From the
Research Center Borstel, Center for
Medicine and Biosciences, Parkallee 22, D-23845 Borstel, Germany, the
||Institute for Biological Sciences, National
Research Council of Canada, Ottawa, Ontario K1A 0R6, Canada, and
**Novartis Pharma AG, CH-4002 Basel, Switzerland
Received for publication, March 21, 2003 , and in revised form, April 23, 2003.
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ABSTRACT |
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INTRODUCTION |
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Antisera against the O-antigens of endotoxins protect against homologous
bacteria. However, the large number of different O-antigens in enterobacteria,
the serotype-restricted specificity of such antisera, and the rapid onset of
shock have prevented their introduction into clinical practice. Whereas the
chemical structure of the O-antigen is highly variable, the core region and
lipid A show only limited structural variability within the enterobacteria.
Following the observation that antibodies against the O-antigen are protective
against homologous bacteria, the search for LPS antibodies with broad
cross-reactivity is a valid concept for the immunotherapy of Gram-negative
sepsis. Many investigators attempted the isolation of antibodies that are
directed against the conserved regions of LPS (i.e. the lipid A and
core region (reviewed in Ref.
7)). Such antibodies have been
presumed to be cross-reactive and cross-protective against different
Gram-negative pathogens. Such a cross-protective effect was described for a
polyclonal antiserum by Braude and Douglas
(8); however, all subsequently
isolated LPS-specific monoclonal antibodies failed to show cross-reactivity
in vitro and cross-protectivity in vivo
(7), with the exception of mAb
WN1 222-5 (9). This mAb bound
to LPS from all tested clinical isolates of Escherichia coli,
Salmonella, and Shigella in Western blots and ELISA and showed
cross-protective effects in vivo against the endotoxic activities of
LPS (9). The smallest LPS
structure bound by WN1 222-5 was found to be present in LPS from E.
coli J-5. Due to the lack of a functional UDP-galactose-4-epimerase
(galE mutant) (10),
this strain is unable to incorporate galactose into its LPS and therefore
produces a truncated LPS consisting of several glycoforms
(Fig. 1). The cross-reactivity
was therefore attributed to a common epitope located in the inner core region
of these LPS (9).
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LPS preparations are heterogenous and there are no methods available for the separation of acylated LPS into homogeneous compounds due to their amphiphilic nature. For this reason, the exact epitope of WN1 222-5 could not be determined using LPS. We have therefore developed methods for the deacylation of these molecules under conditions that do not cleave glycosidic bonds (11) and the purification of LPS oligosaccharides. These oligosaccharides are then amenable to a detailed structural characterization and conjugation to proteins (12, 13).
For J-5 LPS, five different oligosaccharides, which differ in their carbohydrate structures and phosphate substitution (Fig. 1), were obtained by deacylation under strong alkaline conditions (14). The chemical structures of five different E. coli core types (R1 to R4 and K-12) and two chemically distinct core oligosaccharides of S. enterica (2, 1517) are known, and all possess identical inner core structures (Fig. 2). Minor differences in the inner core structures relate to the substitution of the side chain heptose with GlcpN and the concomitant lack of phosphate on the branched heptose residue. Major structural differences between the core types are observed in the outer core region. Identical inner core structures have been described for Shigella species (2).
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Using a panel of highly purified oligosaccharides from Salmonella enterica sv. Minnesota (R1), E. coli F470 (R1 core-type), E. coli F576 (R2 core-type), E. coli F653 (R3 core-type), E. coli F2513 (R4 core-type), and E. coli J-5, shown in Figs. 1 and 2, we have determined the minimal epitope that is recognized by mAb WN1 222-5 by ELISA, ELISA inhibition, isothermal titration microcalorimetry (ITC), and surface plasmon resonance (SPR) and studied the influence of the outer core on the binding of WN1 222-5 to enterobacterial LPS.
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EXPERIMENTAL PROCEDURES |
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Deamination of E. coli J-5 LPSLPS isolated from E. coli J-5 was subjected to a deamination reaction as described by Vinogradov et al. (19). One ml of acetic acid and 200 mg of NaNO2 were added to 200 mg of LPS in 10 ml of water, and after a 12-h incubation at ambient temperature, the deaminated LPS was collected by centrifugation (4 h, 4 °C, 120,000 x g). The precipitate was dissolved in water and dialyzed against deionized water (3x 1 liter, 4 °C) and lyophilized (yield: 149 mg). An aliquot (50 mg) was then de-O- and de-N-acylated, yielding four oligosaccharides, which were isolated by semipreparative HPAEC and gel filtration as described above (oligosaccharide (OS) 1, 4.2 mg; OS 2, 1.8 mg; OS 3, 2.3 mg; OS 4, 0.8 mg).
NeoglycoconjugatesNeoglycoconjugates of deacylated oligosaccharides were prepared as described (20). Briefly, ligands (2.5 mg) were dissolved in 200 µl of 50 mM carbonate buffer, pH 9.2; glutardialdehyde (25%, electron microscopy grade; Merck) was added (1% final concentration); and the sample was stirred for 4 h at 25 °C under N2 atmosphere. Excess glutardialdehyde was removed by lyophilization, and the samples were redissolved in 200 µl of water. BSA (2.5 mg) was added from a 10 mg ml1 solution in 50 mM carbonate buffer, pH 9.2, and the mixture was incubated overnight at 25 °C. Finally, 250 µg of NaBH4 was added, and the samples were incubated for 1 h at 4 °C in the dark followed by dialysis against water once and three times against PBS, pH 7.2.
mAb WN1 222-5The generation and selection of mAb WN1 222-5 has been described in detail previously (9). Stock solutions of affinity purified mAb were kept at20 °C in aliquots (1 mg ml1).
ELISABinding of mAb WN1 222-5 to the neoglycoconjugates was determined by ELISA. Varying amounts of glycoconjugates were coated onto 96-well microtiter plates (Nunc, Maxisorb) and tested against serial dilutions of antibody. Antibody binding was detected with enzyme-conjugated anti-mouse IgG and substrate and measured photometrically at 405 nM. Experiments were done in quadruplicate, and mean values were calculated. Confidence values did not exceed 10%. Binding of the mAb WN1 222-5 to fully acylated LPS was determined using LPS as a solid phase antigen instead of neoglycoconjugates (21).
For ELISA inhibition, serial dilutions of inhibitor in PBS-Tween 20/casein/BSA (30 µl) were mixed in V-shaped microtiter plates (NUNC) with an equal volume of antibody diluted in the same buffer to give an A405 of 1.0 without the addition of inhibitor. After incubation (15 min, 37 °C), 50 µl of the mixture were added to antigen-coated ELISA plates. Further steps were as described above. All measurements were done at least twice in duplicate with confidence values not exceeding 20%.
Surface Plasmon ResonanceAnalyses were performed with a
BIA-CORE 3000 instrument (Biacore, Inc.). WN1 222-5 was immobilized on a CM5
sensor chip (Biacore) at a surface density of 20,000 RU using the amine
coupling kit from Biacore. Analyses were carried out at 25 °C in 10
mM HEPES, pH 7.4, containing 3 mM EDTA, 0.005% P-20, and
150 mM or 300 mM NaCl. Surface regeneration was not
necessary. Data were evaluated using the BIAevaluation 3.0 software
(Biacore).
Isothermal Titration MicrocalorimetryMicrocalorimetric experiments were performed on an MCS isothermal titration calorimeter (Microcal Inc., Northampton, MA). mAb WN1 222-5 was dialyzed against PBS, pH 7.2, and the concentration was determined by UV measurement (1 mg ml1 = A280 of 1.35). The mAb concentration was adjusted to 7.55 µM, assuming a molecular mass of 150 kDa, and the microcalorimeter cell was filled with the antibody solution (volume = 1.3 ml). Purified and desalted deacylated LPS oligosaccharide were dissolved at a concentration of 0.35 mM in dialysis buffer and loaded into the syringe of the microcalorimeter. Both solutions were thoroughly degassed prior to loading. After temperature equilibration, the ligand was injected into the cell in 5-µl portions, and the evolved heat was measured with the first injection not considered for data analysis. A total of 20 injections were performed with 5-min equilibration times between injections. Data were corrected for heat of dilution by measuring the same number of buffer injections and subtraction from the sample data set. Dissociation constants were determined using the MicroCal Origin version 2.9 analysis software and the model of 1 set of binding sites. The antibody concentration in the cell was corrected after the curve fitting as described in the ITC Data Analysis in the Origin Version 2.9 manual provided by the manufacturer.
Nuclear Magnetic Resonance1H (600.12 MHz), 13C (150.13 MHz), and 31P (242.13 MHz) NMR spectra were recorded with a Bruker DRX Avance spectrometer with a 4-mg sample in 0.5 ml of D2O. Acetone (2.225 ppm) (1H) and dioxane (67.4 ppm) (13C) served as references. All spectra were run at a temperature of 300 K. One-dimensional 1H, 13C, and 31P and two-dimensional homonuclear 1H,1H (DQF-COSY, NOESY, TOCSY), heteronuclear 1H,13C, and 1H,31P NMR correlation spectra (HMQC) were recorded using Bruker standard pulse programs and analyzed with Bruker Xwinnmr software.
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RESULTS |
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ELISA with LPS and Complete Core StructuresIt was previously shown that WN1 222-5 binds to whole cells of E. coli and S. enterica and to the LPS of these bacteria in Western blots and passive immunohemolysis (9). The minimal LPS structure bound by WN1 222-5 was the LPS of the rough mutant strain E. coli J-5. To verify this reactivity by ELISA, we first immobilized LPS of E. coli core types R1 to R4 and S. enterica sv. Minnesota on microtiter plates and investigated their reactivity with mAb WN1 222-5 (Fig. 6A). The antibody reacted with all of these LPS. We then investigated whether the lipid A was important for the binding and studied the inhibitory activities of deacylated LPS oligosaccharides by ELISA inhibition. When LPS was treated with mild acid, the mixture of E. coli R3 deacylated LPS oligosaccharides did not show any inhibitory activity up to the concentration tested (5 µg/well; see Table III). On the contrary, oligosaccharides from the same LPS obtained by deacylation under alkaline conditions, which retained the lipid A backbone sugars and the side chain Kdo substitution, possessed inhibitory activity (50% inhibition at 20 ng/well). Therefore, fatty acids did not influence the binding and were not part of the WN1 222-5 epitope. As can be seen in Fig. 6B, mAb WN1 222-5 bound to all tested BSA-neoglycoconjugates of E. coli LPS obtained after alkaline deacylation to the same extent as to LPS. All further experiments were therefore done with oligosaccharides obtained after alkaline deacylation.
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It is known that LPS from E. coli F470 and F653 (R1 and R3 core,
respectively) contain core structures in which the side chain heptose is
substituted by GlcpN via an -1
7 linkage
(15,
16). Concomitantly, the
phosphate at the second heptose is missing in these molecules
(16). In order to investigate
the influence of these structural variations on the binding of mAb WN1 222-5,
we have purified these oligosaccharides and prepared neoglycoconjugates
thereof. These did not bind to WN1 222-5 in ELISA (data not shown), indicating
that either the lack of phosphate substitution at this position, the
substitution of the side chain heptose by GlcpN, or both influence
binding by WN1 222-5. These results were confirmed by ELISA inhibition (see
Table III), where the complete
core oligosaccharide 2 of E. coli F653 (R3 core containing the
GlcpN side chain substitution) was unable to inhibit the interaction
between WN1 222-5 and the R3 core oligosaccharide 1 (without GlcpN in
the core). It was found that the core oligosaccharide of E. coli F576
(R2 core) was the best inhibitor in this system.
ELISA with J-5 Core OligosaccharidesAiming at the identification of the minimal epitope required for the binding of WN1 222-5, we have conjugated each of the oligosaccharides obtained from E. coli J-5 LPS and the newly prepared octasaccharide 1 P3 to BSA using glutardialdehyde coupling (20). The octasaccharide 1 P3 conjugate was included to elucidate the importance of phosphate substitution and side chain heptose substitution with GlcpN for antigen binding by WN1 222-5. The neoglycoconjugates were immobilized on ELISA plates, and the reactivity was tested with mAb WN1 222-5. As shown in Fig. 7, mAb WN1 222-5 did not bind to nonasaccharide P3 and heptasaccharide P3, whereas intermediate binding to heptasaccharide P4 and octasaccharide 1 P3 was observed. The highest affinity was observed for the interaction of WN1 222-5 and octasaccharide P4.
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In ELISA inhibition (see Table III), nonasaccharide P3 and heptasaccharide P3 were both unable to inhibit the interaction between WN1 222-5 and the R3 core-oligosaccharide 1 (without GlcpN in the core), whereas heptasaccharide P4 and octasaccharide 1 P3 showed inhibitory activity, yielding 50% inhibition values at concentrations of 15 and 3.6 µM, respectively. Octasaccharide P4 was the best inhibitor among the J-5 oligosaccharides and showed an inhibitory activity comparable with the homologous R3 oligosaccharide 1.
Affinity and Kinetic Constants Determined by SPR and MicrocalorimetryIn order to gain a deeper insight into the kinetics and affinities of the binding, we performed SPR and isothermal titration microcalorimetry analyses of the binding of core oligosaccharides to WN1 222-5. For SPR, WN1 222-5 was immobilized, and purified oligosaccharides were used as analytes at different concentrations. Although three of the J-5 oligosaccharides are known to bind to WN1 222-5 (Fig. 7), interactions were not observed by SPR in buffer containing the standard NaCl concentration of 150 mM. Binding of the J-5 oligosaccharides was observed only when the NaCl concentration was increased to 300 mM. The complete core oligosaccharides bound to WN1 222-5 at both salt concentrations but gave different KD values at different salt concentrations. Surprisingly, the affinities were higher at 300 mM NaCl, and this was due to faster on-rates; the off-rates remained essentially unchanged. The affinities were 0.625-fold higher at 300 mM NaCl in comparison with those obtained at 150 mM NaCl (Table II). At 150 mM NaCl, measurements were only possible at a low flow rate of 5 µl/min due to matrix effects. Measurements at 300 mM NaCl allowed higher flow rates without changes of the matrix, reducing the risk of mass transport limitations. Global fitting of the data collected at both salt concentrations deviated only slightly from a 1:1 interaction model (Fig. 8). With most of the oligosaccharides, equilibrium data were collected for derivation of KD values by Scatchard analysis (Fig. 9; Table II).
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In view of the discrepancies in the SPR results, we determined the KD value of the interaction of WN1 222-5 with the R4 core oligosaccharide by isothermal titration microcalorimetry at both salt concentrations (Fig. 10). The KD values were determined to be 48 nM at 150 mM NaCl and 74 nM at 300 mM NaCl (Table II), thus indicating stronger binding than determined by SPR (KD = 290 nM by SPR). In order to verify that the relative affinities measured by microcalorimetry were the same as by SPR, we also determined the binding of the E. coli R2 and R3 core oligosaccharides; the relative affinities were the same as determined by SPR at 300 mM NaCl. The molecule that bound most strongly in microcalorimetry and SPR measurements was the E. coli R2 core oligosaccharide; the KD values determined by SPR and microcalorimetry were 32 nM (calculated based on kon = 1.4 x 105 m1 s1 and koff = 4.6 x 103s1) and 5.5 nM, respectively.
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At 300 mM NaCl, the KD values determined by SPR for the E. coli J-5 oligosaccharides confirmed the results obtained by ELISA. Thus, octasaccharide P4 showed the highest affinity with a KD of 950 nM. Nonasaccharide P3 and heptasaccharide P3 bound only poorly, with KD values of 36 and 33 µM, respectively. An intermediate affinity was determined for octasaccharide 1 P3 with a KD of 2.8 µM.
Comparing the SPR KD values on a relative basis with the E. coli R3 core oligosaccharide revealed that the core oligosaccharides with an outer core all bound more tightly to WN1 222-5 than the smaller core oligosaccharides of the mutant E. coli J-5. Whereas octasaccharide P4 was the best binder among the latter, it showed only a relative affinity of 38% in comparison with the complete core oligosaccharide of the homologous chemotype R3. By far the best binding oligosaccharide was the complete core oligosaccharide of the R2 chemotype with an 11-fold higher affinity than the E. coli R3 core oligosaccharide.
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DISCUSSION |
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A detailed epitope analysis requires the separation of individual LPS
components, which is so far not possible for acylated LPS due to their
amphiphilic nature. For this reason, LPS is commonly deacylated, and this can
be achieved in two ways. Mild acid treatment of LPS can be applied for the
cleavage of the acid-labile Kdo-lipid A linkage. The insoluble lipid A can
then be removed by centrifugation, and LPS oligosaccharides are obtained.
However, oligosaccharides prepared in this way lose the lipid A backbone
sugars and also the side chain Kdo residue. Such oligosaccharides did not bind
to WN1 222-5 in ELISA inhibition (Table
III). By contrast, oligosaccharides that were obtained by
deacylation under alkaline conditions and still contained the intact lipid A
backbone and the Kdo region did bind to WN1 222-5 and thus revealed that fatty
acids are not part of the epitope. Therefore, it was possible to use such
oligosaccharides after purification in SPR, ITC microcalorimetry, and
inhibition test systems and as neoglycoconjugates in ELISA. The analysis in
these binding assays revealed that the epitope bound by WN1 222-5 lies in the
junction between the inner and the outer core of these LPS and is composed of
the structural element
-D-Glcp-(1
3)-[L-
-D-Hepp-(1
7)]-L-
-D-Hepp
4P-(1
, which is common to LPS from E. coli, Salmonella, and
Shigella (2). LPS
molecules that are devoid of the side chain heptose, as in the heptasaccharide
P4 of E. coli J-5, or the phosphate at
the second heptose, as in octasaccharide 1 P3,
have affinities that are 21- and 3-fold lower, respectively, than that
observed for the complete epitope. Molecules that lack phosphate at the
branched heptose and the side chain heptose, such as heptasaccharide
P3, or in which the side chain heptose is masked
by GlcpN substitution, such as nonasaccharide
P3, are not recognized by WN1 222-5. From these
data, it is evident that the most important contributions to the binding come
from the side chain heptose and the phosphate at the 4-position of the
branched heptose. Furthermore, either the lipid A backbone, the side chain
Kdo, or both are necessary for WN1 222-5 reactivity. The contribution of the
Glcp-residue adjacent to the branched heptose at position 3 cannot be
evaluated, because rough mutants that cannot incorporate Glc at this position
are also devoid of the side chain heptose
(22). We have unsuccessfully
attempted to remove the terminal Glc of octasaccharide
P4 using
-glucosidases.
The presence of the outer core sugar residues does not inhibit the
reactivity but on the contrary has a positive influence on the affinities.
Thus, WN1 222-5 possesses the highest affinity for deacylated LPS from E.
coli F576 (R2 core) with an affinity constant
(KD) of 3.2 x
108 M determined by SPR. The
interaction with LPS of other E. coli core types was reduced about
5-fold for the R1 and 10-fold for the R3 and R4 core oligosaccharide. In
comparison with octasaccharide P4
(KD = 9.5 x
107 m), which was the best binding molecule
derived from E. coli J-5, the affinities of molecules possessing an
outer core were 35-fold higher and even 29-fold higher for the
E. coli R2 core oligosaccharide. The reason for the higher affinity
of the R2 core oligosaccharide may be the
-1
6-Galp-substitution at the Glcp residue,
which is attached to the branched heptose
(Fig. 2). Whether this residue
is involved in a direct interaction or has an influence on the conformation of
the neighboring sugars cannot be determined at this stage.
Why oligosaccharides without the lipid A backbone and side chain Kdo are not bound by WN1 222-5 must remain undetermined at this stage. One explanation could be that a conformational epitope is formed by sugars of the lipid A, Kdo residues, and the heptoses, and parts of these sugars are involved in a direct interaction with the antibody. We (16) and others (15) have recently described NMR data that indicate a conformational proximity of the side chain heptose and the inner Kdo, which may explain the dependence of binding on the intact inner core. A direct interaction of these sugars with WN1 222-5 in the combining site, however, seems unlikely, in the light of results obtained by crystallization of antibodies in complex with carbohydrate antigens (23, 24). In such complexes, it has been observed that even of a polysaccharide not more than a trisaccharide epitope is accommodated in the antibody combining site, and a single sugar is buried in a deep pocket involved in tight interactions with the antibody. It seems therefore unlikely that the distal sugars of the lipid A backbone are involved in the interaction. Molecular modeling calculations indicated a compact conformation of the Kdo residues and the lipid A based on ionic interactions between the lipid A phosphates and carboxylic groups of the Kdo (25). It may therefore be that the removal of the lipid A and/or the side chain Kdo translates into conformational changes of other core sugars further away. In this case, the Kdo and lipid A sugar residues would not be directly involved in the interaction but would influence the binding to WN1 222-5. Experimental evidence may come from the observation that NMR chemical shift values of the anomeric protons of the heptoses significantly change in octasaccharide 2 P3 of E. coli J-5, where the side chain Kdo is missing (14).
The dramatic effect of ionic strength on the affinities of the WN1 222-5
interaction with various oligosaccharides as determined by SPR highlights the
importance of not relying on a single technique for analysis of molecular
interactions. It is presumed that the salt effect observed with the SPR
analyses relates to the carboxylated dextran matrix on CM5 sensor chips. The
negatively charged matrix must in some way interfere with the binding of
highly negatively charged oligosaccharides with WN1 222-5. At 150
mM NaCl, measurements were only possible at a low flow rate of 5
µl min1, increasing risk of mass transport
limitations. Nevertheless, at this flow rate, high quality data sets were
obtained, and the almost perfect fit excluded the possibility that mass
transport compromised the data. Measurements at 300 mM NaCl allowed
data collection at higher flow rates and gave lower
KD values relative to the 150 mM NaCl
data. However, the KD values were still
10-fold higher than those obtained by microcalorimetry. These results
suggest that the negatively charged matrix on Biacore sensor chips may present
a problem with highly negatively charged analytes such as LPS core
oligosaccharides. However, a comparison of the SPR data, the microcalorimetry
data, and the inhibition ELISA data indicated that ranking, by SPR, of
analytes with respect to binding affinities is valid.
It has been shown that WN1 222-5 can protect mice from death in an
experimental model of septic shock and that this mAb reduces the levels of
proinflammatory cytokines such as tumor necrosis factor- and
interleukin-1, which are the key mediators of septic shock, upon LPS
stimulation in whole blood
(26). The underlying mechanism
of the protective effect is probably the removal of endotoxin from the
circulation, preventing LPS-responsive cells from stimulation. However, since
macrophages are one of the prime sources of proinflammatory cytokines, it is
not known why LPS bound to WN1 222-5 is unable to stimulate their release, in
particular since the biologically active component is the lipid A portion of
LPS, and fatty acids are not part of the epitope, which would explain the
protective effect.
Many of the studies aimed at the induction of cross-reactive antibodies
have used E. coli J-5 or bacteria producing Re-type LPS (E.
coli F515, S. enterica sv. Minnesota R595), which contain only
an 2
4-Kdo disaccharide attached to the lipid A. All of these
attempts failed, which is now understood. In smooth-type LPS, which is the
main form in wild-type E. coli bacteria, the presence of the
O-antigen and further sugars of the inner and outer core probably mask the Kdo
and lipid A part of the molecule, which are therefore inaccessible for
antibodies. In LPS from E. coli J-5, octasaccharide
P4, the molecule with the highest affinity,
accounts for only 25% of the LPS
(14). All other molecules
possess either severely reduced or very low affinities. Therefore,
immunization with E. coli J-5 bacteria or LPS may not lead to the
induction of cross-reactive antibodies that recognize the epitope commonly
present in E. coli, Salmonella, and Shigella LPS. Also, it
may be speculated that antibodies raised by immunization with E. coli
J-5 LPS are either specific for this type of LPS or are inhibited by the
presence of outer core sugars.
WN1 222-5 was isolated by immunization of mice with a combination of LPS of all different E. coli core types and then selected for cross-reactivity (9). The antibody is therefore able to recognize its epitope in the presence of an outer core, which has a positive effect on the interaction and results in a higher affinity. A strategy aimed at the induction of cross-reactive antibodies by vaccination with conjugated LPS of the E. coli F576 (R2 core) is recommended, since WN1 222-5 showed the highest affinity for this structure in all assays employed in this study.
The conjugation of bacterial polysaccharides and LPS is of special interest, because such neoglycoconjugates are promising candidates for safe and immunogenic conjugate vaccines (2729). The conjugation to proteins transforms T-cell-independent polysaccharide antigens into T-cell-dependent antigens leading to B-cell memory and thus improvement of the immune response on repeated immunizations. Such conjugate vaccines are currently in use or being tested in clinical trials for Hemophilus influenzae type b, Neisseria meningitidis, and Streptococcus pneumoniae (28). The successful use of the H. influenzae type b vaccine has prompted several studies that are currently under way for several other bacterial pathogens such as Shigella and Vibrio cholerae O139 (29). The finding that deacylated LPS of the different E. coli and S. enterica when conjugated to protein react equally well with mAb WN1 222-5 like whole LPS and bacteria opens the way for vaccine development. The isolation and characterization of oligosaccharides bound by WN1 222-5 and the identification of the epitope recognized provides the basis for further experiments aimed at the characterization of this interaction by NMR such as saturation transfer difference measurements (30) or by x-ray crystallography. Such experiments would lead to a deeper understanding of this interaction and, combined with conformational analysis of endotoxic molecules, eventually to the rational design of a vaccine based on a single oligosaccharide structure protective against infections and septic shock from different Gram-negative pathogens such as E. coli, Salmonella, Shigella, and Citrobacter.
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FOOTNOTES |
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Both authors contributed equally to this work.
¶ To whom correspondence should be addressed: Research Center Borstel, Center for Medicine and Biosciences, Parkallee 22, D-23845 Borstel, Germany. Tel.: 49-4537-188 (ext. 467); Fax: 49-4537-188 (ext. 419); E-mail: sml{at}fz-borstel.de.
1 The abbreviations used are: LPS, lipopolysaccharide; DQF-COSY, double
quantum-filtered correlation spectroscopy; Glcp, glucopyranose;
GlcpN, 2-amino-2-deoxy-glucopyranose,
L--D-Hepp,
L-glycero-
-D-manno-heptopyranose;
HMQC, heteronuclear multiple quantum correlation; HPAEC, high performance
anion exchange chromatography; ITC, isothermal titration microcalorimetry;
Kdo, 3-deoxy-
-D-manno-oct-2-ulopyranosonic acid;
SPR, surface plasmon resonance; NOESY, nuclear Overhauser effect spectroscopy;
TOCSY, total correlation spectroscopy; ELISA, enzyme-linked immunosorbent
assay; BSA, bovine serum albumin.
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ACKNOWLEDGMENTS |
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REFERENCES |
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