Literature DB >> 25395646

Complete Genome Sequence of the Multiresistant Acinetobacter baumannii Strain AbH12O-A2, Isolated during a Large Outbreak in Spain.

M Merino¹, L Alvarez-Fraga¹, M J Gómez², A M Aransay³, J L Lavín³, F Chaves⁴, G Bou⁵, M Poza⁵.

Abstract

We report the complete genome sequence of Acinetobacter baumannii strain AbH12O-A2, isolated during a large outbreak in Spain. The genome has 3,875,775 bp and 3,526 coding sequences, with 39.4% G+C content. The availability of this genome will facilitate the study of the pathogenicity of the Acinetobacter species.

Entities: Chemical Disease Gene Species

Year: 2014 PMID： 25395646 PMCID： PMC4241672 DOI： 10.1128/genomeA.01182-14

Source DB: PubMed Journal: Genome Announc

GENOME ANNOUNCEMENT

Acinetobacter baumannii is a major cause of hospital-acquired infections. Its success in the hospital environment lies in its genetic versatility and its ability to persist in extreme conditions. During 2006–2008, 377 patients were colonized/infected with multiresistant A. baumannii strains in a hospital in Madrid, Spain. This was one of the most important nosocomial outbreak produced by A. baumannii known to date (1, 2). The clones isolated during the outbreak harbored different plasmids, all containing a blaOXA-24 gene mobilized through a Xer recombination mechanism. Two mutations found to modify the gene expression of virulence factors provided an advantage to strain AbH12O-A2, whose genome sequence is described here. Previous studies have described the molecular mechanisms involved in the spread and epidemiology of this strain (1–6). The total genomic DNA isolated from strain AbH12O-A2 was sheared into smaller fragments with the Covaris S/E210 system. Specific adapters were ligated to DNA fragments, and libraries containing inserts of 500 bp were purified and selectively enriched by PCR. After quality and quantity controls, 90 nucleotide fragments were paired-end sequenced in an HiSeq2000 system, with the TruSeq PE cluster kit version 3, cBot-HS, and TruSeq SBS kit-HS version 3 (Illumina Inc.). Once the gaps were identified, pairs of primers were designed and specific regions were amplified. Products were sequenced by BigDye Terminator version 3.1 chemistry in an ABI Seq Instrument (Applied Biosystems). After quality control of the raw data, clean data were aligned to Acinetobacter baumannii ATCC 17978, as a reference sequence. Assembly of the short reads into the genome sequence was performed using the SOAPdenovo version 1.05 program (http://soap.genomics.org.cn/soapdenovo.html). Key parameter K setting at 47 is determined by optimal assembly according to the paired-end and overlap relationship via mapping reads to contigs. The A. baumannii AbH12O-A2 complete genome consists of 3,875,775 bp with a G+C content of 39.4% and contains 3,526 coding sequences, 72 tRNA genes, and 6 rRNA clusters. A. baumannii ACICU (score 518), A. baumannii AB900 (score 500), and A. baumannii AYE (score 483) were the closest neighbors to strain AbH12O-A2. Moreover, 56 genes associated with resistance to antibiotics and toxic compounds were found. The ResFinder bioinformatic application (7) was used to identify genes coding for antibiotic resistance. The following resistance genes were detected in the genome: aac(3)-lla, strA, and strB conferring resistance to aminoglycosides; blaOXA-65, blaADC-25, and blaTEM-1B conferring resistance to β-lactams; and sul2 conferring resistance to sulfonamides. Comparison of the AbH12O-A2 genome with other completed genomes of A. baumannii by use of Mauve version 2.3.1 (8) revealed a resistance island (3,612,846–3,637,461 bp) flanked by two sequences of ISAba1 in opposite directions. PHAST (9) analysis revealed four putative intact phages integrated in the genome, two of which are similar to Acinetobacter phage Bphi-B1251 and another two that have not previously been identified in A. baumannii: one is similar to Enterobacteria phage mEp235 and the other is similar to Haemophilus phage SuMu.

Nucleotide sequence accession number.

This whole-genome shotgun project has been deposited in GenBank under accession number CP009534.

9 in total

1. Horizontal transfer of the OXA-24 carbapenemase gene via outer membrane vesicles: a new mechanism of dissemination of carbapenem resistance genes in Acinetobacter baumannii.

Authors: Carlos Rumbo; Esteban Fernández-Moreira; María Merino; Margarita Poza; Jose Antonio Mendez; Nelson C Soares; Alejandro Mosquera; Fernando Chaves; Germán Bou
Journal: Antimicrob Agents Chemother Date: 2011-04-25 Impact factor: 5.191

2. Mauve: multiple alignment of conserved genomic sequence with rearrangements.

Authors: Aaron C E Darling; Bob Mau; Frederick R Blattner; Nicole T Perna
Journal: Genome Res Date: 2004-07 Impact factor: 9.043

3. OXA-24 carbapenemase gene flanked by XerC/XerD-like recombination sites in different plasmids from different Acinetobacter species isolated during a nosocomial outbreak.

Authors: María Merino; Joshi Acosta; Margarita Poza; Francisca Sanz; Alejandro Beceiro; Fernando Chaves; Germán Bou
Journal: Antimicrob Agents Chemother Date: 2010-04-12 Impact factor: 5.191

4. Molecular mechanisms involved in the response to desiccation stress and persistence in Acinetobacter baumannii.

Authors: Carmen M Gayoso; Jesús Mateos; José A Méndez; Patricia Fernández-Puente; Carlos Rumbo; María Tomás; Oskar Martínez de Ilarduya; Germán Bou
Journal: J Proteome Res Date: 2013-12-17 Impact factor: 4.466

5. Extracellular proteome of a highly invasive multidrug-resistant clinical strain of Acinetobacter baumannii.

Authors: Jose Antonio Mendez; Nelson C Soares; Jesús Mateos; Carmen Gayoso; Carlos Rumbo; Jesús Aranda; Maria Tomas; Germán Bou
Journal: J Proteome Res Date: 2012-10-31 Impact factor: 4.466

6. Identification of acquired antimicrobial resistance genes.

Authors: Ea Zankari; Henrik Hasman; Salvatore Cosentino; Martin Vestergaard; Simon Rasmussen; Ole Lund; Frank M Aarestrup; Mette Voldby Larsen
Journal: J Antimicrob Chemother Date: 2012-07-10 Impact factor: 5.790

7. PHAST: a fast phage search tool.

Authors: You Zhou; Yongjie Liang; Karlene H Lynch; Jonathan J Dennis; David S Wishart
Journal: Nucleic Acids Res Date: 2011-06-14 Impact factor: 16.971

8. Multidrug-resistant Acinetobacter baumannii Harboring OXA-24 carbapenemase, Spain.

Authors: Joshi Acosta; Maria Merino; Esther Viedma; Margarita Poza; Francisca Sanz; Joaquín R Otero; Fernando Chaves; Germán Bou
Journal: Emerg Infect Dis Date: 2011-06 Impact factor: 6.883

9. Ser/Thr/Tyr phosphoproteome characterization of Acinetobacter baumannii: comparison between a reference strain and a highly invasive multidrug-resistant clinical isolate.

Authors: Nelson C Soares; Philipp Spät; Jose Antonio Méndez; Kehilwe Nakedi; Jesús Aranda; German Bou
Journal: J Proteomics Date: 2014-03-21 Impact factor: 4.044

9 in total

8 in total

1. The FhaB/FhaC two-partner secretion system is involved in adhesion of Acinetobacter baumannii AbH12O-A2 strain.

Authors: A Pérez; M Merino; S Rumbo-Feal; L Álvarez-Fraga; J A Vallejo; A Beceiro; E J Ohneck; J Mateos; P Fernández-Puente; L A Actis; M Poza; G Bou
Journal: Virulence Date: 2016-11-18 Impact factor: 5.882

2. Quantitative proteomic analysis of host--pathogen interactions: a study of Acinetobacter baumannii responses to host airways.

Authors: Jose Antonio Méndez; Jesús Mateos; Alejandro Beceiro; María Lopez; María Tomás; Margarita Poza; Germán Bou
Journal: BMC Genomics Date: 2015-05-30 Impact factor: 3.969

3. Complete genome sequence of hypervirulent and outbreak-associated Acinetobacter baumannii strain LAC-4: epidemiology, resistance genetic determinants and potential virulence factors.

Authors: Hong-Yu Ou; Shan N Kuang; Xinyi He; Brenda M Molgora; Peter J Ewing; Zixin Deng; Melanie Osby; Wangxue Chen; H Howard Xu
Journal: Sci Rep Date: 2015-03-02 Impact factor: 4.379

4. Analysis of the role of the LH92_11085 gene of a biofilm hyper-producing Acinetobacter baumannii strain on biofilm formation and attachment to eukaryotic cells.

Authors: Laura Álvarez-Fraga; Astrid Pérez; Soraya Rumbo-Feal; María Merino; Juan Andrés Vallejo; Emily J Ohneck; Richard E Edelmann; Alejandro Beceiro; Juan C Vázquez-Ucha; Jaione Valle; Luis A Actis; Germán Bou; Margarita Poza
Journal: Virulence Date: 2016-02-08 Impact factor: 5.882

5. Contribution of the A. baumannii A1S_0114 Gene to the Interaction with Eukaryotic Cells and Virulence.

Authors: Soraya Rumbo-Feal; Astrid Pérez; Theresa A Ramelot; Laura Álvarez-Fraga; Juan A Vallejo; Alejandro Beceiro; Emily J Ohneck; Brock A Arivett; María Merino; Steven E Fiester; Michael A Kennedy; Luis A Actis; Germán Bou; Margarita Poza
Journal: Front Cell Infect Microbiol Date: 2017-04-03 Impact factor: 5.293

6. Involvement of HisF in the Persistence of Acinetobacter baumannii During a Pneumonia Infection.

Authors: Marta Martínez-Guitián; Juan C Vázquez-Ucha; Laura Álvarez-Fraga; Kelly Conde-Pérez; Cristina Lasarte-Monterrubio; Juan Andrés Vallejo; Germán Bou; Margarita Poza; Alejandro Beceiro
Journal: Front Cell Infect Microbiol Date: 2019-08-29 Impact factor: 5.293

7. Pneumonia infection in mice reveals the involvement of the feoA gene in the pathogenesis of Acinetobacter baumannii.

Authors: Laura Álvarez-Fraga; Juan C Vázquez-Ucha; Marta Martínez-Guitián; Juan A Vallejo; Germán Bou; Alejandro Beceiro; Margarita Poza
Journal: Virulence Date: 2018-01-01 Impact factor: 5.882

8. Pyomelanin biosynthetic pathway in pigment-producer strains from the pandemic Acinetobacter baumannii IC-5.

Authors: Érica Fonseca; Fernanda Freitas; Raquel Caldart; Sérgio Morgado; Ana Carolina Vicente
Journal: Mem Inst Oswaldo Cruz Date: 2020-11-06 Impact factor: 2.743

8 in total