Neisseria gonorrhoeae secretes chromosomal DNA via a novel type IV secretion system

The process of DNA donation for natural transformation of bacteria is poorly understood and has been assumed to involve bacterial cell death. Recently in Neisseria gonorrhoeae we found that mutations in three genes in the gonococcal genetic island (GGI) reduced the ability of a strain to act as a donor in transformation and to release DNA into the culture. To better characterize the GGI and the process of DNA donation, the 57 kb genetic island was cloned, sequenced and subjected to insertional mutagenesis. DNA sequencing revealed that the GGI has characteristics of a horizontally acquired genomic island and encodes homologues of type IV secretion system proteins. The GGI was found to be incorporated near the chromosomal replication terminus at the dif site, a sequence targeted by the site-specific recombinase XerCD. Using a plasmid carrying a small region of the GGI and the associated dif site, we demonstrated that this model island could be integrated at the dif site in strains not carrying the GGI and was spontaneously excised from that site. Also, we were able to delete the entire 57 kb region by transformation with DNA from a strain lacking the GGI. Thus the GGI was likely acquired and integrated into the gonococcal chromosome by site-specific recombination and may be lost by site-specific recombination or natural transformation. We made mutations in six putative type IV secretion system genes and assayed these strains for the ability to secrete DNA. Five of the mutations greatly reduced or completely eliminated DNA secretion. Our data indicate that N. gonorrhoeae secretes DNA via a specific process. Donated DNA may be used in natural transformation, contributing to antigenic variation and the spread of antibiotic resistance, and it may modulate the host immune response.     

Roles of the recJ and recN Genes in Homologous Recombination and DNA Repair Pathways of Neisseria gonorrhoeae

The paradigm of homologous recombination comes from Escherichia coli, where the genes involved have been segregated into pathways. In the human pathogen Neisseria gonorrhoeae (the gonococcus), the pathways of homologous recombination are being delineated. To investigate the roles of the gonococcal recN and recJ genes in the recombination-based processes of the gonococcus, these genes were inactivated in the N. gonorrhoeae strain FA1090. We report that both recN and recJ loss-of-function mutants show decreased DNA repair ability. In addition, the recJ mutant was decreased in pilus-dependent colony morphology variation frequency but not DNA transformation efficiency, while the recN mutant was decreased in DNA transformation efficiency but not pilus-dependent variation frequency. We were able to complement all of these deficiencies by supplying an ectopic functional copy of either recJ or recN at an irrelevant locus. These results describe the role of recJ and recN in the recombination-dependent processes of the gonococcus and further define the pathways of homologous recombination in this organism.     

Transformation of leucine and rifampin traits in Neisseria gonorrhoeae with deoxyribonucleic acid from homologous and heterologous origins.

A leucine-requiring, rifampin-sensitive strain of Neisseria gonorrhoeae was transformed to a leucine-nonrequiring, rifampin-resistant phenotype with deoxyribonucleic acid (DNA) obtained from both N. meningitidis and N. gonorrhoeae. The transforming efficiency of the meningococcal DNA was about 10- to 100-fold less than that of the homologous gonococcal DNA. A chemically defined medium that would support growth of most gonococcal isolates was used as a complete medium. A minimal medium was used for selection of Leu+ transformants. N-methyl-N'-nitro-N-nitrosoguanidine was used as a mutagen for isolating leucine prototrophs from leucine-requiring isolates of N. gonorrohoeae.     

PilC of Neisseria meningitidis is involved in class II pilus formation and restores pilus assembly, natural transformation competence and adherence to epithelial cells in PilC-deficient gonococci

Type 4 pili produced by the pathogenic Neisseria species constitute primary determinants for the adherence to host tissues. In addition to the major pilin subunit (PilE), neisserial pili contain the variable PilC proteins represented by two variant gene copies in most pathogenic Neisseria isolates. Based upon structural differences in the conserved regions of PilE, two pilus classes can be distinguished in Neisseria meningitidis . For class I pili found in both Neisseria gonorrhoeae and N. meningitidis , PilC proteins have been implicated in pilus assembly, natural transformation competence and adherence to epithelial cells. In this study, we used primers specific for the pilC2 gene of N. gonorrhoeae strain MS11 to amplify, by the polymerase chain reaction, and clone a homologous pilC gene from N. meningitidis strain A1493 which produces class II pili. This gene was sequenced and the deduced amino acid sequence showed 75.4% and 73.8% identity with the gonococcal PilC1 and PilC2, respectively. These values match the identity value of 74.1% calculated for the two N. gonorrhoeae MS11 PilC proteins, indicating a horizontal relationship between the N. gonorrhoeae and N. meningitidis pilC genes. We provide evidence that PilC functions in meningococcal class II pilus assembly and adherence. Furthermore, expression of the cloned N. meningitidis pilC gene in a gonococcal pilC1,2 mutant restores pilus assembly, adherence to ME-180 epithelial cells, and transformation competence to the wild-type level. Thus, PilC proteins exhibit indistinguishable functions in the context of class I and class II pili.     

Analysis of the Piv recombinase-related gene family of Neisseria gonorrhoeae

Neisseria gonorrhoeae (the gonococcus) is an obligate human pathogen and the causative agent of the disease gonorrhea. The gonococcal pilus undergoes antigenic variation through high-frequency recombination events between unexpressed pilS silent copies and the pilin expression locus pilE. The machinery involved in pilin antigenic variation identified to date is composed primarily of genes involved in homologous recombination. However, a number of characteristics of antigenic variation suggest that one or more recombinases, in addition to the homologous recombination machinery, may be involved in mediating sequence changes at pilE. Previous work has identified several genes in the gonococcus with significant identity to the pilin inversion gene (piv) from Moraxella species and transposases of the IS110 family of insertion elements. These genes were candidates for a recombinase system involved in pilin antigenic variation. We have named these genes irg for invertase-related gene family. In this work, we characterize these genes and demonstrate that the irg genes do not complement for Moraxella lacunata Piv invertase or IS492 MooV transposase activities. Moreover, by inactivation of all eight gene copies and overexpression of one gene copy, we conclusively show that these recombinases are not involved in gonococcal pilin variation, DNA transformation, or DNA repair. We propose that the irg genes encode transposases for two different IS110-related elements given the names ISNgo2 and ISNgo3. ISNgo2 is located at multiple loci on the chromosome of N. gonorrhoeae, and ISNgo3 is found in single and duplicate copies in the N. gonorrhoeae and Neisseria meningitidis genomes, respectively.     

Genome plasticity in Neisseria gonorrhoeae

Abstract The pathogenic Neisseria have exploited the processes of horizontal DNA transfer and genetic recombination as mechanisms for the generation of extensive protein variation and modulation of gene expression. Localized recombinations have been well documented in members of multigene families as have alterations in short repetitive sequences. Here we report an analysis of the chromosomal structure of a defined lineage of Neisseria gonorrhoeae strain MS 11 pilin variants. This study reveals the occurrence of large rearrangements, including the amplification of a 26 kb region and an inversion involving more than a third of the chromosome. Additionally, a restriction site polymorphism that correlates with pilin expression has been observed. These findings highlight the flexibility of the gonococcal genome.     

Immunologic classification of Neisseria gonorrhoeae with micro-immunofluorescence.

A reproducible immunologic classification of Neisseria gonorrhoeae strains has been achieved by the micro-immunofluorescence (Micro-IF)3 method by using formalinized whole organisms as test antigens and mouse antisera prepared by i.v. immunization with the whole organisms as antibody. Immunologic differences among Neisseria species were also distinct in this test system. Immunologic differences among gonococcal strains were not influenced by gonococcal colony type. Classification of gonococci was facilitated by use of antisera absorbed with an antigenically unique gonococcus strain. Of 180 gonococcal strains, 175 could be classified into three immunotypes: A, B, and C. Each type was further divided into subtypes designated A1, A2, A3, B1, B2, B3, C1, and C2. Minor antigenic differences still exist within each subtype. The two gonococcal isolates from each of 17 pairs of sexual contacts fell into the same subtype. Seventy-one of 73 isolates which required arginine, hypoxanthine, and uracil for growth (Arg-Hyx-Ura-) and seven of 107 other auxotypes belonged to subtypes A2 and A3. Marked geographical differences in distribution of gonococcal immunotypes were observed among those available for testing. Subtypes A2 and A3 were predominant in Seattle whereas types B and C were predominant in Southeast Asia. The only Arg-Hyx-Ura- isolates not belonging to subtypes A2 or A3 were the only two that were serum sensitive. This Micro-IF immunotyping appears potentially useful for future immunologic, epidemiologic, and genetic studies of N. gonorrhoeae.     

Neisseria gonorrhoeae recJ mutants show defects in recombinational repair of alkylated bases and UV-induced pyrimidine dimers

Neisseria gonorrhoeae lacks several common DNA repair pathways found in other organisms. As recent evidence had indicated that gonococci use recombinational repair to repair UV-induced DNA lesions, this study examined whether the gonococcal RecJ homologue contributes in this repair capacity. The recJ gene from strain MS11 was cloned and sequenced and was found to show a considerable degree of identity to its Escherichia coli homologue. A N. gonorrhoeae delta recJ mutant was constructed and tested for recombinational proficiency as well as for defects in DNA repair. In the absence of the RecJ exonuclease, DNA transformation and pilin switching occurred at wild type levels, indicating that the efficiency of recombination remained unimpaired. In contrast, N. gonorrhoeae delta recJ mutants showed extreme sensitivity to low levels of UV irradiation and to exposure to DNA-alkylating reagents [e.g. ethyl methanesulfonate (EMS) and methyl methanesulfonate (MMS)]. Complementation of the gonococcal recJ mutant in cis restored resistance to low-level UV, indicating that the gonococcal RecJ protein is involved in recombinational repair, and can act independently of other single-strand-specific exonucleases. Furthermore, transformation competence was not required for RecJ-dependent DNA repair. Overall, the data show that N. gonorrhoeae recJ mutants present a unique phenotype when compared to their E. coli recJ counterparts, and further support the contention that RecORJ-dependent recombinational repair is a major DNA repair pathway in the genus Neisseria.     

A genetic screen identifies genes and sites involved in pilin antigenic variation in Neisseria gonorrhoeae

It has previously been shown that the frequency of pilin antigenic variation in Neisseria gonorrhoeae (the gonococcus, Gc) is regulated by iron availability. To identify factors involved in pilin variation in an iron-dependent or an iron-independent manner, we conducted a genetic screen of transposon-mutated gonococci using a pilus-dependent colony morphology phenotype to detect antigenic variation deficient mutants. Forty-six total mutants representing insertions in 30 different genes were shown to have reduced colony morphology changes resulting from impaired pilin variation. Five mutants exhibited an iron-dependent decrease in pilin variation, while the remaining 41 displayed an iron-independent decrease in pilin variation. Based on the levels of antigenic variation impairment, we defined the genes as being essential for, important for, or involved in antigenic variation. DNA repair and DNA transformation frequencies of each mutant were measured to determine whether other recombination-based processes were also affected in the mutants. Each mutant was placed into one of six classes based on their pilin variation, DNA repair and DNA transformation phenotypes. Among the many genes identified, recR is shown to be an additional member of the gonococcal RecF-like recombination pathway. In addition, recG and ruvA represent the first evidence that the processing of Holliday junctions is required for pilin antigenic variation. Moreover, two independent insertions in a non-coding region upstream of the pilE gene suggest that cis-acting sequences important for pilin variation are found in that region. Finally, insertions that effect expression of the thrB and thrC genes suggest that molecules in the threonine biosynthetic pathway are important for pilin variation. Many of the other genes identified in this genetic screen do not have an obvious role in pilin variation, DNA repair, or DNA transformation.     

Biochemical and genetic studies with arginine and proline auxotrophs of Neisseria gonorrhoeae

The prevalence of specific arginine biosynthesis gene defects was studied for 319 arginine-requiring clinical isolates of Neisseria gonorrhoeae by using the ability of the strains to utilize intermediates of arginine biosynthesis. Only 11% of the uracil-requiring strains defective in the carbamylation of ornithine to yield citrulline had a defective carbamoylphosphate synthetase gene (carAB). Strains defective in carAB were of auxotype CUH. The other strains (89%) having a dual requirement for citrulline and uracil, which were mostly of auxotype PCU, were defective in the ornithine transcarbamoylase gene (argF). Over 90% of the strains were defective either in argJ (174 strains) or in argF (126 strains). Three argininosuccinate-requiring strains (i.e., defective in argG) of auxotype PAU were identified. Some of the arginine auxotrophs of N. gonorrhoeae defective in carAB, argJ, argF, or argG were complemented by genetic transformation with DNA from recombinant bacteriophages carrying characterized gonococcal arginine biosynthesis genes. Gene defects in proA (five strains) and in proB (six strains) were identified by gonococcal transformation assays with recombinant bacteriophages or plasmids carrying proline biosynthesis genes from N. gonorrhoeae. None of the 11 proline-requiring strains tested was defective in proC.     

ComE, a competence protein from Neisseria gonorrhoeae with DNA-binding activity

Neisseria gonorrhoeae is naturally able to take up exogenous DNA and undergo genetic transformation. This ability correlates with the presence of functional type IV pili, and uptake of DNA is dependent on the presence of a specific 10-bp sequence. Among the known competence factors in N. gonorrhoeae, none has been shown to interact with the incoming DNA. Here we describe ComE, a DNA-binding protein involved in neisserial competence. The gene comE was identified through similarity searches in the gonococcal genome sequence, using as the query ComEA, the DNA receptor in competent Bacillus subtilis. The gene comE is present in four identical copies in the genomes of both N. gonorrhoeae and Neisseria meningitidis, located downstream of each of the rRNA operons. Single-copy deletion of comE in N. gonorrhoeae did not have a measurable effect on competence, whereas serial deletions led to gradual decrease in transformation frequencies, reaching a 4 x 10(4)-fold reduction when all copies were deleted. Transformation deficiency correlated with impaired ability to take up exogenous DNA; however, the mutants presented normal piliation and twitching motility phenotype. The product of comE has 99 amino acids, with a predicted signal peptide; by immunodetection, a 8-kDa protein corresponding to processed ComE was observed in different strains of N. gonorrhoeae and N. meningitidis. Recombinant His-tagged ComE showed DNA binding activity, without any detectable sequence specificity. Thus, we identified a novel gonococcal DNA-binding competence factor which is necessary for DNA uptake and does not affect pilus biogenesis or function.     

The product of the pilQ gene is essential for the biogenesis of type IV pili in Neisseria gonorrhoeae

The product of the Neisseria gonorrhoeae omc gene possesses regions homologous to those found in members of a protein superfamily that are associated with the translocation of proteins and DNA-protein complexes across the outer membrane. Amongst its protein homologues, Omc has higher overall homology to PilQ, which is required for type IV pilus expression in Pseudomonas aeruginosa , and OrfE, which is required for sequence-specific DNA uptake by Haemophilus influenzae . The function of Omc, however, is unknown and gonococcal omc mutants have not been described. We constructed gonococcal mutants expressing truncated forms of the protein, and found that these mutants are severely defective for both pilus expression and competence for natural transformation. To be consistent with pre-existing pilus gene nomenclature, we have redesignated the gene pilQ instead of omc , and its product, PilQ instead of Omc. The MS11 gene was sequenced and found to differ from the DNA sequence reported for that of another gonococcal strain; these differences were associated with a repeated DNA element, suggesting a genetic basis for structural variation in PilQ. The results also show that PilQ⁻ mutants are distinct from previously described gonococcal pilus-assembly mutants and P. aeruginosa PilQ⁻ mutants by virtue of their expression of rare pilus filaments. Taking these data into account, PilQ is proposed to function in the terminal steps of organelle biogenesis by acting as a pilus channel or pore.     

Neisseria gonorrhoeae virulence factor NG1686 is a bifunctional M23B family metallopeptidase that influences resistance to hydrogen peroxide and colony morphology

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.     

Construction of a Neisseria gonorrhoeae MS11 derivative deficient in NgoMI restriction and modification.

We have cloned from Neisseria gonorrhoeae MS11 the gene encoding a methylase that modifies the sequence GCCGGC. The corresponding restriction enzyme was also encoded by this clone. Sequence analysis demonstrated that the methylase shares sequence similarities with other cytosine methylases, but the sequence organization of M.NgoMI is different from that seen for other cytosine methylases. A deletion was introduced into the chromosome of N. gonorrhoeae MS11 to produce strain MUG701, a strain that is inactivated in both the methylase and the restriction genes. Although this strain no longer methylated its DNA at the NgoMI recognition sequence, cells were viable and had no other significant phenotypic changes. Transformation data indicated that MS11 does not produce enough restriction activity to block plasmid transformation in the gonococcus, even though restriction activity could be demonstrated in E. coli containing the cloned gene.     

Sequence analysis and complementation studies of the argJ gene encoding ornithine acetyltransferase from Neisseria gonorrhoeae.

Clinical isolates of Neisseria gonorrhoeae frequently are deficient in arginine biosynthesis. These auxotrophs often have defects in the fifth step of the arginine biosynthetic pathway, the conversion of acetylornithine to ornithine. This reaction is catalyzed by the enzyme ornithine acetyltransferase, which is a product of the argJ gene. We have cloned and sequenced the gonococcal argJ gene and found that it contains an open reading frame of 1,218 nucleotides and encodes a peptide with a deduced Mr of 42,879. This predicted size was supported by minicell analysis. This gene was capable of complementing both Escherichia coli argE and argA mutations and of transforming an ArgJ- strain of N. gonorrhoeae to Arg+. Southern blots were able to detect bands that specifically hybridized to the gonococcal argJ gene in genomic DNA from Pseudomonas aeruginosa but not E. coli, a result that reflects the divergent nature of the arginine biosynthetic pathway in these organisms.