to the periplasmic face of the membrane, where polysaccharide chain-elongation is believed to occur by a "block-polymerization" mechanism.
Finally, Und-PP-linked ECA polysaccharide chains are transferred to an as-yet-unidentified glyceride acceptor to yield polysaccharide chains
that are linked through the potential reducing terminal GlcNAc to
diacylglycerol via phosphodiester linkage (ECAPG)
(13, 25). Completed ECAPG molecules
are subsequently translocated to the outer membrane by an unknown
mechanism, where they are anchored in the outer leaflet by the
hydrophobic portion of the phosphoglyceride aglycone (1,
29).
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FIG. 1.
ECA biosynthetic pathway. The genetic determinants of
the enzymes involved in the biosynthesis of ECA are indicated next to
the reaction catalyzed by the respective enzyme. Abbreviations: Und-P,
undecaprenylmonophosphate; Und-PP, undecaprenylpyrophosphate; GlcNAc,
N-acetyl-D-glucosamine; ManNAcA,
N-acetyl-D-mannosaminuronic acid;
FucNH2, 4-amino-4,6-dideoxy-D-galactose;
Fuc4NAc, 4-acetamido-4,6-dideoxy-D-galactose; Glc1-P,
glucose-1-phosphate; PPi, inorganic pyrophosphate; KG,
-ketoglutaric acid; acetyl-CoA, acetyl-coenzyme A; CoASH, coenzyme
A; ECAPG, the phosphoglyceride-linked form of ECA.
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Most of the genes involved in the assembly of ECA are located in the
wec gene cluster (formerly the rfe-rff
gene cluster) located at ca. 85.4 min on the Escherichia
coli chromosome (5, 12, 20, 27). Earlier
studies on the genetics and biosynthesis of ECA in E. coli
resulted in the isolation of a mutant that was unable to synthesize ECA
due to a spontaneous mutation, termed rff-726
(21). Although these studies did not reveal the specific step of ECA synthesis affected by this mutation, rough-mapping studies
indicated that it was located in the wec gene cluster near
wecA (formerly rfe). Subsequent biochemical and
genetic studies suggested that the rff-726 mutation resided
in the structural gene for the TDP-Fuc4NAc:lipid II Fuc4NAc
transferase (22). Although this gene was localized to the
3' region of the wec gene cluster, its precise location was
not determined. The complete nucleotide sequence of the E. coli
wec gene cluster was later determined by Daniels et al.
(9). These investigators defined a single open reading
frame (ORF), o716, that was located between o416
and wecG in the 3'-terminal region of the wec
cluster (Fig. 2B), and they tentatively
identified o716 as the structural gene (wecF,
formerly rffT) for the Fuc4NAc transfersase. This conclusion was supported by the results of experiments which demonstrated that the
rff-726 mutation was complemented by a region of the wec cluster that included the putative wild-type
o716 locus (21).
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FIG. 2.
Identification of the genetic determinants located
between o416 and wecG of the
wec gene cluster. (A) wec gene cluster of
E. coli K-12. ORFs are indicated by the solid arrows.
The 13-kb scale above the gene cluster is provided for reference. The
region between o416 and wecG, as defined
by previous investigations, is presented below (B and C). (B)
Identification of a single ORF, o716, between
o416 and wecG, as determined by initial
nucleotide sequencing experiments (9). (C) Revised
characterization of the region between o416 and
wecG, indicating the occurrence of ORFs
o74, o204, and o450
(GenBank accession no. AE000455). (D) Identification of two ORFs,
o359 and o450, in the region between
o416 and wecG, as determined in the
current study. The open triangles indicate the positions of potential
translational start codons. The vertical arrow in panel C indicates the
location of a frameshift resulting from the erroneous detection of two
cytosines rather than a single cytosine immediately downstream of
nucleotide 7617 of the wec cluster. The vertical dashed
line indicates the position of the Tn10cam insertion in
strain PND788. (E) Chromosomal insert fragments contained in the
indicated plasmids, and the ability of these constructs to complement
the ECA-negative phenotype of strain PND788 as determined by passive
hemagglutination assay (26). The 5-kb scale at the bottom
of the figure is presented to provide reference for the region
circumscribed by o416 and wecG.
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Morona et al. (24) noted that the hydropathy profile of
the carboxy-terminal half of the putative protein encoded by
o716 was strikingly similar to that of a wide variety of
putative WzyOAg (Rfc, O-antigen polymerase)
enzymes. These authors speculated that either the putative
o716 gene product possessed both Fuc4NAc transferase and
WzyECA activities or the nucleotide sequence
including o716 was incorrect and this region contained
structural genes for both the Fuc4NAc transferase and the
WzyECA. A subsequent reexamination of the
nucleotide sequence between o416 and wecG of the
wec cluster (GenBank accession no. AE000455) indicated that
it was incorrect. These experiments revealed that this region did not
include an o716; rather, it was reported to contain three putative ORFs: o74, o204, and o450 (Fig. 2C). In
addition, o450 was tentatively identified as the structural
gene for the Fuc4NAc transferase. However, repeated examination of the
nucleotide sequence of this region in our laboratory yielded results
that were not in agreement with this conclusion. In contrast, our data
revealed that the region between o416 and wecG
contains only two ORFs, o359 and o450, and we
report here the results of experiments which clearly demonstrate that
o359 is the structural gene (wecF) for the
TDP-Fuc4NAc:lipid II Fuc4NAc transferase involved in the synthesis of ECA.
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MATERIALS AND METHODS |
Bacterial strains and growth conditions.
The bacterial
strains used in this study are listed in Table
1. Where indicated, transductions were
carried out by using P1 vir as described by Silhavy et al.
(30). Cultures of E. coli were grown in
Luria-Bertani (LB) broth (23) or on LB agar at 37°C.
Cultures of Pseudomonas aeruginosa were grown at 32°C in a
salts medium containing
K2HPO4 (7 g/liter),
KH2PO4 (3 g/liter), MgSO4 · 7H2O (0.1 g/liter), and
(NH4)2SO4
(1.0 g/liter), as well as 3% glycerol as the sole source of carbon.
The following antibiotics were added to media when appropriate at the
indicated final concentrations: ampicillin (100 µg/ml),
chloramphenicol (30 µg/ml), and tetracycline (20 µg/ml).
Radiochemicals, chemicals, and reagents.
D-[1-3H]glucose (15 Ci/mmol),
UDP-N-acetyl-D-[6-3H](N)glucosamine
(20.4 Ci/mmol), and
UDP-N-acetyl-D-[U-14C]glucosamine
(283 mCi/mmol) were purchased from New England Nuclear Corp.
UDP-N-acetyl-D-[U-14C]mannosaminuronic
acid (283 mCi/mmol) and unlabeled
UDP-N-acetyl-D-mannosaminuronic acid
were enzymatically synthesized from
UDP-N-acetyl-D-[U-14C]glucosamine
(283 mCi/mmol) and
UDP-N-acetyl-D-glucosamine,
respectively (4).
D-[1-3H]glucose-6-phosphate
was enzymatically synthesized from
D-[1-3H]glucose (15 Ci/mmol) by using yeast hexokinase.
TDP-D-[1-3H]glucose
(TDP-[3H]glucose) was enzymatically synthesized
from
D-[1-3H]glucose-6-phosphate
by using partially purified TDP-glucose pyrophosphorylase prepared from
extracts of P. aeruginosa 7700 as described by Kornfeld and
Glaser (11).
TDP-4-acetamido-4,6-dideoxy-D-[1-3H]galactose
(TDP-[3H]Fuc4NAc) and TDP-Fuc4NAc were
synthesized from TDP-[3H]glucose and
TDP-D-glucose, respectively, as described by
Matsuhashi and Strominger (18). All other chemicals and
reagents were purchased from standard commercial sources.
Plasmid constructions.
The plasmids used in this study are
listed in Table 1. Primers used for PCR amplification of nucleotide
sequences are listed in Table 2. PCR
amplifications were carried out by using Taq polymerase
(Sigma Chemicals) according to standard protocols. Plasmid pRL150 was
constructed by PCR amplification of the DNA sequence from bp 7067 to
8519 (GenBank accession no. AE000455) by using primers F1 and F8 and
genomic DNA from strain AB1133 as a template. The amplified sequence
included o359 in addition to 375 bp immediately upstream of
the translational start site, and it was cloned into the TA cloning
site of the pBAD-TOPO vector (Invitrogen, Inc.). One of the resulting
constructs contained the C-terminal nucleotide sequence of
o359 in-frame with the polyhistidine (His6) encoding nucleotide sequence of the
vector. Plasmid pRL151 was constructed by PCR amplification of the
insert fragment of pRL150 containing the entire
o359-C-terminal His6 tag fusion by using primers F1 and BAD1. The EcoRI- and
BamHI-cleaved PCR product was subcloned into pBluescript II
KS(+) (Stratagene) that was restricted by the same enzymes. Plasmids
pRL153, pRL154, pRL155, pRL156, and pRL160 were constructed by PCR
amplification of the DNA sequences from bp 7067 to 9948, 7160 to 9948, 7160 to 8683, 7463 to 8683, and 7691 to 9948 (GenBank accession no.
AE000455) by using primer pairs F1-F7, F2-F7, F2-F6, F3-F6, and F4-F7
and genomic DNA from strain AB1133 as a template, respectively.
The PCR products were cloned into the TA-cloning site of the pCR
2.1-TOPO cloning vector. T4 DNA ligase (Invitrogen) and restriction
enzymes were used in accordance with the manufacturer's
recommendations.
In vitro synthesis of lipid III.
Cell envelopes were
prepared as previously described (4). Reaction mixtures
for the in vitro synthesis of lipid III contained the following in a
final volume of 55 µl: 50 mM Tris-HCl (pH 8.2), 30 mM
MgCl2, 5 mM 2-mercaptoethanol, 0.14 µM
TDP-[3H]Fuc4NAc (2.56 × 107 dpm/µmol), and cell envelope membranes (700 to 850 µg of protein). Partially purified native
His6-tagged o359 gene product (6.75 µg of protein) and 0.24 µM UDP-[14C]ManNAcA
(6.3 × 105 dpm/µmol) were added to
reaction mixtures where indicated. Reactions were incubated at 37°C
for 30 min and then terminated by the addition of 1.0 ml of
chloroform-methanol (3:2, by volume). The radioactive products were
extracted from reaction mixtures as described previously (3), and they were analyzed directly by ascending paper
chromatography with SG-81 filter paper (Whatman, Inc.). Protein was
determined by using the BCA Protein Assay Reagent Kit (Pierce)
according to the instructions provided by the manufacturer.
In vivo assay for lipid II accumulation.
The incorporation
of [3H]GlcNAc into lipid II was determined as
previously described (28). Briefly, bacteria were grown
with vigorous aeration at 37°C in 60 ml of LB medium supplemented
with glucose (0.2%, final concentration) to an
A600 of 0.4. The cells were then
harvested by centrifugation, resuspended in fresh medium (6 ml), and
incubated at 37°C with [3H]GlcNAc (75 µCi,
8.2 Ci/mmol) for 30 min. The labeled cells were then poured over
crushed ice, harvested by centrifugation, and washed with cold 0.9%
saline. The washed cells were then successively extracted with 95%
ethanol (6 ml) and acetone (6 ml) and dried in vacuo. The dried cells
were extracted with 1.5 ml of chloroform-methanol (3:2, by volume), and
75 µl of the resulting extract was analyzed by ascending paper
chromatography on EDTA-treated SG-81 paper by using
chloroform-methanol-water-concentrated ammonium hydroxide (88:48:10:1,
by volume) as the developing solvent. The amount of radioactivity in
the region of the chromatogram corresponding to lipid II was then
determined as described below.
Partial purification of C-terminal histidine-tagged
o359 gene product.
Strain PND788F was grown in 200 ml of LB-glucose medium at 37°C. IPTG
(isopropyl--D-thiogalactopyranoside) was added at
A600 = 0.2 to give a final
concentration of 1 mM, and the culture was incubated overnight with
vigorous aeration. The cells were harvested by centrifugation and lysed
with 10 ml of B-PER (Pierce) according to the manufacturer's
recommendation. The suspension was then briefly sonicated, and the
insoluble material was then separated from the soluble fraction (B-PER
extract) by centrifugation at 12,000 × g. The pellet
was resuspended in 5 ml of a solution containing 8 M urea, 0.1 M
NaH2PO4, and 0.01 M
Tris-HCl (pH 8.0; final concentrations) and then incubated at room
temperature for 60 min with gentle stirring. The urea-soluble fraction
was next separated from cell debris by centrifugation at 12,000 × g for 20 min. The His-tagged o359 gene product
present in the B-PER extract and the urea-soluble fraction were then
partially purified by affinity chromatography by using
nickel-nitrilotriacetic acid (Ni+-NTA) agarose
resin (Qiagen, Inc.) under native and denaturing conditions,
respectively. Briefly, for partial purification by using native
conditions, imidazole was added to 4 ml of crude B-PER extract to give
a final concentration of 10 mM. Then, 1 ml of a slurry containing 50%
Ni+-NTA agarose resin was added, and the mixture
was incubated with gentle shaking at 4°C for 60 min. The mixture was
poured into a small column and, after the resin settled, the liquid
fraction was allowed to flow out of the column. The resin was then
washed twice with 4 ml of wash buffer (50 mM
NaH2PO4, pH 8.0; 300 mM NaCl; 20 mM imidazole). His-tagged protein was then eluted by four
successive 0.5-ml washes of the resin with elution buffer (50 mM
NaH2PO4, pH 8.0; 300 mM
NaCl, 250 mM imidazole), and fractions were analyzed by Western blot
analyses by using mouse anti-Penta-His antibody (Qiagen, Inc.) and
horseradish peroxidase-conjugated anti-mouse immunoglobulin G (IgG)
(Amersham). Fractions containing C-terminal His-tagged o359
were used for in vitro assay of Fuc4NAc transferase activity.
For partial purification of the C-terminal His-tagged
o359
gene product using denaturing conditions, 4 ml of the urea-soluble
extract was mixed with 1 ml of a slurry containing 50%
Ni
+-NTA agarose resin and incubated with gentle
shaking for 60 min
at room temperature. The mixture was poured into a
small column
and, after the resin settled, the liquid fraction was
allowed
to flow out of the column. The resin was then washed twice with
4 ml of buffer B (8 M urea, 0.1 M
NaH
2PO
4, 0.01 M
Tris-hydrochloride;
pH 6.3). His-tagged protein was then eluted with
four successive
0.5-ml washes of the resin with buffer C (8 M urea, 0.1 M NaH
2PO
4,
0.01 M
Tris-hydrochloride; pH 5.9), followed by four successive
0.5-ml washes
with buffer D (8 M urea, 0.1 M
NaH
2PO
4, 0.01 M
Tris-hydrochloride;
pH 4.5). The fractions were analyzed by Western
blot analyses
by using mouse anti-Penta-His antibody (Qiagen) and
horseradish
peroxidase-conjugated anti-mouse IgG (Amersham). Increased
yields
of more highly purified urea-soluble His-tagged protein were
obtained
by combining sonicated B-PER extracts with the urea-soluble
fraction,
followed by batch purification by using a modification of the
denaturing conditions as described above. Briefly, the material
that
eluted from the column with buffer C was concentrated by
centrifugation
by using a Microcon YM-30 centrifugal filtration
device (Amicon
Bioseparations) according to the manufacturer's
recommendations and
then reapplied to a new column containing
Ni
+-NTA
agarose resin. The column was then eluted successively with
buffers B
and C as described above. The material that eluted after
development of
the column with buffer C was detected as a single
band by Western blot
analyses.
Cellular localization of C-terminal histidine-tagged
o359 gene product.
The cellular localization of
C-terminal His6-tagged o359 gene
product was determined by using a modification of the microprocedure described by Carlone et al. (6). Strain PND788F was grown
with vigorous aeration in 500 ml of LB broth at 37°C. IPTG was added at A600 = 0.2 to give a final
concentration of 1 mM, and the culture was incubated overnight with
vigorous aeration. The cells were then harvested by centrifugation,
suspended in 5 ml of ice-cold 20 mM Tris-HCl-10 mM EDTA (pH 7.5)
(Tris-EDTA) buffer, and disrupted by three passages through a French
pressure cell (10,000 lb/in2, high ratio) at 0 to
4°C. Unbroken cells and cellular debris were removed by
centrifugation at 20,000 × g for 20 min. Cell envelope
membranes were isolated by centrifugation of the turbid supernatant
solution at 200,000 × g for 2 h. The resulting
pellet was resuspended in 1 ml of Tris-EDTA buffer, and the total cell envelope protein concentration was determined by using the BCA Protein
Assay Reagent Kit (Pierce) according to the instructions provided by
the manufacturer. The suspension was then diluted with Tris-EDTA buffer
to give a protein concentration of 4.4 mg/ml, and 1/10 volume of a 10%
(wt/vol) solution of Sarkosyl (N-lauroylsarcosine, sodium
salt) (Sigma) was subsequently added with gentle mixing. The mixture
was then incubated in an ice bath for 1 h, followed by
centrifugation at 200,000 × g (2 h, 4°C). The
supernatant solution was removed, and the pellet was resuspended in 0.5 ml of Tris-EDTA buffer and once again extracted with 1/10 volume of
Sarkosyl, followed by centrifugation at 200,000 × g (2 h, 4°C) as described above. The quantity of protein in the
Sarkosyl-insoluble fraction and pooled Sarkosyl-soluble fractions was
determined. The proteins in these fractions were then precipitated by
the addition of 8 volumes of cold acetone. The precipitates were
resuspended in sodium dodecyl sulfate-polyacrylamide gel
electrophoresis (SDS-PAGE) sample buffer.
Determination of the nucleotide sequence in the region between
o416 and wecG
The nucleotide
sequence of the wec gene cluster in the region between
o416 and wecG (2,882 bp) contained in the
cloned fragment of pRL153 was determined in both directions with BigDye
Terminator Cycle Sequencing Ready Reaction kits (Applied Biosystems)
and an ABI377 sequencer (Applied Biosystems). The data from these experiments were compared with the corresponding nucleotide sequence from E. coli (GenBank accession number AE000455). The
nucleotide sequence of the same region of the chromosome of the mutant
strain PND788 was also determined in order to confirm the position of the Tn10::cam insertion.
Passive hemagglutination assay.
The presence of ECA on the
surface of bacterial strains was determined by passive hemagglutination
assay with polyclonal rabbit anti-ECA antiserum as previously described
(26).
Western blot analyses.
Western blot analyses were carried
out as previously described (26), except that SDS-PAGE was
conducted by using 10% polyacrylamide gels, and C-terminal
His6-tagged WecF was detected by using mouse anti-tetra-His antibody (Qiagen), horseradish peroxidase-conjugated anti-mouse IgG (Amersham), and Western blot Chemiluminescence Reagent
Plus (NEN Life Science Products).
Chromatographic and electrophoretic procedures.
Paper
chromatography was carried out by using SG-81 paper (Whatman) that was
prepared as previously described (28). Samples were
spotted onto the paper, and the chromatogram was developed with a
solvent mixture containing chloroform-methanol-water-concentrated ammonium hydroxide (88:48:10:1, by volume). Lanes of the air-dried chromatogram were cut into 1-cm sections, and the sections were soaked
in 0.5 ml of 1.25% SDS for 6 to 8 h at 42°C. The samples were
then analyzed for radioactivity by liquid scintillation counting.
Nucleotide sequence accession number.
The revised nucleotide
sequence of the region of the wec gene cluster between
o416 and wecG has been deposited in the GenBank database under accession number AF375882.
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RESULTS AND DISCUSSION |
Occurrence of ORFs o359 and
o450 in the region between o416 and
wecG of the wec gene cluster of E.
coli.
The wec gene cluster of E. coli contains genes involved in the synthesis and assembly of ECA.
Although the location and function of many of the genes in this cluster
have been defined (2, 5, 17, 27), only the approximate
location of the gene encoding the TDP-Fuc4NAc:lipid II Fuc4NAc
transferase involved in the synthesis of the ECA trisaccharide repeat
unit has been determined. The results of previous investigations
support the conclusion that this gene is located in the region between
o416 and wecG of the wec gene cluster
(21). However, confusion regarding the nucleotide sequence
of this region has hampered an unequivocal determination of the
location of this gene. The nucleotide sequence between o416
and wecG of the wec gene cluster of E. coli has been reported to contain three putative ORFs:
o74, o204, and o450 (GenBank accession no. AE000455). However, repeated determination of the nucleotide sequence of this region during the present study revealed only two
putative ORFs, o359 and o450, whose
transcriptional orientation is the same as that of the other genes in
the wec gene cluster (Fig. 2D). These two ORFs overlap by 4 bp, and the overlapping sequence,
5'
o359ATGAo4503',
includes the predicted translational start codon of o450
(underlined) and the predicted translational stop codon of
o359 (boldface lettering). This organization suggests tight
coupling at both the transcriptional and the translational levels. The
previous assignments of o74 and o204 and the
failure to detect o359 were found to be due to a frameshift
stemming from the erroneous detection of two cytosines rather than a
single cytosine immediately downstream of nucleotide 7617 of the
nucleotide sequence of the wec cluster (Fig. 2C). However,
with one exception, the predicted amino acid sequence of the
o450 gene product as determined by nucleotide sequencing
experiments carried out in this study revealed that it was essentially
identical to that predicted by the published sequence. In this regard,
the published sequence reported an aspartic acid residue at position
283, whereas the current study revealed a histidine residue at this position.
Complementation of mutants of E. coli defective in
the synthesis of lipid III by o359 of the
wec gene cluster.
Previous studies resulted in the
isolation of E. coli PND788 which contains a
Tn10cam insertion in the region of the chromosome originally
identified as o716 of the wec gene cluster
(8). These studies also demonstrated that mutant strain
PND788 was unable to synthesize ECA and that it accumulated lipid II. A
determination of the location of the Tn10cam insertion in
the chromosome of strain PND788 revealed that it was inserted in codon
141 of the newly defined o359. This site corresponds to the
insertion of Tn10cam between bp 7863 and 7864 as defined by
the most recently published sequence of this region of the chromosome
(GenBank accession no. AE000455).
ECA synthesis was rescued in transformants of PND788 containing either
plasmid pRL153, pRL154, or pRL155, all of which contain
o359
(Fig.
2E). Although the cloned fragment in plasmids pRL153
and pRL154
also contains
o450 located immediately downstream of
o359, the data clearly indicate that the observed
complementation
was not due to
o450 since the cloned
fragment in pRL155 contains
o359 as the only complete ORF.
This conclusion was supported by
the observation that plasmid pRL160,
which contains
o450 as the
only complete ORF, was unable to
complement the ECA-negative phenotype
of PND788. As previously stated,
the inability of strain PND788
to synthesize ECA is accompanied by the
accumulation of lipid
II (
8). However, lipid II
accumulation was markedly reduced
in strain PND788F, a derivative of
PND788 that contains plasmid
pRL151 which encodes the putative
o359 gene product possessing
a carboxy-terminal
His
6 tag (Table
3).
Furthermore, the decreased
accumulation of lipid II in strain PND788F
was accompanied by
the synthesis of ECA.
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TABLE 3.
Complementation of the phenotype of strain PND788
(o359::cam) in a derivative
expressing carboxy-terminal His6-tagged
o359a
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The nucleotide sequence of
o359 contains three ATG codons:
the putative translation initiation codon and two downstream ATG
codons
(codons 38 and 184) (Fig.
2D). However, translation does
not appear to
be initiated at either of the downstream codons
since the ECA-negative
phenotype of PND788 was not complemented
by plasmid pRL156, which
encodes a truncated
o359 allele that
includes codons 38 and
184 but which lacks the 5' terminus from
bp 1 to 121 (Fig.
2D and E).
In addition, only the putative translational
start codon is immediately
preceded by a nucleotide sequence that
conforms to the Shine-Dalgarno
consensus sequence (data not shown).
Taken together, the above data
support the conclusion that
o359 is indeed functional and
that it is responsible for the observed
complemention of the phenotype
of mutant strain
PND788.
The o359 gene product catalyzes the transfer of
Fuc4NAc from TDP-Fuc4NAc to lipid II.
The accumulation of lipid II
in strain PND788 suggested that o359 encoded the
TDP-Fuc4NAc:lipid II Fuc4NAc transferase required for lipid III
synthesis. However, the phenotype of this mutant is also compatible
with the possibility that o359 is in some way required for
TDP-Fuc4NAc synthesis. In order to distinguish between these
possibilities, in vitro synthesis of lipid III was examined by
utilizing cell envelopes prepared from E. coli PR4144, an
o359::Tn10cam wecE::Tn10tet double mutant, as a source of
enzymes and lipid acceptors in cell-free reaction mixtures. The null
mutation in wecE precludes synthesis of
TDP-Fuc4NH2, the immediate precursor of
TDP-Fuc4NAc, thus resulting in the accumulation of lipid II as well as
lesser amounts of lipid I (21). Incubation of cell envelopes obtained from strain PR4144 with
UDP-[14C]ManNAcA and
TDP-[3H]Fuc4NAc resulted in the incorporation
of only [14C]ManNAcA into lipid II (Fig.
3A); thus, the incorporation of [14C]ManNAcA reflects the conversion of
accumulated lipid I to lipid II. Similar results were obtained by using
cell envelopes obtained from PND788 (data not shown). In contrast, the
incorporation of both [14C]ManNAcA and
[3H]Fuc4NAc into lipid III was observed in
reaction mixtures containing cell envelopes obtained from transformants
of strain PR4144 that contained plasmid pRL151 which encodes the
putative o359 gene product containing a carboxy-terminal
His6 tag (Fig. 3B). It is important to note that
lipids II and III have the same chromatographic mobility under the
assay conditions employed (3). Therefore, the single peak
of radiolabeled material in Fig. 3B actually includes [14C]ManNAcA-labeled lipid II, as well as lipid
III that is labeled with both [14C]ManNAcA and
[3H]Fuc4NAc. These data are in agreement with
the conclusion that o359 is not involved in TDP-Fuc4NAc
synthesis but rather that it is the structural gene for the
glycosyltransferase that catalyzes the transfer of Fuc4NAc from
TDP-Fuc4NAc to lipid II to form lipid III.
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FIG. 3.
In vitro transfer of [3H]Fuc4NAc
from TDP-[3H]Fuc4NAc to lipid II present in cell
envelopes of strains PR4144 and PR4144/pRL151. Cell envelope membranes
(700 to 850 µg of protein) were incubated with
UDP-[14C]ManNAcA and TDP-[3H]Fuc4NAc in the
standard reaction mixture (55 µl) at 37°C for 30 min. Reactions
were terminated by the addition of chloroform-methanol, and radioactive
products were extracted from the reaction mixtures and subsequently
analyzed by ascending paper chromatography by using SG-81 filter paper.
Additional details are provided in Materials and Methods. (A) Cell
envelopes of strain PR4144
(o359::Tn10cam
wecE::Tn10tet). (B) Cell envelopes of
strain PR4144/pRL151 (o359::Tn10cam
wecE:: Tn10tet/C-terminal
His6-tagged o359). Symbols:  , carbon-14;
 , tritium. The chromatographic mobility of authentic lipid III is
indicated by the bracket.
|
|
Additional evidence in support of the proposed function of
o359 was obtained by analyses of partially purified
C-terminal
His
6-tagged
o359 gene
product. Native His
6-tagged protein was
obtained
by mild nonionic detergent extraction of strain PND788F
cells after the
induction of synthesis of the His-tagged protein
with IPTG. The protein
was then partially purified by affinity
chromatography by using
Ni
+-NTA agarose resin. The in vitro transfer of
[
3H]Fuc4NAc from
TDP-[
3H]Fuc4NAc to endogenous lipid II present
in the cell envelopes
of strain PR4144 was observed in reaction
mixtures containing
affinity purified native
His
6-tagged protein (Fig.
4). In contrast,
no
[
3H]Fuc4NAc-labeled product was observed in
reaction mixtures lacking
the affinity purified native
His
6-tagged protein. Furthermore,
no
Fuc4NAc-transferase activity was detected in column fractions
obtained
by chromatography of soluble B-PER extracts of PND788
and
PND788/
pBluescript II KS(+) when we used the same procedures
for partial purification of the His
6-tagged
protein by Ni
+-NTA agarose resin affinity
chromatography (data not shown). Western
blot analyses revealed that
the affinity-purified native His
6-tagged
protein
migrated as a 41.5-kDa component (Fig.
5). This observation
is in excellent
agreement with the predicted size of the
His
6-tagged
o359 gene product since
the calculated size of the wild-type protein
is 39.5 kDa and the size
of the additional C-terminal sequence
of the
His
6-tagged protein, including the V5 epitope and
polyhistidine
region, is 2 kDa. The enzymatically active fraction
eluted from
the Ni
+-NTA agarose resin was also
considerably enriched for the 41.5-kDa
component as determined by
SDS-PAGE and Coomassie brilliant blue
staining (data not shown). The
above data strongly support the
conclusion that
o359 does
indeed encode the TDP-Fuc4NAc:lipid
II Fuc4NAc transferase involved in
the synthesis of the ECA trisaccharide
repeat unit and, accordingly, we
propose that this gene locus
be designated
wecF.
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FIG. 4.
In vitro transfer of [3H]Fuc4NAc from
TDP-[3H]Fuc4NAc to endogenous lipid II present in cell
envelopes of strain PR4144 catalyzed by partially purified C-terminal
His6-tagged o359 gene product. Cell envelope
membranes (700 to 850 µg of protein) prepared from strain PR4144
(o359::Tn10cam
wecE::Tn10tet) were incubated with
TDP-[3H]Fuc4NAc in standard reaction mixtures that also
contained partially purified C-terminal His6-tagged
o359 gene product (6.75 µg of protein) in a final
volume of 55 µl. Experiments were also carried out with reaction
mixtures (55 µl) that did not contain partially purified C-terminal
His6-tagged o359 gene product. The reaction
mixtures were incubated at 37°C for 30 min, and reactions were
terminated by the addition of chloroform-methanol. Radioactive products
were extracted from the reaction mixtures and subsequently analyzed by
ascending paper chromatography with SG-81 filter paper. Additional
details are provided in Materials and Methods. Symbols: , presence
of His6-tagged o359 gene product; ,
absence of His6-tagged o359 gene product.
The chromatographic mobility of authentic lipid III is indicated by the
bracket.
|
|
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FIG. 5.
Western blot analysis of partially purified
C-terminal His6-tagged o359 gene product.
Lane 1, native His6-tagged o359 gene product
present in the soluble B-PER extract obtained from strain PND788F; lane
2, soluble B-PER extract obtained from strain
PND788/pBluescript II KS(+) vector; lane 3, soluble
B-PER extract obtained from strain PND788; lane 4, urea-soluble
His6-tagged o359 gene product obtained from
the insoluble fraction after B-PER extraction of strain PND788F.
Details regarding the affinity purification and Western blot procedures
are provided in Materials and Methods.
|
|
It is interesting that a significant amount of
His
6-tagged protein remained insoluble after
extraction of cells with mild
nonionic detergent; however, this
material was rendered soluble
by subsequent extraction with urea. In
addition, Western blot
analyses of this urea-soluble material revealed
that it also migrated
as a single 41.5-kDa component (Fig.
5), and it
is likely that
the urea-solubilized protein simply reflects inefficient
detergent
solubilization. In this regard, an examination of the
hydropathy
profile of the predicted
wecF gene product
suggests that it may
contain a single transmembrane segment. These
observations suggest
that WecF is an integral membrane protein. In
addition, C-terminal
His
6-tagged WecF protein was
extracted from cell envelopes with
the anionic detergent Sarkosyl,
which preferentially solubilzes
cytoplasmic membrane proteins (
7,
10), and this protein was
not detected in the Sarkosyl-insoluble
fraction (Fig.
6). Accordingly,
these
data support the conclusion that WecF is indeed a component
of the
cytoplasmic membrane. However, details regarding the association
of
WecF with the cytoplasmic membrane and its membrane topology
remain to
be established.
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|
FIG. 6.
Sarkosyl extraction of the C-terminal
His6-tagged o359 gene product from cell
envelopes. Cell envelopes obtained from strain PND788F were extracted
with Sarkosyl, and the unextracted total cell envelope (lane 1) and the
Sarkosyl-soluble (lane 2) and -insoluble (lane 3) fractions, were
examined for the presence of the C-terminal His6-tagged
o359 gene product by Western blot analysis by using
mouse anti-Penta-His antibody. The arrow indicates the location of
C-terminal His6-tagged o359 gene product
that was partially purified by Ni+-NTA agarose resin
affinity chromatography. Additional details are provided in Materials
and Methods.
|
|
The available data suggest that ECA chain elongation occurs by a
Wzy-mediated block-polymerization mechanism. However, the
gene encoding
the polymerase that catalyzes this reaction has
not yet been
identified. The
wecF gene is located immediately
upstream
from
o450; however, the function of
o450 is not
known.
Previous observations suggest the possibility that
o450 of the
wec gene cluster is the structural
gene for the polymerase involved
in ECA polysaccharide chain elongation
(
24). This conclusion
is supported by recent observations
that mutants of
E. coli K-12
containing a null mutation in
o450 are unable to synthesize ECA
and that they accumulate
lipid III (unpublished results). However,
biochemical data that
directly demonstrate the ability of the
o450 gene product to
catalyze polymerization of ECA trisaccharide
repeat units have not yet
been
obtained.
| |
ACKNOWLEDGMENT |
This work was supported by an NIGMS grant (GM52882) to P.D.R.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Microbiology and Immunology, Uniformed Services University of the
Health Sciences, 4301 Jones Bridge Rd., Bethesda, MD 20814-4799. Phone: (301) 295-3418. Fax: (301) 295-1545. E-mail:
rickp{at}usuhs.mil.
| |
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Journal of Bacteriology, November 2001, p. 6509-6516, Vol. 183, No. 22
0021-9193/01/$04.00+0 DOI: 10.1128/JB.183.22.6509-6516.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
