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J Biol Chem, Vol. 274, Issue 49, 35129-35138, December 3, 1999
From the During O antigen lipopolysaccharide (LPS)
synthesis in bacteria, transmembrane migration of
undecaprenylpyrophosphate (Und-P-P)-bound O antigen subunits occurs
before their polymerization and ligation to the rest of the LPS
molecule. Despite the general nature of the translocation process,
putative O-antigen translocases display a low level of amino acid
sequence similarity. In this work, we investigated whether complete O
antigen subunits are required for translocation. We demonstrate that a
single sugar, GlcNAc, can be incorporated to LPS of Escherichia
coli K-12. This incorporation required the functions of two O
antigen synthesis genes, wecA (UDP-GlcNAc:Und-P GlcNAc-1-P
transferase) and wzx (O-antigen translocase). Complementation experiments with putative O-antigen translocases from
E. coli O7 and Salmonella enterica indicated
that translocation of O antigen subunits is independent of the chemical
structure of the saccharide moiety. Furthermore, complementation with
putative translocases involved in synthesis of exopolysaccharides
demonstrated that these proteins could not participate in O antigen
assembly. Our data indicate that recognition of a complete
Und-P-P-bound O antigen subunit is not required for translocation and
suggest a model for O antigen synthesis involving recognition of
Und-P-P-linked sugars by a putative complex made of Wzx translocase and
other proteins involved in the processing of O antigen.
The biogenesis of complex carbohydrate structures in eukaryotic
and prokaryotic organisms generally involves the participation of
nucleotide sugar precursors and polyisoprenol lipids.
Polyisoprenol-linked sugars are involved in early stages of protein
glycosylation as well as in the synthesis of bacterial cell walls and
surface polysaccharides (1). Nucleotide sugars are normally available
as soluble molecules in cytosolic compartments, while polyisoprenol
lipids are associated with lipid membrane bilayers. Once assembled,
polyisoprenol-linked sugar molecules must have a way to cross the lipid
bilayer for further processing. Thus, transmembrane movement of
phospholipids and glycolipids, including polyisoprenol-linked sugars,
is a process of fundamental biological importance in all types of cells
(1, 2). In the case of protein glycosylation in eukaryotes, a
topological model has been proposed involving the transmembrane
movement of dolichol-linked sugars across the endoplasmic reticulum
membrane (3). A similar model involving the transmembrane
"flipping" of polyisoprenol-linked sugars has been proposed to
explain the synthesis of bacterial cell wall peptidoglycan and
lipopolysaccharide (LPS).1
However, currently it is not known how lipid-linked carbohydrates are
translocated from one leaflet of the lipid bilayer to the other. Using
several different experimental strategies, it has been shown that the
unassisted transbilayer movement of polyisoprenol-linked sugars in
liposomes is extremely slow (4, 5), suggesting the need for
protein-assisted translocation.
LPS, a major component of the outer leaflet of outer membranes in
Gram-negative bacteria, consists of lipid A, core oligosaccharide (OS),
and in some microorganisms, O-specific polysaccharide or O antigen that
is made of repeating OS subunits (6, 7). LPS biosynthesis involves a
large number of enzyme activities, governed by more than 40 genes
(7-10). The core OS is assembled on preformed lipid A by sequential
glycosyl transfer of sugar components, while the O antigen is assembled
on undecaprenylpyrophosphate (Und-P-P) (7). These pathways eventually
converge by the ligation of the O antigen onto the lipid A-core OS
acceptor, with the concomitant release of Und-P-P (7-11).
At least two different mechanisms for biosynthesis and assembly of O
antigens have been described. One of them involves the synthesis of O
repeating subunits by the addition of subsequent monosaccharides at the
nonreducing end of the molecule, a process that takes place on the
cytosolic side of the cytoplasmic membrane (11). These subunits are
translocated across the cytoplasmic membrane, and they become
polymerized by a mechanism involving the successive addition of the
reducing end of the growing polymer to the nonreducing end of
undecaprenylphosphate-linked subunits (Fig.
1). The undecaprenyl-linked polymer is
then ligated "en bloc" to the lipid A-core OS by reactions
occurring on the periplasmic face of the membrane (12-14). This
pathway, also referred to as the wzy
(polymerase)-dependent pathway, occurs in the synthesis of
the majority of O antigens, especially in those made of repeating units
of different sugars (heteropolymeric O antigens) (15). The second
mechanism involves the formation of a polymeric O antigen by reactions
taking place on the cytosolic face of the cytoplasmic membrane that are
mediated by the sequential action of glycosyltransferases elongating
the polysaccharide at the nonreducing end (16). The nascent
polysaccharide is transported across the cytoplasmic membrane by an
ATP-binding cassette transporter (17) and subsequently ligated to lipid
A-core OS. This pathway has been observed especially in O antigens made
of repeating units of the same sugar (homopolymeric O antigens) such as
those from Escherichia coli O8 and O9 (11), as well as in
group 2 and 3 exopolysaccharide capsules (16). In both
wzy-dependent and wzy-independent
mechanisms, the synthesis of the O subunit is initiated by the
formation of a sugar phosphodiester linkage with undecaprenol
phosphate. Various studies have recently shown that in most E. coli O-types, the initiating enzyme is a tunicamycin-sensitive
UDP-GlcNAc:Und-P GlcNAc-1-P transferase (18-20). This enzyme is also
involved in synthesis of enterobacterial common antigen (ECA) (18).
Genetic and biochemical evidence strongly suggest that wecA
(formerly rfe) is the structural gene encoding this enzyme
(18). In the most common Salmonella O antigens, the
initiating sugar is galactose, a reaction mediated by the UDP-Gal:Und-P
Gal-1-P transferase WbaP (formerly RfbP) (21).
In contrast to the wzy-independent O antigens, no obvious
ABC transporters have been identified in
wzy-dependent systems. It has been proposed that
in these cases, undecaprenol-bound O subunits on the periplasmic face
of the membrane arise by a process of transmembrane "flipping." All
wzy-dependent O antigen clusters studied to date
contain a gene that encodes a presumptive cytoplasmic membrane protein
designated Wzx (formerly RfbX) that has been postulated as a candidate
for the O unit flippase or translocase (22). Wzx proteins share very
little amino acid sequence similarity, and their genes have also very
poor nucleotide sequence homology, to the point that they can be used
as genetic markers for distinguishing among specific O antigens (23,
24). Based on comparison of predicted hydrophobicity, Wzx proteins were
recently classified within a family of integral membrane proteins with
12 predicted transmembrane helices (25). Liu et al. (22)
have reported that a strain carrying a wzx mutation of the
Shigella dysenteriae type 1 O antigen gene cluster
accumulates Und-P-P-linked O subunits on the cytoplasmic membrane, but
the evidence that accumulated O subunits are indeed on the cytoplasmic
side of the membrane is less conclusive. Thus, the assignment of Wzx as
a flippase is only tentative and awaits further confirmation as well as
the elucidation of the biochemical mechanism involved in the presumed "flipping" activity.
The lack of identifiable motifs in Wzx proteins, other than the
presence of putative membrane-spanning domains, contrasts with the
anticipated general nature of the translocation. One plausible
hypothesis is that translocation of O antigen subunits is a highly
specific process involving the recognition of unique O subunits in each
individual microorganism. However, at the same time, the process of
translocation should have common elements. Therefore, we decided to
evaluate the translocation and assembly of O antigen from two
perspectives. First, we investigated whether the formation of a
complete O subunit is a prerequisite for translocation and ligation to
the lipid A-core OS and also determined whether this process requires
Wzx. Next, we examined the interchangeability of Wzx proteins from
different sources, using a genetic reconstitution system in E. coli K12/O16 for ligation of O antigen components to the lipid
A-core OS and a nonpolar mutation in the wzx gene of the O7
LPS biosynthesis cluster. In this work, we present genetic, biochemical, and structural data indicating that an incomplete O16
antigen subunit can be processed and assembled onto the lipid A-core
OS. We also show that the Wzx translocase encoded by E. coli
O7, O16, and Salmonella enterica LT2 O antigen clusters can complement a wzx gene defect in E. coli K-12/O16
and E. coli O7. Nevertheless, no complementation with
E. coli K-12 or Rhizobium meliloti putative
translocases involved in exopolysaccharide assembly was observed.
Altogether, our data suggest a model for the processing of the O
repeating unit that involves the recognition of Und-P-P-linked sugars
not only by the translocase Wzx but also by a complex formed by
translocase, polymerase (Wzy), and the O antigen ligase or WaaL.
Bacterial Strains and Plasmids--
Unless otherwise indicated
all chemicals were from Sigma. A nalidixic acid-resistant derivative of
E. coli K-12 strain W3110 (rph-1
IN(rrnD-rrnE)1) was used in these studies. Strain CLM4 (26)
is a recA derivative of SØ874 (27) with a large deletion eliminating the genes for synthesis of colanic acid capsule and O16
LPS. CLM20 also derives from SØ874, and its construction is described
below. E. coli DH5 DNA Methods--
Restriction enzymes, T4 DNA ligase,
polynucleotide kinase, and Klenow DNA polymerase were all purchased
from Roche Diagnostics (Laval, Canada), and used according to the
conditions recommended by the supplier. Recombinant plasmids were
introduced into E. coli strains by electroporation using a
Bio-Rad Gene Pulser. Isolation of chromosomal DNA was conducted by the
miniprep method of Owen and Borman (28). Plasmids were purified as
described previously (29). When necessary DNA fragments were isolated
from agarose gels using the Qiaquick kit (Qiagen Inc., Mississauga,
Canada). Oligonucleotides were purchased from Life Technologies, Inc.
PCR amplifications were carried out using PwoI and
Taq DNA polymerases (Roche Diagnostics) as recommended by
the manufacturer. Recombinant plasmids were verified by DNA sequencing
performed using an ABI377 DNA sequencing apparatus (Perkin-Elmer) in
the Robarts Research Institute DNA Sequencing Facility (London, Canada).
Construction of a glf Mutant of E. coli K12 W3110 (Strain
MFF1)--
A 1.9-kb fragment containing the glf gene and
the contiguous region (Fig.
2A) was amplified by PCR with
primers 85 (5'-CTGGTTGCTGGAATTAT-3) and 88 (5'-CGCATACGGCTGGATAA-3')
using pZY1018 as template. The amplification product was phosphorylated
and then cloned in the HincII site of vector pGEM3 to obtain
pMF1. This plasmid was used as a starting point to generate a mutated
glf by inserting the chloramphenicol acetyltransferase
(cat) gene within its coding region. A DNA fragment
containing the cat gene with its own promoter sequence, but
lacking transcription termination signals, was amplified by PCR with
primers 39 (5'-GATCACTTCGCAGAAT-3') and 40 (5'-AATTACGCCCCGCCCT-3') using pMAV3 as a template. The PCR product was phosphorylated with
polynucleotide kinase and inserted in a unique StyI site within the glf of pMF1. Following transformation,
AmpR and CmR colonies were screened by PCR
using primers 85 and 40 to determine the orientation of the
cat gene. The resulting plasmid with the cat gene
in the desired orientation (pMF2) was digested with SmaI and
SphI. The 2.5-kb fragment containing the
glf::cat gene was recovered by gel purification
and ligated into the suicide vector pGP704 (AmpR)
previously digested with SphI and EcoRV. The
ligated mixture was transformed in the strain BW19610 (30), and the
resulting plasmid obtained was designated pMF9. A sacB-npt1
cassette conferring kanamycin resistance and sucrose sensitivity was
obtained from plasmid pUM24Cm (31) by digestion with BamHI,
recovered from the agarose gel, and ligated to the BglII
site of pMF9. The resulting construct, named pMF10, was used for the
gene replacement in W3110 as described elsewhere (30). pMF10 was
transformed into strain BW19851 (30), and mobilized by conjugation to
the W3110 NxR recipient strain. Exconjugants were plated
onto LB medium containing 10% sucrose, nalidixic acid, and
chloramphenicol and screened for sensitivity to kanamycin and
ampicillin. KanS AmpS colonies were screened by
PCR using primer 39 within the cat gene and primer 98 (5'-TCAACGTAGCGTCATTTA-3') in the wzy gene, located
immediately downstream of glf (Fig. 2A). The
correct allelic replacement was further confirmed by Southern blot
hybridization analysis, and the mutant strain was designated MFF1.
Construction of pMF19--
wbbL, encoding the
rhamnosyltransferase for O16 biosynthesis (Fig. 2A), was
amplified by PCR with primers 99 (5'-TGCTCGCGCCCTGGAATG-3') and 100 (5'-GAACATTGAAATGGTAT-3') using pPR1474 (32) as template and
Taq polymerase (Life Technologies, Inc.). PCR product was ligated into pGEM-T-easy (Promega) to obtain plasmid pMF5, and this
plasmid was digested with EcoRI in order to recover a
fragment containing wbbL. The recovered fragment was ligated
into the expression vector pEXT21 that was previously digested with
EcoRI and treated with alkaline phosphatase. The resulting
plasmid was named pMF19.
Construction and Characterization of E. coli Strain
CLM20--
The wecC::Tn10 (formerly
rffD::Tn10) insertion in strain 21566 (33) was transduced into SØ874 using bacteriophage P1 (34). TetR colonies were purified, and the insertion of
Tn10 in the correct gene was confirmed by PCR. One of these
colonies, CLM5, was used to construct a derivative lacking the
Tn10 transposon as described by Maloy and Nunn (35). The
resulting TetS colonies were examined for their ability to
support expression of O7 LPS when transformed with pJHCV32 (36). Since,
the wecA gene but not wecD is necessary for O7
LPS expression (20, 37), failure to express O7 LPS by these colonies
indicated a deletion eliminating all or a portion of wecA
that is located upstream of wecD (Fig. 2B). One
of such colonies, designated CLM20 was examined further by PCR using
primers 15 (5'-CATGACGAGCTTCGGACTGA-3') and 62 (5'-TCGATGCAATGGAAT). A
9-kb fragment was obtained and cloned into the SmaI site of
pMAV3, resulting in plasmid pCM206. The exact extent of the deletion
was verified by DNA sequencing.
Expression Cloning of wzx Genes--
All of these cloning
experiments were conducted using the low copy number expression vector
pEXT21. The coding regions of the cloned genes were placed under the
control of the plac-inducible promoter. The copy number of
pEXT21 is 3-4 copies per chromosome (38), ensuring a similar level of
expression in all constructs. Construction of pMF21 containing the
wzxEcO7 was described previously (23).
Plasmid pZY1001 (39) was used as a template to clone wzxEcK12/O16 using primers
5'-ATGGATCCTGCATGAATACGAATAAATTAC-3' and
5'-TAAAGCTTAATCCTCAGCAAACCAG-3' having BamHI and
HindIII sites (underlined) in their 5'-ends. The
PCR-amplified fragment containing the coding region of
wzxEcK12/O16 was digested with BamHI
and HindIII and ligated to pEXT21 digested with the same
enzymes, resulting in pMF20. An identical strategy was used to clone
wzxC from E. coli K-12 strain W3110,
exoT from R. meliloti strain B399, and
wzxSeLT2 from S. enterica serovar
typhimurium strain LT2. In these cases, the PCR amplifications were
from chromosomal DNA. The following primers were used: wzxC,
5'-ATGGATCCGATATGAGCTTACGTGA-3' and
5'-TAAAGCTTAACCAGCAATCACCCCG-3'; exoT,
5'-ATGGATCCATGACCCCAACCGTTAACG-3' and
5'-TAAAGCTTCTCTTTCTTCCGCAGTCG-3'; and
wzxSeLT2,
5'-TAGAATTCTGCATAATGAAAGTTCAATTG-3' and
5'-ATGTCGACGCATATGATTATCCCTTATTTG-3', except that in
this case the underlined bases correspond to EcoRI and
SalI sites, respectively. The resulting plasmids were
designated as pMF26 (wzxC), pMF28 (ExoT), and
pMF24 (wzxSeLT2).
LPS Analysis--
Fresh cultures were induced with 2 mM isopropyl-1-thio- Bacterial Slide Agglutination by WGA--
Standardized bacterial
suspensions were prepared by growing bacteria to the logarithmic phase
(absorbance of 0.4 at 600 nm) and inducing the expression of Wzx
proteins with isopropyl-1-thio- Sugar Composition, Methylation Linkage Analyses, and Fast Atom
Bombardment Mass Spectrometry--
Sugar composition analysis was
performed by the alditol acetate method (43). Hydrolysis of glycosidic
bonds was carried out in 4 M trifluoroacetic acid at
100 °C for 4 h followed by reduction in H2O with
NaBD4 and subsequent acetylation with acetic anhydride,
using residual sodium acetate as the catalyst. Alditol acetate
derivatives were analyzed and characterized by gas-liquid chromatography-mass spectrometry using a Hewlett-Packard chromatograph equipped with a 30-m DB-17 capillary column (210 °C (30 min)
240 °C at 2 °C/min). Mass spectra in the electron impact mode
were recorded using a Varian Saturn II mass spectrometer. Methylation linkage analysis was carried out by the
NaOH/Me2SO/CH3I procedure (44) and with
characterization of permethylated alditol acetate derivatives by
gas-liquid chromatography-mass spectrometry in the electron impact mode
(DB-17 column, isothermally at 190 °C for 60 min).
A fraction of the methylated sample was used for positive ion fast atom
bombardment-mass spectrometry that was performed on a Jeol JMS-AX505H
mass spectrometer with glycerol/thioglycerol (1:3) as the matrix, and a
tip voltage of 3 kV. Product ion scan (B/E) and
precursor ion scan (B2/E) were
performed on metastable ions created in the first free field with a
source pressure of 5 × 10 An Incomplete O16 Subunit Can Be Attached to Lipid A-Core
OS--
We investigated whether the formation of a complete O antigen
subunit is a prerequisite for its assembly onto lipid A-core OS. Our
experimental model system was the O polysaccharide biosynthesis cluster
of E. coli K-12/O16 (Fig. 2A). E. coli
K-12 strains of the W3110 lineage are usually O16-deficient because of
an IS5 insertion interrupting the function of
wbbL, the last gene of the E. coli K-12/O16
polysaccharide cluster (32, 39, 46) that encodes a rhamnosyltransferase
involved in the addition of rhamnose to the second position of the O16
backbone (Figs. 2 and 3). Other
investigators have previously shown that complementation in
trans with pPR1474, a plasmid encoding a functional
rhamnosyltransferase gene, restored in these strains the synthesis of
O16 antigen (32, 46). We reasoned that if the synthesis of a complete
O16 subunit is required for its assembly onto lipid A-core OS, a
mutation affecting the biosynthesis of the Galf terminal
sugar residue (Fig. 3) would result in an O16-deficient LPS phenotype.
Furthermore, introduction of pPR1474 or an equivalent plasmid would not
complement the mutant phenotype. We therefore constructed by gene
replacement a nonpolar mutation in the glf gene that is
located within the E. coli O16 LPS biosynthesis cluster (39,
46) and encodes the UDP-Galp mutase catalyzing the
interconversion between UDP-Galp and UDP-Galf
(47). To ensure expression of the O16 genes downstream of
glf, we inserted the cat gene lacking
transcription termination signals in an orientation such that the genes
downstream of the mutated glf would be transcribed by the
cat promoter (Fig. 2A). The correct insertion in
the mutant strain, designated as MFF1, was verified by PCR as described
under "Experimental Procedures."
To investigate the effect of the
glf::cat insertion in O16 LPS
synthesis, we complemented the
wbbL::IS5 mutation with pMF19 (Fig.
2A). This plasmid carries the functional
rhamnosyltransferase gene from pPR1474 under the control of the
ptac promoter. In the absence of pMF19, both W3110 and its
isogenic glf::cat mutant MFF1 produced
only lipid A-core OS (Fig. 4A,
lanes 1 and 3) that, as expected, did
not react with the O16 antiserum (Fig. 4B, lanes 1 and 3). Introduction of pMF19 in the parent
strain W3110 resulted in the formation of O polysaccharide, as revealed
by typical silver-stained ladder-like bands that also reacted with the
O16-specific antiserum (Fig. 4, A and B,
lanes 2). In contrast, MFF1 transformed with pMF19 displayed a single LPS band that migrated above the lipid A-core
OS band (Fig. 4A, lane 4) and also
reacted with O16 antibodies (Fig. 4B, lane
4). The LPS phenotype of MFF1(pMF19) was unexpected and
resembled that of O antigen polymerase-deficient mutants, where a
single O antigen subunit is attached to the lipid A-core OS acceptor
(7). However, the O16-reacting LPS band in MFF1(pMF19) has a faster
mobility in the gel than the corresponding band in W3110(pMF19),
suggesting that the two bands were not identical. The positive reaction
with the O16 antiserum indicated that the chemical composition and
structure of the novel band in MFF1(pMF19) might be similar to that of
the O16 antigen subunit. This was further corroborated by failure to
detect this band with a monoclonal antibody that only recognizes high
molecular weight O16 polysaccharide but does not react with single O16
subunits (data not shown). Therefore, the novel O16-reactive LPS band
expressed by MFF1(pMF19) was consistent with an incomplete O16 subunit
that, although it could not be recognized as a substrate for the O16
polymerase, could presumably be translocated across the cytoplasmic
membrane and incorporated onto lipid A-core OS.
Structural Analysis of Outer Core OS--
Detailed structural
analyses of the LPS molecules of strains MFF1 and MFF1(pMF19) employing
chemical and physical methods were conducted to confirm the above
conclusions. The established structure of the E. coli K-12
core OS in W3100 (Fig. 3) (48) served as a framework for the
interpretation of results. A monosaccharide composition analysis
carried out on the intact MFF1 LPS showed the presence of glucose
(Glc), galactose (Gal), GlcNAc, and
L-glycero-D-manno-heptose (LDHep). MFF1(pMF19) LPS was also composed of Glc, Gal, GlcNAc, and
LDHep residues and in addition contained rhamnose (Rha). Methylation linkage analysis of intact MFF1 LPS revealed the presence of terminal Gal, LDHep, and GlcNAc units; 2-, 6-, and 3,6-substituted Glc residues;
and a linear 7-substituted LDHep component. The inner core LDHep units
were not detected in this methylation linkage analysis due to the fact
that these sugars were phosphorylated (48). The primary A-type glycosyl
oxonium ion at m/z 260 observed in the fast atom
bombardment-mass spectrometry spectrum of the methylated MFF1 LPS
confirmed the presence of the terminal GlcNAc component in this
molecule. The sugar linkage types detected in the LPS of MFF1(pMF19)
were of the same type as those observed in MFF1 LPS, with the exception
that the only GlcNAc residue detected was a 3,6-disubstituted
derivative. Furthermore, two additional units not present in MFF1 LPS,
terminal Glc and 3-substituted Rha, were determined to be components of
the MFF1(pMF19) LPS. The GlcNAc, Rha, and Glc derivatives found in
MFF1(pMF19) LPS were of the same type as found in the O16 O-chain
polysaccharide region of this strain (Fig. 3). The fast atom
bombardment-mass spectrometry spectrum of the methylated intact
MFF1(pMF19) LPS yielded a strong A-type primary ion at m/z
842 and a corresponding secondary ion, from The O Antigen Synthesis Pathway Contributes the GlcNAc Residue in
the Outer Core of E. coli K-12--
The fact that an incomplete O16
subunit made of three backbone sugars and a glucosyl branch can be
ligated to lipid A-core OS raised the question of what is the minimum
number of O antigen sugar components required for this process. The
presence of a terminal GlcNAc in the structure of MFF1 LPS suggests
that this sugar is part of the O16 subunit and may have been donated
from Und-P-P-bound GlcNAc. Therefore, we hypothesized that the terminal GlcNAc in MFF1 LPS arises from the synthesis and translocation pathway
of an incomplete O16 subunit. This hypothesis predicts that the
presence of a terminal GlcNAc in MFF1 LPS would require the activities
of the UDP-GlcNAc:Und-P GlcNAc-1-P transferase (WecA) and the putative
O translocase Wzx. To test this prediction, we constructed strain CLM20
that has a deletion eliminating the O16 and colanic acid biosynthesis
gene clusters, as well as another deletion eliminating the first four
genes of the ECA biosynthesis cluster. This deletion includes part of
wecA (Fig. 2B) that is not only needed for the
initiation of synthesis of ECA (18) but is also required for the
initiation of the synthesis of many O antigens containing GlcNAc (20,
49), including O16 (39, 46). Therefore, CLM20 could be used to
reconstruct in a stepwise fashion the synthesis and assembly of the O16
subunit, by the sequential addition of individual components encoded by
specific plasmids. pMAV11 and pMF20, carrying wecA and the
putative translocase O16 translocase gene
wzxEcO16, respectively, were transformed separately or together into CLM20. LPS from these strains was extracted
and examined by Western blot using digoxenin-labeled WGA, since this
lectin has a high specificity for terminal GlcNAc residues (50). In
parallel, samples were stained with silver to corroborate that
comparable amounts of LPS were loaded in each lane (Fig.
6B). Ovalbumin was used in
these experiments as a positive control (Fig. 6A,
lane 9). Only LPS from CLM20 carrying both pMAV11 and pMF20 bound the lectin probe (Fig. 6A, lane
4). Also, the WGA-reacting LPS band was slightly higher in
molecular mass than the bands found in the LPS from CLM20 (Fig.
6B, lanes 1 and 4). In some
experiments, a faint WGA-reacting band could be observed in CLM20
without any plasmids and in CLM20 with either pMAV11 or pMF20, but only
after loading a considerable amount of LPS in the gels (data not
shown). This was confirmed by additional experiments involving the
agglutination by WGA of standardized bacterial suspensions.
Agglutination of CLM20 was possible with 250 µg/ml of WGA, while 3.12 µg/ml was sufficient to detect agglutination of CLM20 containing
pMAV11 and pMF20 (Table II). These
results were strengthened by the fact that the WGA-reacting band
disappeared following the transformation of CLM20 with pZY1003, pMAV11,
and pMF19 (Fig. 6A, lane 6). The
disappearance of the WGA-reactive band coincided with a new band of
higher molecular weight than the lipid A-core OS band of CLM20, and
this band was only present in the silver-stained gel (Fig.
6B, lane 6, asterisk).
pZY1003 contains the biosynthetic genes for dTDP-rhamnose and the
wzxEcO16 translocase gene (39), while pMF19
contains the rhamnosyltransferase gene wbbL (Fig.
2A). Therefore, the higher molecular weight band is
consistent with the addition of rhamnose to the GlcNAc residue to form
an incomplete O16 subunit with two sugar components. As a consequence
of the attachment of rhamnose, the GlcNAc residue is no longer terminal
(Fig. 3) and therefore cannot bind WGA. The result of the control
experiment with CLM20 containing only pMAV11 and pZY1003, where a
WGA-reacting LPS band was observed (Fig. 6A, lane
5), confirmed this interpretation. In this case, since the
rhamnosyltransferase WbbL is not present, the higher LPS band is absent
in the silver-stained gel (Fig. 6B, lane
5). Also, since a WGA-reacting LPS band was not found in
CLM20 lacking pMAV11 (Fig. 6A, lanes
1-3), the GlcNAc precursor is probably in the form of
GlcNAc-P-P-undecaprenol. The experiments presented in this section
provided strong evidence indicating that the GlcNAc residue in the
E. coli K-12/O16 LPS originates from the O antigen biosynthetic and assembly machinery and requires the presence of both
WecA and Wzx proteins. At the same time, the results show that a single
sugar bound to undecaprenylphosphate can be translocated across the
cytoplasmic membrane in a Wzx-dependent fashion.
Specificity in the Translocation of O Antigen--
Data above
supported the view that an incomplete O subunit can be synthesized and
further ligated onto lipid A-core OS. Since this process required the
wzx translocase gene product, we explored the specificity of
the wzx function. In general, proteins of the Wzx family
share very little homology in the primary amino acid sequence,
displaying around 20% identity or less. BLAST searches using the
E. coli K12/O16 translocase as a query revealed low level
homology with several putative O antigen translocases (from E. coli O7, S. enterica, Bacteroides fragilis,
Yersinia enterocolitica, Pseudomonas aeruginosa, and
Shigella flexneri) and those of E. coli (WzxC)
and R. meliloti (ExoT) exopolysaccharide synthesis (data not
shown). Therefore, we used the CLM20 strain transformed with
wzx genes from some of these other O antigen clusters in similar reconstitution experiments to those described above. In the
presence of pMAV11 and pMF24, containing the S. enterica LT2 wzx gene cloned under the control of the ptac
promoter, CLM20 formed WGA-reacting LPS (Fig. 6A,
lane 8), not present in the absence of pMAV11
(Fig. 6A, lane 7). A similar result
was observed with pMF21, containing the E. coli O7
wxz gene (data not shown). The results of lectin blots were
supported by slide agglutination tests, indicating that agglutination
of CLM20 containing these wzx genes required a concentration
of WGA ranging from 40- to 160-fold lower than the WGA concentration
giving a comparable agglutination of CLM20 alone (Table II). We also
conducted similar complementation experiments with cloned genes
encoding ExoT from R. meliloti and WxzC from E. coli K12. These proteins were postulated to participate in the
translocation of Und-P-P-linked sugars involved in the synthesis of
exopolysaccharides (16), but their actual function has not been
elucidated (51). No WGA-positive LPS band was detected with pMF26
(exoT) and pMF28 (wxzC), and a high concentration of WGA was required to promote the agglutination of CLM20 containing these plasmids (Table II). We concluded from these experiments that the
translocases from E. coli and S. enterica, but
not those implicated in exopolysaccharide transport, are involved in
the transfer of GlcNAc to the lipid A-core OS.
We wanted to also investigate whether these findings hold true for a
system where the complete O antigen subunit is made. For this purpose,
we turned to the O7 LPS system, since we have available a nonpolar
wzxEcO7 translocase mutant (23). In a previous publication, we have reported that the
wzxEcO7::Tn3HoHo1-128
mutation expressed a complete O7 LPS in E. coli K-12 strains
that contain an intact O antigen biosynthesis cluster but failed to
express O7 LPS in derivatives of E. coli SØ874 that carry a
deletion of the O16 antigen gene cluster (23), suggesting that the
E. coli K12/O16 wzx translocase could complement
the phenotype of insertion 128. To confirm that
wxzEcO16 can indeed complement the
wzxEcO7-128 mutation, pMF20 was
transformed into the strain CLM4 containing pJHCV32::Tn3HoHo1-128 (23, 29). A Western blot
analysis of LPS using O7-specific antibodies showed that pMF20
(wzxEcO16) complemented the formation of O7 LPS
at a level similar to that obtained with pMF21
(wzxEcO7) (Fig. 7,
lanes 3 and 4). A complementation experiment with the S. enterica wzx gene (pMF24) also
resulted in the detection of O7-specific LPS by Western blot (Fig. 7,
lane 5), although at a lower level than in the
case of complementation with the O7 and O16 counterparts. These
differences were not due to a loading artifact, since equal
concentrations of LPS, as determined by KDO analysis, were loaded in
each lane. No complementation was observed in similar experiments with
pMF28 (exoT) and pMF28 (wzxC), in agreement with
the observations made before with the strain CLM20 (Fig. 7,
lanes 6 and 7). Lack of
complementation was not due to the absence of expression of cloned
exoT and wzxC genes as determined by reverse
transcriptase-PCR analysis using RNA prepared from CLM4 cells
containing pMF26 and pMF28 (data not shown). These results suggest that
Wzx translocases from various sources, but all involved in O-antigen
assembly, may be functionally interchangeable despite their apparent
lack of amino acid sequence conservation and act independently from the
structure of the saccharide moiety being translocated. In contrast,
translocases involved in the synthesis of exopolysaccharides cannot
complement an O-antigen translocase null mutation.
The classical model for wzy-dependent O
antigen synthesis (Fig. 1) assumes the completion of the synthesis of
the O subunit prior to its translocation across the cytoplasmic
membrane (11, 14, 22). However, our experiments using the O16 synthesis of E. coli K-12 provide conclusive evidence that incomplete
O subunits can serve as substrates for the O antigen assembly
machinery. We have constructed a derivative of E. coli K-12
devoid of genes for the synthesis of the surface polysaccharide colanic
acid, O16 antigen, and ECA. This strain, CLM20, produced a complete lipid A-core OS and permitted us to reconstruct in a stepwise fashion
the synthesis and assembly of O16 sugar components onto lipid A-core OS
by examining the structure of the outer core OS for the presence of
sugar components corresponding to partial O subunits. The presence of
these components depended on specific genes that were added as
recombinant plasmids.
Structural and biochemical data using WGA binding to terminal GlcNAc
show conclusively a terminal GlcNAc residue that can be incorporated
into the lipid A-core OS in a wzx-dependent
manner. The addition of GlcNAc did not occur in the absence of the
wecA function, strongly suggesting that must be donated to
the core OS acceptor as a GlcNAc-P-P-undecaprenol intermediate. The
unequivocal proof that the GlcNAc residue is transferred into the core
OS from GlcNAc-P-P-undecaprenol would require a biochemical
demonstration of this reaction in a defined in vitro system,
currently under development in our laboratories.
L-Rhamnose, the next sugar of the O16 repeat, could also be
added to GlcNAc-P-P-undecaprenol if the genes for the synthesis of
dTDP-Rha and the WbbL rhamnosyltransferase were provided. The
Rha-GlcNAc disaccharide was also incorporated into the lipid A-core OS
in a wzx-dependent fashion, as evidenced by
abolition of LPS binding to WGA concomitantly with a proportional increase in the molecular mass of the core OS. Finally, a mutation affecting the synthesis of the Galf terminal residue of the
O16 subunit resulted in the formation of a truncated O16 subunit that was incorporated to lipid A-core OS. From these results, we can conclude that (i) the translocation of the O subunits in
wzy-dependent systems is independent of the
length and completion of the assembly of the O subunit and (ii)
undecaprenyl-GlcNAc is the minimal glycolipid structure that can be
recognized as a substrate for the translocation and ligation to the
core OS. These conclusions may be applicable to other O types, since
GlcNAc is not unique to the O16 subunit. This sugar is not only present
in a large number of E. coli O types from enteric bacteria
(52) but also is the first residue added to undecaprenylphosphate by
WecA in many O antigens (19, 20, 39, 53). In a previous work using a
wzx mutant in the S. dysenteriae type 1 gene
cluster, Klena and Schnaitman (19) reported an extra band in the lipid
A-core OS profile that could be attributed to the addition of a partial
O subunit. Although these authors did not provide any further evidence,
our biochemical and structural data support their conclusions and
confirm that our findings can be applied to other O types in addition
to O16.
The structural data obtained from the LPS analysis of strain MFF1 with
and without pMF19, encoding the WbbL rhamnosyltransferase, confirmed a
previous report indicating that there is a GlcNAc residue linked to a
terminal
L-glycero-D-manno-heptose
(HepIV) in the outer core OS of strains W3110 and W3100 (48). More
importantly, we determined that the GlcNAc residue is contributed by
the O antigen synthesis pathway, as indicated by the studies with WGA. Therefore, we concluded that HepIV is the site of attachment of the O16
antigen to the outer core OS, and the GlcNAc-HepIV Our experimental system permitted us to also explore a second critical
question in the O antigen processing regarding the specificity of the
Wzx proteins. The addition of GlcNAc to the lipid A-core OS in strain
CLM20 occurred not only with O16 Wzx but also with the heterologous
proteins from E. coli O7 and S. enterica LT2.
These proteins share very little homology in their primary amino acid
sequences, and the O antigens in the three cases are structurally
different (Fig. 3). In contrast, proteins implicated in the export of
capsular polysaccharides such as ExoT and WzxC did not result in a
significant addition of GlcNAc to the lipid A-core OS. A
semiquantitative analysis by slide agglutination with WGA shows that in
the presence of Wzx translocases from E. coli K-12/O16 and
E. coli O7 the lipid A-core OS contained higher amounts of
GlcNAc residues than in the presence of the translocase from S. enterica. A parallel study with a wzx mutation in the E. coli O7 gene cluster also showed that Wzx from E. coli K-12 or from E. coli O7 complemented the mutation
very efficiently, whereas the S. enterica protein also
corrected the phenotype but to a lesser extent. These differences
cannot be attributed to differences in the expression of the respective
genes, since they were cloned in the same vector using the same cloning
strategy. One possible explanation for these differences is that the
Wzx proteins may be able to recognize the Und-P-P-linked sugar. Thus, Wzx proteins from the E. coli K-12/O16 and O7 would function
on the same molecule, Und-P-P-GlcNAc, while the Salmonella
LT2 Wzx would interact better with Und-P-P-Gal, since galactose is the first sugar attached to undecaprenylphosphate in this microorganism (21). Alternatively, it is also possible that the process of translocation and ligation requires the efficient interaction among the
proteins involved such that the O antigen ligase of E. coli
K-12 (WaaLEcK12) may function more efficiently with
WzxEcK12/O16 and WzxEcO7 than with
WzxSeLT2. The notion that specific interactions between
proteins involved in processing and assembly of Und-P-P-linked O
subunits is required for proper O antigen biosynthesis is further supported by the fact that proteins responsible for translocation of
Und-P-P-linked saccharides involved in exopolysaccharide biosynthesis could not complement an O-antigen translocase mutant, although both
types of proteins are predicted to perform the same function. These
putative protein interactions may contribute to a fine-tuning in the
assembly of O antigen, and they will be further investigated using our
experimental reconstitution system in strain CLM20.
There are remarkable similarities in the topology of the
wzy-dependent O antigen biosynthesis and the
initial steps in the formation of the glycan incorporated to
glycoproteins in eukaryotic cells. The glycan, in this case, is
assembled onto dolichol phosphate, and its synthesis also involves an
initiating enzyme transferring GlcNAc-P, as well as specific
glycosyltransferases subsequently adding mannose residues. Furthermore,
the dolichol-linked heptasaccharide, Man5GlcNAc2-P-P-dolichol, is synthesized on the
cytoplasmic face of the endoplasmic reticulum and must also be
translocated to the luminal side, where it is further enlarged and
finally attached to proteins (55, 56). Therefore, the process of
membrane transit of lipid-linked oligosaccharides represents a basic
biological process found in eukaryotic and prokaryotic cells. Recent
work using microsomal vesicles suggests that transbilayer movement of
dolichol-bound sugars involves protein-mediated transport (57, 58), but
at the present time the specific protein(s) have not been identified.
Interestingly, alg2 mutants in yeast form truncated oligosaccharides only containing Man2GlcNAc2
structures that are transferred in vivo from
dolicholpyrophosphate to proteins, suggesting that a complete
dolichol-linked oligosaccharide is not strictly necessary for membrane
translocation (59). These results could be explained if, as we propose
here, the activity of the putative eukaryotic translocase is also
independent of the structure of the dolichol-bound sugar moiety.
Further experiments are required to test the generality of our model.
In the meantime, the experimental system we have devised in this study
will permit a detailed analysis of the interrelationships between
lipid-linked substrates and the protein components involved in the
assembly of O antigen and other similar lipid-linked sugar polymers.
*
This work was supported by Medical Research Council of
Canada Grant MT1026 (to M. A. V.) and grants from the United Nations Development Programme/World Bank/World Health Organization Special Programme for Research and Training in Tropical Diseases, the Mizutani
Foundation for Glycoscience, the University of Buenos Aires, the
Consejo Nacional the Investigaciones Científicas y Técnicas
(CONICET), and the Argentine National Agency for Scientific and
Technological Research (ANPCT) (to A. J. P.).The costs of publication of this
article were defrayed in part by the
payment of page charges. The article
must therefore be hereby marked
"advertisement" in
accordance with 18 U.S.C. Section
1734 solely to indicate this fact.
§
Recipient of a doctoral fellowship from the National Research
Council of Argentina (CONICET).
**
Research Career Investigator of the National Research Council of
Argentina (CONICET).
The abbreviations used are:
LPS, lipopolysaccharide;
ECA, enterobacterial common antigen;
LDHep, L-glycero-D-manno-heptose;
Und-P-P, undecaprenylpryrophosphate;
OS, oligosaccharide;
WGA, wheat
germ agglutinin;
PCR, polymerase chain reaction;
Rha, rhamnose;
kb, kilobase pair.
The Activity of a Putative Polyisoprenol-linked Sugar Translocase
(Wzx) Involved in Escherichia coli O Antigen Assembly Is
Independent of the Chemical Structure of the O Repeat*
§,
,,**, and
Instituto de Investigaciones
Bioquímicas Fundación Campomar, Buenos Aires, Argentina,
the ¶ Department of Microbiology and Immunology, University of
Western Ontario, London, Ontario N6A 5C1, Canada, and the
Institute for Biological Sciences, National Research Council,
Ottawa, Ontario K1A 0R6, Canada
ABSTRACT
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
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DISCUSSION
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INTRODUCTION
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
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DISCUSSION
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Fig. 1.
Diagram showing a topographic model and
protein components involved in the synthesis and processing of the
wzy-dependent O16 antigen of E. coli K-12. The following proteins are indicated.
WecA, UDP-GlcNAc:Und-P GlcNAc-1-P transferase;
WbbL, rhamnosyltransferase; GlcT,
glucosyltransferase; Glf, UDP-Galp mutase;
GalfT, galactofuranosyltransferase; Wzx
?, putative O antigen translocase; Wzy, O antigen
polymerase; WaaL, O antigen ligase. A detailed chemical
structure of the O16 repeat is shown in Fig. 3. The glucosylation of
GlcNAc at position 6 has been omitted for simplicity.
EXPERIMENTAL PROCEDURES
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was used as an initial host for the
cloning experiments. Cells were generally grown at 37 °C in LB
medium consisting of 10 g of NaCl, 5 g of yeast extract, and 10 g of tryptone per liter. Antibiotics were added as needed at final concentrations of 100 µg/ml for ampicillin, 20 µg/ml for tetracycline, 40 µg/ml for kanamycin, 80 µg/ml for spectinomycin, 15 µg/ml for chloramphenicol, and 50 µg/ml for nalidixic acid. In
some cases, a final sucrose concentration of 10% (w/v) was also added.
The plasmids used in this study are described in Table I.
Characteristics of the plasmids used in this study
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Fig. 2.
A, genetic map of the
wbEcK12/O16 cluster indicating the
glf gene and the mutated wbbL carrying an
IS5 insertion (shaded). The location and
direction of transcription (arrow) of the cat
cassette inserted in glf (strain MFF1) is indicated. The
boundaries of DNA inserts in pMF19, pPR1474 (32), pZY1003 (39), pMF1
and pMF20, as well as the location of PCR primers 99, 100, 85, and 88 are shown. B, partial genetic map of the wec (ECA
synthesis) cluster in E. coli K-12 strains CLM5 and CLM20.
The genes indicated are rho and
wecA-wzz-wecB-wecC-rmlB-rmlA. The shaded
area denotes the region deleted in CLM20. CLM5 also contains
a Tn10 insertion inserted near the 5'-end of wecC
(37). The location of annealing sequences for primer 62 and primer 15, used to amplify the fragment clone in pCM206, are also indicated.
-D-galactopyranoside for
3 h. Cells were centrifuged and resuspended to an absorbance at
600 nm of 1. 1.5-ml aliquots of the cell suspension were used to
extract LPS as described previously (29). For some experiments, large
scale LPS preparations were made by the hot phenol method (40) using
500-ml cultures. The concentration of LPS was measured by the KDO assay
(41). Duplicate 12.5% SDS-polyacrylamide gel electrophoresis gels were
run. One gel was stained with silver as described elsewhere (29). The
other gel was transferred to a polyvinylidene difluoride membrane
(Roche Diagnostics) and processed as recommended by the supplier for
application of digoxenin-labeled lectin in glycoconjugate analysis
(Roche Diagnostics). Briefly, the membrane was treated with the
blocking reagent, washed several times with Tris-buffered saline, pH
7.5, and incubated with 7 µg/ml of digoxenin-labeled WGA. The
presence of bound lectin was detected using anti-digoxenin antibody
conjugated with alkaline phosphatase, followed by developing with
5-bromo-4-chloro-3-indoyl-phosphate and 4-nitro blue tetrazolium
chloride. Ovalbumin was used as positive control for lectin binding. In
other experiments, LPS samples were transferred to nitrocellulose and
reacted with anti-O16 and anti-O7 polyclonal antibodies. Western blots
were developed using protein A-peroxidase as described elsewhere (29).
For structural analysis, LPS was isolated by the hot phenol-water
extraction procedure (40) and purified by gel permeation chromatography on a column of Bio-Gel P-2 (1 m × 1 cm) with water as eluent. In
all cases, only one carbohydrate-positive fraction was obtained that
eluted in the high Mr range (42) and was
utilized for chemical analyses.
-D-galactopyranoside for
3 h. 1-ml aliquots were washed once with phosphate-buffered saline, and the absorbance was adjusted to a value of 2. WGA lectin (Roche Diagnostics) was also diluted in phosphate-buffered saline, and
25 µl of the bacterial cell suspension were mixed with 25 µl of
serial dilutions of WGA. Agglutination was recorded after 3 min of
gentle rotation of the glass plate. The specificity of WGA for GlcNAc
was determined by examining the agglutination of bacteria in the
presence of glucose or GlcNAc. Different concentrations of sugars at
0.1, 0.156, 0.312, 0.625, and 1.25 M were mixed with 12.5 µg/ml WGA, and the mixture was examined by agglutination as described
above. A concentration-dependent agglutination inhibition was only found in the presence of GlcNAc (50% inhibition was obtained with 0.312 M GlcNAc and 100% inhibition with 1.25 mM).
5 torr. The
interpretations of positive ion mass spectra of the permethylated LPS
derivatives were as described previously by Dell et al.
(45).
RESULTS
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Fig. 3.
Chemical structures of the E. coli
O16 and O7 and S. enterica LT2 O antigen
repeating units as well as the outer core OS structures in strains MFF1
and MFF1(pMF19), indicating the residues (shaded) that
correspond to incomplete O subunit components attached to the core
OS.
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Fig. 4.
A, silver-stained SDS-polyacrylamide gel
containing LPS samples prepared from the strain W3110 and its isogenic
glf::cat derivative MFF1.
Lane 1, W3110; lane 2,
W3110(pMF19); lane 3, MFF1; lane
4, MFF1(pMF19). B, Western blot of a gel similar
to that in A reacted with anti-O16 polyclonal antiserum. The
arrows indicate the position of the lipid A-core OS bands
with one complete (lane 2) and one incomplete
(lane 4) O16 repeat.
-elimination of Glc-Rha
(m/z 410) from the O-3 position of GlcNAc, at
m/z 432 (m/z 842-410) that represented the
following structural saccharide moiety:
Glc-(1-3)-Rha-(1-3)[Glc-(1-6)]-GlcNAc+ (Fig.
5). Two additional higher mass primary
ions at m/z 1090 (Glc-(1-3)-Rha-(1-3)[Glc-(1-6)]-GlcNAc-(1-7)-LDHep+)
and m/z 1294 (Glc-(1-3)-Rha-(1-3)[Glc-(1-6)]-GlcNAc-(1-7)-LDHep-(1-6)-Glc+)
showed the connection of the Glc-(1-3)-Rha-(1-3)[Glc-(1-6)]-GlcNAc O-chain moiety to the core via the 7-substituted LDHep unit. The structural data indicated the presence of an incomplete O16 O-chain repeating block lacking the terminal Galf unit (Fig. 3).
This incomplete O16 repeating unit, Glc-(1-3)-Rha-
(1-3)[Glc-(1-6)]-GlcNAc, carried a terminal Glc attached to the
O-6 position of the 3,6-disubstituted GlcNAc. The absence of
this terminal Glc unit in the MFF1 LPS strongly suggested that this
glucosylation required the prior presence of Rha of the repeating unit
(Fig. 3). Furthermore, since GlcNAc is a component of the O16 repeating
unit, these results show that the GlcNAc-(1-7)-LDHep linkage is the
site of attachment between the O-chain and the E. coli K-12
core oligosaccharide (Fig. 3), a function performed by the O-chain
ligase WaaL (Fig. 1).
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Fig. 5.
Fast atom bombardment mass spectrum showing
mass regions between m/z 400 and 1300 of the
methylated intact MFF1 LPS. The type A primary glycosyl oxonium
ions (m/z 842, 1090, and 1294) and a secondary ion
(m/z 432) from -elimination of the structure at
m/z 842 are shown. *, peak not assigned. The structures
represented by each peak are indicated under "Results."
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Fig. 6.
A, Western blot of LPS core OS
preparations from CLM20 containing various single or multiple
combinations of recombinant plasmids. The blot was incubated with
digoxenin-labeled WGA and developed with horseradish peroxidase-labeled
anti-digoxenin monoclonal antibody. Lane 1, no
plasmid; lane 2, pMAV11
(wecA+); lane 3, pMF20
(wzxEcK12/O16+); lane
4, pMAV11 plus pMF20; lane 5, pMAV11
plus pZY1003 (rmlBDAC+,
wzxEcK12/O16+); lane
6, pMAV11, pZY1003, and pMF19
(wbbL+); lane 7, pMF24
(wzxSeLT2+); lane
8, pMAV11 plus pMF24; lane 9,
ovalbumin. B, silver-stained SDS-polyacrylamide gel similar
to that in A, except that lane 9 is
not shown. An asterisk indicates the highest core OS band
containing a terminal rhamnose. The arrows indicate the core
OS bands containing terminal GlcNAc that react with WGA as shown in
A.
Slide agglutination of standard bacterial suspensions of CLM20 with
WGA
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Fig. 7.
Western blot reacted with O7 polyclonal
antiserum of LPS samples prepared from strain CLM4 containing
pJHCV32::Tn3HoHo1-128
(wzx128; O7 ) (lane 1) and
pJHCV32 (O7+) (lane 2). Samples in
lanes 3-7 are from CLM4
(pJHCV32::Tn3HoHo1-128) transformed with plasmids
carrying translocase genes from different sources as follows: 3, pMF21
(wzxEcO7+); 4, pMF20
(wzxEcK12/O16+); 5, pMF24
(wzxSeLT2+); 6, pMF28
(wzxC+); 7, pMF26
(exoT+).
DISCUSSION
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ABSTRACT
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EXPERIMENTAL PROCEDURES
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DISCUSSION
REFERENCES
(1
7) linkage
defines the specificity of the O antigen ligase of E. coli
K-12. The ligase, encoded by the waaL gene, is the only gene product known to be required for the ligation reaction that joins newly
synthesized polymeric O antigen to lipid A-core OS (8). WaaL is also an
integral membrane protein and acts on the periplasmic face of the
cytoplasmic membrane (8). Several lines of evidence suggest that ligase
proteins appear to lack any obvious specificity for the structure of
the ligated polysaccharide, possibly because it may be presented for
ligation in the form of a common undecaprenol-P-P-linked form (8). Our
results confirm this suggestion and also indicate that a similar
property exists for Wzx proteins. Furthermore, this also explains why
it has been possible to clone and express many different O antigens in
E. coli K-12. Based on the results of this study, we can
safely conclude that the minimal components required for the processing
of the O subunit are Wzx and WaaL. One other interesting finding from
our study is the identification of an additional Glc residue attached
to GlcNAc in the LPS structure of MFF1(pMF19) (Fig. 3). The presence of
this residue could be explained by the activity of a glucosylation gene
cluster that is present at a different location than the wb
cluster in the E. coli K-12 chromosome and is homologous to
bacteriophage-encoded glucosylation systems involved in antigenic
changes in S. flexneri (54). The construction of a
waaL-deficient mutant derivative of CLM20 as well as of a
mutant defective in glucosylation is in progress to investigate in
detail the role of these proteins in our experimental system.
FOOTNOTES
To whom correspondence should be addressed. Tel.: 519-661-3996;
Fax: 519-661-3499; E-mail: mvalvano@julian.uwo.ca.
ABBREVIATIONS
REFERENCES
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
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