Caracterização fenotípica e genotípica de Acinetobacter spp. e Pseudomonas aeruginosa produtores de carbapenemases / Phenotypic and genotypic characterization of carbapenemase-producing Acinetobacter spp. e Pseudomonas aeruginosa

A resistência bacteriana a antibióticos é um grave e crescente problema de saúde pública de âmbito mundial. O principal, e mais eficiente, mecanismo de resistência aos ß-lactâmicos em bacilos Gram-negativos é a produção de ß-lactamases, que possuem a capacidade de hidrolisar o anel ß-lactâmicos e consequentemente inativar essa classe de antibióticos. Vale ressaltar, que atualmente os antibióticos ß-lactâmicos são os mais utilizados clinicamente, particularmente em infecções graves. Dentre as ß-lactamases existentes destacam-se as carbapenemases, enzimas capazes de inativar a maioria dos antibióticos ß-lactâmicos. Uma grande preocupação é o fato dessas enzimas, em sua maioria, serem codificadas por plasmídeos, o que propicia a disseminação desses genes de resistência; portanto, é de extrema importância a realização de um rápido e efetivo monitoramento da presença de patógenos portadores desses genes de resistência, para que assim se possa prevenir a disseminação desses determinantes. Foram incluídos neste estudo 230 amostras únicas de Acinetobacter e Pseudomonas aeruginosa resistentes a imipenem detectados em pacientes internados em hospitais privados da cidade de São Paulo durante o período de fevereiro a outubro de 2013. As amostras foram avaliadas quanto à hidrólise de imipenem por espectrofotometria, quanto à presença de genes de carbapenemases por PCR e sequenciamento, e quanto à clonalidade por eletroforese em campos pulsados (PFGE) ou ERIC-PCR. Foram realizados ensaios de conjugação, transformação e sequenciamento completo de plasmídeos. Dentre as amostras de Acinetobacter spp. 80% (88) foram capazes de hidrolisar o imipenem. Dentre esses 76,1% (67) foram positivos para blaOXA-51-like, 19,3% (17) foram positivos para blaOXA-72. blaOXA-23, blaOXA-482 e blaIMP-1 foram detectados isoladamente em isolados distintos. O gene blaIMP-1 foi detectado em A. ursingii inserido em integron de classe 1 e representa a primeira descrição no Brasil. Uma nova carbapenemase OXA-482-like foi detectada em A. baumanii. Utilizando-se ERIC-PCR, observou-se uma grande diversidade de grupos clonais, com o máximo de quatro isolados por grupo. Dentre as amostras de P. aeruginosa, apenas 35,3% foram capazes de hidrolisar o imipenem. Dessas amostras, 14 possuíam o gene blaSPM-1, e isolados únicos possuíam, individualmente, os genes blaIMP, blaVIM, blaKPC-2 ou blaGES-23. O gene blaKPC-2 foi detectado inserido em contexto genético diferente dos descritos anteriormente, em plasmídeo IncU de 32 Kb, mobilizável, mas não conjugativo. Esta é a primeira descrição da sequencia completa de plasmídeo albergando o gene blaKPC-2 em P. aeruginosa no Brasil. Nas demais amostras (20) com atividade hidrolítica, não foram detectados genes de carbapenemase conhecidos, o que sugere a presença de genes de carbapenemase ainda não descritos. Em três amostras foi possível obter transformantes com plasmídeos, resistentes a carbapenêmicos. As amostras com blaSPM-1 apresentaram perfis de PFGE estreitamente relacionados. Em contraste, os perfis de PFGE das amostras com potenciais novas carbapenemases apresentaram índice de similaridade de Dice inferior ix a 80%, evidenciando grande diversidade clonal. Nossos achados evidenciam que a carbapenemase não intrínseca predominante em Acinetobacterem hospitais privados da cidade de São Paulo é OXA-72, e em hospitais privados há uma grande diversidade clonal. Em P. aeruginosa, a carbapenemase predominante é SPM-1, cuja disseminação é mediada por um único clone. Há potencialmente um número significativo de novas carbapenemases em Acinetobacter e P. aeruginosa, algumas delas mediadas por plasmídeos

Bacterial resistance to antibiotics is a serious and growing public health problem worldwide. The main and most efficient mechanism of resistance to ß-lactams in Gram-negative bacilli is the production of ß-lactamases, which have the ability to hydrolyze the ß-lactam ring and consequently inactivate this class of antibiotics. It is worth mentioning that currently ß-lactam antibiotics are the most used clinically, particularly in severe infections. Among the existing ß-lactamases, carbapenemases are capable of inactivating most ß-lactam antibiotics. A major concern is that these enzymes are mostly encoded by plasmids, which facilitates the spread of these resistance genes; therefore, it is of extreme importance to carry out a rapid and effective monitoring of the presence of pathogens bearing these resistance genes, in order to prevent the dissemination of these determinants. This study included 230 unique samples of imipenem-resistant Acinetobacterand Pseudomonas aeruginosa detected in patients hospitalized in private hospitals in the city of São Paulo during the period from February to October 2013. The samples were evaluated for the imipenem hydrolysis by spectrophotometry, the presence of carbapenemase genes by PCR and sequencing, and concerning clonality by pulsed field electrophoresis (PFGE) or ERIC-PCR. Conjugation, transformation and complete sequencing of plasmids were performed. Among Acinetobacter spp. samples, 80% (88) were able to hydrolyze imipenem. Among these, 76.1% (67) were positive for blaOXA-51-like genes and 19.3% (17) were positive for blaOXA-72. The blaOXA-23, blaOXA-482 and blaIMP-1 genes were detected alone in distinct isolates. The blaIMP-1 gene was detected in A. ursingii inserted in class 1 integron and represents the first description in Brazil. A novel OXA-482-like carbapenemase was detected in A. baumanii. Using ERIC-PCR, a great diversity of clonal groups was observed, with a maximum of four isolates per group. Among P. aeruginosa samples, only 35.3% were able to hydrolyze imipenem. Of these samples, 14 had the blaSPM-1 gene, and single isolates individually possessed the blaIMP, blaVIM, blaKPC-2 or blaGES-23 genes. The blaKPC-2 gene was found inserted in a genetic context different from those described previously, in a mobilizable, but not conjugative, 32 Kb IncU plasmid. This is the first description of the complete nucleotide sequence of a plasmid harboring the blaKPC-2 gene in P. aeruginosa in Brazil. In the remaining samples (20) with hydrolytic activity, no known carbapenemase genes were detected, suggesting the presence of carbapenemase genes not yet described. In three samples it was possible to obtain transformants with plasmids, resistant to carbapenems. Samples with blaSPM-1 showed closely related PFGE profiles. In contrast, the PFGE profiles of the samples with potential new carbapenemases showed Dice similarity index lower than 80%, evidencing a great clonal diversity. Our findings show that the predominant non-intrinsic carbapenemase in Acinetobacter in the city of São Paulo is OXA-72, and in private hospitals there is great clonal diversity. In P. aeruginosa, the predominant carbapenemase is SPM-1, the spread of this enzyme is mediated by a single clone. There are potentially a significant number of new carbapenemases in Acinetobacter and P. aeruginosa, some of them plasmid mediated

fosI Is a New Integron-Associated Gene Cassette Encoding Reduced Susceptibility to Fosfomycin.

In this work, we demonstrate that the fosI gene encodes a predicted small protein with 134 amino acids and determines reduced susceptibility to fosfomycin. It raised the MIC from 0.125 to 6 µg/ml when the pBRA100 plasmid was introduced into Escherichia coli TOP10 and to 16 µg/ml when the gene was cloned into the pBC_SK(-) vector and expressed in E. coli TOP10.

Characterization of Tn3000, a Transposon Responsible for blaNDM-1 Dissemination among Enterobacteriaceae in Brazil, Nepal, Morocco, and India.

In Enterobacteriaceae, the blaNDM genes have been found in many different genetic contexts, and a wide diversity of plasmid scaffolds bearing those genes has been found. In August 2013, we identified NDM-1-producing Escherichia coli and Enterobacter hormaechei strains from a single rectal swab sample from a patient hospitalized in Rio de Janeiro, Brazil, who had no history of travel abroad. Complete DNA sequencing using the Illumina platform and annotation of the two plasmids harboring the blaNDM-1 gene, one from each strain, showed that they belonged to incompatibility groups IncFIIK and IncX3 and harbored a novel transposon named Tn3000. Similar genetic structures have been identified among other isolates in Brazil but also on plasmids from other continents. Our findings suggest that the blaNDM-1 gene may be transmitted by Tn3000 in different parts of the world.