Acinetobacter baumannii is a Gram-negative bacterial pathogen notorious for causing serious nosocomial infections that resist antibiotic therapy. Research to identify factors responsible for the pathogen's success has been limited by the resources available for genome-scale experimental studies. This report describes the development of several such resources for A. baumannii strain AB5075, a recently characterized wound isolate that is multidrug resistant and displays robust virulence in animal models. We report the completion and annotation of the genome sequence, the construction of a comprehensive ordered transposon mutant library, the extension of high-coverage transposon mutant pool sequencing (Tn-seq) to the strain, and the identification of the genes essential for growth on nutrient-rich agar. These resources should facilitate large-scale genetic analysis of virulence, resistance, and other clinically relevant traits that make A. baumannii a formidable public health threat. IMPORTANCEAcinetobacter baumannii is one of six bacterial pathogens primarily responsible for antibiotic-resistant infections that have become the scourge of health care facilities worldwide. Eliminating such infections requires a deeper understanding of the factors that enable the pathogen to persist in hospital environments, establish infections, and resist antibiotics. We present a set of resources that should accelerate genome-scale genetic characterization of these traits for a reference isolate of A. baumannii that is highly virulent and representative of current outbreak strains.A cinetobacter baumannii is a Gram-negative opportunistic pathogen that causes infections with serious morbidity and mortality and is one of a group of six pathogens responsible for most multidrug-resistant (MDR) nosocomial infections (the ESKAPE pathogens, i.e., Enterococcus faecium, Staphylococcus aureus, Klebsiella pneumoniae, Acinetobacter baumannii, Pseudomonas aeruginosa, and Enterobacter species) (1, 2). The pathogen is infamous for its ability to persist in hospital settings, a feature that reflects its capacity for long-term survival on abiotic surfaces through resistance to desiccation and disinfectants (3).Genomic and molecular epidemiological studies of A. baumannii isolates have helped define the pathogen's global population structure, its antibiotic resistance gene repertoire, the size and content of its pangenome, and phylogenetic relationships among outbreak strains (3-6). Three primary clonal lineages (GC1 to GC3) appear responsible for the majority of hospital outbreaks globally (7). Although these lineages display restricted genetic diversity among core genes (7), the species' genome is actually quite dynamic. Strains display striking variability in accessory gene content (5, 8), including antibiotic resistance genes (9), even among related isolates of a single outbreak (10). This genomic variability presumably reflects the actions of transmissible plasmids, insertion elements, phage, integrons, natural transformation, and reco...
Francisella tularensis, the causative agent of tularemia, is one of the most infectious bacterial pathogens known and is a category A select agent. We created a sequence-defined, near-saturation transposon mutant library of F. tularensis novicida, a subspecies that causes a tularemia-like disease in rodents. The library consists of 16,508 unique insertions, an average of >9 insertions per gene, which is a coverage nearly twice that of the greatest previously achieved for any bacterial species. Insertions were recovered in 84% (1,490) of the predicted genes. To achieve high coverage, it was necessary to construct transposons carrying an endogenous Francisella promoter to drive expression of antibiotic resistance. An analysis of genes lacking (or with few) insertions identified nearly 400 candidate essential genes, most of which are likely to be required for growth on rich medium and which represent potential therapeutic targets. To facilitate genome-scale screening using the mutant collection, we assembled a sublibrary made up of two purified mutants per gene. The library provides a resource for virtually complete identification of genes involved in virulence and other nonessential processes.essential genes ͉ promoter ͉ tularemia ͉ U112
Mutant hunts using comprehensive sequence-defined libraries make it possible to identify virtually all of the nonessential functions required for different bacterial processes. However, the success of such screening depends on the accuracy of mutant identification in the mutant library used. To provide a high-quality library for Pseudomonas aeruginosa PAO1, we created a sequence-verified collection of 9,437 transposon mutants that provides genome coverage and includes two mutants for most genes. Mutants were cherry-picked from a larger library, colony-purified, and resequenced both individually using Sanger sequencing and in a pool using Tn-seq. About 8% of the insertion assignments were corrected, and in the final library nearly 93% of the transposon locations were confirmed by at least one of the resequencing procedures. The extensive sequence verification and inclusion of more than one mutant for most genes should help minimize missed or erroneous genotype-phenotype assignments in studies using the new library. Comprehensive sequence-defined mutant libraries have facilitated the genetic dissection of complex processes in several bacterial species (7). In principle, such libraries can be screened directly for mutants exhibiting a given phenotype to provide relatively complete identification of nonessential functions responsible for the trait. In practice, however, such screens can fail to achieve completeness and may even suggest incorrect genotypephenotype associations. There are several potential contributing factors that arise from how mutant libraries are created and quality control tested.Most defined mutant libraries have been generated by largescale transposon mutagenesis and sequencing. Relatively complete genome coverage requires that an average of 5 to 10 unique insertions per gene be identified (7). Such large primary libraries serve as a source of mutants for smaller secondary libraries that retain genome coverage and facilitate phenotype screening (1-3, 6). Secondary libraries are usually made up of one or more colonypurified mutants per gene, with insertions situated toward the centers of coding regions to help ensure inactivation. A limitation of most secondary libraries is that mutant identities have not been verified by resequencing. In rare cases in which they have been checked, many assignments (typically on the order of 10%) have been found to be incorrect (3). An additional limitation of secondary libraries consisting of only one mutant per gene is that screens using them are at risk of missing genotype-phenotype associations due to mutant cross-contamination and insertion alleles that fail to inactivate. Libraries with more than one mutant per gene provide more than one chance to identify an association.This report describes a Pseudomonas aeruginosa PAO1 secondary transposon mutant library with two mutants for most genes in which mutant identities have been confirmed by multiple resequencings. The redundancy and verification of mutant identities should make the library particularly useful...
Burkholderia pseudomallei, the etiologic agent of human melioidosis, is capable of causing severe acute infection with overwhelming septicemia leading to death. A high rate of recurrent disease occurs in adult patients, most often due to recrudescence of the initial infecting strain. Pathogen persistence and evolution during such relapsing infections are not well understood. Bacterial cells present in the primary inoculum and in late infections may differ greatly, as has been observed in chronic disease, or they may be genetically similar. To test these alternative models, we conducted whole-genome comparisons of clonal primary and relapse B. pseudomallei isolates recovered six months to six years apart from four adult Thai patients. We found differences within each of the four pairs, and some, including a 330 Kb deletion, affected substantial portions of the genome. Many of the changes were associated with increased antibiotic resistance. We also found evidence of positive selection for deleterious mutations in a TetR family transcriptional regulator from a set of 107 additional B. pseudomallei strains. As part of the study, we sequenced to base-pair accuracy the genome of B. pseudomallei strain 1026b, the model used for genetic studies of B. pseudomallei pathogenesis and antibiotic resistance. Our findings provide new insights into pathogen evolution during long-term infections and have important implications for the development of intervention strategies to combat recurrent melioidosis.
The nosocomial pathogen Acinetobacter baumannii is a frequent cause of hospital-acquired infections worldwide and is a challenge for treatment due to its evolved resistance to antibiotics, including carbapenems. Here, to gain insight on A. baumannii antibiotic resistance mechanisms, we analyse the protein interaction network of a multidrug-resistant A. baumannii clinical strain (AB5075). Using in vivo chemical cross-linking and mass spectrometry, we identify 2,068 non-redundant cross-linked peptide pairs containing 245 intra- and 398 inter-molecular interactions. Outer membrane proteins OmpA and YiaD, and carbapenemase Oxa-23 are hubs of the identified interaction network. Eighteen novel interactors of Oxa-23 are identified. Interactions of Oxa-23 with outer membrane porins OmpA and CarO are verified with co-immunoprecipitation analysis. Furthermore, transposon mutagenesis of oxa-23 or interactors of Oxa-23 demonstrates changes in meropenem or imipenem sensitivity in strain AB5075. These results provide a view of porin-localized antibiotic inactivation and increase understanding of bacterial antibiotic resistance mechanisms.
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