Search results for "Genomic island"

showing 10 items of 12 documents

Wild eel microbiome reveals that skin mucus of fish could be a natural niche for aquatic mucosal pathogen evolution

2017

Background Fish skin mucosal surfaces (SMS) are quite similar in composition and function to some mammalian MS and, in consequence, could constitute an adequate niche for the evolution of mucosal aquatic pathogens in natural environments. We aimed to test this hypothesis by searching for metagenomic and genomic evidences in the SMS-microbiome of a model fish species (Anguilla Anguilla or eel), from different ecosystems (four natural environments of different water salinity and one eel farm) as well as the water microbiome (W-microbiome) surrounding the host. Results Remarkably, potentially pathogenic Vibrio monopolized wild eel SMS-microbiome from natural ecosystems, Vibrio anguillarum/Vibr…

0301 basic medicineMicrobiology (medical)DNA BacterialVibrio anguillarumGenomic IslandsZoologyAnimals WildVibrio vulnificusmedicine.disease_causeMicrobiologylcsh:Microbial ecologyEvolution Molecular03 medical and health sciencesMicrobial ecologymedicineAnimalsHumansMicrobiomeVibrioSkin mucusSkinbiologyBacteriaResearchMicrobiotaAttached microbiotaGenomicsbiology.organism_classificationAnguillaPathogenicity islandMucusVibrioMucusGenòmica030104 developmental biologyVibrio choleraeBacteris patògenslcsh:QR100-130MicrobiomeMetagenomicsWater Microbiology
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New insights regarding Acinetobacter genomic island-related elements

2020

The objective of this study was to mobilize the Acinetobacter genomic island 1-A (AGI1-A) from Enterobacter hormaechei EclCSP2185 (E. cloacae complex) and to search for the distribution and structure of AGI1-related elements in the NCBI database. AGI1-A was transferred to Escherichia coli. Analysis of the attachment (att) sites could locate the possible recombination crossover in the att sequences at position 10-11 (GG) in the last 18 bp of trmE. In silico detection of AGI backbones in the wgs database identified AGI variants in Salmonella enterica (83 strains), Vibrio cholerae (33), E. hormaechei (12), Acinetobacter baumannii (2), most belonging to prevalent clones (ST40, ST69, ST114 and S…

Acinetobacter baumanniiDNA Bacterial0301 basic medicineMicrobiology (medical)Genomic IslandsKlebsiella pneumoniae[SDV]Life Sciences [q-bio]030106 microbiologyEnterobactermedicine.disease_causeIntegronIntegrons03 medical and health sciences0302 clinical medicineDrug Resistance Multiple BacterialGenomic islandEscherichia colimedicineHumansPharmacology (medical)030212 general & internal medicineProteus mirabilisVibrio choleraeEscherichia coliGeneticsbiologySalmonella entericaSequence Analysis DNAGeneral MedicineAcinetobacterbiology.organism_classificationAnti-Bacterial AgentsAcinetobacter baumanniiInfectious DiseasesSalmonella entericaVibrio choleraebiology.protein
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Dissemination of a Carbapenem-Resistant Acinetobacter baumannii Strain Belonging to International Clone II/Sequence Type 2 and Harboring a Novel AbaR…

2013

ABSTRACT An outbreak of hospital-acquired Acinetobacter baumannii infections, caused by a bla OXA-23 -positive carbapenem-resistant strain belonging to international clone II/ST2, was detected in Latvia. The strain was partially equipped with the armA gene and the intI1-aacA4-catB8-aadA1-qacE Δ 1 class 1 integron. In addition, the strain carried AbaR25, a novel AbaR4-like resistance island of ∼46,500 bp containing structures similar to the previously described AbaR22 and Tn 6167 islands. AbaR25 was characterized by the occurrence of a second copy of Tn 6022a interrupted by Tn 2006 carrying the bla OXA-23 gene.

Acinetobacter baumanniiclone (Java method)Genomic IslandsMolecular Sequence DataMicrobial Sensitivity TestsIntegronbeta-Lactam Resistancebeta-LactamasesDisease OutbreaksIntegronsMicrobiologyMechanisms of ResistancePharmacology (medical)GeneVDP::Medical disciplines: 700::Basic medical dental and veterinary science disciplines: 710::Medical molecular biology: 711Sequence (medicine)PharmacologyCross InfectionMolecular EpidemiologyMolecular epidemiologyStrain (chemistry)biologyOutbreakMethyltransferasesVDP::Medical disciplines: 700::Basic medical dental and veterinary science disciplines: 710::Medical microbiology: 715biology.organism_classificationLatviaAnti-Bacterial AgentsBacterial Typing TechniquesAcinetobacter baumanniiInfectious DiseasesCarbapenemsVDP::Medisinske Fag: 700::Basale medisinske odontologiske og veterinærmedisinske fag: 710::Medisinsk immunologi: 716VDP::Medisinske Fag: 700::Basale medisinske odontologiske og veterinærmedisinske fag: 710::Medisinsk mikrobiologi: 715DNA Transposable Elementsbiology.proteinGenes MDRVDP::Medical disciplines: 700::Basic medical dental and veterinary science disciplines: 710::Medical immunology: 716VDP::Medisinske Fag: 700::Basale medisinske odontologiske og veterinærmedisinske fag: 710::Medisinsk molekylærbiologi: 711Acinetobacter Infections
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Two new Salmonella genomic islands 1 from Proteus mirabilis and description of blaCTX-M-15 on a variant (SGI1-K7)

2018

Objectives To characterize the structure of Salmonella genomic islands 1 (SGI1s) from two clinical Proteus mirabilis isolates: one producing an ESBL and the other a penicillinase. Methods WGS completed by PCR and Sanger sequencing was performed to determine sequences of SGI1s from Pm2CHAMA and Pm37THOMI strains. Results Two new variants of SGI1 named SGI1-Pm2CHAMA (53.6 kb) and SGI1-K7 (55.1 kb) were identified. The backbone of SGI1-Pm2CHAMA shared 99.9% identity with that of SGI1. Its MDR region (26.3 kb) harboured two class 1 integrons (an In2-type integron and an In4-type integron) containing in particular a qacH cassette (encoding a quaternary ammonium compound efflux pump). These two i…

DNA Bacterial0301 basic medicineMicrobiology (medical)Transposable elementSalmonellaGenomic Islands030106 microbiologyBiologyIntegronmedicine.disease_causePolymerase Chain Reactionbeta-LactamasesIntegronsTransposition (music)03 medical and health sciencessymbols.namesakePlasmidSalmonellaDrug Resistance Multiple BacterialmedicineHumansPharmacology (medical)Proteus mirabilisPharmacologySanger sequencingGeneticsWhole Genome SequencingGenetic Variationbiology.organism_classificationProteus mirabilisEnterobacteriaceaeAnti-Bacterial AgentsHospitalizationInfectious DiseasesGenes Bacterialsymbolsbiology.proteinFranceProteus InfectionsPlasmidsJournal of Antimicrobial Chemotherapy
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The rise and the fall of a Pseudomonas aeruginosa endemic lineage in a hospital

2021

The biological features that allow a pathogen to survive in the hospital environment are mostly unknown. The extinction of bacterial epidemics in hospitals is mostly attributed to changes in medical practice, including infection control, but the role of bacterial adaptation has never been documented. We analysed a collection of Pseudomonas aeruginosa isolates belonging to the Besançon Epidemic Strain (BES), responsible for a 12year nosocomial outbreak, using a genotype-to-phenotype approach. Bayesian analysis estimated the emergence of the clone in the hospital 5 years before its opening, during the creation of its water distribution network made of copper. BES survived better than the refe…

DNA Bacterialparallel evolutionLineage (genetic)Genomic IslandsPathogens and EpidemiologyBiologymedicine.disease_causeAmoeba (operating system)Disease OutbreaksMicrobiology03 medical and health sciencesAntibiotic resistanceDrug Resistance Multiple BacterialGenomic islandbacterial pathogensmedicineHumansPseudomonas InfectionsPathogenGenome size[SDV.MP] Life Sciences [q-bio]/Microbiology and ParasitologyResearch Articles030304 developmental biology0303 health sciencesoutbreak030306 microbiologyPseudomonas aeruginosahigh-risk cloneOutbreakBayes TheoremSequence Analysis DNAGeneral MedicineHospitals3. Good healthPhenotype[SDV.MP]Life Sciences [q-bio]/Microbiology and ParasitologyPseudomonas aeruginosa
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Contamination of a hospital plumbing system by persister cells of a copper-tolerant high-risk clone of Pseudomonas aeruginosa

2019

Abstract Background Pseudomonas aeruginosa (PA) is an important opportunistic pathogen that thrives best in the distal elements of plumbing and waste-water systems. Although nosocomial outbreaks of PA have been associated with water sources, the role of the plumbing system of healthcare premises as a reservoir for this pathogen is still unclear. Materials and methods We collected water samples from 12 technical areas, distant from any medical activity, in a teaching hospital in France once a week for 11 weeks. We used a method that resuscitates persister cells because of the nutrient-poor conditions and the presence of inhibitors (e.g. chlorine and copper ions). Briefly, water was sampled i…

Environmental EngineeringMultidrug tolerance0208 environmental biotechnology02 engineering and technology010501 environmental sciencesmedicine.disease_cause01 natural sciencesMicrobiologyAgar platechemistry.chemical_compoundGenomic islandmedicinePseudomonas syringaeHumansWaste Management and DisposalPathogen0105 earth and related environmental sciencesWater Science and TechnologyCivil and Structural EngineeringOne healthbiologyPersistersPseudomonas aeruginosaEcological Modelingbiology.organism_classificationPollutionPremises plumbingPseudomonas putidaHospitals020801 environmental engineering3. Good healthR2a agar[SDV.MP]Life Sciences [q-bio]/Microbiology and ParasitologychemistryPseudomonas aeruginosaFranceSanitary EngineeringCopper
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The rise and the fall of a Pseudomonas aeruginosa epidemic lineage in a hospital

2020

AbstractThe biological features that allow a pathogen to survive in the hospital environment are mostly unknown. The extinction of bacterial epidemics in hospitals is mostly attributed to changes in medical practice, including infection control, but the role of bacterial adaptation has never been documented. We analyzed a collection of Pseudomonas aeruginosa isolates belonging to the Besançon Epidemic Strain (BES), responsible for a 12-year nosocomial outbreak, using a genotype-to-phenotype approach. Bayesian analysis estimated the emergence of the clone in the hospital five years before its opening, during the creation of its water distribution network made of copper. BES survived better t…

Genome evolutionAntibiotic resistancePseudomonas aeruginosaGenomic islandmedicineOutbreakBacterial genome sizeBiologymedicine.disease_causeGenome sizePathogenMicrobiology
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Legionella pneumophila pangenome reveals strain-specific virulence factors

2010

Abstract Background Legionella pneumophila subsp. pneumophila is a gram-negative γ-Proteobacterium and the causative agent of Legionnaires' disease, a form of epidemic pneumonia. It has a water-related life cycle. In industrialized cities L. pneumophila is commonly encountered in refrigeration towers and water pipes. Infection is always via infected aerosols to humans. Although many efforts have been made to eradicate Legionella from buildings, it still contaminates the water systems. The town of Alcoy (Valencian Region, Spain) has had recurrent outbreaks since 1999. The strain "Alcoy 2300/99" is a particularly persistent and recurrent strain that was isolated during one of the most signifi…

Genomic Islandslcsh:QH426-470biologyVirulence FactorsLegionellalcsh:BiotechnologyStrain (biology)OutbreakVirulenceGenomicsbiology.organism_classificationLegionella pneumophilaGenomeLegionella pneumophilaMicrobiologyEvolution Molecularlcsh:Geneticslcsh:TP248.13-248.65Horizontal gene transferGeneticsCRISPRGenome BacterialResearch ArticleBiotechnologyBMC Genomics
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Forward genetics inWolbachia: Regulation ofWolbachiaproliferation by the amplification and deletion of an addictive genomic island

2021

Copyright: © 2021 Duarte et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

MaleLife CyclesCancer ResearchPhysiologyEggsMutantForward geneticsQH426-470LarvaeReproductive PhysiologyTiter regulationGenomic islandreproductive and urinary physiologyGenetics (clinical)Gene EditingGenetics0303 health sciencesbiologyEukaryotaAnimal ModelsGenomicsPhenotype3. Good healthInsectsPhenotypeDrosophila melanogasterExperimental Organism SystemsDicistroviridaeOctomomFemaleDrosophilaWolbachiaDrosophila melanogasterWolbachiaResearch ArticleGenomic IslandsArthropodaLongevityGenomicsResearch and Analysis MethodsInvertebrate genomics03 medical and health sciencesModel Organismsparasitic diseasesGeneticsAnimalsSymbiosisMolecular BiologyEcology Evolution Behavior and Systematics030304 developmental biologyBacteria030306 microbiologyHost (biology)OrganismsBiology and Life SciencesSingle nucleotide polymorphismsbiochemical phenomena metabolism and nutritionbiology.organism_classificationInvertebratesBacterial LoadForward geneticsAnimal GenomicsAnimal StudiesbacteriaZoologyEntomologyGenome BacterialDevelopmental BiologyGenetic screen
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Salmonella enterica serotype Typhimurium DT 104 antibiotic resistance genomic island I in serotype paratyphi B

2002

We have identified Salmonella genomic island I (SGI1) in an isolate of Salmonella enterica serotype Paratyphi B. This antibiotic-resistance gene cluster, which confers multidrug resistance, has been previously identified in S. enterica serotype Typhimurium phage types DT 104 and DT 120 and in S. enterica serotype Agona.

Salmonella typhimuriumCanadaSalmonella genomic island I[SDV]Life Sciences [q-bio]lcsh:MedicineMicrobial Sensitivity Testslcsh:Infectious and parasitic diseasesantibiotiqueDrug Resistance Multiple BacterialHumanslcsh:RC109-216SerotypingComputingMilieux_MISCELLANEOUSlcsh:RDispatchsérotypegène de résistancePhysical Chromosome MappingTyphimurium DT 104Electrophoresis Gel Pulsed-FieldParatyphi BBlotting SouthernPhenotypeItalyGenes BacterialMultigene Familyilot génomiqueFrancesalmonella enterica
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