Taking Shape DNA recombination mechanisms enable certain pathogens to modify the proteins on their outer surfaces by rearranging their genes and so avoid repeated detection by the immune system. Cahoon and Seifert (p. 764 ) have found that antigenic variation of a single genetic locus in the human pathogen Neisseria gonorrhoeae is triggered by a specific cis-acting DNA element. This 16–base pair DNA sequence formed an unusual DNA structure in vitro; a guanine quartet (G4), which has been implicated in only a few other biological processes. The G4 forming sequence is required for processing the gene conversion reaction leading to antigenic variation. These findings have implications both for understanding mechanisms of DNA recombination and its role in microbial pathogenesis.
Neisseria gonorrhoeae (Gc) pili undergo antigenic variation when the amino acid sequence of the pilin protein is changed, aiding in immune avoidance and altering pilus expression. Pilin antigenic variation occurs by RecA-dependent unidirectional transfer of DNA sequences from a silent pilin locus to the expressed pilin gene through high-frequency recombination events that occur at limited regions of homology. We show that the Gc recQ and recO genes are essential for pilin antigenic and phase variation and DNA repair but are not involved in natural DNA transformation. This suggests that a RecF-like pathway of recombination exists in Gc. In addition, mutations in the Gc recB, recC or recD genes revealed that a Gc RecBCD pathway also exists and is involved in DNA transformation and DNA repair but not in pilin antigenic variation.
The pilus of Neisseria gonorrhoeae (the gonococcus Gc), the causative agent of gonorrhoea, promotes attachment of the gonococcus to the host epithelium and is essential for the establishment of disease. The ability of N. gonorrhoeae to infect previously exposed individuals is partially due to pilus antigenic variation. In addition, variation of the pilus has been proposed to function in the adaptation of the gonococcus to host environments. Previously, we described the development of a competitive reverse transcriptase (RT)-PCR assay that quantifies the frequency of pilin antigenic variation within a gonococcal population. Using this assay, the effect of different biologically relevant environmental conditions on the frequency of pilin antigenic variation was tested. Of the environmental conditions examined in vitro, only limited iron affected a significant change in the frequency of antigenic variation. Further investigation revealed that an observed increase in pilin antigenic variation reflected an increase in other DNA recombination and DNA repair processes within iron-starved cultures. In addition, this low iron-induced increase was determined to be independent of changes in RecA expression and was observed in a Fur mutant strain. As gonococci encounter conditions of low iron during infection, these data suggest that iron-limitation signals for increased recombinational events that are important for gonococcal pathogenesis.
Ross and Thompson's 1910 report of periodic spikes of Trypanosoma gambiense parasitemia (1), made possible by the relatively large size of the parasite, which allowed quantitation using light microscopy, was seminal in understanding how pathogens persist and led to later studies defining how trypanosomes and numerous other pathogens use antigenic variation to evade host immunity and clearance. Antigenic variation is a strategy used by a broad diversity of microbial pathogens to persist within mammalian hosts, from small RNA viruses, notably the human immunodeficiency virus (HIV), to large eukaryotic parasites with multiple chromosomes, illustrated by trypanosomal and malarial parasites (2, 3). Using a variety of genetic mechanisms to generate antigenic variants, immune evasion results in the infected host serving as a microbial reservoir for subsequent transmission. Unlike respiratory and gastrointestinal pathogens that have essentially continual opportunities for transmission, arthropod vector-borne and sexually transmitted pathogens have episodic transmission opportunities. Correspondingly, both vector-borne and sexually transmitted agents are overrepresented among antigenically variant pathogens (3, 4).
ABSTRACT Type IV pili are required for virulence in Neisseria gonorrhoeae , as they are involved in adherence to host epithelium, twitching motility, and DNA transformation. The outer membrane secretin PilQ forms a homododecameric ring through which the pilus is proposed to be secreted. pilQ null mutants are nonpiliated, and thus, all pilus-dependent functions are eliminated. Mutagenesis was performed on the middle one-third of pilQ , and mutants with colony morphologies consistent with the colony morphology of nonpiliated or underpiliated bacteria were selected. Nineteen mutants, each with a single amino acid substitution, were isolated and displayed diverse phenotypes in terms of PilQ multimer stability, pilus expression, transformation efficiency, and host cell adherence. The 19 mutants were grouped into five phenotypic classes based on functionality. Four of the five mutant classes fit the current model of pilus functionality, which proposes that a functional pilus assembly apparatus, not necessarily full-length pili, is required for transformation, while high levels of displayed pili are required for adherence. One class, despite having an underpiliated colony morphology, expressed high levels of pili yet adhered poorly, demonstrating that pilus expression is necessary but not sufficient for adherence and indicating that PilQ may be directly involved in host cell adherence. The collection of phenotypes expressed by these mutants suggests that PilQ has an active role in pilus expression and function.
Neisseria gonorrhoeae possesses a programmed recombination system that allows the bacteria to alter the major subunit of the type IV pilus, pilin or PilE. An alternate DNA structure known as a guanine quadruplex (G4) is required for pilin antigenic variation (pilin Av). The G-C base pairs within the G4 motif are required for pilin Av, but simple mutation of the loop bases does not affect pilin Av. We show that more substantial changes to the loops, in both size and nucleotide composition, with the core guanines unchanged, decrease or abrogate pilin Av. We investigated why these loop changes might influence the efficiency of pilin Av. RecA is a recombinase required for pilin Av that can bind the pilE G4 in vitro. RecA binds different G4 structures with altered loops with varied affinities. However, changes in RecA binding affinities to the loop mutants do not absolutely correlate with the pilin Av phenotypes. Interestingly, the yeast RecA ortholog, Rad51, also binds the pilE G4 structure with a higher affinity than it binds single-stranded DNA, suggesting that RecA G4 binding is conserved in eukaryotic orthologs. The thermal stability the pilE G4 structure and its loop mutants showed that the parental G4 structure had the highest melting temperature, and the melting temperature of the loop mutants correlated with pilin Av phenotype. These results suggest that the folding kinetics and stability of G4 structures are important for the efficiency of pilin Av.
The PilB protein of Neisseria gonorrhoeae has been reported to be involved in the regulation of pilin gene transcription, but it also possesses significant homology to the peptide methionine sulfoxide reductase family of enzymes, specifically MsrA and MsrB from Escherichia coli . MsrA and MsrB in E. coli are able to reduce methionine sulfoxide residues in proteins to methionines. In addition, the gonococcal PilB protein encodes for both MsrA and MsrB activity associated with the repair of oxidative damage to proteins. In this work, we demonstrate that the PilB protein of Neisseria gonorrhoeae is not involved in pilus expression. Additionally, we show that wild-type N. gonorrhoeae produces two forms of this polypeptide, one of which contains a signal sequence and is secreted from the bacterial cytoplasm to the outer membrane; the other lacks a signal sequence and is cytoplasmic. Furthermore, we show that the secreted form of the PilB protein is involved in survival in the presence of oxidative damage.
Symptomatic gonococcal infection, caused exclusively by the human-specific pathogen Neisseria gonorrhoeae (the gonococcus), is characterized by the influx of polymorphonuclear leukocytes (PMNs) to the site of infection. Although PMNs possess a potent antimicrobial arsenal comprising both oxidative and non-oxidative killing mechanisms, gonococci survive this interaction, suggesting that the gonococcus has evolved many defenses against PMN killing. We previously identified the NG1686 protein as a gonococcal virulence factor that protects against both non-oxidative PMN-mediated killing and oxidative killing by hydrogen peroxide. In this work, we show that deletion of ng1686 affects gonococcal colony morphology but not cell morphology and that overexpression of ng1686 does not confer enhanced survival to hydrogen peroxide on gonococci. NG1686 contains M23B endopeptidase active sites found in proteins that cleave bacterial cell wall peptidoglycan. Strains of N. gonorrhoeae expressing mutant NG1686 proteins with substitutions in many, but not all, conserved metallopeptidase active sites recapitulated the hydrogen peroxide sensitivity and altered colony morphology of the Δng1686 mutant strain. We showed that purified NG1686 protein degrades peptidoglycan in vitro and that mutations in many conserved active site residues abolished its degradative activity. Finally, we demonstrated that NG1686 possesses both dd-carboxypeptidase and endopeptidase activities. We conclude that the NG1686 protein is a M23B peptidase with dual activities that targets the cell wall to affect colony morphology and resistance to hydrogen peroxide and PMN-mediated killing.
Summary Some pathogenic microbes utilize homologous recombination to generate antigenic variability in targets of immune surveillance. These specialized systems rely on the cellular recombination machinery to catalyse dedicated, high‐frequency reactions that provide extensive diversity in the genes encoding surface antigens. A description of the specific mechanisms that allow unusually high rates of recombination without deleterious effects on the genome in the well‐characterized pilin antigenic variation systems of Neisseria gonorrhoeae and Neisseria meningitidis is presented. We will also draw parallels to selected bacterial and eukaryotic antigenic variation systems, and suggest the most pressing unanswered questions related to understanding these important processes.
