Genetic and biochemical characterization of BIM-1, a novel acquired subgroup B1 MBL found in a Pseudomonas sp. strain from the Brazilian Amazon region.

OBJECTIVES: To characterize a novel acquired MBL, BIM-1, in a Pseudomonas #2 (subgroup P. guariconensis) strain isolated from the Aurá river located in the Brazilian Amazon hydrographic basin. METHODS: WGS using an Illumina® MiSeq System was used to characterize the genome of Pseudomonas sp. IEC33019 strain. Southern blotting/hybridization assays were performed to confirm the location of the MBL-encoding gene, blaBIM-1 (Belém Imipenemase). Antimicrobial susceptibility testing, cloning, and biochemical and phenotypic characterization were performed to determine BIM-1 kinetics. RESULTS: The IEC33019 strain showed high resistance rates to ß-lactams, ciprofloxacin and aminoglycosides, being susceptible only to polymyxins and susceptible, increased exposure to aztreonam. WGS analysis revealed a novel acquired MBL-encoding gene, blaBIM-1, found as a gene cassette inserted into a class 1 integron (In1326) that also carried qnrVC1 and aadA11e. In1326 was located in a complex transposon, Tn7122, carried by a 52.7 kb conjugative plasmid (pIEC33019) with a toxin/antitoxin system (vapB/vapC). BIM-1 belongs to the molecular subgroup B1 and shares 70.2% and 64.9% similarity with SIM-1 and IMP-1, respectively. Kinetics analysis of BIM-1 showed hydrolytic activity against all ß-lactams tested. CONCLUSIONS: BIM-1 is a novel acquired MBL encoded by a gene carried by mobile genetic elements, which can be transferred to other Gram-negative bacilli (GNB). Because the IEC33019 strain was recovered from a river impacted by a populous metropolitan region with poor basic sanitation and served by limited potable freshwater, it would be important to establish the role of the BIM-1-producing GNB as nosocomial pathogens and/or as colonizers of the riverside population in this geographical region.

Genomic characterization of BKC-1-producing Klebsiella pneumoniae strain belonging to high-risk clone sequence type 11 isolated from a river in Brazil.

Carbapenem-resistant Klebsiella pneumoniae is a common cause of healthcare-related infections, and it is widespread in hospitals and diverse environments with potentially serious public health implications. Herein, we have reported the isolation and characterization of an environmental Brazilian Klebsiella carbapenemase (BKC-1)-producing K. pneumoniae strain (IEC1205) isolated in 2018 from a river in the Amazon region, Brazil. Antimicrobial susceptibility of this strain was evaluated by broth microdilution and demonstrated resistance to several antibiotics including ß-lactams, aminoglycosides, fluoroquinolones, and polymyxins. It has an extensively drug-resistant phenotype. Genomic analysis revealed that IEC1205 belonged to sequence type 11, clonal complex 258 and the presence of blaBKC-1 and two other ß-lactamase-encoding genes (blaCTX-M-15 and blaSHV-11). The predicted virulence was associated with biofilm formation-related genes, a type VI secretion system, siderophore production, and type I and II fimbriae formation. We have identified an IncQ1 plasmid, named pIEC1205, harboring blaBKC-1 with high similarity to previously described plasmids carrying blaBKC-1 and blaBKC-2 genes. To our knowledge, this is the first report of an environmental BKC-1-producing K. pneumoniae strain.

The changing epidemiology of Acinetobacter spp. producing OXA carbapenemases causing bloodstream infections in Brazil: a BrasNet report.

We evaluated the epidemiology of Acinetobacter spp. recovered from patients diagnosed with bloodstream infections in 9 tertiary hospitals located in all Brazilian geographic regions between April and August 2014. Although OXA-23-producing Acinetobacter baumannii clones were disseminated in most hospitals, it was observed for the first time the spread of OXA-72 among clonally related A. baumannii isolated from distinct hospitals. Interestingly, Acinetobacter pittii was the most frequent species found in a Northern region hospital. Contrasting with the multisusceptible profile displayed by A. pittii isolates, the tetracyclines and polymyxins were the only antimicrobials active against all A. baumannii isolates.