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Journal of Bacteriology, June 2005, p. 4198-4206, Vol. 187, No. 12
0021-9193/05/$08.00+0     doi:10.1128/JB.187.12.4198-4206.2005
Copyright © 2005, American Society for Microbiology. All Rights Reserved.

A Second Outer-Core Region in Klebsiella pneumoniae Lipopolysaccharide

Departamento de Microbiología i Parasitología Sanitarias, Facultad de Farmacia, Universidad de Barcelona, Av. Joan XXIII s/n, 08028 Barcelona, Spain,¹ Departamento de Microbiología, Facultad de Biología, Universidad de Barcelona, Diagonal 645, 08028 Barcelona, Spain,² Dipartimento di Chimica Organica e Biochimica, Università Federico II di Napoli, Complesso Universitario Monte S. Angelo, Via Cintia 4, 80126 Napoli, Italy,³ Applied Biosystems, Frankfurter Strasse 129B, 64293 Darmstadt, Germany⁴

Received 28 February 2005/ Accepted 11 March 2005

	ABSTRACT

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Up to now only one major type of core oligosaccharide has been found in the lipopolysaccharide of all Klebsiella pneumoniae strains analyzed. Applying a different screening approach, we identified a novel Klebsiella pneumoniae core (type 2). Both Klebsiella core types share the same inner core and the outer-core-proximal disaccharide, GlcN-(1,4)-GalA, but they differ in the GlcN substituents. In core type 2, the GlcpN residue is substituted at the O-4 position by the disaccharide ß-Glcp(1-6)--Glcp(1, while in core type 1 the GlcpN residue is substituted at the O-6 position by either the disaccharide -Hep(1-4)--Kdo(2 or a Kdo residue (Kdo is 3-deoxy-D-manno-octulosonic acid). This difference correlates with the presence of a three-gene region in the corresponding core biosynthetic clusters. Engineering of both core types by interchanging this specific region allowed studying the effect on virulence. The replacement of Klebsiella core type 1 in a highly type 2 virulent strain (52145) induces lower virulence than core type 2 in a murine infection model.

	INTRODUCTION

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Lipopolysaccharide (LPS) is the major inmunodominant antigen in gram-negative bacteria. In the LPS of Enterobacteriaceae, three domains are recognized: the highly conserved and hydrophobic lipid A; the hydrophilic and highly variable O antigen; and the core, connecting lipid A and O antigen. The core domain is usually divided into inner and outer core. The inner core is highly conserved within the Enterobacteriaceae, but the outer core shows an increasingly recognized variability. The difference in variability among the three LPS domains has been attributed to the degree of exposure to the selective pressure of the environment where these cells live. The contribution to Enterobacteriaceae pathogenicity of lipid A and O antigen has been well studied, but so far little is known about the role of the core domain (30).

A possible role in pathogenesis or in adaptation to several body sites is suggested by the prevalence of some core types within clinical isolates. Thus, in Escherichia coli, there are five known core types (K-12, R1, R2, R3, and R4). All are found among commensal isolates (1), whereas the R1 and R3 types predominate among strains causing extraintestinal infections (2, 14) and verotoxigenic strains (8), respectively. Similarly, in Salmonella enterica two core types are known: the Typhimurium type predominates among isolates from human infections, whereas Arizonae IIIA predominates in other Salmonella enterica subspecies (30).

By contrast, no such core variability has been detected in other Enterobacteriaceae, such as Klebsiella pneumoniae (32). In this bacterial species, one major core structure has been found but with variation in the extent of nonstoichiometric substituents (Fig. 1A) (37, 40, 42); and so far, no differences in the core biosynthesis gene cluster (waa) (32) have been described among different K. pneumoniae isolates. However, differences in reactivity with a core-specific monoclonal antibody (38) suggest that there could be more than one major core type among K. pneumoniae isolates. K. pneumoniae is an important cause of nosocomial infections (10) at almost all body sites but with highest incidence in the urinary and respiratory tracts. Thus, it would not be surprising that different K. pneumoniae isolates could have different core LPS types related to preferred body site infection.

View larger version (16K): [in this window] [in a new window]   FIG. 1. K. pneumoniae oligosaccharide (OS) core LPS structures. (A) Type 1 core (40, 42). Depending on the K. pneumoniae strain, residues J and K could be H or GalA, and residue P could be H or Hep. Broken lines denote the truncation level for the different core biosynthetic gene mutations (12, 18-20, 32). (B) Type 2 core found in K. pneumoniae 52145 (O1:K2). Oligosaccharides OS1 and OS2 from K. pneumoniae 52145 waaL mutant LPS obtained by complete O and N deacylation under alkaline conditions and mild acid hydrolysis, respectively. Letters denoting OS1 and OS2 residues are the same used in Fig. 4 and 5 (also Tables S2 and S3 in the supplemental material). Kdop, L,D-Hepp, Glcp, GlcNp, and GalAp.

	MATERIALS AND METHODS

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Bacterial strains, plasmids, and growth conditions. Bacterial strains and plasmids used in this study are shown in Table 1. All strains were grown in LB broth and LB agar (24). LB media were supplemented with kanamycin (50 µg ml^–1), ampicillin (100 µg ml^–1), chloramphenicol (20 µg ml^–1), and tetracycline (25 µg ml^–1) when needed.

LPS isolation and electrophoresis. To isolate LPS from the K. pneumoniae 52145 waaL mutant, the strain was grown in LB. LPS was extracted from dry cells (11.8 g) by the phenol-chloroform/light petroleum ether method (13), with a yield of 2.86% of the bacterial dry mass. For screening purposes, LPS was obtained after proteinase K digestion of whole cells (17). LPS samples were separated by sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis (PAGE) or SDS-Tricine-PAGE and visualized by silver staining as previously described (29, 39).

Preparation of oligosaccharides. The LPS (50 mg) was hydrolyzed in 1% acetic acid (100°C, 60 min), and the precipitate was removed by centrifugation (8,000 x g, 30 min) and lyophilized to give lipid A (22 mg; 44% of LPS). The supernatant was evaporated to dryness, dissolved in water, and lyophilized (13 mg, 26% of LPS). Another fraction of LPS (200 mg) was first O delipidated by mild hydrazinolysis and then dephosphorylated with HF, reduced with NaBH₄, and finally N delipidated by an alkaline hydrolysis with KOH as reported previously (7). The oligosaccharides were purified from salts by gel filtration chromatography on a Sephadex G10 column (Pharmacia), giving after lyophilization a residue of 25 mg.

Glycosyl and lipid analysis. A sample (1 mg) of LPS was dried over P₂O₅ overnight and treated with 1 M HCl-CH₃OH (1 ml) to obtain fatty acid methylesters and methylglycoside derivatives as reported previously (17).

Determination of absolute configuration of monosaccharides. To determine the absolute configuration of galacturonic acid, glucosamine, and glucose, a sample of LPS (2 mg) was treated with 1 M HCl-MeOH (500 µl) for 20 h at 80°C. The sample was then hydrolyzed with a mixture of 2 M H₂SO₄-AcOH and derivatized as acetylated octyl glycosides as described previously (21).

Methylation analysis. The alditol oligosaccharide mixture was N acetylated by dissolving a sample (2 mg) in dry methanol and treating it with 50 µl of acetic anhydride for 16 h. After evaporation of the solvents, the sample was methylated as reported previously (4). Linkage analysis was performed as follows: the methylated sample was reduced and carboxymethylated with lithium triethylborodeuteride (Super-Deuteride, Aldrich), subjected to mild acid hydrolysis to cleave ketosidic linkage, reduced again with NaBD₄, and then totally hydrolyzed, reduced with NaBD₄, and finally acetylated as described previously (11).

Gas chromatography-MS analysis. An Agilent Technologies 5973N mass spectrometry (MS) instrument equipped with a 6850A gas chromatography and an RTX-5 capillary column (Restek, 30 m by 0.25 inside diameter; flow rate, 1 ml min^–1; He as carrier gas) was used for analysis of alditol acetates and methyl glycoside acetates as previously described (17). Analysis of acetylated octyl glycosides was performed as follows: 150°C for 5 min, 150°C240°C at 6°C min^–1, 240°C for 5 min.

Nuclear magnetic resonance (NMR) spectroscopy. Spectra were recorded on a Varian Inova 500 spectrometer equipped with a reverse probe at 25°C. ¹³C and ¹H chemical shifts were measured in D₂O using acetone, at 2.225 and 31.4 for proton and carbon, respectively, as an internal standard. Two-dimensional homo- and heteronuclear experiments (correlation spectroscopy [COSY], heteronuclear multiple bond correlation [HMBC], heteronuclear single quantum coherence [HSQC], HSQC-distortionless enhancement by polarization transfer spectroscopy [DEPT], HSQC-total correlation spectroscopy [TOCSY], rotating-frame nuclear Overhauser enhancement spectroscopy [ROESY], and TOCSY) were performed using standard pulse sequences available in the Varian software.

Mass spectrometry studies. The matrix-assisted laser desorption ionization-time of flight (MALDI-TOF) mass spectrum was obtained on the Applied Biosystems 4700 proteomics analyzer with TOF/TOF optics. Calibration was done in positive mode on a peptide (Glu-fibrinopeptide) and used also in negative mode. The energy of laser was set to 4,900 in MS mode. The matrix was 2,5-dihydroxybenzoic acid at 25 mg m^–1 in 20% acetonitrile in water. Spectra were acquired in negative mode.

K. pneumoniae mutant construction. To obtain K. pneumoniae mutant strains with defects in core LPS, chromosomal in-frame nonpolar waa deletions were made (22). Sets of four primers (see Table S1 in the supplemental material), designed from the K. pneumoniae 52145 waa gene cluster sequence, were used in PCR DNA fragment amplifications to create the waa gene deletions. These constructs were subcloned in a suicide plasmid vector, pKO3 (22). The suicide plasmid derivatives obtained were used to introduce each mutation into wild-type K. pneumoniae strains by double recombination, as previously described (22).

Mutant complementation studies. To complement the constructed mutants, each of the waa genes from K. pneumoniae strains C3 and 52145 were PCR amplified using pairs of specific primers (see Table S1 in the supplemental material). The amplified fragments were ligated to the vector pGEM-T. The recombinant plasmids were introduced into the mutants by electroporation, and the core LPS characteristics were studied.

Fifty-percent lethal dose (LD₅₀). Albino Swiss female mice (5 to 7 weeks old; Harlan Ibérica, S.L.) were injected intraperitoneally with 0.2 ml of the test samples (from 10⁸ to 10³ CFU ml^–1). Mortality was recorded up to 7 days.

Dot blot hybridization. The two DNA probes A and B used consisted of the digoxigenin-labeled PCR amplification products of strains C3 and 52145 produced with the DIG DNA labeling and detection kit (Boehringer, Mannheim, Germany). The 2,264-bp probe A, containing the strain C3 genes wabI, waaL, and wabJ, was obtained using primers WaaLOR and WaaLOF. The 2,267-bp probe B, containing the strain 52145 genes wabK, waaL, and wabM, was obtained by using primers ORF5.A and ORF5.D (see Table S1 in the supplemental material for primer sequence). Cell lysates were obtained by resuspending the cells of a 500-µl overnight culture in LB in 100 µl of 0.4 M NaOH and heating it for 30 min at 80°C. One microliter of cell lysate was blotted on a Hybond membrane and bound by UV cross-linking. Hybridization was done following standard protocols (34) with stringent washing at 65°C in 0.2x SSC (20x SSC is 3 M NaCl plus 0.3 M sodium citrate, pH 7.0). Probe that remained bound to homologous sequences was detected with the DIG DNA labeling and detection kit following the supplier's instructions.

	RESULTS

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Evidence for a second major core LPS type in K. pneumoniae. Differences in reactivity with a core-specific monoclonal antibody among K. pneumoniae isolates (38) suggested the existence of different cores. A previous approach based on PCR amplification of genomic DNA fragments using K. pneumoniae C3-specific primers failed to detect any variability in the core LPS biosynthetic gene cluster (waa) from different K. pneumoniae strains (32). This failure could be due to the use of primers matching conserved regions shared by different putative K. pneumoniae waa gene clusters. Bacteriophage FC3-10 infects K. pneumoniae C3 and other strains using the core LPS as a receptor (5). Some naturally resistant strains became sensitive owing to mutations that interfere with O- and/or K-antigen biosynthesis, suggesting that these antigens might hinder the interaction between the phage and the core. By contrast, several K. pneumoniae strains, such as 52145, remained FC3-10 resistant after the introduction of these mutations. The strain C3 core LPS is of the K. pneumoniae core type 1. Thus, we reasoned that phage FC3-10-resistant K. pneumoniae strains that did not revert to phage sensitivity upon mutations precluding O- and/or K-antigen production might possess a different LPS core type.

A collection of K. pneumoniae strains from our laboratory and their O^–, K^–, and O^– K^– derivatives were screened for phage FC3-10 resistance. The LPS from K. pneumoniae FC3-10-resistant strains was extracted and compared to LPS from K. pneumoniae-sensitive strains that produce the classical core LPS by SDS-Tricine-PAGE. Some of these strains, such as 52145, showed LPS molecules with a slightly different pattern of gel migration. These differences in gel migration suggested differences in core LPS structure.

To test this hypothesis, strain 52145 was chosen for further study. Genomic DNA from strain 52145 was isolated and used in PCR amplification experiments using sets of primer pairs designed from the K. pneumoniae C3 waa gene cluster sequence. All but one of the primer pairs used allowed the amplification of DNA fragments of the same size as those of the C3 gene cluster. The primer pair WaaLOR-WaaLOF failed to generate DNA amplification using 52145 genomic DNA as template. This primer pair amplifies a DNA region containing the O-antigen ligase gene waaL and its two flanking genes when using strain C3 genomic DNA as a template, suggesting that there could be significant differences between the waa gene clusters of strains 52145 and C3.

K. pneumoniae 52145 waa gene cluster analysis. The nucleotide sequence of the whole waa gene cluster from strain 52145 was determined in two steps. First the nucleotide sequence of the successfully amplified DNA fragments from the strain 52145 genome, using primer pairs S₇-Nih5.A5, Nuk1-Kor, Nuk5-Nuk8, and Nuk7-Nuk10 (Fig. 2), was determined. Second, sequence-derived primers were used for further PCR amplification and sequence determination to close the sequenced gaps. Analysis of the data obtained revealed homologues of the reported strain C3 genes encoding L,D-heptose epimerase (hldD), heptosyltransferases I, II, and III (waaC, waaF, and waaQ), 3-deoxy-D-manno-oct+ulosonic acid (Kdo) transferase (waaA) (32), inner-core glucosyltransferase (waaE) (18, 20), galacturonyltransferase (wabG) (19), N-acetyl-glucosaminyltransferase (wabH) (12), and a gene of unknown function (orf10) similar to E. coli yibD (32) (Fig. 2). Although a putative waaL gene was also found, the 416-residue ORF5₅₂₁₄₅ (WaaL) showed significant similarity to the putative O-antigen ligase (WaaL) of Serratia marcescens (6) among other Enterobacteriaceae but limited identity (19%) and similarity (38%) to the WaaL protein from strain C3.

View larger version (15K): [in this window] [in a new window]   FIG. 2. Diagram of the K. pneumoniae 52145 waa gene cluster and comparison of this cluster to those of K. pneumoniae C3 (32) and S. marcescens N28b (6). White boxes denote PCR-amplified DNA fragments. Common inner core genes (black arrows), common outer-core genes (gray arrows). Common outer-core genes between K. pneumoniae 52145 and S. marcescens N28b (striped arrows). Cluster-specific genes (white arrows). K. pneumoniae 52145 waa gene cluster, GenBank accession no. AY823268.

In both strains C3 and 52145, the gene pairs wabI-wabJ and wabK-wabM were found flanking the corresponding O-antigen ligase (waaL_C3 and waaL₅₂₁₄₅) gene. The gene order and transcription direction were the same for these three genes in K. pneumoniae 52145 and S. marcescens N28b, while in the waa_C3 gene cluster the wabJ gene was transcribed in the opposite direction (32) (Fig. 2).

Mutational and complementation studies. To properly identify the additional genes from the waa₅₂₁₄₅ gene cluster, new nonpolar in-frame deletion mutants were constructed (see Materials and Methods). LPS from these mutants was analyzed by SDS-Tricine-PAGE (Fig. 3), revealing a gradation of electrophoresis migration patterns, in agreement with the postulated functions for the genes common to both K. pneumoniae waa clusters (Fig. 1A). In addition, each mutant was complemented by the corresponding K. pneumoniae C3 homologous genes (data not shown), except O-antigen ligase waaL_C3 and waaL₅₂₁₄₅. The O^– 52145waaL mutant was only partially complemented by waaL_C3, while full restoration of O-antigen production was achieved by complementation with waaL₅₂₁₄₅. Since the O antigen is linked to the outer-core residue Kdo in K. pneumoniae strains containing type 1 core LPS (41), our results suggest differences in the O-antigen outer-core linkage region between strains C3 and 52145.

View larger version (77K): [in this window] [in a new window]   FIG. 3. SDS-Tricine-PAGE analysis of LPS samples from K. pneumoniae 52145- and 52145-derived nonpolar core biosynthetic mutants.

Chemical characterization of the K. pneumoniae 52145 core LPS. The LPS from the waaL₅₂₁₄₅ mutant was extracted by the PCP method. Sugar analysis of the oligosaccharide (OS) fractions revealed the presence of D-GalA, D-GlcN, D-Glc, L,D-Hep, and Kdo. Methylation analysis indicated the attachment points of each residue: GalA was present both as terminal and 4-linked, GlcN as 4-linked and 6-linked, L,D-Hep was present as 7-linked, 3,4-, and 3,7-linked, Glc as terminally and 6-linked, and Kdo as both terminally and 4,5-linked.

The core OS was obtained by degradation of LPS under both the alkaline (OS1) and acid conditions (OS2) (see Materials and Methods). The ¹H-NMR spectra showed seven (A to G) (Fig. 4) and nine (H to R) (Fig. 5A) anomeric signals for OS1 and OS2, respectively. The complete assignment of all NMR signals from OS1 was achieved by two-dimensional homonuclear and heteronuclear experiments (COSY, TOCSY, HSQC-DEPT, HSQC-TOCSY, HMBC and ROESY), allowing us to show that in addition to the seven anomeric signals (A to G) occurring in the ¹H spectrum (Fig. 1B and Fig. 4) (see Table S2 in the supplemental material), a further signal at 5.75 ppm (A4) occurred, which was correlated to the unsaturated C-4 of a threo-hex-4-enuronopyranosyl unit. This finding suggested that position 4 of galactopyranuronic acid is probably substituted by a sugar chain which was lost during the hot alkaline treatment by ß-degradation during the alkaline hydrolysis of LPS (see Materials and Methods).

View larger version (10K): [in this window] [in a new window]   FIG. 4. Anomeric region of the 1H-NMR spectra of OS1 obtained from K. pneumoniae 52145 waaL mutant LPS by complete O and N deacylation. Letters denote residues as in Fig. 1B OS1.

View larger version (20K): [in this window] [in a new window]   FIG. 5. (A) Anomeric region of the 1H-NMR spectra and (B) ROESY spectra of OS2 obtained from K. pneumoniae 52145 waaL mutant LPS by mild acid hydrolysis. Letters denote residues as in Fig. 1B OS2.

The sequence of residues in OS1 (Fig. 1B) was deduced from the scalar interresidual correlations measured by a long-range ¹H,¹³C-HMBC. A ROESY experiment confirmed this sequence by interresidual dipolar coupling and showed the spatial proximity of the C unit with the 4,5-linked Kdo residue, for which the HMBC did not show any diagnostic correlation. The sequence of residues in OS2 was deduced by interresidue nuclear Overhauser enhancement spectroscopy (NOEs) and confirmed by the long-range ¹³C-¹H-HMBC, which also supported the attachment points of interglycosidic linkages suggested by the low-field chemical shift of the glycosylated carbons (see Table S3 in the supplemental material). In particular, the HMBC spectrum showed the following correlations: H-1 H/C-4 M, H-1 M/C4 I, H-1 I/C-3 L, H-1 L/C-3 N, H-1 P/C-4 N, H-1 R/C-7 O, and H-1 O/C-7 L, and the ROESY spectrum (Fig. 5B) showed the NOE contacts between H-1 of Q and the methylene protons of H, indicating the spatial proximity of these residues, for which the HMBC spectrum did not show any correlation. These experiments allowed to deduce the structure of OS1 and OS2 (Fig. 1B).

Mass spectroscopy studies. To determine the degree of heterogeneity in the core OS fraction, a negative-mode MALDI-TOF mass spectrum was obtained (Fig. 6). The spectrum showed a complex pattern of mass peaks, some containing one or two sodium ions. The major signal at m/z 1812.52 was in close agreement with a structure consisting of Glc₃GlcN GalA₂Hep₃Kdo (calculated mass, 1814.55 Da). Satellite peaks at m/z 1794.52 and m/z 1766.52 correspond to the anhydro form (M-18) and a Kdo artifact (M-46), respectively (27). Thus, the core OS2 is the most abundant in K. pneumoniae C3 core LPS. Additional peaks (Fig. 6) could be attributed to molecular species lacking outer-core residues Glc, one or two, GlcN, and GalA. A low intense peak was found at m/z 1892.47, probably indicating the presence of a phosphate group in the core oligosaccharide.

View larger version (26K): [in this window] [in a new window]   FIG. 6. Positive ion MALDI-TOF spectrum of acid-released core LPS oligosaccharides from K. pneumoniae 52145 waaL.

View larger version (19K): [in this window] [in a new window]   FIG. 7. Positive ion MALDI-TOF/TOF spectrum of m/z 1814.55 signal of acid-released core LPS oligosaccharide isolated from K. pneumoniae 52145waaL, in the positive ion mode. Insert shows the fragmentation pattern.

View larger version (16K): [in this window] [in a new window]   FIG. 8. Positive ion MALDI-TOF/TOF spectrum of m/z 1652.07 signal of acid-released core LPS oligosaccharide isolated from K. pneumoniae 52145waaL, in the positive ion mode. Insert shows the fragmentation pattern.

Engineering K. pneumoniae core LPS. We decided to construct K. pneumoniae strains expressing heterologous core LPS to study the effects of core LPS type on its expression and virulence. Nonpolar triple deletion wabI waaL_C3 wabJ and wabM waaL₅₂₁₄₅ wabK mutants were constructed from K. pneumoniae strains C3 and 52145, respectively (see Table S1 in the supplemental material for primers used in these constructions). As expected, LPS from mutants C3wabI-J and 52145wabM-K migrated faster than the corresponding wild-type LPS and were devoid of O antigen (Fig. 9). The three type 1 core-specific waa genes on pGEM-T-wabI-waaL_C3-wabJ were transformed into 52145wabM-K, resulting in full O1-antigen-containing LPS (Fig. 9). Similarly, C3wabI-J cells transformed with pGEM-T-wabM-waaL₅₂₁₄₅-wabK showed full O8-antigen-containing LPS. Thus, the complemented triple mutants produce their parental O-antigen LPS independently of the complementing gene's origin (Fig. 9, data shown for 52145 and derivative strains). In addition, the engineered strains 52145wabM-K(pGEM-T-wabI-waaL_C3-wabJ) and C3wabI-J(pGEM-T-wabM-waaL₅₂₁₄₅-wabK) produced the original wild-type K2 and K66 antigen, respectively. Thus, changing the core type among strains C3 and 52145 does not modify the nature of the parental O and K antigens.

View larger version (50K): [in this window] [in a new window]   FIG. 9. SDS-PAGE (A) and SDS-Tricine-PAGE (B) analysis of LPS samples from K. pneumoniae type 2 core strains 52145 (O1:K2) and B5055 (O1:K2), 52145-derived triple core biosynthesis mutants, homologous and heterologous complemented mutants, and type 1 core strain C3 (O8:K66).

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

 
We have identified in this study a second core type in K. pneumoniae 52145 that we have designated type 2 core. The elucidation of the chemical structure of type 2 core and the comparison of this structure with that of type 1 core revealed that both core types differ only in the outer-core region. The GlcpN residue is substituted at the O-6 position by either the disaccharide -Hep(1-4)--Kdo(2 or a Kdo residue in the previously described K. pneumoniae type 1 core (Fig. 1A). By contrast, the GlcpN residue is substituted at the O-4 position by the disaccharide ß-Glcp(1-6)--Glcp(1 in K. pneumoniae type 2 core (Fig. 1B). An identical disaccharide moiety has already been found in Serratia marcescens, indicating a close similarity of the biosynthetic pathways for S. marcescens and K. pneumoniae type 2 core LPS.

Comparison of the gene clusters encoding the core biosynthetic genes among strains producing type 1 (C3) and type 2 (52145) cores clearly showed that only two genes account for the differences between both core types. Strains containing type 1 core present the genes wabI (outer-core Kdo transferase) and wabJ (outer-core heptosyltransferase), while strains with type 2 core have the genes wabK and wabM. Evidence suggesting that the genes wabK and wabM encode glucosyltransferases involved in the transfer of the last two outer-core Glc residues of type 2 core is based on analysis of LPS from mutants 52415wabK and -M by SDS-Tricine-PAGE and mass spectrometry. In agreement with the outer-core structural similarity between K. pneumoniae 52145 and S. marcescens N28b, wabK and wabM homologues were found in S. marcescens. These outer-core-specific genes are always found flanking the corresponding O-antigen ligase gene (waaL).

Previously it has been shown that in K. pneumoniae strains containing type 1 core, the O antigen is linked to the outer-core residue Kdo (41). K. pneumoniae 52145 mutants containing deletions in either wabK or wabM are devoid of O antigen, suggesting that in this strain, the O antigen is linked to the last Glcp outer-core residue. Interestingly, the similarity between the deduced putative O-antigen ligase proteins is quite low, and no full complementation was found between waaL_C3 and waaL₅₂₁₄₅, suggesting some degree of specificity of the O-antigen ligase for each core type.

An analysis of the G+C percentage of each individual gene (Table 3) reveals an unusually low value for the contiguous genes wabK, waaL₅₂₁₄₅, and wabM, suggesting that they could have been acquired relatively recently by horizontal transfer, leading to the appearance of type 2 core in K. pneumoniae. In addition, this analysis suggests that this genetic information was not acquired from S. marcescens, because of the difference in G+C percentage between the two equivalent regions (Table 3).

The type 2 core frequency among Klebsiella isolates was assayed by analysis of the presence of the type 1 and 2 core-specific genes. Preliminary results obtained with 100 Klebsiella strains from our laboratory suggest that they represent 19% of our Klebsiella collection, with a highest prevalence in serotype O1 strains (29%) and serotype O1:K2 strains (83%). Four of the five Klebsiella O1:K2 strains with type 2 core tested are highly virulent for mice. Furthermore, the presence of two Klebsiella strains that cannot be assigned to either type 1 or type 2 cores suggests the existence of additional Klebsiella core types. Since K. pneumoniae is an important cause of nosocomial infections ranging from urinary tract infections to septicemia and pneumonia (10) and can also produce primary liver infection in both healthy and unhealthy persons (3, 26, 33), future studies will be needed to determine if each core type is associated with groups of strains producing infections with specific clinical manifestations.

In conclusion, a second core LPS type from K. pneumoniae, probably arising by horizontal transfer, has been characterized both genetically and structurally. Genetic exchange of type 1 and 2 cores suggests that they are not equivalent in a mouse infection model.

	ACKNOWLEDGMENTS

 
This work was supported by Plan Nacional de I + D grants (Ministerio de Ciencia y Tecnología, Spain) and from Generalitat de Catalunya. L.I. and S.F. are recipients of predoctoral fellowships from Ministerio de Ciencia y Tecnología (Spain) and Universidad de Barcelona.

We also thank Maite Polo for her technical assistance.

	FOOTNOTES

 
* Corresponding author. Mailing address: Departamento de Microbiología, Facultad de Biología, Universidad de Barcelona, Diagonal 645, 08028 Barcelona, Spain. Phone: 34-934021486. Fax: 34-93-4039047. E-mail: jtomas{at}ub.edu.

Supplemental material for this article may be found at http://jb.asm.org/.

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Top Abstract Introduction Materials and Methods Results Discussion References

 

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