The genetic basis of the phase variation repertoire of lipopolysaccharide immunotypes in Neisseria meningitidis The GenBank accession number for the sequence reported in this paper is U65788.

Jennings, Michael P.; Srikhanta, Yogitha N.; Moxon, E. Richard; Krämer, Marco; Poolman, Jan; Kuipers, Betsy; Ley, Peter van der

doi:10.1099/00221287-145-11-3013

Cited by 129 publications

(120 citation statements)

References 18 publications

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“…Whereas capsules prevent desiccation during open-air transmission and make the bacteria less vulnerable to phagocytosis in the blood, they also reduce the likelihood of N. meningitidis invading the cells of the epithelia (Hammerschmidt et al 1996;de Vries et al 1996). Sialylated LPS play a dual role in evading host immunity in the blood and facilitating entry into epithelial cells (de Vries et al 1996;Jennings et al 1999 L8 LPS are favoured in the epithelia and sub-epithelia. In addition, in the blood, capsulated N. meningitidis with assembled pili and L3, L9 and L7 LPS have an advantage.…”

Section: Overviewmentioning

confidence: 99%

Epidemiology, hypermutation, within–host evolution and the virulence ofNeisseria meningitidis

Meyers

Levin

Richardson

et al. 2003

Proc. R. Soc. Lond. B

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Many so-called pathogenic bacteria such as Neisseria meningitidis, Haemophilus influenzae, Staphylococcus aureus and Streptococcus pneumoniae are far more likely to colonize and maintain populations in healthy individuals asymptomatically than to cause disease. Disease is a dead-end for these bacteria: virulence shortens the window of time during which transmission to new hosts can occur and the subpopulations of bacteria actually responsible for disease, like those in the blood or cerebral spinal fluid, are rarely transmitted to new hosts. Hence, the virulence factors underlying their occasional pathogenicity must evolve in response to selection for something other than making their hosts sick. What are those selective pressures? We address this general question of the evolution of virulence in the context of phase shifting in N. meningitidis, a mutational process that turns specific genes on and off, and, in particular, contingency loci that code for virulence determinants such as pili, lipopolysaccharides, capsular polysaccharides and outer membrane proteins. We use mathematical models of the epidemiology and the within-host infection dynamics of N. meningitidis to make the case that rapid phase shifting evolves as an adaptation for colonization of diverse hosts and that the virulence of this bacterium is an inadvertent consequence of shortsighted within-host evolution, which is exasperated by the increased mutation rates associated with phase shifting. We present evidence for and suggest experimental and retrospective tests of these hypotheses.

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Section: Overviewmentioning

confidence: 99%

Epidemiology, hypermutation, within–host evolution and the virulence ofNeisseria meningitidis

Meyers

Levin

Richardson

et al. 2003

Proc. R. Soc. Lond. B

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“…These genes are often referred to as contingency loci . Phase variable expression has been experimentally demonstrated for surface antigens such as opacity proteins, lipopolysaccharides, capsular polysaccharides, pili, haemoglobin receptors, PorA and Opc outer-membrane proteins, a putative protease and the NadA adhesin (de Vries et al, 1996;Jennings et al, 1998Jennings et al, , 1999Hammerschmidt et al, 1996;Jonsson et al, 1991;Lewis et al, 1999;Richardson & Stojiljkovic,1999;van der Ende et al, 2000;Sarkari et al, 1994;Martin et al, 2003). We recently showed that 47 genes were likely to be regulated by such a mechanism in N. meningitidis strain MC58 (Martin et al, 2003).…”

Section: Introductionmentioning

confidence: 99%

Involvement of genes of genome maintenance in the regulation of phase variation frequencies in Neisseria meningitidis

et al. 2004

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In Neisseria meningitidis, the reversible expression of surface antigens, i.e. phase variation, results from changes within repeated simple sequence motifs located in coding or promoter regions of the genes involved in their biosynthesis. The mutation rates of these simple sequences, which have a major influence on the generation of phenotypic diversity, can affect the fitness of the population. The aim of the present study was to investigate the involvement of genetic factors involved (mutS and dam) and not yet analysed (drg and dinB) in the regulation of phase variation frequencies of genes associated with a variety of repeat tracts. The frequency of frameshifts occurring in the polycytidine (polyC) tracts associated with siaD, spr and lgtG and in the tetranucleotide (TAAA) repeat tract associated with nadA was determined by colony immunoblotting or using the lacZ gene as a reporter. Inactivation of mutS increased the frequency of phase variation of genes presenting homopolymeric tracts of diverse length. Overexpression of dinB enhanced the instability of the homopolymeric tract associated with siaD. Investigation of the dam locus in a population of genetically distinct N. meningitidis strains revealed that 27 % of strains associated with invasive disease contained the dam gene. In all strains where a Dam function was absent, the drg gene had been inserted into the dam locus. Disruption of dam and drg in strains representative of each genotype, i.e. dam + /drg and dam/drg + , did not modify phase variation frequencies. In contrast to the effects of certain genes on homopolymeric tracts, none of the genetic factors investigated affected the stability of tetranucleotide repeat tracts.

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“…One important example is LPS phase variation by means of contingency loci that allows these bacteria to express different LPS molecules after every generation, enhancing their ability to survive and escape host immune cell recognition (23,24,27). Thus, strong selective pressure from the immune system during bacterial invasion is believed to be the driving force of LPS variation among these bacteria.…”

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confidence: 99%

“…Bacterial survival within the host's blood stream depends on the ability to escape the innate and adaptive immune systems, and H. influenza and N. meningitidis both have multiple genes under control of phase variation that result in antigenic variants arising every generation, allowing for immune evasion (20)(21)(22)(23)(24)(25)(26)(27)(28). One important example is LPS phase variation by means of contingency loci that allows these bacteria to express different LPS molecules after every generation, enhancing their ability to survive and escape host immune cell recognition (23,24,27).…”

mentioning

confidence: 99%

Protozoan predation, diversifying selection, and the evolution of antigenic diversity in Salmonella

Wildschutte

Wolfe

Tamewitz

et al. 2004

Proc. Natl. Acad. Sci. U.S.A.

147

142

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Extensive population-level genetic variability at the Salmonella rfb locus, which encodes enzymes responsible for synthesis of the O-antigen polysaccharide, is thought to have arisen through frequency-dependent selection (FDS) by means of exposure of this pathogen to host immune systems. The FDS hypothesis works well for pathogens such as Haemophilus influenzae and Neisseria meningitis, which alter the composition of their O-antigens during the course of bloodborne infections. In contrast, Salmonella remains resident in epithelial cells or macrophages during infection and does not have phase variability in its O-antigen. More importantly, Salmonella shows host-serovar specificity, whereby strains bearing certain O-antigens cause disease primarily in specific hosts; this behavior is inconsistent with FDS providing selection for the origin or maintenance of extensive polymorphism at the rfb locus. Alternatively, selective pressure may originate from the host intestinal environment itself, wherein diversifying selection mediated by protozoan predation allows for the continued existence of Salmonella able to avoid consumption by host-specific protozoa. This selective pressure would result in high population-level diversity at the Salmonella rfb locus without phase variation. We show here that intestinal protozoa recognize antigenically diverse Salmonella with different efficiencies and demonstrate that differences solely in the O-antigen are sufficient to allow for prey discrimination. Combined with observations of the differential distributions of both serotypes of bacterial species and their protozoan predators among environments, our data provides a framework for the evolution of high genetic diversity at the rfb locus and host-specific pathogenicity in Salmonella.T he enteric pathogen Salmonella enterica presents at least 70 different O-antigens [the outermost structure of the Gramnegative lipopolysaccharide (LPS)] to mammalian immune systems (1); this polysaccharide decorates the outer surface of the cell. Historically, extensive genetic diversity at the rfb locus, which encodes enzymes directing O-antigen synthesis (2-6), has been attributed to frequency-dependent selection (FDS) (7,8) imposed by the host immune system (5, 9, 10). Novel rfb loci would have an advantage because their cognate O-antigens would be unrecognized by immune systems (Fig. 1A); strains carrying rare loci would have higher fitness and would avoid rapid stochastic loss, rising to higher frequency. Yet selective advantages decrease with abundance; as a result, strains with common rfb loci cannot dominate the population or elicit a selective sweep (7) because their fitnesses become lower as they become more abundant. In concert, FDS prevents the loss of rare alleles or the dominance of common alleles, thus maintaining diversity (8).According to the FDS model, expression of different LPS molecules through gene regulation allows invading bacteria to escape host immunity, survive, and proceed throughout its life cycle; this hypothesis explains...

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The genetic basis of the phase variation repertoire of lipopolysaccharide immunotypes in Neisseria meningitidis The GenBank accession number for the sequence reported in this paper is U65788.

Cited by 129 publications

References 18 publications

Epidemiology, hypermutation, within–host evolution and the virulence ofNeisseria meningitidis

Epidemiology, hypermutation, within–host evolution and the virulence ofNeisseria meningitidis

Involvement of genes of genome maintenance in the regulation of phase variation frequencies in Neisseria meningitidis

Protozoan predation, diversifying selection, and the evolution of antigenic diversity in Salmonella

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