THE JOURNAL OF BIOLOGICAL CHEMISTRY VOL. 284, NO. 32, pp. 21738 –21751, August 7, 2009
© 2009 by The American Society for Biochemistry and Molecular Biology, Inc. Printed in the U.S.A.
Biosynthesis and Structure of the Burkholderia cenocepacia
K56-2 Lipopolysaccharide Core Oligosaccharide
TRUNCATION OF THE CORE OLIGOSACCHARIDE LEADS TO INCREASED BINDING AND
SENSITIVITY TO POLYMYXIN B *□
S
Received for publication, March 5, 2009, and in revised form, May 19, 2009 Published, JBC Papers in Press, June 12, 2009, DOI 10.1074/jbc.M109.008532
Ximena Ortega‡1, Alba Silipo§1, M. Soledad Saldías‡2, Christa C. Bates‡3, Antonio Molinaro§,
and Miguel A. Valvano‡¶4
From the ‡Infectious Diseases Research Group, Siebens-Drake Research Institute, Department of Microbiology and Immunology,
and ¶Department of Medicine, University of Western Ontario, London, Ontario N6A 5C1, Canada and the §Dipartimento di
Chimica Organica e Biochimica, Universitá di Napoli, Complesso Universitario Monte Sant’angelo, Via Cintia 4, 80126 Napoli, Italy
* This work was supported in part by grants from the Canadian Cystic Fibrosis
Foundation (to M. A. V.) and the Italian Cystic Fibrosis Foundation Grant
FFC 8/2007, Furla Spa, GSV Spa, Delegazione FFC di Bologna (to A. M.).
The on-line version of this article (available at http://www.jbc.org) contains
supplemental Table S1 and Figs. S1–S3.
1
Both authors contributed equally to this work.
2
Supported by a postdoctoral fellowship from the Canadian Cystic Fibrosis
Foundation.
3
Supported by a summer studentship from the Canadian Cystic Fibrosis
Foundation.
4
Holder of Canada Research Chair in Infectious Diseases and Microbial Pathogenesis and a senior scientist research training award from the Canadian
Cystic Fibrosis Foundation. To whom correspondence should be
addressed: Dept. of Microbiology and Immunology, Dental Sciences Bldg.
3014, University of Western Ontario, London, Ontario N6A 5C1, Canada.
Fax: 519-661-3499; E-mail: mvalvano@uwo.ca.
□
S
21738 JOURNAL OF BIOLOGICAL CHEMISTRY
Burkholderia cenocepacia is a Gram-negative opportunistic
pathogen ubiquitously found in the environment (1, 2).
Although generally harmless to healthy individuals, B. cenocepacia affects immunocompromised patients (1) such as those
with cystic fibrosis and chronic granulomatous disease.
Infected cystic fibrosis patients commonly develop chronic
lung infections that are very difficult to treat because these bacteria are intrinsically resistant to virtually all clinically useful
antibiotics as well as antimicrobial peptides (APs)5 (1, 3).
Lipopolysaccharide (LPS) is the major surface component of
Gram-negative bacteria and consists of lipid A, core oligosaccharide (OS), and in some bacteria O-specific polysaccharide or
O antigen (4, 5). The O antigen acts as a protective barrier
against desiccation, phagocytosis, and serum complement-mediated killing, whereas the core OS and the lipid A contribute to
maintain the integrity of the outer membrane (4, 5). The lipid A
also anchors the LPS molecule to the outer leaflet of the outer
membrane and accounts for the endotoxic activity of LPS (4, 6).
Lipid A is a bisphosphorylated -1,6-linked glucosamine disaccharide substituted with fatty acids ester-linked at positions 3
and 3⬘ and amide-linked at positions 2 and 2⬘ (4). The core OS
can be subdivided into the inner core and outer core. The inner
core OS typically consists of one or two 3-deoxy-D-manno-octulosonic acid (Kdo) residues linked to the lipid A and three
L-glycero-D-manno-heptose residues linked to the first Kdo (4).
The outer core OS in enteric bacteria typically consists of 8 –12
branched sugars linked to heptose II of the inner core. As a
result of phosphate groups on the lipid A and core OS, the
bacterial surface has a net negative charge. This plays an important role in the interaction of the bacterial surface with positively charged compounds such as cationic APs, which are cat5
The abbreviations used are: AP, antimicrobial peptide; DQF-COSY, double
quantum filtered correlation spectroscopy; D-QuiN, D-quinovosamine;
HMBC, heteronuclear multiple bond correlation; HSQC, heteronuclear single quantum coherence; Kdo, 3-deoxy-D-manno-octulosonic acid; Ko,
D-glycero-D-talo-octulosonic acid; L-Ara4N, 4-amino-4-deoxy-L-arabinose;
LPS, lipopolysaccharide; L-Rha, L-rhamnose; MALDI, matrix-assisted laser
desorption ionization; MS, mass spectrometry; NOE, nuclear Overhauser
effect; OS, oligosaccharide; PmB, polymyxin B; TOCSY, total correlation
spectroscopy; TOF, time-of-flight; T-ROESY, transverse rotating-frame
Overhauser enhancement spectroscopy; DMEM, Dulbecco’s modified
Eagle’s medium; FBS, fetal bovine serum; dansyl, 5-dimethylaminonaphthalene-1-sulfonyl; Tricine, N-[2-hydroxy-1,1-bis(hydroxymethyl)ethyl]glycine; BcCV, B. cenocepacia-containing vacuole.
VOLUME 284 • NUMBER 32 • AUGUST 7, 2009
Downloaded from http://www.jbc.org/ by guest on May 30, 2020
Burkholderia cenocepacia is an opportunistic pathogen that
displays a remarkably high resistance to antimicrobial peptides.
We hypothesize that high resistance to antimicrobial peptides
in these bacteria is because of the barrier properties of the outer
membrane. Here we report the identification of genes for the
biosynthesis of the core oligosaccharide (OS) moiety of the B.
cenocepacia lipopolysaccharide. We constructed a panel of isogenic mutants with truncated core OS that facilitated functional
gene assignments and the elucidation of the core OS structure in
the prototypic strain K56-2. The core OS structure consists of
three heptoses in the inner core region, 3-deoxy-D-manno-octulosonic acid, D-glycero-D-talo-octulosonic acid, and 4-amino-4deoxy-L-arabinose linked to D-glycero-D-talo-octulosonic acid.
Also, glucose is linked to heptose I, whereas heptose II carries a
second glucose and a terminal heptose, which is the site of
attachment of the O antigen. We established that the level of
core truncation in the mutants was proportional to their
increased in vitro sensitivity to polymyxin B (PmB). Binding
assays using fluorescent 5-dimethylaminonaphthalene-1-sulfonyl-labeled PmB demonstrated a correlation between sensitivity and increased binding of PmB to intact cells. Also, the
mutant producing a heptoseless core OS did not survive in macrophages as compared with the parental K56-2 strain. Together,
our results demonstrate that a complete core OS is required for
full PmB resistance in B. cenocepacia and that resistance is due,
at least in part, to the ability of B. cenocepacia to prevent binding
of the peptide to the bacterial cell envelope.
Structure-Function of B. cenocepacia Core Oligosaccharide
TABLE 1
Bacterial strains and plasmids used in this study
Strain or plasmid
B. cenocepacia strains
CCB1
K56-2
XOA3
XOA6
XOA7
XOA8
XOA9
XOA15
XOA17
XOA19
Plasmids
pAP20
pGP⍀TP
pGPApTp
pJR1
a
Reference or source
K56-2, waaC::pGP⍀Tp, TpR
ET12 clone, cystic fibrosis clinical isolate
K56-2, wbxE::pGP⍀Tp, TpR
K56-2, wabP::pGP⍀Tp, TpR
K56-2, waaL::pGP⍀Tp, TpR
K56-2, wabO::pGP⍀Tp, TpR
K56-2, wabQ::pGP⍀Tp, TpR
K56-2, wabR::pGP⍀Tp, TpR
K56-2, wabS::pGPApTp, TpR
K56-2, waaF::pSC200, TpR
This study
CBCCRRRa
This study
This study
This study
This study
This study
This study
This study
This study
oripBBR1, CmR, mob⫹, Pdhfr
oriR6K, ⍀TpR cassette, mob⫹
pGP704, TpR, ApR, mob⫹
pMLBAD (56) expressing the red fluorescent protein mRFP1
under the control of a constitutive Pdhfr promoter, TpR
oricolE1, RK2 derivative, KanR, mob⫹, tra⫹
oriR6K, PRhaB rhamnose-inducible promoter, ⍀TpR cassette, mob⫹
pAP20, wabO under the control of Pdhfr
pAP20, waaL under the control of Pdhfr
pAP20, wabS under the control of Pdhfr
pAP20, waaC under the control of Pdhfr
pAP20, waaL-wabR under the control of Pdhfr
S. Cardona
20
21
40
23
19
This study
This study
This study
This study
This study
Canadian B. cepacia complex Research and Referral Repository.
ionic amphipathic molecules that kill bacteria by membrane
permeabilization. In response to a series of environmental conditions such as low magnesium or high iron, bacteria can
express modified LPS molecules that result in a less negative
surface. This reduces the binding of APs and promotes resistance to these compounds. Previous studies have shown that
Burkholderia LPS molecules possess unique properties. For
example, Kdo cannot be detected by classic colorimetric methods in LPS from Burkholderia pseudomallei and Burkholderia
cepacia, and the covalent linkage between Kdo and lipid A is
more resistant to acid hydrolysis than in conventional LPS
molecules (7). In B. cepacia, 4-amino-4-deoxy-L-arabinose
(L-Ara4N) is bound to the lipid A by a phosphodiester linkage at
position 4 of the nonreducing glucosamine (GlcN II) (8) and is
also present as a component of the core OS. Also, instead of two
Kdo molecules, the B. cepacia core OS has only one Kdo and the
unusual Kdo analog, D-glycero-D-talo-octulosonic acid (Ko),
which is nonstoichiometrically substituted with L-Ara4N forming a 138 linkage with ␣-Ko (7, 9). Although this is also the case
for the inner core OS of B. cenocepacia J2315 (10), it is not a
common feature for the core OS in all Burkholderia. For example, the inner core of Burkholderia caryophylli consists of two
Kdo residues and does not possess L-Ara4N (11).
Burkholderia species, including B. cenocepacia, are intrinsically resistant to human and non-human APs such as these
produced by airway epithelial cells (12, 13), human -defensin 3
(14), human neutrophil peptides (15), and polymyxin B (PmB)
(15, 16). The minimum inhibitory concentration determined
for some of these peptides in several Burkholderia species is
greater than 500 g/ml, which could aid these microorganisms
during colonization of the respiratory epithelia (13). It has been
proposed that the resistance of B. cepacia to cationic APs stems
from ineffective binding to the outer membrane, as a consequence of the low number of phosphate and carboxylate groups
in the lipopolysaccharide (17), but a systematic analysis of the
molecular basis of AP resistance in B. cenocepacia and other
AUGUST 7, 2009 • VOLUME 284 • NUMBER 32
Burkholderia is lacking. We have previously reported that a
heptoseless B. cenocepacia mutant (SAL1) is significantly more
sensitive than the parental clinical strain K56-2 to APs (15).
This mutant has a truncated inner core and lacks the outer core,
suggesting that a complete core OS is required for resistance of
B. cenocepacia to APs.
Apart from heptoses, the role of other sugar moieties of the B.
cenocepacia core OS in AP resistance is not known. In this
study, we report the structure of the core OS for B. cenocepacia
strain K56-2 and its isogenic mutants XOA3, XOA7, and
XOA8, which carry various core OS truncations. The structural
analysis, combined with mutagenesis, allowed us to assign function to the majority of the genes involved in core OS biosynthesis and ligation of the O antigen and to establish that the degree
of truncation of the core OS correlates with increased binding
and bacterial sensitivity to PmB in vitro and reduced bacterial
intracellular survival in macrophages.
EXPERIMENTAL PROCEDURES
Bacterial Strains and Growth Conditions—Strains and plasmids used in this study are listed in Table 1. B. cenocepacia
strain K56-2 was grown at 37 °C in LB medium supplemented,
as required, with 100 g/ml trimethoprim and 50 g/ml gentamicin. This strain is a clinical isolate that belongs to the same
clonal group as the type strain J2315 (18). Escherichia coli
strains were grown at 37 °C in LB medium supplemented with
trimethoprim (50 g/ml), kanamycin (40 g/ml), or chloramphenicol (30 g/ml), as required. Conditional mutants were
grown at 37 °C in M9 medium supplemented with 5 mg/ml
yeast extract and 0.5% (w/v) rhamnose (permissive conditions)
or 0.5% (w/v) glucose (nonpermissive conditions) as described
previously (19).
Mammalian Cell Lines—Murine macrophage (RAW 264.7;
ATCC TIB-71) and human lung epithelial cell lines (A549;
CCL-185) were obtained from the American Type Culture Collection (Manassas, VA). Cells were maintained in Dulbecco’s
JOURNAL OF BIOLOGICAL CHEMISTRY
21739
Downloaded from http://www.jbc.org/ by guest on May 30, 2020
pRK2013
pSC200
pXO13
pXO14
pXO20
pXO21
pXO22
Genotype and relevant characteristics
Structure-Function of B. cenocepacia Core Oligosaccharide
21740 JOURNAL OF BIOLOGICAL CHEMISTRY
from bacteria grown in liquid cultures at nonpermissive
conditions.
Purification and Compositional Analysis of LPS—Large scale
LPS preparations for structural analysis were obtained by the
method of Westphal and Jann (26) from 1-liter cultures of B.
cenocepacia strains XOA3, XOA7, and XOA8. The quality of
the purified LPS samples was confirmed by Tricine-SDS-PAGE
as described above. Fractions containing the core OS were
obtained by mild acid hydrolysis in sodium acetate buffer, pH
4.4, for 3 h at 100 °C as described previously (10). The determination of sugar residues, their absolute configuration, and linkage analysis, as well as the characterization of total fatty acids
content and their absolute configuration were all carried out as
described previously (10).
NMR Analysis—For structural assignments of OS fractions,
one-dimensional and two-dimensional 1H NMR spectra were
recorded on Bruker 600 DRX equipped with a cryoprobe on a
solution of 300 l of D2O using Shigemi tubes. T-ROESY experiments were recorded using data sets (t1 ⫻ t2) of 4096 ⫻ 256
points with mixing times between 100 and 400 ms. The spin
lock field was attenuated (⬃ 4000 Hz) with respect to that
employed for the hard pulses. No correction for HartmannHahn effects was applied, because T-ROESY effectively
removed most of these effects. Double quantum-filtered phasesensitive COSY experiments were performed using data sets of
4096 ⫻ 512 points. TOCSY were performed with spin lock
times from 20 to 100 ms, using data sets (t1 ⫻ t2) of 4096 ⫻ 256
points. In all homonuclear experiments the data matrix was
zero-filled in both dimensions to give a matrix of 4000 ⫻ 2000
points and was resolution-enhanced in both dimensions by a
cosine-bell function before Fourier transformation. Coupling
constants were determined on a first order basis from high resolution one-dimensional spectra or by two-dimensional phasesensitive DQF-COSY. HSQC and HMBC experiments were
measured in the 1H-detected mode via single quantum coherence with proton decoupling in the 13C domain, using data sets
of 2048 ⫻ 256 points. Experiments were carried out in the
phase-sensitive mode. A 60-ms delay was used for the evolution of long range connectivity in the HMBC experiment.
In all heteronuclear experiments the data matrix was
extended to 2048 ⫻ 1024 points using forward linear prediction extrapolation.
MALDI-TOF MS Analysis—MALDI-TOF mass spectra were
recorded in the negative and positive polarity in linear mode on
a Voyager STR from PerSeptive Biosystems (Framingham, MA)
equipped with delayed extraction technology. Ions formed by a
pulsed UV laser beam (nitrogen laser, ⫽ 337 nm) were accelerated at 24 kV. The mass spectra reported are the result of 256
laser shots. Resolution was about 1500.
Sensitivity to PmB—Bacteria were grown overnight in LB
medium or LB medium supplemented with the appropriate
antibiotics as required. The next day cultures were diluted to an
A600 of 0.01, and 50 l of this suspension were added to LB
medium or LB medium supplemented with 100 g/ml trimethoprim to make a final volume of 5 ml. 500 l of this bacterial suspension were aliquoted into Eppendorf tubes, and 10
l of buffer or PmB (5 mg/ml stock) were added to each tube to
reach a final concentration of 100 g/ml. Cells were incubated
VOLUME 284 • NUMBER 32 • AUGUST 7, 2009
Downloaded from http://www.jbc.org/ by guest on May 30, 2020
modified Eagle’s medium (DMEM) with 10% fetal bovine serum
(FBS) and were grown at 37 °C in a humidified atmosphere with
5% CO2. DMEM and FBS were purchased from Wisent Inc. (St.
Bruno, Quebec, Canada).
Construction of Mutants in B. cenocepacia K56-2—An internal 300-bp fragment near the 5⬘ end of the gene targeted for
mutagenesis was PCR-amplified and cloned into the XbaI and
EcoRI restriction sites of the suicide vector pGP⍀Tp to provide
the homology region for recombination. Vector and recombinant plasmids were maintained in E. coli SY327 (araD ⌬lac-pro
argE recA56 nalA pir RifR). The integration vector has a replication origin that cannot function in B. cenocepacia and also
contains transcriptional and translational stops causing polar
effects on genes downstream from the insertion point (20).
Similarly, the suicide plasmid pGPApTp (21) was used to construct nonpolar insertional mutants, and the plasmid pSC200
was used to construct conditional mutants as described (19).
These plasmids were introduced into B. cenocepacia strain
K56-2 by triparental mating (22) using E. coli MM294 (endA
hsdR pro) containing the helper plasmid pRK2013 (23). Exconjugants were selected on LB agar plates supplemented with 50
g/ml gentamicin (to kill the E. coli donor and helper bacteria)
and 100 g/ml trimethoprim for selection of K56-2 exconjugants. Exconjugants were screened for plasmid integration into
the chromosome by colony PCR using a primer annealing to a
region of the mutagenesis vector and another primer annealing
to chromosomal sequences upstream of the insertion site.
Integration was confirmed by Southern blot hybridization
using a probe corresponding to a DNA fragment spanning
the homology region used for recombination. The sequences
of the DNA primers used for mutagenesis are listed in supplemental Table S1.
Molecular Cloning for Complementation of LPS Production
and PmB Sensitivity—To construct the complementing plasmids pXO13, pXO14, pXO20, pXO21, and pXO22, the corresponding genes were PCR-amplified using ProofStart polymerase (Qiagen Inc., Valencia, CA). The PCR products were
digested with XbaI and EcoRI and ligated into pAP20, which
was also cut with the same restriction enzymes. Ligation mixtures were introduced into E. coli DH5␣ (F⫺ 80lacZ M15
endA recA hsdR[rK⫺mK⫺] supE thi gyrA relA ⌬[lacZYAargF]U169) competent cells by the calcium chloride method
(24), and transformants were plated on LB agar plates supplemented with 30 g/ml chloramphenicol. The correct DNA
inserts were verified by colony PCR using primers 1630 (5⬘CGCAGCAGGGTAGTCGCCCT-3⬘) and 1631 (5⬘-ACTCTCGCATGGGGAGACCC-3⬘), which anneal to sequences flanking the cloning sites of pAP20. Plasmids from PCR-positive
colonies were isolated, initially confirmed by restriction digestion and ultimately by DNA sequencing of the DNA insert.
These plasmids were mobilized by conjugation into the corresponding B. cenocepacia mutant strains as described above.
Electrophoretic Analysis of LPS—For electrophoresis analysis, LPS samples were extracted as described previously (25).
LPS was resolved by electrophoresis in 16.4% polyacrylamide
gels using a Tricine-SDS system and visualized by silver staining. In the case of conditional mutants, the LPS was extracted
Structure-Function of B. cenocepacia Core Oligosaccharide
AUGUST 7, 2009 • VOLUME 284 • NUMBER 32
JOURNAL OF BIOLOGICAL CHEMISTRY
21741
Downloaded from http://www.jbc.org/ by guest on May 30, 2020
ing, Mississauga, Ontario, Canada).
Each experiment was independently repeated at least three times.
Adhesion Assays—Monolayers for
adhesion assays were prepared by
seeding 7 ⫻ 104 human lung epithelial A549 cells in DMEM, 10% FBS
into a 48-multiwell plate and incubating at 37 °C for 20 h in a humidified atmosphere containing 5%
CO2. Overnight bacterial cultures
were washed and resuspended in
DMEM, 10% FBS and added to the
cells at multiplicity of infection of
50, centrifuged for 2 min at 300 ⫻ g,
and incubated for 30 min at 4 °C.
FIGURE 1. Genetic maps of the gene loci (in gray) involved in the biosynthesis of the B. cenocepacia K56-2
lipid A-core OS. A, region spanning BCAL2401–BCAL2409(dnaE). B, region spanning BCAL3109(ureG)– Nonadherent bacteria were reBCAL3136(apaH) and containing genes involved in Kdo transfer (waaA), core OS synthesis (waaC), and O anti- moved by rinsing five times with
gen biosynthesis (34). The location of the IS402 insertion element interrupting the continuity of the wbxE gene
ice-cold phosphate-buffered saline.
in the type ET12 strain J2315 is indicated. However, this gene is functional in the strain K56-2 (34). C, region
containing BCAL0967, which was identified as a waaF homolog, which encodes the heptosyltransferase II that Cells were lysed with 100 ml of 0.5%
is predicted to add the second heptose residue onto the core OS.
sodium deoxycholate. Serial dilutions were performed in LB and
with PmB at 37 °C for 22 h with constant rotation using a Barn- plated in duplicated. The percentage of adhesion was calculated
stead Thermolyne LABQUAKE (Barnstead International, as follows: 100 ⫻ (number of cell-associated bacteria/initial
Dubuque, IA), and the A600 was recorded. To determine the number of bacteria added). Data were calculated from at least
MIC50 (concentration of PmB causing 50% reduction in bacte- three independent experiments performed in triplicate and are
rial growth), cells were incubated as described above with PmB expressed as means ⫾ S.E.
at final concentrations of 0, 25, 50, 100, and 200 g/ml.
Statistical Analyses—The statistical significance of differBinding of Dansyl-PmB to Whole Cells—Dansyl/PmB was ences in the data were determined using the one-way analysis of
prepared from PmB and dansyl/chloride by the method of variance test and the Tukey post-test, provided in the Prism
Schindler and Teuber (27) and quantified by the dinitropheny- GraphPad software version 4.0.
lation assay (28). For the binding assay bacteria were grown
overnight in LB medium or LB medium supplemented with 100 RESULTS
g/ml trimethoprim, as required. The overnight cultures were
Organization of Core OS Synthesis Gene Loci in B. cenocepadiluted in LB to an A600 of 0.1 and grown at 37 °C for an addi- cia Strains J2315 and K56-2—We examined the genome of
tional 4 h. Bacteria were collected by centrifugation, suspended strain J2315 (31) for genes predicted to encode enzymes for the
in 1 ml of 5 mM Hepes, pH 7.4, 10 mM sodium azide buffer, and synthesis of the core OS. Unlike enteric bacteria, the B. cenocediluted to an A600 of 0.5. Aliquots (80 l) of this suspension pacia core OS genes are not found within a single cluster but
were added to 96-well plates (Microfluor 2 white, flat bottom rather dispersed into three different locations in chromosome 1
96-well microtiter plates, ThermoLabsystems, Franklin, MA) (Fig. 1). One of these regions is located between nucleotides
and mixed with 20-l aliquots of Hepes/sodium azide buffer 2,656,960 and 2,669,740 and contains eight genes named
(negative control) or the corresponding solutions of dansyl- BCAL2402 to BCAL2409. The last two genes, BCAL2409 and
PmB prepared by dilution of a 1.7-g/l stock solution in BCAL2408, have also been annotated as dnaE (encoding DNA
Hepes/sodium azide buffer. Fluorescence was read in a Varian polymerase C or PolC) and msbA (encoding the ATPase transCary Eclipse fluorescence spectrofluorometer using an excita- ported for lipid A-core oligosaccharide (6)), respectively (31).
tion wavelength of 340 nm and an emission wavelength of 485 According to the established norms for nomenclature of bactenm as described (29).
rial polysaccharide genes (32) and in consultation with the BacMacrophage Infection Assays—Macrophage infections were terial Polysaccharide Gene Data Base, we have annotated the
performed as described previously (30). Briefly, bacterial sus- remaining genes as wabO, wabP, wabQ, waaL, wabR, and wabS
pensions were added to RAW 264.7 cells grown on glass cover- (Fig. 1A). The first gene of the cluster, wabO, is transcribed in
slips at a multiplicity of infection of 50 and incubated at 37 °C in the opposite direction relative to the other seven genes. There
5% CO2 for 4 h. When needed, 0.5 mM LysoTracker Red are 66 nucleotides separating the coding sequences of wabP and
DND-99 (Invitrogen) was added for 1 min prior to visualiza- wabQ, but this sequence is too short to harbor a promoter
tion. Fluorescence and phase contrast images were acquired region. The coding sequences of wabQ, waaL, and wabR overusing a Qimaging (Burnaby, British Columbia, Canada) cooled, lap suggesting these three genes may be cotranscribed. In concharged-coupled device camera on an Axioscope 2 (Carl Zeiss) trast, 260 bp separate wabR from wabS, suggesting this region
microscope. Images were digitally processed using the North- could accommodate a promoter region. Also, it would appear
ern Eclipse version 6.0 imaging analysis software (Empix Imag- that the dnaE-msbA-wabS genes are transcribed from a pro-
Structure-Function of B. cenocepacia Core Oligosaccharide
moter region upstream of dnaE. This organization suggests a
complex transcriptional regulation of these gene loci, which we
are currently investigating. Bioinformatic analyses indicate that
the products from wabP and wabR are heptosyltransferases,
because they have strong similarities to the E. coli WaaQ (heptosyltransferase III) and proteins of the GT1_LPS-heptosyltransferase family, respectively. The products of wabO, wabQ,
and wabS have homologies with various glycosyltransferases.
BCAL2405 was assigned as waaL based on the characteristics of
its predicted product containing the typical topological features
observed in O antigen ligases, including 12 predicted transmembrane domains and a large periplasmic loop, which contains highly conserved arginine and histidine residues (33). As
expected, the insertional inactivation of waaL results in loss
of O antigen surface expression in B. cenocepacia K56-2 (see
below).
Additional loci for lipid A-core OS synthesis were previously
reported in a 4-gene transcriptional unit next to the O antigen
gene cluster (Fig. 1B) (34). They include waaC (encoding a heptosyltransferase I homolog) and waaA (encoding a Kdo transferase) genes. Also, there is a monocystronic gene locus
between nucleotides 1,055,340 and 1,056,400 that corresponds
to waaF (heptosyltransferase II) homolog (Fig. 1C). As expected, all of these loci were also present with an identical gene
organization in the B. cenocepacia strain K56-2, which is from
the same clonal lineage as J2315 (18).
Functional Assignment of Core OS Genes—To assign function and establish the order of synthesis of the core OS sugars,
we constructed insertional mutants in each of the identified
genes as described under “Experimental Procedures.” Also, an
insertional mutation in the wbxE gene (Fig. 1B), which produces a truncated O antigen (Fig. 2, lane 1), was constructed.
The LPS banding pattern profiles of parental and mutant
strains were examined by gel electrophoresis and silver stain-
21742 JOURNAL OF BIOLOGICAL CHEMISTRY
VOLUME 284 • NUMBER 32 • AUGUST 7, 2009
Downloaded from http://www.jbc.org/ by guest on May 30, 2020
FIGURE 2. Electrophoretic profiles of the LPS from B. cenocepacia K56-2
parental and mutant strains. LPS fractions were prepared as described
under “Experimental Procedures” and separated by SDS-PAGE followed by
silver staining. Polymeric Oag denotes the portion of the gel where the lipid
A-core containing O antigen polysaccharides of varying number of repeating
units migrate. Core ⫹ Oag denotes the extra band in mutant XOA3 that corresponds to lipid A-core ⫹ an incomplete O antigen repeat. Core denotes the
region of the gel corresponding to the migration of the lipid A-core. The
genes in parentheses indicate the gene that is mutated by insertional
mutagenesis in the appropriate strain. Lanes 10 –13 correspond to a different
gel in which the effect of the waaF mutation on the core OS LPS was tested
using the other wild type and mutant strains as controls. The gels were run
under identical conditions of voltage, and the migration of the lipid A-core OS
band was compared with that of the wild type strain as standard. The relative
migration of the mutant lipid A-core OS bands relative to the wild type positive control was reproducible in different runs.
ing. Compared with the parental strain K56-2, the mutants
XOA6 (wabP::pGP⍀Tp) and XOA9 (wabQ::pGP⍀Tp) did not
compromise O antigen synthesis as evidenced by the detection
of typical O-ladder-like banding patterns (Fig. 2, lanes 2– 4).
This suggests that wabP and wabQ gene products mediate lipid
A-core OS modifications that are nonessential for the attachment of O antigen polysaccharide chains, or alternatively, their
functions can be supplemented by unidentified genes in the B.
cenocepacia K56-2 genome. The LPS from the strain XOA7
(waaL::pGP⍀Tp) displayed a lipid A-core OS band that comigrated with the corresponding band in the parental K56-2 LPS
(Fig. 2, lanes 2 and 5). This is in agreement with the functional
assignment of this gene as encoding the O antigen ligase. In
contrast, insertional mutations in wabR, wabS, and wabO, as
well as the mutations in waaC and waaF (Fig. 2, lanes 6 –9 and
11) resulted not only in loss of O antigen surface expression
but also gave rise to progressive truncations of the lipid
A-core OS, as determined by the presence of fast migrating
bands of smaller mass than the band produced by XOA7
(waaL::pGP⍀Tp).
The CCB1 (waaC::pGP⍀Tp) mutant produced the shortest
lipid A-core OS band (Fig. 2, lanes 9 and 12), which also comigrated with the lipid A-core OS of the SAL1 strain (data not
shown). Because SAL1 has a defect in the synthesis of ADPglycero-manno-heptose precursors (15), these results confirm
the functional assignment of WaaC as the heptosyltransferase I
enzyme. The lipid A-core OS band produced by the
waaF::pSC200 mutant XOA19 migrated between the lipid
A-core OS from the waaC and wabO mutants, suggesting that
waaF encodes the heptosyltransferase II. LPS production in all
of the mutants examined except for XOA15 (wabR::pGP⍀Tp)
was restored to parental levels after introducing complementing plasmids carrying the corresponding gene under the control
of a constitutive promoter (data not shown). In the case of
XOA15 (wabR::pGP⍀Tp), the complementing plasmid pXO22
could not be introduced by either conjugation or electroporation, suggesting this mutant has a defect preventing the stable
maintenance of the complementing plasmid. Together, the
mutagenesis experiments suggest that the lipid A-core OS synthesis in B. cenocepacia K56-2 requires the sequential glycosyltransferase activities of WaaC, WaaF, WabO, WabS, and
WabR, although the participation of WabP and WabQ could
not be deduced.
Structural Characterization of the Core OS of B. cenocepacia K56-2 LPS—To verify the functional assignments of the
core OS genes and to characterize in more detail the structure-function of the core OS in B. cenocepacia, we determined the structure of the core OS produced by strains
XOA3 (wbxE::pGP⍀Tp), XOA7 (waaL::pGP⍀Tp), and XOA8
(wabO::pGP⍀Tp). LPS fractions from these strains were
extracted by large scale purification and confirmed by SDSPAGE. Monosaccharide and fatty acid analyses showed the
same content in fatty acids (data not shown) but different composition in sugars (Table 2).
To elucidate the primary structure of the core OS of the
XOA3 strain, a mild hydrolysis with sodium acetate buffer was
performed to split the lipid A from the core OSXOA3 fraction
that by gel permeation chromatography yielded one main frac-
Structure-Function of B. cenocepacia Core Oligosaccharide
TABLE 2
Monosaccharide components of core OS from B. cenocepacia strains
XOA3 (wbxE::pGP⍀Tp), XOA7 (waaL::pGP⍀Tp), and XOA8
(wabO::pGP⍀Tp)
The sugar content was obtained by performing a methanolysis (the sample was methanolyzed and acetylated) followed by analysis via gas chromatography-mass spectrometry. The ring size and the attachment points were determined by methylation analysis,
and the absolute configuration of sugar residues has been determined by gas chromatography-mass spectrometry analysis of the acetylated O-(⫹)-Oct-2yl glycoside derivatives. In all cases, both the fragmentation pattern and a systematic comparison with
standards allowed the unequivocal identification and assignment of the sugar content.
The results were reproducible over the course of three repeated experiments. X is the
first letter defining the name of the mutant strains (e.g. XOA3); x indicates that the sugar
is present in the analysis; ⫺ indicates that the sugar is absent in the analysis.
XOA3
XOA7
XOA8
x
x
x
x
x
x
x
⫺
x
x
x
x
x
x
x
x
x
x
x
x
x
x
⫺
x
x
x
x
⫺
⫺
⫺
X
X
X
X
X
X
⫺
X
⫺
x
⫺
⫺
⫺
⫺
⫺
FIGURE 3. Top, 1H NMR spectrum of core OSXOA3 product; in the inset the expanded anomeric region is shown. Bottom, section of the T-ROESY (red) and TOCSY
(black) spectrum is shown. Monosaccharide labels are as indicated in Table 3. The relevant inter-residue rotating-frame Overhauser enhancement cross-peaks
are indicated. The presence of a terminal nonstoichiometric disaccharide induces a visible shift in the H-2 C signals.
AUGUST 7, 2009 • VOLUME 284 • NUMBER 32
JOURNAL OF BIOLOGICAL CHEMISTRY
21743
Downloaded from http://www.jbc.org/ by guest on May 30, 2020
Assignment
6-Substituted-D-GlcNp
5-Substituted-Kdop
4,5-Substituted-Kdop
8-Substituted-Kop
Terminal Kop
Terminal L-Ara-4N
3,4-Substituted LD-Hep
3-Substituted LD-Hep
3,7-Substituted LD-Hep
Terminal LD-Hep
2-Substituted D-Glc
Terminal D-Glc
Terminal L-Rha
3-Substituted D-QuiN
7-Substituted D-Hep
tion. The compositional analysis of the isolated OSXOA3
showed 3,4-di-substituted LD-Hep, 3,7-di-substituted LD-Hep,
7-substituted LD-Hep, terminal LD-Hep, 2-substituted glucose
(Glc), terminal L-rhamnose (L-Rha), terminal D-Glc, 3-substituted D-quinovosamine (D-QuiN), 4,5-di-substituted Kdo, and
a terminal Ko, all in the pyranose ring conformation.
The 1H NMR spectrum of OSXOA3 is shown in Fig. 3. A combination of homo- and heteronuclear two-dimensional NMR
experiments, including double quantum-filtered correlation
spectroscopy (DQF-COSY), total correlation spectroscopy
(TOCSY), transverse rotating-frame Overhauser enhancement
spectroscopy (T-ROESY), 1H-13C HSQC, and 1H-13C HMBC
were performed to assign all the spin systems of OSXOA3 and
the monosaccharide sequence. In the anomeric region of the 1H
NMR spectrum (Fig. 3), nine anomeric signals were identified
(A–H, Table 3). Furthermore, the signals at 1.92/2.16 ppm were
identified as the H-3 methylene of the Kdo residue. The NMR
data indicated a mixture of two oligosaccharides with different
lengths. Spin systems A, B, D, Dⴕ, and F (Table 3) were all
identified as ␣-heptose residues, as indicated by their 3JH1,H2
and 3JH2,H3 coupling constants (below 3 Hz) and by the intraresidual nuclear Overhauser effect (NOE) of H-1 with H-2.
Structure-Function of B. cenocepacia Core Oligosaccharide
TABLE 3
1
H and 13C (italics) NMR chemical shifts (ppm) of sugar residues of the core region of the oligosaccharide OSXOA3
The heptose residues possess a L-glycero-D-manno configuration. ND indicates not detectable.
Downloaded from http://www.jbc.org/ by guest on May 30, 2020
These data, together with the C-613C chemical shift values (all
below 70 ppm) allowed us to identify them as L-glycero-Dmanno heptose, in agreement with the chemical analysis. Spin
21744 JOURNAL OF BIOLOGICAL CHEMISTRY
systems C and E were identified as glucose residues, as indicated by their large ring 3JH,H coupling constants (above 10 Hz).
The strong intra-residue NOE contacts of H-1 E with H-3 and
VOLUME 284 • NUMBER 32 • AUGUST 7, 2009
Structure-Function of B. cenocepacia Core Oligosaccharide
AUGUST 7, 2009 • VOLUME 284 • NUMBER 32
HMBC spectrum confirmed the OS sequence assigned so far.
Thus, methylation analyses, glycosylation shifts, NOE, and
HMBC data were all in agreement to indicate an OSXOA3 structure as depicted in Fig. 4A.
An alternative glycoform of the ␣-heptose D was found, indicated as residue Dⴕ (H-1 4.99 ppm; Fig. 3 and Table 3), which
was identified as a 7-␣-Hep. The NOE contact of H-7 D with
H-1 of -D-QuiN G confirmed the glycosylation by G of residue
D at position 7. Residue G was in turn substituted at O-3 by the
terminal ␣-rhamnose H, as suggested by the NOE contact of
H-1 G with H-3 H. These data validated the structure
depicted in Fig. 4B, differing from the one in Fig. 4A by the
presence of the additional terminal disaccharide (G-(133)H-(13 in Fig. 4B).
A MALDI-TOF mass spectrum of the OSXOA3 mixture OS1
confirmed the above structural hypotheses (Fig. 5A). The
negative ion mass spectrum showed two major ions at m/z 1565.9
and 1899.0 (⌬m/z ⫽ 333). Species at m/z 1565.9 was identified
as the octosaccharide built up of four Hep, two Hex, one Kdo,
and one Ko residues. Species at m/z 1899.0 (⌬m/z 333) was
consistent with the decasaccharide that differed by the presence of the additional dHex-dHexNAc disaccharide.
In addition to the molecular ions in the mass range 2500 –
4000 Da, the negative ion MALDI mass spectrum of intact core
OSXOA3 revealed ion peaks related to fragments arising from
the very labile glycoside bond cleavage between Kdo and the
lipid A moiety (Fig. 5B). Thus, at low molecular masses (Fig.
5B), the ion peak at m/z 1548.2 could be assigned to the octosaccharide described above. Ion peaks A–E were derived from the
lipid A that was constituted by a mixture of tetra- and pentaacylated species differing by the phosphorylation pattern. Species A at m/z 1444.1 was identified as a tetra-acylated disaccharide backbone carrying in ester linkage one 14:0 (3-OH) chain
and in amide linkage two 16:0 (3-OH) chains, one of which, on
the GlcN II, was further substituted by a secondary fatty acid, a
14:0 residue. Species C at m/z 1670.8 (⌬m/z ⫽ 131) was the
corresponding penta-acylated species carrying two ester-linked
14:0 (3-OH) residues. The other species differed for the presence of one or two L-Ara4N residues linked to the phosphate
groups. The core OS molecular ions, in the mass range 2500 –
4000 Da (Fig. 3), were given by the combination of the peaks of
the lipid A and the core region. Interestingly, peaks related to
the presence of an additional pentosamine identified via gas
chromatography-mass spectrometry as L-Ara4N linked at position O-8 of the Ko residue were also present (see ions at m/z
3254.5 and 3587.1). Peaks at m/z 3455.5 and 3587.1 (⌬m/z ⫽
332 with respect to 3123.5 and 3254.5) were consistent with the
presence of the additional terminal dHex-dHexNAc disaccharide. The penta-acylated species was present in a very low
amount, and peaks corresponding to penta-acylated lipid A in
the core OS region were not detectable. Together, NMR and
MS data validated the structure for the lipid A-core OS of strain
XOA3 (wbxE::pGP⍀Tp) that is shown in Fig. 4C.
A similar approach was used to elucidate the structure of the
core OS from XOA7 (waaL::pGP⍀Tp). The NMR fraction isolated by gel filtration chromatography following the acid treatment was identical to the OS from XOA3 (wbxE::pGP⍀Tp) but
lacked the terminal -D-QuiNAc-(133)-␣-L-Rha disaccharide
JOURNAL OF BIOLOGICAL CHEMISTRY
21745
Downloaded from http://www.jbc.org/ by guest on May 30, 2020
H-5 E together with the 3JH1,H2 coupling constant (7 Hz) were
diagnostics of -configuration, whereas the intra-residue NOE
contact of H-1 with H-2 and the 3JH1,H2 coupling constant (3
Hz) were indicative of ␣-anomeric configuration of residue C.
Residue H was recognized as ␣-Rha. Actually, in TOCSY spectrum scalar correlations of the ring protons with methyl signals
in the shielded region at 1.14 ppm were visible. The manno
configuration of residue H was established from the 3JH1,H2 and
3
JH1,H3 values (below 3 Hz), and the ␣-configuration was
assigned by the intra-residual NOE contact of H-1 with H-2
and chemical shift of its H-5 and C-5. Residue G was recognized
as -QuiN, as indicated by the ring 3JH,H coupling constants
(above 10 Hz). The intra-residual NOE contact of H-1 with H-3
and H-5 and the 3JH1,H2 coupling constant were indicative of
-anomeric configuration. The 13C-1H HSQC spectrum
showed the correlation of H-2 G, at 3.76 ppm, with a nitrogenbearing carbon signal at 55.4 ppm. The downfield shift of proton resonance of H-2 H was diagnostic of N-acetylation at this
position. Because of the absence of the anomeric proton signal,
spin system of Kdo K was assigned starting from the diastereotopic H-3 methylene protons, resonating in a shielded
region at 1.92 and 2.16 ppm (H-3ax and H-3eq, respectively).
Because of its free reducing end, the Kdo residue was present in
multiple forms. However, the signals belonging to the ␣-reducing unit were clearly evident, whereas the ␣-anomeric orientation at C-2 was attributed by the chemical shift values of H-3
and by the values of 3JH7, H8a and 3JH7, H8b coupling constants
(35, 36). Residue J of ␣-Ko was assigned starting from its
oxymethine H-3 signal at 3.74 ppm. The talo and the anomeric
configuration of Ko were assigned by the analysis of vicinal
3
JH,H coupling constants from the DQF-COSY, in particular by
the existence of a 5JH3,H5, typical of the W long range couplings
and after the comparison with published data (35). The downfield shift of carbon resonances identified the glycosylated positions as follows: O-3 and O-4 of residue A; O-3 and O-7 of
residue B; O-2 of residue C; O-7 of residue Dⴕ; O-3 of residue G;
O-5 of residue K; and residues D, E, F, H, and J were nonreducing terminal sugars, in full agreement with the methylation
analysis. The inter-residual NOE contacts (Fig. 3) and the long
range correlations present in the HMBC spectrum yielded the
OS sequence. The linkage of the heptose A to O-5 of Kdo K was
proven by the NOE connectivity between H-1 of heptose A
(5.21 ppm) and H-5 K (4.17 ppm). The inter-residue NOE contacts between H3eq of Kdo and H-6 of Ko (J) were diagnostic for
the ␣-D-Ko-(234)-␣-D-Kdo linkage (7, 35, 37) (Fig. 3). Residue
A was substituted at O-3 and O-4. The NOE contact of H-4
(4.21 ppm) and H-6 A with H-1 E (4.49 ppm) evidenced that the
O-4 of ␣-heptose A was glycosylated by residue E, the -glucose. Residue A was also substituted at O-3 by residue B,
according to the NOE (Fig. 3) of H-3 A with H-1 B. Residue B
was identified as the 3,7-disubstituted ␣-heptose. The NOE
correlation of H-3 B (3.93 ppm) with H-1 C (5.21 ppm) (Fig. 3)
gave evidence of substitution of residue B at O-3 by the ␣-glucose C. Furthermore, residue B was glycosylated at O-7 by the
heptose residue F, as demonstrated by the NOE contact of H-7
B with H-1 F. Residue C was substituted at O-2 by the ␣-heptose D, as shown by the NOE correlation of H-2 C (3.58 ppm)
with H-1 D (5.00 ppm). The scalar correlation found in the
Structure-Function of B. cenocepacia Core Oligosaccharide
as demonstrated by the comparison of the NMR spectra of
XOA3 and XOA7 (supplemental Fig. S1) and by the
MALDI-MS spectrum (supplemental Fig. S2). The MALDI-MS
spectrum of the intact OS (Fig. 5B) also showed, at low molecular masses, the ion peak derived from the core OS at m/z
1548.4 that was identified as an octosaccharide carrying four
heptoses, one Kdo, one Ko, and two hexoses. The lipid A was
constituted by a mixture of tetra- and penta-acylated species
differing by the phosphorylation pattern (species A–E) and carrying from none to two L-Ara4N residues. The L-Ara4N residue
on the Ko residue was present in nonstoichiometric amounts.
Therefore, we concluded that the lipid A-core OS of the mutant
XOA7 (waaL::pGP⍀Tp) has the structure indicated in Fig. 4D
lacking the ␣-L-Rha-(133)--D-QuiNAc disaccharide. This
suggests that the addition of this disaccharide requires the
activity of the WaaL protein.
In the case of the XOA8 (wabO::pGP⍀Tp), the ion peak
derived from the core OS was found at m/z 839.4 in the
MALDI-TOF MS spectrum of intact OS (Fig. 5D). This corresponded to a tetrasaccharide with two heptoses, one Kdo and
one Ko. The lipid A was constituted by a mixture of tetra- and
penta-acylated species differing by the phosphorylation pattern
(species A–E) and carrying from none to two L-Ara4N residues.
The L-Ara4N residue on the Ko residue was present in nonstoichiometric amount (see MALDI of intact core OS). Based on
21746 JOURNAL OF BIOLOGICAL CHEMISTRY
the results from MALDI and NMR (not shown), the core OS
structure of the XOA8 (wabO::pGP⍀Tp) contains a heptose
disaccharide attached to the Kdo (Fig. 4E). The structural data,
together with the rapid banding pattern of the lipid A-core OS
in SDS-PAGE, support the assignment of wabO as the gene
encoding the glucosyltransferase responsible for the addition of
-D-Glc to HepI (Fig. 4, B and C).
PmB Sensitivity for B. cenocepacia K56-2 LPS Core Mutants—
The sensitivity of the different mutants to PmB was determined
as described under “Experimental Procedures.” Except for
mutants XOA9 (wabQ) and XOA6 (wabP), all the mutants with
truncations in their lipid A-core OS (Fig. 2) grew significantly
less (p ⬍ 0.001) than the parental strain in the presence of 100
g/ml PmB (Fig. 6A). To further investigate the role of the lipid
A-core OS in the resistance of B. cenocepacia to PmB, we grew
the mutants XOA7 (waaL), XOA8 (wabO), XOA15 (wabR),
XOA17 (wabS), and CCB1 (waaC) in the presence of a range of
PmB concentrations from 0 to 200 g/ml, and we determined
the concentration for which the growth was reduced to 50%
(MIC50) when compared with a control culture grown in the
absence of PmB. Deeper truncations of the lipid A-core OS
correlated with increased sensitivity to PmB in this assay (Fig.
6B). The MIC50 values for the different mutants ranged from
3.5- to 14.6-fold less than ⬎512 g/ml, the MIC50 value of the
parental strain K56-2 (data not shown) (15). Furthermore, the
VOLUME 284 • NUMBER 32 • AUGUST 7, 2009
Downloaded from http://www.jbc.org/ by guest on May 30, 2020
FIGURE 4. Structural assignments of the core OS in mutants XOA3, XOA7, and XOA8. A and B, structural predictions based on NMR on XOA3 mutant OS (see
Fig. 3). C–E indicate the structures of the lipid A-core OS for the mutants XOA3, XOA7, and XOA8. The functional assignment for the proteins encoded by the
wab genes, waaL ligase, waaC, waaF, and wbxE are based on the structural data and the migration profiles of purified lipid A-core OS in SDS-PAGE. Rectangles
indicate the assignment is confirmed. ? indicates proposed functional assignments.
Structure-Function of B. cenocepacia Core Oligosaccharide
31 and 36 g/ml MIC50 values for XOA8 (wabO) CCB1 (waaC)
were comparable with that reported for the heptoseless mutant
SAL1 (15).
To determine whether the increased sensitivity to PmB correlated with increased binding of the mutants to this peptide,
we performed binding assays using the fluorescence analog
dansyl-PmB. This compound only fluoresces when bound to
whole cells or purified LPS. As reported before for B. cepacia
(29), B. cenocepacia K56-2 did not bind dansyl-PmB. In contrast, all the mutants bound dansyl-PmB with a degree of binding that was proportional to their sensitivity to PmB (supplemental Fig. S3). Thus, deeper truncations of the core lipid A-OS
correlated with greater binding of the bacterial cells to
dansyl-PmB.
Loss of O Antigen Production Increases the Adherence of B.
cenocepacia to Lung Epithelial Cells—Airway epithelial cells
play a key role in maintaining mucosal integrity, and they are
the first cells to be challenged by airborne pathogens. We investigated the ability of our panel of mutants in LPS O antigen and
lipid A-core OS synthesis to adhere to A549 human lung epithelial cells. Previous work has shown that B. cenocepacia can
survive intracellularly in this cell line (38). Our results showed
AUGUST 7, 2009 • VOLUME 284 • NUMBER 32
that XOA7 (waaL::pGP⍀Tp), which lost the ability to produce
O antigen but produces a complete lipid A-core OS, exhibited
100-fold increased adhesion to A549 cells compared with the
parental strain (31 ⫾ 18% adhesion for XOA7 versus 0.23 ⫾
0.13% for K56-2). Similar results were obtained with all of the
other mutants producing truncated core OS (data not shown).
We conclude from these results that loss of O antigen production, but not core OS truncations, in B. cenocepacia correlates
with increased bacterial adhesion to epithelial cells.
Lipid A-Core OS Heptoseless Mutant CCB1 Is Defective for
Intracellular Survival in Macrophages—Previous work in our
laboratory demonstrated that B. cenocepacia can survive intracellularly in macrophages (39). Survival occurs in B. cenocepacia-containing vacuoles (BcCVs) that delay normal phagosomal maturation by interfering with vacuolar acidification and
the phagolysosomal fusion (40). We investigated the role of O
antigen and the core OS in the intracellular behavior of B. cenocepacia. RAW 264.7 macrophages were infected with K56-2,
XOA7 (waaL::pGP⍀Tp), and CCB1 (waaC::pGP⍀Tp) strains,
and the colocalization of BcCVs with LysoTracker Red was
assessed by fluorescence microscopy. LysoTracker Red is an
acidotropic dye that preferentially accumulates in lysosomes
JOURNAL OF BIOLOGICAL CHEMISTRY
21747
Downloaded from http://www.jbc.org/ by guest on May 30, 2020
FIGURE 5. A, negative ion MALDI mass spectrum of core OS product from XOA3 strain. B, negative ion MALDI-TOF mass spectrum of core OS from XOA3
obtained in linear mode. C, negative ion MALDI TOF mass spectrum of core OS from XOA7 obtained in linear mode. D, negative ion MALDI TOF mass spectrum
of core OS from XOA8 obtained in linear mode.
Structure-Function of B. cenocepacia Core Oligosaccharide
abnormal morphologies such as rounding and a highly dense
cytoplasm, further suggesting a compromise of their cellular
envelope (data not shown). Together, these experiments indicate that the CCB1 mutant loses the ability to survive intracellularly, whereas mutants containing less severe core OS truncations or a complete core OS with no O antigen are not
impaired in intracellular survival.
(41). At 4 h post-infection, less than 30% of the BcCVs containing either K56-2 or XOA7 B. cenocepacia colocalized with
Lysotracker Red (Fig. 7, A and C, and data not shown). Similar
results were obtained with mutants XOA8 (WabO::pGP⍀Tp),
XOA15 (WabR::pGP⍀Tp), and XOA17 (WabS::pGPApTp)
(Fig. 7C). In contrast, over 85.4 ⫾ 6.6% of BcCVs in macrophages infected with the heptoseless mutant CCB1 colocalized
with the dye at 4 h (Fig. 7, A and C).
Given that intracellular CCB1 bacteria did not prevent
phagolysosomal acidification, we also investigated their viability in RAW 264.7 macrophages. For these experiments we performed infections with bacteria expressing the monomeric red
fluorescent protein 1 (mRFP1) encoded by pJR1 (Table 1).
Using B. cenocepacia cells expressing mRFP1, we have previously demonstrated that intracellular bacteria trafficking into
lysosomes rapidly lose cell envelope integrity and are destroyed,
resulting in the leakage of mRFP1 into the vacuolar lumen (30,
40, 42). At 4 h post-infection, 68.9 ⫾ 4.7% of BcCVs containing
CCB1(pJR1) bacteria were fluorescently labeled, suggesting
that soluble mRFP1 had leaked from the bacterial cytoplasm
into the phagosomal lumen (Fig. 7B). In contrast, 11 ⫾ 5% of the
BcCVs containing K56-2 (pJR1) showed leakage of mRFP1 (p ⬍
0.0001; Fig. 7D and data not shown). Furthermore, in contrast
to the apparently normal bacterial morphology of intracellular
K56-2 (pJR1), internalized CCB1(pJR1) exhibited a variety of
21748 JOURNAL OF BIOLOGICAL CHEMISTRY
VOLUME 284 • NUMBER 32 • AUGUST 7, 2009
Downloaded from http://www.jbc.org/ by guest on May 30, 2020
FIGURE 6. A, growth of mutants with truncated LPS in the presence of 100
g/ml PmB as compared with the wild type K56-2. Graph shows the % relative
growth of the different strains in the presence of 100 g/ml PmB as compared
with the growth without PmB. Error bars correspond to S.E. for three independent experiments done in triplicate. ***, denotes p ⬍ 0.001 for the pairwise comparisons of the % relative growth of each mutant versus the %
growth of the parental strain, as determined by the Tukey post-test. B, dosedependent growth for mutants with truncated LPS under increasing concentrations of PmB ranging from 25 to 100 g/ml as compared with the growth
without PmB. Error bars correspond to S.E. for three independent experiments done in triplicate.
DISCUSSION
We have identified gene loci responsible for the biosynthesis of the core OS moiety in B. cenocepacia K56-2. This
allowed us to create a set of core OS-deficient mutants, three
of which were used to determine the structure of the core
OS. The mutant XOA3 has an insertional mutation in the
wbxE gene that encodes a glycosyltransferase involved in O
antigen synthesis, resulting in the production of lipid A-core
OS and a partial O antigen unit (34). This mutation recreates
the same LPS phenotype as observed in strain J2315, whose
structure has been recently reported (10). In J2315, the spontaneous insertion of the IS402 element in wbxE causes the
formation of a lipid A-core OS with a partial O antigen
repeat that cannot be polymerized (34). The core OS structures in J2315 and XOA3 strains are identical, except for the
presence of ␣-galactose instead of ␣-Glc linked to the outer
core branched 3,7-disubstituted Hep. The galactose in the
J2315 strain has an additional ␣-glucose at the O-6 position.
The mutant XOA7, which has an inactivated waaL gene,
lacks the terminal Rha-QuiNAc disaccharide found in the
outer core OS of strains XOA3 and J2315 (10). From these
data, we conclude that the Rha-QuiNAc disaccharide is a
remnant of the interrupted O antigen in these strains. The O
antigen in B. cenocepacia K56-2 is synthesized via the ABC
export pathway (4, 34). This particular mode of O antigen
synthesis requires an adaptor sugar bound to undecaprenylPP, to which the remainder of the O antigen repeating units
become attached (4). Based on our structural information,
combined with the mutagenesis data, we conclude that the
QuiNAc residue is the adaptor sugar for the O antigen synthesis in B. cenocepacia K56-2. Furthermore, our data support the conclusion that the -D-QuiNAc-(137)-␣-LD-Hep
linkage is made by the WaaL O antigen ligase, explaining
why the Rha-QuiNAc disaccharide is absent in strain XOA7.
The terminal rhamnose in the core OS of the XOA3 mutant,
is likely the first sugar of the repeating O unit, which we have
previously established as a Rha-GalNAc-GalNAc trisaccharide (34), but which cannot be completed because of the
mutation in the WbxE glycosyltransferase. Therefore, our
data also suggest that WbxE encodes a GalNAc transferase.
Current work in our laboratories is under way to resolve the
complete biosynthesis pathway of the O antigen component
of the B. cenocepacia LPS.
The structure of the core OS in the XOA8 strain revealed a
major truncation, consistent with the migration pattern of the
LPS in SDS-PAGE. The mutated wabO gene in XOA, encodes a
putative glycosyltransferase, and based on the elucidated structure and the short lipid A-core OS band produced by the
mutant strain, we predict that WabO protein is the glucosyltransferase responsible for the glucosylation of HepI (Fig. 4C).
Structure-Function of B. cenocepacia Core Oligosaccharide
AUGUST 7, 2009 • VOLUME 284 • NUMBER 32
JOURNAL OF BIOLOGICAL CHEMISTRY
21749
Downloaded from http://www.jbc.org/ by guest on May 30, 2020
The composition of the lipid A
moiety of B. cenocepacia K56-2 was
identical to that of B. cepacia (8) and
B. cenocepacia J2315 (10), and the
inner core OS is also composed of
the trisaccharide Kdo-Ko-L-Ara4N,
as described before (7, 9, 10).
L-Ara4N is found as a nonstoichiometric substitution in the core OS of
several bacteria such as Proteus penneri (43). The presence of L-Ara4N
as a component of the core OS is
unusual as this positively charged
sugar is commonly found as a modification of the lipid A in response to
specific environmental signals (4),
but it is rarely found as a component
of the core OS. In a previous study,
we demonstrated that the synthesis
of L-Ara4N is essential for the viability of B. cenocepacia (19), and more
recently we have observed the same
requirement for a B. cenocepacia
mutant defective in the production
of UDP-glucuronic acid, a precursor
for UDP-L-Ara4N (44), and speculated that the presence of L-Ara4N
in the core OS may be critical for the
completion of the synthesis or the
assembly of the LPS. The presence
of L-Ara4N linked to Ko is not universal to all Burkholderia, as it has
been recently shown that a heptose
residue is located at this position in
the core OS of “B. cepacia” serotype
O4 (45). This strain also has a very
different core OS structure than the
ones we have determined for B.
cenocepacia ET12 strains. Unfortunately, given the heterogeneity of
the genus Burkholderia (46), the
lack of a detailed taxonomical
FIGURE 7. Lipid A-core OS heptoseless mutant CCB1 is defective for intracellular survival in macro- assignment for B. cepacia serotype
phages. A, images of RAW 264.7 macrophages infected for 4 h with B. cenocepacia K56-2 or with the O4 makes it difficult to compare
mutant CCB1 at a multiplicity of infection of 50 using fluorescence and phase contrast microscopy. Macro- with other strains. The presence of
phages were incubated with 0.5 M LysoTracker Red prior to visualization. K56-2 bacteria are within
membrane-bound vacuoles that do not colocalize with LysoTracker Red (arrow). B, images of RAW 264.7 the Kdo analog Ko is also unusual.
macrophage cells infected for 4 h with B. cenocepacia CCB1(pJR1) at an multiplicity of infection of 50 by Ko has also been found as a substifluorescence and phase-contrast microscopy. CCB1 mutant bacteria had compromised cell envelope tute for Kdo II in the LPS of Yersinia
permeability, as shown by the release of mRFP1 into the vacuolar lumen. C, percent of bacteria-containing
vacuoles colocalizing with LysoTracker Red. D, percent of bacteria-containing vacuoles containing pestis and Serratia marcescens and
released mRFP1. The values in C and D correspond to the average and S.E. of three experiments in which for Kdo I in the LPS of Acinetobacter
21 fields were examined. DIC, differential interference contrast.
haemolyticus (5), but the function of
such substitution and its biosyntheAlso, the structural data suggest that glucosylation of HepI may sis are unknown (43). On the other hand, the LPS of other
be a requirement for the glucosylation of HepII and the contin- Burkholderia species such as B. caryophylli do not contain Ko
uation of the extension of the lipid A-core OS. Analysis of the (11, 47).
A heptoseless mutant of B. cepacia has been reported as a
LPS structure of XOA17, currently in progress in our laboratories, would be required to unequivocally support this result of a mutation of the heptosyltransferase I waaC (48). The
structure of the core OS for this mutant is the same as the one
conclusion.
Structure-Function of B. cenocepacia Core Oligosaccharide
6
S. A. Loutet and M. A. Valvano, unpublished observations.
21750 JOURNAL OF BIOLOGICAL CHEMISTRY
ment with other observations indicating that B. cenocepacia
heptoseless mutants have defects in motility and increased permeability to other hydrophobic compounds in addition to antimicrobial peptides (15).6
In conclusion, we have identified the genes involved in the
biosynthesis of the core OS in B. cenocepacia, performed the
structural analysis of the core OS, and assigned function to
most of the genes of the core OS loci. We also demonstrated
that progressive truncations of core OS are associated with a
dramatic reduction in the resistance to PmB, which inversely
correlates with increasing binding of this peptide to the bacterial cell envelope of the mutant strains. Finally, we also show
that the majority of the core OS is expendable for intracellular
survival of B. cenocepacia in macrophages, whereas the O antigen contributes to prevent bacterial adhesion to epithelial cells.
Further investigations are underway in our laboratories to better elucidate the characteristic of the outer membrane and the
LPS molecules that contribute to the extraordinary resistance
of B. cenocepacia to a wide range of antimicrobial molecules,
including APs.
Acknowledgments—We thank Dr. L. Sturiale and Prof. D. Garozzo for
MS spectrometry, C. Fehlner-Gardiner for preparing dansyl-polymyxin B, and S. A. Loutet and C. L. Marolda for critical reading of the
manuscript.
REFERENCES
1. Mahenthiralingam, E., Urban, T. A., and Goldberg, J. B. (2005) Nat. Rev.
Microbiol. 3, 144 –156
2. Balandreau, J., Viallard, V., Cournoyer, B., Coenye, T., Laevens, S., and
Vandamme, P. (2001) Appl. Environ. Microbiol. 67, 982–985
3. Aaron, S. D., Ferris, W., Henry, D. A., Speert, D. P., and Macdonald, N. E.
(2000) Am. J. Respir. Crit. Care Med. 161, 1206 –1212
4. Raetz, C. R., and Whitfield, C. (2002) Annu. Rev. Biochem. 71, 635–700
5. Caroff, M., and Karibian, D. (2003) Carbohydr. Res. 338, 2431–2447
6. Raetz, C. R., Reynolds, C. M., Trent, M. S., and Bishop, R. E. (2007) Annu.
Rev. Biochem. 76, 295–329
7. Isshiki, Y., Kawahara, K., and Zähringer, U. (1998) Carbohydr. Res. 313,
21–27
8. Silipo, A., Molinaro, A., Cescutti, P., Bedini, E., Rizzo, R., Parrilli, M., and
Lanzetta, R. (2005) Glycobiology 15, 561–570
9. Isshiki, Y., Zähringer, U., and Kawahara, K. (2003) Carbohydr. Res. 338,
2659 –2666
10. Silipo, A., Molinaro, A., Ieranò, T., De Soyza, A., Sturiale, L., Garozzo, D.,
Aldridge, C., Corris, P. A., Khan, C. M., Lanzetta, R., and Parrilli, M. (2007)
Chemistry 13, 3501–3511
11. Molinaro, A., De Castro, C., Lanzetta, R., Evidente, A., Parrilli, M., and
Holst, O. (2002) J. Biol. Chem. 277, 10058 –10063
12. Baird, R. M., Brown, H., Smith, A. W., and Watson, M. L. (1999) Immunopharmacology 44, 267–272
13. Devine, D. A. (2003) Mol. Immunol. 40, 431– 443
14. Sahly, H., Schubert, S., Harder, J., Rautenberg, P., Ullmann, U., Schröder,
J., and Podschun, R. (2003) Antimicrob. Agents Chemother. 47, 1739 –1741
15. Loutet, S. A., Flannagan, R. S., Kooi, C., Sokol, P. A., and Valvano, M. A.
(2006) J. Bacteriol. 188, 2073–2080
16. Burtnick, M. N., and Woods, D. E. (1999) Antimicrob. Agents Chemother.
43, 2648 –2656
17. Cox, A. D., and Wilkinson, S. G. (1991) Mol. Microbiol. 5, 641– 646
18. Mahenthiralingam, E., Coenye, T., Chung, J. W., Speert, D. P., Govan, J. R.,
Taylor, P., and Vandamme, P. (2000) J. Clin. Microbiol. 38, 910 –913
19. Ortega, X. P., Cardona, S. T., Brown, A. R., Loutet, S. A., Flannagan, R. S.,
Campopiano, D. J., Govan, J. R., and Valvano, M. A. (2007) J. Bacteriol.
189, 3639 –3644
VOLUME 284 • NUMBER 32 • AUGUST 7, 2009
Downloaded from http://www.jbc.org/ by guest on May 30, 2020
we have determined for the B. cenocepacia K56-2 heptoseless
mutant SAL16 (15). Thus, the inner core OS is highly conserved
in Burkholderia species.
The panel of isogenic strains with gradual truncations in
their lipid A-core OS allowed us to investigate the relationship
between LPS and the extraordinary resistance of B. cenocepacia
against cationic APs. Although, as it was shown previously with
B. cepacia (49), PmB binds to P. aeruginosa much better than to
B. cenocepacia K56-2, progressive truncation of the lipid
A-core OS leads to increased PmB binding. These findings support the notion that the cell envelope of B. cenocepacia has
unusual characteristics that enable it to act as a barrier against
APs. Although significantly more sensitive than the wild type
strain to PmB, our core mutants are still much more resistant to
PmB than other organisms such as Salmonella and E. coli with
intact core OS. Thus B. cenocepacia must possess additional
mechanisms that make these bacteria extremely resistant to
APs.
Taking advantage of the set of isogenic mutants in B. cenocepacia K56-2 that range from the formation of a full-length LPS
O antigen (parental strain) to a mutant producing heptoseless
lipid A-core OS (CCB1), we also investigated the biological role
of LPS in adhesion to epithelial cells and intracellular survival in
macrophages. Our results demonstrated that O antigen production by B. cenocepacia prevents bacterial adhesion to epithelial cells. This suggests that the O antigen in these bacteria
masks bacterial surface molecules that can interact with epithelial cell receptors, or alternatively, the exposed core OS residues
are themselves ligands for binding. We considered the latter
hypothesis less likely given that all the core OS mutants with
progressive truncations showed increased adhesion, suggesting
that no specific sugar residue is required for adhesion, in contrast to recent observations in other bacteria (50). It has been
previously shown that Bcc isolates can survive intracellularly
within amoebae (51), respiratory epithelial cells (38), and macrophages (39, 40). Others have reported that the LPS O antigen
plays an essential role in internalization and survival of the
related bacterium B. pseudomallei in macrophages (52). Our
data investigating the ability of the various mutants with defects
in lipid A-core OS production to survive intracellularly in macrophages revealed that only the heptoseless mutant CCB1 is
impaired for survival. These results are somewhat surprising
and indicate that the ability of B. cenocepacia to survive in macrophages does not correlate with the level of truncation of the
core OS. B. cenocepacia can resist oxidative (53, 54) and nonoxidative (55) intracellular killing mechanisms, and the latter
mainly depend on APs. Therefore, the intracellular survival of
the other mutants with core OS truncations, despite their
increased sensitivity to PmB in vitro, suggest that either the AP
concentration in BcCVs is not enough to compromise the viability of these mutants or other factors are involved. It is possible that the ability of B. cenocepacia to survive intracellularly is
highly dependent on the stability of the outer membrane cell
envelope, which may be only seriously perturbed in the presence of a drastically truncated lipid A-core OS. This is in agree-
Structure-Function of B. cenocepacia Core Oligosaccharide
AUGUST 7, 2009 • VOLUME 284 • NUMBER 32
183–194
37. Bock, K., Vinogradov, E. V., Holst, O., and Brade, H. (1994) Eur. J. Biochem.
225, 1029 –1039
38. Burns, J. L., Jonas, M., Chi, E. Y., Clark, D. K., Berger, A., and Griffith, A.
(1996) Infect. Immun. 64, 4054 – 4059
39. Saini, L. S., Galsworthy, S. B., John, M. A., and Valvano, M. A. (1999)
Microbiology 145, 3465–3475
40. Lamothe, J., Huynh, K. K., Grinstein, S., and Valvano, M. A. (2007) Cell.
Microbiol. 9, 40 –53
41. Via, L. E., Fratti, R. A., McFalone, M., Pagan-Ramos, E., Deretic, D., and
Deretic, V. (1998) J. Cell Sci. 111, 897–905
42. Maloney, K. E., and Valvano, M. A. (2006) Infect. Immun. 74, 5477–5486
43. Holst, O. (2007) FEMS Microbiol. Lett. 271, 3–11
44. Loutet, S. A., Bartholdson, S. J., Govan, J. R. W., Campopiano, D. J., and
Valvano, M. A. (2009) Microbiology 155, 2029 –2039
45. Masoud, H., Perry, M. B., Brisson, J. R., Uhrin, D., Li, J., and Richards, J. C.
(2009) Glycobiology 19, 462– 471
46. Coenye, T., and Vandamme, P. (2003) Environ. Microbiol. 5, 719 –729
47. Molinaro, A., Lindner, B., De Castro, C., Nolting, B., Silipo, A., Lanzetta,
R., Parrilli, M., and Holst, O. (2003) Chemistry 9, 1542–1548
48. Gronow, S., Noah, C., Blumenthal, A., Lindner, B., and Brade, H. (2003)
J. Biol. Chem. 278, 1647–1655
49. Moore, R. A., and Hancock, R. E. (1986) Antimicrob. Agents Chemother.
30, 923–926
50. Hoare, A., Bittner, M., Carter, J., Alvarez, S., Zaldívar, M., Bravo, D., Valvano, M. A., and Contreras, I. (2006) Infect. Immun. 74, 1555–1564
51. Marolda, C. L., Hauröder, B., John, M. A., Michel, R., and Valvano, M. A.
(1999) Microbiology 145, 1509 –1517
52. Arjcharoen, S., Wikraiphat, C., Pudla, M., Limposuwan, K., Woods, D. E.,
Sirisinha, S., and Utaisincharoen, P. (2007) Infect. Immun. 75, 4298 – 4304
53. Keith, K. E., Hynes, D. W., Sholdice, J. E., and Valvano, M. A. (2009)
Microbiology 155, 1004 –1015
54. Bylund, J., Burgess, L. A., Cescutti, P., Ernst, R. K., and Speert, D. P. (2006)
J. Biol. Chem. 281, 2526 –2532
55. Speert, D. P., Bond, M., Woodman, R. C., and Curnutte, J. T. (1994) J. Infect. Dis. 170, 1524 –1531
56. Lefebre, M. D., and Valvano, M. A. (2002) Appl. Environ. Microbiol. 68,
5956 –5964
JOURNAL OF BIOLOGICAL CHEMISTRY
21751
Downloaded from http://www.jbc.org/ by guest on May 30, 2020
20. Flannagan, R. S., Aubert, D., Kooi, C., Sokol, P. A., and Valvano, M. A.
(2007) Infect. Immun. 75, 1679 –1689
21. Flannagan, R. S., and Valvano, M. A. (2008) Microbiology 154, 643– 653
22. Craig, F. F., Coote, J. G., Parton, R., Freer, J. H., and Gilmour, N. J. (1989)
J. Gen. Microbiol. 135, 2885–2890
23. Figurski, D. H., and Helinski, D. R. (1979) Proc. Natl. Acad. Sci. U.S.A. 76,
1648 –1652
24. Cohen, S. N., Chang, A. C., and Hsu, L. (1972) Proc. Natl. Acad. Sci. U.S.A.
69, 2110 –2114
25. Marolda, C. L., Welsh, J., Dafoe, L., and Valvano, M. A. (1990) J. Bacteriol.
172, 3590 –3599
26. Westphal, O., and Jann, K. (1965) in Methods in Carbohydrate Chemistry
(Whistler, R. L., BeMiller, J. N., and Wolfrom, M. L., eds) pp. 83–91,
Academic Press, New York
27. Schindler, P. R., and Teuber, M. (1975) Antimicrob. Agents Chemother. 8,
95–104
28. Bader, J., and Teuber, M. (1973) Z. Naturforsch. 28, 422– 430
29. Moore, R. A., Bates, N. C., and Hancock, R. E. (1986) Antimicrob. Agents
Chemother. 29, 496 –500
30. Saldías, M. S., Lamothe, J., Wu, R., and Valvano, M. A. (2008) Infect. Immun. 76, 1059 –1067
31. Holden, M. T., Seth-Smith, H. M., Crossman, L. C., Sebaihia, M., Bentley,
S. D., Cerdeño-Tárraga, A. M., Thomson, N. R., Bason, N., Quail, M. A.,
Sharp, S., Cherevach, I., Churcher, C., Goodhead, I., Hauser, H., Holroyd,
N., Mungall, K., Scott, P., Walker, D., White, B., Rose, H., Iversen, P.,
Mil-Homens, D., Rocha, E. P., Fialho, A. M., Baldwin, A., Dowson, C.,
Barrell, B. G., Govan, J. R., Vandamme, P., Hart, C. A., Mahenthiralingam,
E., and Parkhill, J. (2009) J. Bacteriol. 191, 261–277
32. Reeves, P. R., Hobbs, M., Valvano, M. A., Skurnik, M., Whitfield, C., Coplin, D., Kido, N., Klena, J., Maskell, D., Raetz, C. R., and Rick, P. D. (1996)
Trends Microbiol. 4, 495–503
33. Pérez, J. M., McGarry, M. A., Marolda, C. L., and Valvano, M. A. (2008)
Mol. Microbiol. 70, 1424 –1440
34. Ortega, X., Hunt, T. A., Loutet, S., Vinion-Dubiel, A. D., Datta, A.,
Choudhury, B., Goldberg, J. B., Carlson, R., and Valvano, M. A. (2005) J.
Bacteriol. 187, 1324 –1333
35. Birnbaum, G. I., Roy, R., Brisson, J. R., and Jennings, H. J. (1987) J. Carbohydr. Chem. 6, 17–39
36. Holst, O., Thomas-Oates, J. E., and Brade, H. (1994) Eur. J. Biochem. 222,
Biosynthesis and Structure of the Burkholderia cenocepacia K56-2
Lipopolysaccharide Core Oligosaccharide: TRUNCATION OF THE CORE
OLIGOSACCHARIDE LEADS TO INCREASED BINDING AND SENSITIVITY
TO POLYMYXIN B
Ximena Ortega, Alba Silipo, M. Soledad Saldías, Christa C. Bates, Antonio Molinaro
and Miguel A. Valvano
J. Biol. Chem. 2009, 284:21738-21751.
doi: 10.1074/jbc.M109.008532 originally published online June 12, 2009
Access the most updated version of this article at doi: 10.1074/jbc.M109.008532
Click here to choose from all of JBC's e-mail alerts
Supplemental material:
http://www.jbc.org/content/suppl/2009/06/12/M109.008532.DC1
This article cites 55 references, 25 of which can be accessed free at
http://www.jbc.org/content/284/32/21738.full.html#ref-list-1
Downloaded from http://www.jbc.org/ by guest on May 30, 2020
Alerts:
• When this article is cited
• When a correction for this article is posted