Frequency of Pilin Antigenic Variation in Neisseria gonorrhoeae
51
Citation
25
Reference
10
Related Paper
Citation Trend
Abstract:
ABSTRACT Variation of the pilus of Neisseria gonorrhoeae occurs by the recombination of silent pilin DNA sequences into the pilin expression locus. We have developed a quantitative, competitive reverse transcription-PCR assay which measures the frequency of pilin antigenic variation independently of changes in gonococcal colony morphology and have determined this frequency within a gonococcal population. We have also studied the frequency of antigenic variation during growth and have concluded that growth does not dramatically influence the frequency of pilin antigenic variation, although a reproducible, twofold increase is observed upon the transition into late log/stationary phase.Keywords:
Pilin
Neisseria gonorrhoeae
Antigenic variation
Phase variation
Neisseriaceae
Summary: The occurrence of antigenic shift during meningococcal infection has been investigated by comparison of paired isolates obtained from the blood, cerebrospinal fluid or nasopharynx of patients. Isolates from any individual produced identical DNA "fingerprints" and showed stability in expression of both class 2 outer membrane protein and an antigen common to pathogenic Neisseria, confirming their origin as a single strain. One of the four strains examined produced variants which differed in the molecular mass of their class 5 outer membrane proteins. Three of the strains produced pili containing the epitope recognized by monoclonal antibody SM1 and two of these gave rise to variants which expressed pili of differing subunit molecular masses. The two variants of the remaining strain produced pilins lacking the common epitope detected by antibody SM1 but radioimmune precipitation with polyclonal anti-pilus antiserum revealed that variation in the molecular mass of the pilin expressed also occurred with this second class of pili. Antigenic variation in expression of both class 5 outer membrane proteins and pili therefore appears to be a common occurrence during meningococcal infection.
Pilin
Antigenic variation
Neisseria
Phase variation
Neisseriaceae
Polyclonal antibodies
Molecular mass
Fimbriae Proteins
Cite
Citations (100)
The Gram-negative bacterial pathogen Neisseria gonorrhoeae is naturally competent for transformation with species-related DNA. We show here that two phase-variable pilus-associated proteins, the major pilus subunit (pilin, or PilE) and PilC, a factor known to function in the assembly and adherence of gonococcal pili, are essential for transformation competence. The PilE and PilC proteins are necessary for the conversion of linearized plasmid DNA carrying the Neisseria-specific DNA uptake signal into a DNase-resistant form. The biogenesis of typical pilus fibers is neither essential nor sufficient for this process. DNA uptake deficiency of defined piliated pilC1,2 double mutants can be complemented by expression of a cloned pilC2 gene in trans. The PilC defect can also be restored by the addition of purified PilC protein, or better, pili containing PilC protein, to the mutant gonococci. Our data suggest that the two phase-variable Pil proteins act on the bacterial cell surface and cooperate in DNA recognition and/or outer membrane translocation.
Pilin
Neisseria gonorrhoeae
Fimbriae Proteins
Phase variation
Neisseria
Cite
Citations (117)
ABSTRACT The gonococcal pilus is a primary virulence factor, providing the initial attachment of the bacterial cell to human mucosal tissues. Pilin, the major subunit of the pilus, can carry a wide spectrum of primary amino acid sequences which are generated by the action of a complex antigenic variation system. Changes in the pilin amino acid sequence can produce different pilus-dependent colony morphotypes, which have been previously shown to reflect phase variation of pili on the bacterial cell surface. In this study, we further examined the relationships between changes in pilus-dependent colony morphology, pilin sequence, pilus expression, and pilus function in Neisseria gonorrhoeae FA1090. A group of FA1090 colony variants expressed different pilin sequences and demonstrated different levels of pilin, S-pilin, and pilus expression. The analysis of these colony variants shows that they do not represent two distinct phases of pilus expression, but that changes in pilin protein sequence produce a spectrum of S-pilin production, pilus expression, and pilus aggregation levels. These different levels of pilus expression and aggregation influence not only colony morphology but also DNA transformation efficiency and epithelial cell adherence.
Pilin
Phase variation
Neisseria gonorrhoeae
Fimbriae Proteins
Neisseria
Antigenic variation
Cite
Citations (54)
Neisseria gonorrhoeae displays considerable potential for antigenic variation as shown in human experimental studies. Various surface antigens can change either by antigenic variation using RecA-dependent recombination schemes (e.g. PilE antigenic variation) or, alternatively, through phase variation (on/off switching) in a RecA-independent fashion (e.g. Opa and lipooligosaccharide phase variation). PilE antigenic variation has been well documented over the years. However, with the availability of the N. gonorrhoeae FA1090 genome sequence, considerable genetic advances have recently been made regarding the mechanistic considerations of the gene conversion event, leading to an altered PilE protein. This review will compare the various models that have been presented and will highlight potential mechanistic problems that may constrain any genetic model for pilE gene variation.
Antigenic variation
Pilin
Neisseria gonorrhoeae
Phase variation
Variation (astronomy)
Gene conversion
Cite
Citations (52)
The human pathogen Eikenella corrodens expresses type IV pili and exhibits a phase variation involving the irreversible transition from piliated to nonpiliated variants. On solid medium, piliated variants form small (S-phase), corroding colonies whereas nonpiliated variants form large (L-phase), noncorroding colonies. We are studying pilus structure and function in the clinical isolate E. corrodens VA1. Earlier work defined the pilA locus which includes pilA1, pilA2, pilB, and hagA. Both pilA1 and pilA2 predict a type IV pilin, whereas pilB predicts a putative pilus assembly protein. The role of hagA has not been clearly established. That work also confirmed that pilA1 encodes the major pilus protein in this strain and showed that the phase variation involves a posttranslational event in pilus formation. In this study, the function of the individual genes comprising the pilA locus was examined using a recently developed protocol for targeted interposon mutagenesis of S-phase variant VA1-S1. Different pilA mutants were compared to S-phase and L-phase variants for several distinct aspects of phase variation and type IV pilus biosynthesis and function. S-phase cells were characterized by surface pili, competence for natural transformation, and twitching motility, whereas L-phase cells lacked these features. Inactivation of pilA1 yielded a mutant that was phenotypically indistinguishable from L-phase variants, showing that native biosynthesis of the type IV pilus in strain VA1 is dependent on expression of pilA1 and proper export and assembly of PilA1. Inactivation of pilA2 yielded a mutant that was phenotypically indistinguishable from S-phase variants, indicating that pilA2 is not essential for biosynthesis of functionally normal pili. A mutant inactivated for pilB was deficient for twitching motility, suggesting a role for PilB in this pilus-related phenomenon. Inactivation of hagA, which may encode a tellurite resistance protein, had no effect on pilus structure or function.
Eikenella corrodens
Phase variation
Pilin
Cite
Citations (24)
Cite
Citations (293)
Adherence to eukaryotic cells is essential in the pathogenesis of Neisseria meningitidis . Pilus‐mediated adhesion has been shown to play an essential role in this process. Pilin, the pilus major subunit, and two pilus associated proteins, PilC1 and PilC2, are key components in meningococcal adhesiveness. Phase and/or antigenic variation of these molecules are the only identified means by which N. meningitidis modulates pilus‐mediated adhesion. PilA/PilB is a pleiotropic regulatory system first characterized in Neisseria gonorrhoeae where it controls pilin gene transcription. Similar alleles are found in N. meningitidis . To address the role of this regulatory pathway in N. meningitidis , we engineered a meningococcal pilA mutant strain and analysed the consequences of this mutation on pilus‐mediated adhesion using epithelial Hec‐1‐B cells. This mutation resulted in a threefold reduction in adhesiveness. As no change in the amount of pilin nor in pilin gene mRNA was detected, we compared the expression of the pilC genes in both pilA and parental strains. Two transcriptional fusions pilC1–lacZ and pilC2–lacZ were constructed. A threefold reduction in β‐galactosidase activity was observed in the pilA mutant strain harbouring the pilC1–lacZ fusion. No effect of the pilA mutation on β‐galactosidase activity was observed in the strain carrying the pilC2–lacZ fusion. Gel retardation experiments confirmed that the PilA protein binds to the promoter region of pilC1 but not of pilC2 . Taken together, these data demonstrate that PilA modulates meningococcal adhesiveness via the transcription of pilC1 . Thus, in addition to phase variation, a more co‐ordinate and responsive system may allow a fine adaptation of adhesiveness of meningococci to various environmental signals.
Pilin
Phase variation
Transcription
Cite
Citations (36)
Pilin
Phase variation
Neisseria gonorrhoeae
Cite
Citations (168)
In order to investigate possible functional consequences of phase and antigenic variation of meningococci, the attachment of 15 strains of Neisseria meningitidis to human erythrocytes was studied by a nitrocellulose hemadsorption assay. This assay allows the study of individual meningococcal colonies with respect to erythrocyte attachment. Of the 15 strains studied, 7 demonstrated binding of human erythrocytes (HA+). Among these seven strains, the percentage of colonies that were HA+ ranged from 0.2 to 97%. Meningococcal colonies that did not produce pilin (the major structural subunit of pili) did not demonstrate erythrocyte binding (HA-). The HA+ colony phenotype was correlated with assembly of pilin into pili and expression of pili on the meningococcal surface. However, only some piliated colonies bound human erythrocytes. This could not be explained by differences between piliated HA+ and HA- colonies in the amount of pilin produced or by differences in number of pili expressed per diplococcus. Pili of five of the meningococcal strains with HA+ colonies were antigenically related to gonococcal pili (class I meningococcal pili), but HA+ colonies were also seen in two meningococcal strains expressing class II meningococcal pili. Changes from HA+ to HA- and from HA- to HA+, in the presence of continuing pilin production and pilus assembly, occurred at frequencies of up to 10(-2)/CFU per generation. Such frequencies resemble those of phase and antigenic variation described previously for Neisseria species pilin. These studies indicate that phase variation influences the ability of meningococci to attach to human cells and suggest that meningococci may express functionally different pili.
Pilin
Phase variation
Neisseria gonorrhoeae
Neisseriaceae
Antigenic variation
Fimbriae Proteins
Neisseria
Cite
Citations (23)
Pilin
Neisseria gonorrhoeae
Antigenic variation
Phase variation
Neisseria
Fimbriae Proteins
Cite
Citations (348)