Analysis of lipooligosaccharide biosynthesis in the Neisseriaceae

Neisserial lipooligosaccharide (LOS) contains three oligosaccharide chains, termed the alpha, beta, and gamma chains. We used Southern hybridization experiments on DNA isolated from various Neisseria spp. to determine if strains considered to be nonpathogenic possessed DNA sequences homologous with genes involved in the biosynthesis of these oligosaccharide chains. The presence or absence of specific genes was compared to the LOS profiles expressed by each strain, as characterized by their mobilities on sodium dodecyl sulfate-polyacrylamide gel electrophoresis gel and their reactivities with various LOS-specific monoclonal antibodies. A great deal of heterogeneity was seen with respect to the presence of genes encoding glycosyltransferases in Neisseria. All pathogenic species were found to possess DNA sequences homologous with the lgt gene cluster, a group of genes needed for the synthesis of the alpha chain. Some of these genes were also found to be present in strains considered to be nonpathogenic, such as Neisseria lactamica, N. subflava, and N. sicca. Some nonpathogenic Neisseria spp. were able to express high-molecular-mass LOS structures, even though they lacked the DNA sequences homologous with rfaF, a gene whose product must act before gonococcal and meningococcal LOS can be elongated. Using a PCR amplification strategy, in combination with DNA sequencing, we demonstrated that N. subflava 44 possessed lgtA, lgtB, and lgtE genes. The predicted amino acid sequence encoded by each of these genes suggested that they encoded functional proteins; however, structural analysis of LOS isolated from this strain indicated that the bulk of its LOS was not modified by these gene products. This suggests the existence of an additional regulatory mechanism that is responsible for the limited expression of these genes in this strain.     

The repertoire of minimal mobile elements in the Neisseria species and evidence that these are involved in horizontal gene transfer in other bacteria

In the Neisseria spp., natural competence for transformation and homologous recombination generate antigenic variants through creation of mosaic genes (such as opas) and through recombination with silent cassettes (such as pilE/pilS) and gene-complement diversity through the horizontal exchange of whole genes or groups of genes, in minimal mobile elements (MMEs). An MME is a region encompassing 2 conserved genes between which different whole-gene cassettes are found in different strains, which are chromosomally incorporated solely through the action of homologous recombination. Comparative analyses of the neisserial genome sequences identified 39 potential MME sites, the contents of which were investigated in 11 neisserial strains. One hundred and eight different MME regions were identified, 20 of which contain novel sequences and these contain 12 newly identified neisserial coding sequences. Neisserial uptake signal sequences are associated with 38 of the 40 MMEs studied. In some sites, divergent dinucleotide signatures of the sequences between the flanking genes suggest relatively recent horizontal acquisition of some cassettes. The neisserial MMEs were used to interrogate all of the other available bacterial genome sequences, revealing frequent conservation of the flanking genes combined with the presence of different gene cassettes between them. In some cases, these sites can definitively be classified as MMEs in these other genera. These findings provide additional evidence for the MME model, indicate that MME-directed investigations are a good basis for the identification of novel strain-specific genes and differences within bacterial populations and demonstrate that these elements are probably ubiquitously involved in genetic exchange, particularly in naturally competent bacteria.     

Identification and characterization of a cross-reactive and a unique B-cell epitope on the hsp60 homologue from Neisseria gonorrhoeae

Two monoclonal antibodies (G6 and 7B), generated against a 63-kDa stress protein (GSP63) from Neisseria gonorrhoeae strain VP1, were used to investigate the antigenic heterogeneity of GSP63 among the Neisseriaceae and its antigenic relationship with the Hsp60 heat-shock protein family. Immunoblotting experiments demonstrated antibody reactivity with all pathogenic Neisseria tested and with some of the commensal strains. One of the antibodies (7B) cross-reacted with the 65-kDa M. bovis BCG heat-shock protein and with 14 out of the 21 similarly sized proteins in other bacterial species. The other antibody (G6) specifically recognized neisserial GSP63 homologues. These results demonstrate that GSP63 is a conserved neisserial antigen bearing both a unique neisserial B-cell epitope and a more widely distributed Hsp60 epitope.     

Phosphorylcholine decoration of lipopolysaccharide differentiates commensal Neisseriae from pathogenic strains: identification of licA-type genes in commensal Neisseriae

Phosphorylcholine (ChoP) is a potential candidate for a plurispecific vaccine, because it is present on surface components of many mucosal organisms, including Haemophilus influenzae, Streptococcus pneumoniae and Pseudomonas aeruginosa. In addition, ChoP has been detected on pili of Neisseria meningitidis and Neisseria gonorrhoeae. In this study, we demonstrate the presence of the phosphorylcholine epitope on the lipopolysaccharides (LPSs) of several species of commensal Neisseriae (Cn), a property that differentiates commensal from the pathogenic strains of Neisseriae. In an extended survey of 78 strains, we confirmed the exclusive expression of the ChoP epitope on pili of pathogenic Neisseriae. Despite the presence of pili on Cn, which are homologous to Class II pili of N. meningitidis, they did not react with anti-ChoP antibody. This observation was further supported by the fact that 14C-labelled choline was incorporated only in the LPSs of Cn. Analysis of the LPS of N. lactamica strain NL4 revealed two distinct and interconvertible molecular species of LPS with high and low levels of reactivity with anti-ChoP antibody. In addition, on/off phase variation gave rise to frequent modulation in the levels of antibody reactivity. A concurrent modulation was also observed in the binding of C-reactive protein, CRP, a ChoP-binding reactant that is implicated in bacterial clearance. Genetic analysis showed the presence of a gene in several Cn spp. with significant sequence identity to H. influenzae licA. This gene encodes choline kinase and is also involved in phase variation of the LPS-associated ChoP in H. influenzae. In contrast, licA-like genes were not identified in the pathogenic Neisseria strains tested. They are absent from N. meningitidis strain Z2491 genome database. These data suggest that the genetic basis for ChoP incorporation in Cn LPS resembles that in H. influenzae spp. and may be distinct from that generating the ChoP epitope on pili of pathogenic Neisseriae. Further, the modulation of ChoP expression on Cn LPS, and corresponding modulation of CRP binding, has the potential to confer the property of immune avoidance and thus of persistence on mucosa.     

Investigation of the structural heterogeneity of lipooligosaccharides from pathogenic Haemophilus and Neisseria species and of R-type lipopolysaccharides from Salmonella typhimurium by electrospray mass spectrometry.

Heterogeneity in the lipooligosaccharides (LOS) of pathogenic Haemophilus and Neisseria species is evident from the multiplicity of components observed with electrophoretic analyses. Knowledge of the precise structures that make up these diverse LOS molecules is clearly the key to reaching an understanding of pathogenic processes such as phase variation and molecular mimicry. Except for a few cases, little is known about the specific structural features of LOS that underlie phase variation and molecular mimicry, partly because of the inherent difficulties in the structural elucidation of these complex glycolipids. In the lipopolysaccharides (LPS) from Salmonella typhimurium and Escherichia coli, rough, or R-type, mutants have been isolated that have provided insight into the biosynthetic pathways and associated genetics that control LPS expression. Nonetheless, recent work has shown that these R-type LPS are more complex than originally thought, and significant heterogeneity is still observed, primarily in their phosphorylation states. In order to investigate the structures of LPS and LOS in a more rapid fashion, we have determined the precise molecular weights of LOS (and LPS) preparations from various Haemophilus, Neisseria, and Salmonella species by electrospray ionization-mass spectrometry. The LOS (or LPS) were first O-deacylated under mild hydrazine conditions to remove O-linked esters primarily from the lipid A portion. Under negative-ion conditions, the O-deacylated LOS yield abundant multiply deprotonated molecular ions, (M-nH)n-, where n refers to the number of protons removed and therefore determines the absolute charge state, n = z. Mass spectra from different LOS and LPS preparations have provided detailed information concerning the structural basis for LOS (and LPS) heterogeneity and corresponding saccharide compositions. The identification of sialic acid in the LOS of Haemophilus and Neisseria species and the variable phosphorylation of the core of S. typhimurium LPS have afforded insights into the biosynthetic pathways used by these organisms. Information of this type is important for understanding the underlying genetic and environmental factors controlling LOS and LPS expression.     

Western blot analysis of neisserial lipooligosaccharide at the lower femtomole level with normal human sera

Lipooligosaccharide (LOS) is a major immunogenic component of pathogenic Neisseria species such as Neisseria meningitidis and N. gonorrhoeae. Recent immunochemical studies have found that normal human sera (NHS) contain bactericidal anti-LOS antibodies that bind to the oligosaccharide (OS) moiety of neisserial LOS. Although affinity-purified anti-LOS antibodies can be characterized using 10-100 ng of LOS samples (up to a few tens of pmoles), a more sensitive immunoblotting assay must be established in order to analyze NHS directly and characterize anti-LOS antibodies without affinity purification. We examined analytical PAGE/blot conditions using a 15-well mini gel. For the first time, Western blot detection of LOS at the lower femtomole level was accomplished by both chromogenic and chemiluminescent detection. A model LOS, 15253 LOS, was detected in a low femtomole range (62.5-500 pg, 16-125 femtomole) even with 10 pM of a monoclonal antibody (MAb) 2C7. Furthermore, detection of similar amounts (50-250 femtomole) of neisserial LOSs and Salmonella truncated lipopolysaccharides (LPSs) was also possible with 1:50 and with 1:100 diluted NHS. The results obtained here indicate that the binding of IgG in NHS to the LOS and LPS samples is probably due to their carbohydrate moieties. The detection level accomplished in this study should help not only to further characterize anti-LOS antibodies in blood and body fluids but also to analyze carbohydrate structures that are recognized by them.     

Characterization of lipooligosaccharide-biosynthetic loci of Campylobacter jejuni reveals new lipooligosaccharide classes: evidence of mosaic organizations

The lipooligosaccharide (LOS) biosynthesis region is one of the more variable genomic regions between strains of Campylobacter jejuni. Indeed, eight classes of LOS biosynthesis loci have been established previously based on gene content and organization. In this study, we characterize additional classes of LOS biosynthesis loci and analyze various mechanisms that result in changes to LOS structures. To gain further insights into the genomic diversity of C. jejuni LOS biosynthesis region, we sequenced the LOS biosynthesis loci of 15 strains that possessed gene content that was distinct from the eight classes. This analysis identified 11 new classes of LOS loci that exhibited examples of deletions and insertions of genes and cassettes of genes found in other LOS classes or capsular biosynthesis loci leading to mosaic LOS loci. The sequence analysis also revealed both missense mutations leading to "allelic" glycosyltransferases and phase-variable and non-phase-variable gene inactivation by the deletion or insertion of bases. Specifically, we demonstrated that gene inactivation is an important mechanism for altering the LOS structures of strains possessing the same class of LOS biosynthesis locus. Together, these observations suggest that LOS biosynthesis region is a hotspot for genetic exchange and variability, often leading to changes in the LOS produced.     

Structural Characterization of an Oligosaccharide Made by Neisseria sicca

Neisseria sicca 4320 expresses two carbohydrate-containing components with sodium dodecyl sulfate-polyacrylamide gel electrophoresis mobilities that resemble those of lipooligosaccharide and lipopolysaccharide. Using matrix-assisted laser desorption ionization—time of flight and electrospray ionization mass spectrometry, we characterized a disaccharide carbohydrate repeating unit expressed by this strain. Gas chromatography identified the sugars composing the unit as rhamnose and N-acetyl-d-glucosamine. Glycosidase digestion confirmed the identity of the nonreducing terminal sugar of the disaccharide and established its β-anomeric configuration. Mass spectrometry analysis and lectin binding were used to verify the linkages within the disaccharide repeat. The results revealed that the disaccharide repeat is [-4) β-l-rhamnose (1-3) β-N-acetyl-d-glucosamine (1-] with an N-acetyl-d-glucosamine nonreducing terminus. This work is the first structural characterization of a molecule that possesses rhamnose in the genus Neisseria.Commensal Neisseria strains colonize the human respiratory tract. Frequent interspecific genetic exchange between commensal Neisseria strains and the pathogens Neisseria meningitidis and Neisseria gonorrhoeae occurs (13). It is thought the commensal organisms serve as reservoirs for antibiotic resistance genes (20). The similarity between the gene complements of the commensals and pathogens suggests that the virulence of the pathogenic Neisseria spp. may not result from the genes that they possess but rather from a “genetic personality” which is a result of combinations of these genes, sequence variations that alter the function of gene products, the presence of genes for which a virulence phenotype has not yet been identified, and/or differences in the regulation of genes (25).Lipooligosaccharide (LOS) is an important neisserial virulence determinant consisting of an oligosaccharide (OS) component attached to lipid A via 3-deoxy-2-keto-d-manno-octulosonic acid (Kdo). The structures of a sufficient number of neisserial LOS molecules have been determined to form a coherent yet incomplete picture of the structural diversity of their LOS (Fig. ​(Fig.1).1). The different LOS structures have a conserved core with two Kdo molecules, two heptose (Hep) molecules, and one N-acetylhexosamine (HexNAc) molecule and vary in the composition and size of the OS attached to one Hep (HepI; α-chain variation) and in the attachment of an OS or phosphoethanolamine to the other Hep (HepII; β-chain variation) or by addition of a galactose to the N-acetylglucosamine (GlcNAc) found on HepII (γ-chain extension) (3, 6, 7, 9-11). This structural motif is different from that of lipopolysaccharide (LPS) of other types of bacteria, which contains an O antigen composed of a repeating sugar polymer, typically consisting of four to seven sugars (26). No one has reported the presence of an O antigen in pathogenic strains of Neisseria.Open in a separate windowFIG. 1.Structrual diversity of the sugar backbone of LOS isolated from pathogenic Neisseria spp. The various LOS structures that have been identified in N. gonorrhoeae or N. meningitidis are shown.A few studies have analyzed the structure of LOS produced by commensal Neisseria strains, and the data indicate that the LOS heterogeneity is greater than the heterogeneity in the gonococcus and meningococcus (21). Commensal Neisseria strains are capable of producing LOS molecules that are structurally different from the molecules in the known Neisseria repertoire in that they fail to bind monoclonal antibodies specific for LOS epitopes characteristic of the gonococcus and meningococcus (1). They also can lack some of the LOS biosynthesis genes found in N. meningitidis and N. gonorrhoeae (1, 33). These findings suggest that alternative LOS structures are present in commensal Neisseria strains. Sandlin and Stein (21) identified a strain of Neisseria sicca that expressed an unusual glycolipid that appeared based on sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) to be analogous to LPS made by enteric bacteria. A poly-N-acetyllactosamine repeat was seen in some strains of the gonococcus (10), and we postulated that the repeating carbohydrate found in N. sicca could be a variant of this structure.A few studies have shown that both Neisseria and Haemophilus strains have the ability to extend their LOS by adding lactosamine repeats to form polylactosamine; these strains seem to possess increased virulence (4, 10, 22). When N. gonorrhoeae MS11mkC was used to inoculate healthy male volunteers, 100% of the volunteers developed urethritis, compared to an infectivity rate of 40% for strains expressing a truncated LOS (23). Fresh isolates from the volunteers who had contracted urethritis produced LOS molecules with N-acetyllactosamine repeats, whereas the isolates in the original inoculum expressed paraglobsyl and gangliosyl LOS (23, 24). However, the number of disaccharide repeats was limited to two or three (10). Analogous results were generated when the infectivity of Haemophilus ducreyi, a causative agent of genital ulcers, was studied; infectious strains made LOS with a few lactosamine repeats (4, 22).N. sicca is normally not pathogenic in healthy adults. A previous study indicated that N. sicca 4320 expressed a molecule with a repeating carbohydrate structure that appeared to be similar to the O-antigen structure (21). Because such molecules have not been found in pathogenic Neisseria strains, we analyzed the structure of the repeating carbohydrate unit and showed that it is a repeating disaccharide that is novel to the genus Neisseria.     

Identification and characterization of specific sequences encoding pathogenicity associated proteins in the genome of commensal Neisseria species

Abstract The distribution of distinct sequences in pathogenic and commensal Neisseria species was investigated systematically by dot blot analysis. Probes representing the genes of Rmp, pilin and IgA1 protease were found to hybridize exclusively to the chromosomal DNA of the pathogenic species, Neisseria gonorrhoeae and/or Neisseria meningitidis . In contrast, specific sequences for the genes of the porin protein Por and the opacity protein (Opa) were also detected in a panel of commensal Neisseria species such as N. lactamica, N. subflava, N, flava, N. mucosa and N. sicca . Using opa -specific oligonucleotides as probes in chromosomal blots, the genomes of the commensal Neisseria species show a totally reduced repertoire of cross-hybridizing loci compared to the complex opa gene family of N. gonorrhoeae . DNA sequence analysis of one opa -related gene derived from N. flava and N. sicca , respectively, revealed a large degree of homology with previously described gonococcal and meningococcal genes e.g., a typical repetitive sequence in the leader peptide and the distribution of the hypervariable and conserved regions. This observation, together with the finding, that the gene is constitutively transcribed, leads to the assumption that some of the commensal Neisseria species may have the potential for the expression of a protein harboring similar functions as the Opa proteins in pathogenic Neisseriae .     

Interspecies recombination, and phylogenetic distortions, within the glutamine synthetase and shikimate dehydrogenase genes of Neisseria meningitidis and commensal Neisseria species

Visual inspection showed clear evidence of a history of intraspecies recombinational exchanges within the neighbouring meningococcal shikimate dehydrogenase ( aroE  ) and glutamine synthetase ( glnA) genes, which was supported by the non-congruence of the trees constructed from the sequences of these genes from different meningococcal strains, and by statistical tests for mosaic structure. Many examples were also found of highly localized interspecies recombinational exchanges between the meningococcal aroE and glnA genes and those of commensal Neisseria species. These exchanges appear to have inflated the sequence variation at these loci, and have resulted in major distortions of the phylogenetic trees constructed from the sequences of the aroE and glnA genes of human pathogenic and commensal Neisseria species. Statistical tests for sequence mosaicism, and for anomalies within the Neisseria species trees, strongly supported the view that frequent interspecies recombination has occurred within aroE and glnA . The high levels of sequence variation, and intra- and interspecies recombination, within aroE and glnA did not appear to be due to a 'hitch-hiking' effect caused by positive selection for variation at a neighbouring gene. Our results suggest that interspecies recombinational exchanges with commensal Neisseria occur frequently in some meningococcal 'housekeeping' genes as they can be observed readily even when there appears to be no obvious selection for the recombinant phenotypes.     

Identification of acquired DNA in Neisseria lactamica

Anomalous DNA (aDNA) in prokaryotic genomes, identified by its aberrant nucleotide composition, generally represents horizontally acquired DNA. Previous studies showed that frequent DNA transfer occurs between commensal Neisseriae and Neisseria meningitidis. Currently, it is unknown whether aDNA regions are also transferred between these species. The genome of Neisseria lactamica strain 892586 was assessed by a strategy that enables the selective isolation of aDNA, using endonucleases with recognition sites that are overrepresented in aDNA. Of eight regions with aDNA, five displayed similarity to virulence-associated meningococcal sequences. Of three aDNA fragments with limited or no similarity to neisserial sequences, one encodes a novel putative autotransporter/adhesin. The remaining two fragments are adjacent in the N. lactamica genome, and encode a novel putative ATPase/subtilisin-like protease operon. A similar operon is present in the genomes of different respiratory tract pathogens. The identification of aDNA from N. lactamica with similarity to meningococcal aDNA shows that genetic exchange between the Neisseriae is not limited to the neisserial core genome. The discovery of aDNA in N. lactamica similar to a locus in other pathogens substantially expands the neisserial gene pool.     

Characterization of the neisserial lipid-modified azurin bearing the H.8 epitope

The pathogenic Neisseria have multiple genes encoding proteins that bind monoclonal antibody (MAb) H.8. We previously reported the cloning and sequencing of a meningococcal gene (laz) encoding an H.8 MAb-binding protein with a consensus lipoprotein processing site, an N-terminal domain containing the epitope for H.8 MAb binding, and a C-terminal domain with extensive similarity to the sequences of azurins from other organisms. In the current study, we showed that the product of the cloned gene could be labelled with palmitic acid, that it was subject to globomycin-sensitive processing, and that it was immunologically cross-reactive with azurin from Pseudomonas aeruginosa. All neisserial species tested, both pathogens and commensals, produced a protein recognized by anti-azurin serum. Southern blots with oligonucleotide probes specific for the azurin domain of the gene showed that it was present in a single copy in the chromosome; it was highly conserved in gonococci and meningococci, and less conserved in commensal Neisseria species.     

Analysis of genome plasticity in pathogenic and commensal Escherichia coli isolates by use of DNA arrays

Genomes of prokaryotes differ significantly in size and DNA composition. Escherichia coli is considered a model organism to analyze the processes involved in bacterial genome evolution, as the species comprises numerous pathogenic and commensal variants. Pathogenic and nonpathogenic E. coli strains differ in the presence and absence of additional DNA elements contributing to specific virulence traits and also in the presence and absence of additional genetic information. To analyze the genetic diversity of pathogenic and commensal E. coli isolates, a whole-genome approach was applied. Using DNA arrays, the presence of all translatable open reading frames (ORFs) of nonpathogenic E. coli K-12 strain MG1655 was investigated in 26 E. coli isolates, including various extraintestinal and intestinal pathogenic E. coli isolates, 3 pathogenicity island deletion mutants, and commensal and laboratory strains. Additionally, the presence of virulence-associated genes of E. coli was determined using a DNA "pathoarray" developed in our laboratory. The frequency and distributional pattern of genomic variations vary widely in different E. coli strains. Up to 10% of the E. coli K-12-specific ORFs were not detectable in the genomes of the different strains. DNA sequences described for extraintestinal or intestinal pathogenic E. coli are more frequently detectable in isolates of the same origin than in other pathotypes. Several genes coding for virulence or fitness factors are also present in commensal E. coli isolates. Based on these results, the conserved E. coli core genome is estimated to consist of at least 3,100 translatable ORFs. The absence of K-12-specific ORFs was detectable in all chromosomal regions. These data demonstrate the great genome heterogeneity and genetic diversity among E. coli strains and underline the fact that both the acquisition and deletion of DNA elements are important processes involved in the evolution of prokaryotes.     

Comparative overview of the genomic and genetic differences between the pathogenic Neisseria strains and species

The availability of complete genome sequences from multiple pathogenic Neisseria strains and species has enabled a comprehensive survey of the genomic and genetic differences occurring within these species. In this review, we describe the chromosomal rearrangements that have occurred, and the genomic islands and prophages that have been identified in the various genomes. We also describe instances where specific genes are present or absent, other instances where specific genes have been inactivated, and situations where there is variation in the version of a gene that is present. We also provide an overview of mosaic genes present in these genomes, and describe the variation systems that allow the expression of particular genes to be switched ON or OFF. We have also described the presence and location of mobile non-coding elements in the various genomes. Finally, we have reviewed the incidence and properties of various extra-chromosomal elements found within these species. The overall impression is one of genomic variability and instability, resulting in increased functional flexibility within these species.     

Pathogenic consequences of Neisseria gonorrhoeae pilin glycan variation

A Neisseria gonorrhoeae (gonococcus, GC) pilin glycosylation gene, pgtA, can either possess or lack phase-variation ability. Many GC, particularly the disseminated strains, carry a phase-variable pgtA. However, other GC, predominantly the uncomplicated gonorrhea isolates, carry a pgtA lacking phase-variability. These and other results suggest GC pilin glycan's pathogenic involvement.     

Genetic diversity of the iron-binding protein (Fbp) gene of the pathogenic and commensal Neisseria

Abstract The pathogenic Neisseria and most commensal Neisseria species produce an iron-binding protein (Fbp) when grown under iron-limited conditions. In the current study, we confirmed the presence of Fbp, as well as DNA sequences homologous to the gonococcal fbp , in strains of N. gonorrhoeae, N. meningitidis, N. cinerea, N. lactamica, N. subflava, N. kochii and N. polysaccharea . The fbp genes from these strains were amplified by the polymerase chain reaction, digested with Stu I or Rsa I, and the restriction patterns examined. The patterns for the gonococcal and meningococcal fbp were virtually identical; however, variations were observed in the fbp sequences of the commensal Neisseria species. N. flavescens, N. mucosa, N. sicca, N. ovis and Branhamella catarrhalis , did not produce Fbp as detected by sodium dodecyl sulfate-polyacrylamide gel electropheris and reactivity with an Fbp specific monoclonal antibody, nor did they hybridize to an fbp -specific DNA probe.     

Genetic and functional analysis of the phosphorylcholine moiety of commensal Neisseria lipopolysaccharide

Phosphorylcholine (ChoP) is a common surface feature of many mucosal organisms, including Neisseria spp., in which it is present exclusively on pili of pathogenic Neisseria and on the lipopolysaccharide (LPS) of commensal Neisseria (Cn). Its presence in Cn has been confirmed by nuclear magnetic resonance. It appears that choline is the main source for the production of ChoP by Cn. We have sequenced a locus, containing four genes (licA-D) with 47-73% identity to the lic1 locus of Haemophilus influenzae (Hi) and 21-40% identity to lic genes in Streptococcus pneumoniae, involved in the production and incorporation of ChoP. The arrangement of the Cn genes and the presence of CAAT repeats, responsible for phase variation of ChoP expression, resemble Hi and differ from S. pneumoniae. Cn DNA flanking the lic locus contains genes ilvE and NMA2149 with >85% identity to the pathogenic Neisseria genes. However, there are no lic genes in the corresponding location or elsewhere in pathogenic Neisseria. This suggests either the loss of the locus from pathogenic Neisseria or a horizontal transfer of genes to Cn, perhaps from H. influenzae spp. As in Hi, ChoP enhances adherence to and invasion of human epithelial cells via the receptor for platelet-activating factor. However, ChoP expression also increases susceptibility to serum killing mediated by complement and C-reactive protein. Taken together, these observations support the hypothesis that the ability of many organisms to switch off ChoP expression rapidly represents an important adaptation to different environments encountered during the colonization/infection process and that the ChoP moiety apparently synthesized by distinct means in pathogenic and commensal Neisseria represents an advantage in the colonization properties of these bacteria.     

Lipooligosaccharide Structures of Invasive and Carrier Isolates of Neisseria meningitidis Are Correlated with Pathogenicity and Carriage

The degree of phosphorylation and phosphoethanolaminylation of lipid A on neisserial lipooligosaccharide (LOS), a major cell-surface antigen, can be correlated with inflammatory potential and the ability to induce immune tolerance in vitro. On the oligosaccharide of the LOS, the presence of phosphoethanolamine and sialic acid substituents can be correlated with in vitro serum resistance. In this study, we analyzed the structure of the LOS from 40 invasive isolates and 25 isolates from carriers of Neisseria meningitidis without disease. Invasive strains were classified as groups 1–3 that caused meningitis, septicemia without meningitis, and septicemia with meningitis, respectively. Intact LOS was analyzed by high resolution matrix-assisted laser desorption/ionization time-of-flight mass spectrometry. Prominent peaks for lipid A fragment ions with three phosphates and one phosphoethanolamine were detected in all LOS analyzed. LOS from groups 2 and 3 had less abundant ions for highly phosphorylated lipid A forms and induced less TNF-α in THP-1 monocytic cells compared with LOS from group 1. Lipid A from all invasive strains was hexaacylated, whereas lipid A of 6/25 carrier strains was pentaacylated. There were fewer O-acetyl groups and more phosphoethanolamine and sialic acid substitutions on the oligosaccharide from invasive compared with carrier isolates. Bioinformatic and genomic analysis of LOS biosynthetic genes indicated significant skewing to specific alleles, dependent on the disease outcome. Our results suggest that variable LOS structures have multifaceted effects on homeostatic innate immune responses that have critical impact on the pathophysiology of meningococcal infections.