SummaryThe 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.
Most strains of Neisseria gonorrhoeae carry the 57-kb gonococcal genetic island (GGI), as do a few strains of Neisseria meningitidis. The GGI is inserted into the chromosome at the dif site (difA) and is flanked by a partial repeat of the dif site (difB). Since dif is a sequence recognized by the site-specific recombinases XerC and XerD and the GGI shows evidence of horizontal acquisition, we hypothesized that the GGI may be acquired or lost by XerCD-mediated site-specific recombination. We show that while the GGI flanked by wild-type dif sites, difA and difB, is not readily lost from the gonococcal chromosome, the substitution of difB with another copy of difA allows the frequent excision and loss of the GGI. In mutants carrying two difA sites (difA ؉ difA ؉ ), the GGI can be detected as an extrachromosomal circle that exists transiently. A mutation of xerD diminished GGI excision from the chromosome of a difA ؉ difA ؉ strain, while mutations in recA or type IV secretion genes had no effect on the loss of the GGI. These data indicate that the GGI is maintained by the replication of the chromosome and that GGI excision and loss are dependent upon the dif sequence and xerD. The detection of a circular form of the GGI in a wild-type strain suggests that GGI excision may occur naturally and could function to facilitate GGI transfer. These data suggest a model of GGI excision and loss explaining the absence of the GGI from some gonococcal strains and the maintenance of variant GGIs in some gonococcal and meningococcal isolates.
Survival of Neisseria gonorrhoeae within host epithelial cells is expected to be important in the pathogenesis of gonococcal disease. We previously demonstrated that strain FA1090 derives iron from a host cell in a process that requires the Ton complex and a putative TonB-dependent transporter, TdfF. FA1090, however, lacks the gonococcal genetic island (GGI) that is present in the majority of strains. The GGI in strain MS11 has been partially characterized, and it encodes a type IV secretion system (T4SS) involved in DNA release. In this study we investigated the role of iron acquisition and GGI-encoded gene products in gonococcal survival within cervical epithelial cells. We demonstrated that intracellular survival of MS11 was dependent on acquisition of iron from the host cell, but unlike the findings for FA1090, expression of the Ton complex was not required. Survival was not dependent on a putative TonB-like protein encoded in the GGI but instead was directly linked to T4SS structural components in a manner independent of the ability to release or internalize DNA. These data suggest that expression of selected GGI-encoded open reading frames confers an advantage during cervical cell infection. This study provides the first link between expression of the T4SS apparatus and intracellular survival of gonococci.Neisseria gonorrhoeae is the causative agent of the sexually transmitted infection gonorrhea. Although symptomatic urethritis is the most common presentation in men, asymptomatic infections associated with cervical acquisition in women can lead to ascension of the bacteria to the upper reproductive tract. In this context, an understanding of the immune evasion tactics employed by this organism is essential for eliminating potential downstream sequelae, including disseminated gonococcal infection, pelvic inflammatory disease, infertility, and ectopic pregnancy (23,45). The outcome of gonococcal infections and the resulting clinical manifestations elicited are determined, in part, by strain-specific factors. The differences are expected to impact host-pathogen interactions that occur at the primary site of infection, the urogenital epithelium.Productive gonococcal infections require that the bacteria circumvent the innate iron-withholding mechanisms employed by the human host. Moreover, epithelial cell responses to Neisseria infection, including reduced expression of the transferrin receptor gene and diminished transferrin receptor cycling, which result in further limitation of iron availability, have been described previously (8,9,34). As the ability to acquire iron from the human host is a key determinant in gonococcal pathogenesis (1,15), N. gonorrhoeae has evolved numerous mechanisms to acquire this required nutrient in an iron-depleted environment. Various iron uptake systems that are thought to promote gonococcal replication in extracellular niches have been characterized (42). Specifically, these systems hijack iron from the host proteins transferrin (14), lactoferrin (7), and hemoglobin (12) in a ma...
IntroductionApproximately 25%–35% of the 1991 Gulf War Veteran population report symptoms consistent with Gulf War Illness (GWI), a chronic, multi-symptom illness characterised by fatigue, pain, irritable bowel syndrome and problems with cognitive function. GWI is a disabling problem for Gulf War Veterans, and there remains a critical need to identify innovative, novel therapies.Gut microbiota perturbation plays a key role in the symptomatology of other chronic multi-symptom illnesses, including myalgic encephalomyelitis/chronic fatigue syndrome (ME/CFS). Given similarities between ME/CFS and GWI and the presence of gastrointestinal disorders in GWI patients, Veterans with GWI may also have gut abnormalities like those seen with ME/CFS. In this longitudinal cohort study, we are comparing the diversity (structure) and the metagenomes (function) of the gut microbiome between Gulf War Veterans with and without GWI. If we find differences in Veterans with GWI, the microbiome could be a target for therapeutic intervention to alleviate GWI symptoms.Methods and analysisParticipants answer questions about diet, exercise and lifestyle factors. Participants also complete a questionnaire (based on the Kansas case definition of GWI) regarding their medical history and symptoms; we use this questionnaire to group participants into GWI versus healthy control cohorts. We plan to enrol 52 deployed Gulf War Veterans: 26 with GWI and 26 healthy controls. Participants provide stool and saliva samples weekly for an 8-week period for microbiome analyses. Participants also provide blood samples at the beginning and end of this period, which we will use to compare measures of inflammation markers between the groups.Ethics and disseminationThe protocol was approved by the University of Wisconsin-Madison Health Sciences Institutional Review Board and the William S. Middleton Memorial Veterans Hospital Research and Development Committee. Results of this study will be submitted for publication in a peer-reviewed journal.
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