Susceptibility Pattern and Distribution of Oxacillinases and bla _PER-1 Genes among Multidrug Resistant Acinetobacter baumannii in a Teaching Hospital in Iran

The OXA β-lactamases were among the earliest β-lactamases detected; however, these molecular class D β-lactamases were originally relatively rare and always plasmid mediated. They had a substrate profile limited to the penicillins, but some became able to confer resistance to cephalosporins. From the 1980s onwards, isolates of Acinetobacter baumannii that were resistant to the carbapenems emerged, manifested by plasmid-encoded β-lactamases (OXA-23, OXA-40, and OXA-58) categorized as OXA enzymes because of their sequence similarity to earlier OXA β-lactamases. It was soon found that every A. baumannii strain possessed a chromosomally encoded OXA β-lactamase (OXA-51-like), some of which could confer resistance to carbapenems when the genetic environment around the gene promoted its expression. Similarly, Acinetobacter species closely related to A. baumannii also possessed their own chromosomally encoded OXA β-lactamases; some could be transferred to A. baumannii, and they formed the basis of transferable carbapenem resistance in this species. In some cases, the carbapenem-resistant OXA β-lactamases (OXA-48) have migrated into the Enterobacteriaceae and are becoming a significant cause of carbapenem resistance. The emergence of OXA enzymes that can confer resistance to carbapenems, particularly in A. baumannii, has transformed these β-lactamases from a minor hindrance into a major problem set to demote the clinical efficacy of the carbapenems.

The rapid expansion of Acinetobacter baumannii clinical isolates exhibiting resistance to carbapenems and most or all available antibiotics during the last decade is a worrying evolution. The apparent predominance of a few successful multidrug-resistant lineages worldwide underlines the importance of elucidating the mode of spread and the epidemiology of A. baumannii isolates in single hospitals, at a country-wide level and on a global scale. The evolutionary advantage of the dominant clonal lineages relies on the capability of the A. baumannii pangenome to incorporate resistance determinants. In particular, the simultaneous presence of divergent strains of the international clone II and their increasing prevalence in international hospitals further support the ongoing adaptation of this lineage to the hospital environment. Indeed, genomic and genetic studies have elucidated the role of mobile genetic elements in the transfer of antibiotic resistance genes and substantiate the rate of genetic alterations associated with acquisition in A. baumannii of various resistance genes, including OXA- and metallo-β-lactamase-type carbapenemase genes. The significance of single nucleotide polymorphisms and transposon mutagenesis in the evolution of A. baumannii has been also documented. Establishment of a network of reference laboratories in different countries would generate a more complete picture and a fuller understanding of the importance of high-risk A. baumannii clones in the international dissemination of antibiotic resistance. Copyright © 2012 Elsevier B.V. and the International Society of Chemotherapy. All rights reserved.

Acinetobacter baumannii is a gram-negative organism that is increasingly recognized as a major pathogen causing nosocomial infections, including bacteremia and ventilator-associated pneumonia, particularly in patients admitted to intensive care units ( 1 ). Several studies have shown the geographically widespread occurrence of multidrug-resistant A. baumannii strains, which suggested a clonal relatedness of these strains. Three international A. baumannii clones associated with multidrug resistance (European clones I, II, and III) have been reported ( 2 ). Increasing resistance to carbapenems has been observed worldwide in the past decade, frequently mediated by production of class D β-lactamases with carbapenemase activity. Three acquired class D β-lactamases with carbapenemase gene clusters have been described in A. baumannii, which correspond to bla OXA-23-like, bla OXA-40-like, and bla OXA-58-like genes ( 3 ). The bla OXA-23 gene, first characterized in Scotland ( 4 ), has been increasingly reported worldwide. A. radioresistens was recently identified as the progenitor of the bla OXA-23-like genes ( 5 ). Clonal outbreaks of carbapenem-resistant and OXA-23–producing A. baumannii have been reported in many countries, such as Bulgaria ( 6 ), People’s Republic of China ( 7 ), Brazil ( 8 ), Iraq ( 9 ), Afghanistan ( 9 ), and French Polynesia ( 10 ). Genetic acquisition of the bla OXA-23 gene was investigated and transposons Tn2006, Tn2007, and Tn2008 were identified as genetic structures harboring this gene ( 10 – 12 ). In Tn2006, the bla OXA-23 gene is flanked by 2 copies of the insertion sequence ISAba1, which are located in opposite orientations (Figure 1). The functionality of Tn2006 has been recently demonstrated ( 13 ). Tn2008 is similar to Tn2006 but lacks the second copy of ISAba1 and the bla OXA-23 gene is associated with 1 copy of ISAba4 (which differs from ISAba1) in Tn2007 (Figure 1) ( 11 ). As reported for strains from United Arab Emirates and Bahrain, the bla OXA-23 gene can be associated with only 1 copy of ISAba1 ( 14 , 15 ). We studied the clonal relationship and genomic environment of sequences surrounding the bla OXA-23 gene among a collection of OXA-23–producing isolates from 15 countries. Figure 1 Genetic structures associated with the bla OXA-23 gene of Acinetobacter baumannii. A) Tn2006 from isolates 240, 512, 810, 859, 883 and AUS (ST22/ST2). B) Tn2008 from isolate 614. C) Tn2007 from isolates Ab14, BEL, and DOS. D) ISAba1 from isolates AS3, 1190, 861, and 877. Boundaries of Tn2006, Tn2007, and Tn2008 are indicated with the target site duplication likely generated by transposition events underlined. The 7-bp difference in the site of insertion of ISAba1 for isolate 614 is double-underlined. The open reading frame 1 (orf1), orf2, and orf3 genes of unknown function is indicated. tnpA, gene encoding a putative transposase; ATPase, gene encoding the putative AAA ATPase; DEAD, gene encoding the putative DEAD (Asp-Glu-Ala-Asp) helicase; DNAmethyl, DNA methylase. Materials and Methods Bacterial Strains and Susceptibility Testing Twenty OXA-23–producing A. baumannii clinical isolates were obtained from 15 countries. These isolates had been obtained from patients hospitalized in intensive care units from December 2003 through March 2008. Isolates were obtained from tracheal aspirates (n = 3), bile (n = 1), urine (n = 4), wounds (n = 1), respiratory tract (n = 1), blood (n = 4), and sputum (n = 1). The isolates were initially chosen after preliminary pulsed-field gel electrophoresis (PFGE)–based typing had identified 13 pulsotypes. Isolates were obtained from France (n = 4), Vietnam (n = 1), New Caledonia (n = 1), Thailand (n = 1), Australia (n = 1), Tahiti (n = 1), Reunion (n = 2), South Africa (n = 1), United Arab Emirates (n = 2), Libya, (n = 1), Bahrain (n = 1), Egypt (n = 1), Belgium (n = 1), Algeria (n = 1), and Brazil (n = 1). Presence of the bla OXA-23 gene was screened by PCR by using specific primers (OXA-23-A 5′-GGAATTCCATGAATAAATATTTTACTTGC-3′ and OXA-23-B 5′-CGGGATCCCGTTAAATAATATTCAGGTC-3′) and additional sequencing (ABI 3100 sequencer; Applied Biosystems, Foster City, CA, USA). Susceptibility patterns to β-lactam antimicrobial drugs were determined by using a standard disk diffusion method according to published standards ( 16 ) and Etest strips (AB Biodisk, Solna, Sweden). Isolates were identified by using 16S rRNA gene sequencing ( 17 ). Clonal Relationships Isolates were typed by using ApaI macrorestriction analysis and PFGE according to the manufacturer’s recommendations (Bio-Rad, Marnes-la-Coquette, France). Bacteria were grown in a medium appropriate for the strain until an optical density of 0.8 to 1 at 600 nm was reached. One milliliter of cells was centrifuged, washed, and resuspended in 10 mmol/L Tris, pH 7.2, 20 mmol/L NaCl, 50 mmol/L EDTA. Immediately after resuspension, an equal volume of 2% low melting point InCert agarose (Bio-Rad) was added. Solid agarose plugs were lysed at 37°C for 2 h in 1 mL of lysis buffer (10 mmol/L Tris, pH 7.2, 50 mmol/L NaCl, 0.5% sodium laurylsarcosine, 0.2% sodium deoxycholate) supplemented with 20 mg/L of lysozyme. The plugs were then incubated at 55°C for 16 h with proteinase K buffer (100 mmol/L EDTA, pH 8, 0.2% sodium deoxycholate, 1% sodium laurylsarcosine) supplemented with 20 mg/L of proteinase K. Plugs were washed with Tris-EDTA buffer containing 1 mmol/L phenylmethylsulfonyl fluoride (Sigma, St. Louis, MO, USA) and 3× with Tris-EDTA buffer at room temperature. Whole-cell DNA of A. baumannii isolates was digested with ApaI overnight at room temperature (New England Biolabs, St. Quentin-en-Yvelines, France). Electrophoresis was performed on a 1% agarose gel with 0.5× Tris-borate-EDTA buffer by using a CHEF DRII apparatus (Bio-Rad). Samples were subjected to electrophoresis at 14°C, 6 volts/cm, and a switch angle with 1 linear switch ramp of 3–8 s for 10.5 h, and then for 12–20 s for 10.5 h. Identification of PCR-based sequence groups was conducted by using 2 multiplex PCR assays designed to selectively amplify group 1 or group 2 alleles of the gene encoding outer-membrane protein A (ompA), the gene encoding part of a pilus assembly system required for biofilm formation (csuE), and the gene encoding the intrinsic carbapenemase gene of A. baumannii) (bla OXA-51) ( 18 ). Clonal relationships were established by multilocus sequence typing (MLST) by using 7 standard housekeeping loci (citrate synthase [gltA], gyrase B [gyrB], glucose dehydrogenase B [gdhB], recombination A [recA], chaperone 60 [cpn60], glucose-6-phosphate isomerase [gpi], and RNA polymerase [rpoD]) as described ( 18 ). Sequencing of internal fragments was performed by using BigDye fluorescent terminators and primers described ( 19 ). Sequences were compared with the A. baumannii database at the MLST Website (http://mlst.zoo.ox.ac.uk). To supplement epidemiologic results, we performed a second MLST typing using the scheme developed by Nemec et al. ( 20 ). Sequences of the 7 housekeeping genes were analyzed by using an A. baumannii database (www.pasteur.fr/recherche/genopole/PF8/mlst/Abaumannii.html). Southern Blot Analysis and Location of bla OXA-23 Gene Southern blot analysis was performed by using total genomic DNA digested with EcoRI, separated by electrophoresis on 0.8% agarose gels, transferred onto Hybond N+ membranes, and hybridized with enhanced chemiluminescence labeled probes overnight at 42°C. The membranes were developed according to the manufacturer’s instructions (GE Healthcare, Saclay, France). Chromosomal or plasmid locations of the β-lactamase gene were assessed by hybridization of I-CeuI–digested genomic DNA with bla OXA-23 and 16S rDNA probes and electrophoresis (20–120 s for 9 h and 60–100 s for 11 h at 14°C and 5 V/cm2) ( 21 ). DNA was transferred from an agarose gel to a nylon membrane by capillary transfer. Hybridization, labeling, and detection were conducted as described above. Mating-out assays were performed by using isolates that had plasmid-borne bla OXA-23 as donors and rifampin-resistant A. baumannii BM4547 as recipients as described ( 22 ). Transconjugants were selected on trypticase soy agar plates containing ticarcillin (50 mg/L) and rifampin (50 mg/L). Cloning Experiments To identify entire transposon structures containing the bla OXA-23 gene in different isolates and determine their location in the target DNA, a cloning procedure was used. Some data had been reported for 6 of 20 isolates ( 11 ). Total DNA was digested with either SacI or SalI, ligated into the SacI or SalI sites of plasmid pBK-CMV (kanamycin-resistant cloning vector), and the recombinant plasmids were transformed into Escherichia coli TOP10, as described ( 14 ). Recombinant plasmids were selected on trypticase soy agar plates containing amoxicillin (50 mg/L) and kanamycin (30 mg/L). Cloned DNA fragments of several recombinants plasmids were sequenced on both strands by primer walking as described ( 11 ). Results Clonal Relatedness of the Isolates Twenty carbapenem-resistant A. baumannii isolates were obtained from 15 countries (Table). All isolates were highly resistant to ticarcillin (MIC >256 mg/L) and showed a high level of resistance to ceftazidime (MIC >256 mg/L), except isolates Ab14 (MIC 4 mg/L) 861 and DOS (MIC 8 mg/L). All isolates were resistant to imipenem and meropenem (MIC >16 mg/L) (Table). Table Characteristics of 20 bla OXA-23-positive Acinetobacter baumannii clinical isolates* Isolate Origin Date of isolation Specimen EC ST† Copy no. of bla OXA-23 Genetic location and size, kb Genetic structure MIC, μg/mL CAZ IPM MEM 240 France 2003 Dec Tracheal aspirate II 22/2 1 Chromosome, ≈200‡ Tn2006 128 >32 >32 512 Tahiti 2004 Mar Tracheal aspirate II 22/2 1 Chromosome, ≈200‡ Tn2006 64 >32 >32 761 Vietnam 2005 May Bile II 22/2 1 Chromosome, ≈200‡ Tn2006 64 >32 >32 810 New Caledonia 2004 Jun Blood II 22/2 1 Chromosome, ≈200‡ Tn2006 96 >32 >32 863 Thailand 2006 Jun Urine II 22/2 1 Chromosome, ≈200‡ Tn2006 256 >32 >32 883 Reunion 2006 Jun Unknown II 22/2 1 Chromosome, ≈200‡ Tn2006 128 >32 >32 Ab13 France 2004 Jun Urine II 22/2 2 Chromosome, ≈200,‡ and plasmid, 70 Tn2006 128 >32 >32 AUS Australia 2004 Oct Urine II 22/2 1 Chromosome, ≈200‡ Tn2006 96 >32 >32 859 South Africa 2006 Jan Urine II 22/2 1 Chromosome, ≈200‡ Tn2006 128 >32 >32 585 France 2004 Jul Tracheal aspirate II 53/2 1 Chromosome, ≈200‡ Tn2006 128 >32 >32 614 Libya 2004 Oct Unknown I 25/20 1 Plasmid, 130 Tn2008 256 >32 16 AS3 UAE† 2006 Oct Blood I 25/20 1 Plasmid, 130 ISAba1 256 >32 >32 1190 Bahrain 2008 Mar Blood I 25/20 1 Plasmid, 130 ISAba1 256 >32 >32 AS1 UAE 2006 Jul Blood I 44/1 1 Chromosome, ≈40‡ Tn2006 256 >32 >32 Ab14 Algeria 2004 Dec Unknown I 44/1 2 Plasmid, 25, and plasmid, >150 Tn2007 4 16 >32 910 Reunion 2006 Oct Unknown I New1/1 1 Plasmid, 130 Tn2006 256 16 16 861 Egypt 2005 Nov Sputum I New1/ 1 1 Plasmid, 130 ISAba1 8 32 32 BEL Belgium 2007 Jul Respiratory tract I New2/ 1 2 Plasmid, 25, and plasmid, >150 Tn2007 256 >32 >32 DOS France 2004 May Unknown – New3/ New 2 Plasmid, 25, and plasmid, >150 Tn2007 8 >32 >32 877 Brazil 2006 Jul Wound – New4/15 1 Plasmid, 130 ISAba1 96 >32 >32 *EC, European clone; ST, sequence type; UAE, United Arab Emirates; CAZ, ceftazidime; IPM, imipenem; MEM, meropenem. The MIC for ticarcillin was >256 μg/mL for all 20 isolates.
†ST determined by Bartual et al. ( 19 ) compared with ST determined by Nemec et al. ( 20 ).
‡Size of chromosome band carrying the bla OXA-23 gene, as determined by using the I-CeuI technique. Multiplex PCR for identification of sequence groups showed 10 isolates that belonged to group 1 according to Turton et al. ( 18 ), eight that belonged to group 2, and 2 isolates that did not belong to groups 1 or 2. The 10 isolates that belonged to group 1 and corresponded to European clone II ( 18 ) were classified into 2 sequence types (STs), ST22 and ST53, according to MLST analysis ( 18 ). ST22 (1–3-3–2-2–7-3) was the most frequent type identified. Nine isolates were identified: 2 from France and 1 each from Vietnam, New Caledonia, Thailand, Australia, Tahiti, Reunion, and South Africa. A single European clone II isolate was classified as ST53 (1–3-3–2-2,3-3), a single-locus variant of ST22. Among 10 other isolates, 8 belonged to group 2 (corresponding to European clone I). Four STs were identified: ST25 (10–12–4–11–1–9–5) (Libya, United Arab Emirates, and Bahrain), ST44 (10–12–4–11–4–9–5) (United Arab Emirates and Algeria), and 2 new STs, 1 for isolates from Reunion and Egypt (10–12–4–11–4–16–5) and another related ST identified in the single isolate from Belgium (10–12–4–11–4,4–5). These 4 STs differ by 1 locus. The 2 most recent isolates from France and Brazil did not belong to European clones I or II and corresponded to 2 STs (1–22–3-11–1-9–7 and 12–18–12–1-15–9-19, respectively) (Table). Although 8 STs were identified in this collection, 9 pulsotypes were characterized by PFGE according to the criteria of Tenover et al. (23) (Figure 2). Figure 2 Pulsed-field electrophoresis (PFGE) profiles of ApaI-digested genomic DNA from strains of Acinetobacter baumannii. PFGE types, European clone types, and multilocus sequence typing (MLST) results are shown. *ST, sequence type determined by Bartual et al. ( 19 ) compared with ST determined by Nemec et al. ( 20 ). Lane M, molecular size markers (48.5 kb). According to MLST analysis developed by Nemec et al. ( 20 ), all isolates that belonged to European clone II had the same sequence type (ST2) (2,2-2,2-2,2-2), including isolate 585, which had a distinct but related ST in the first analysis. Among isolates that belonged to European clone I, two sequence types were determined: ST20 (3–1-1,1-5–1-1) (Libya, United Arab Emirates, Bahrain) and ST1 (1,1-1,1-5–1-1) (United Arab Emirates, Reunion, Egypt, Belgium, Algeria). Isolates 910 (Reunion), 861 (Egypt), and BEL (Belgium) were included in ST1. These isolates had a distinct ST according to methods of Bartual et al. ( 19 ). The 2 most recent isolates were classified into 2 STs, a new ST (3–2-2,2-5–4-8) for isolate DOS (France) and ST15 (6,6-8–2-3–5-4) for isolate 877 (Brazil) (Table). Location and Transferability of the bla OXA-23 Gene Location of the bla OXA-23 gene was evaluated by using the I-CeuI method. Eleven isolates had the bla OXA-23 gene on the chromosome, with a hybridization signal for an ≈40-kb band for isolate AS1 and an ≈200-kb band for 10 isolates (Table). Nine isolates carried the bla OXA-23 gene on a plasmid and 1 isolate had 2 copies of the bla OXA-23 gene, 1 on the chromosome and 1 on a 7–kb plasmid (Table). To examine the copy number of the bla OXA-23 gene in different A. baumannii genomes, we performed Southern blot hybridization on EcoRI-digested DNA fragments using a 589-bp DNA probe specific for the bla OXA-23 gene. Sixteen isolates showed only 1 copy of the bla OXA-23 gene. Isolates BEL, Ab14, and DOS had 2 copies of the bla OXA-23 gene on different plasmids, and Ab13 had 1 copy on the chromosome and 1 copy on a plasmid according to results of the I-Ceu1 technique. Mating-out assays were performed by using the 10 plasmid-positive strains as donor strains and rifampin-resistant A. baumannii BM4547 as the recipient strain. Five transconjugants were obtained; all had a 130-kb plasmid that did not provide additional antimicrobial drug resistance to the A. baumannii recipient strain, except in 1 case (co-resistance to kanamycin and amikacin on a bla OXA-23–carrying plasmid that originated from isolate 1190). Plasmids carrying the bla OXA-23 gene in isolates Ab14, DOS, BEL, and 877 were not self-transferable (Table) ( 24 ). Variability of Genetic Structures Flanking the bla OXA-23 Gene The 10 isolates that belonged to European clone II had a bla OXA-23 gene that was part of Tn2006. The 9-bp direct repeat (DR) that corresponded to duplication of the Tn2006 target site, which was consistent with a transposition event, was identified in the 9 ST22/ST2 isolates. Tn2006 was inserted in different locations on the chromosomes of those isolates (Table). For isolates 240, 512, 810, 859, 883, and Aus, the insertion occurred between 2 genes encoding hypothetical proteins (DR: GTCATTTAA) (Figure 1). In isolate 761, transposon Tn2006 was located between a gene encoding a hypothetical protein and a gene encoding an isoleucyl tRNA synthase (DR: ATTCGCGGG). In isolate 863, Tn2006 was identified between a gene encoding a cytochrome D terminale oxidase and a putative transposase (DR: ATAATTATT). In isolate 585, Tn2006 was located between a gene encoding a hypothetical protein and a sul1 gene (DR: ATTCGCGGG). The plasmid-borne bla OXA-23 gene identified in isolate Ab13 was also part of Tn2006 but was inserted into the sul gene that encoded a putative sulfonamide resistance determinant (DR: ATTCGCGGG). Isolates that belonged to European clone I had diverse genetic structures at the origin of bla OXA-23 acquisition. Two isolates had transposon Tn2006: one on the chromosome (AS1) and 1 on a plasmid (910). Transposon Tn2007 was identified in 3 isolates; it was specific for the same open reading frame in 2 isolates (BEL and Ab14) (Figure 2). Only 1 copy of ISAba1 was identified upstream of the bla OXA-23 gene in isolates AS3, 1190, 861, and 877. Transposon Tn2008 was identified only in isolate 614 (Figure 1). Sequences of these specific genetic structures have been deposited in Genbank (accession nos. EF127491, EF059914, GQ861438, and GQ861439). Discussion This study was conducted to define which features may explain the worldwide dissemination of the bla OXA-23 gene in A. baumannii. Isolates were from the Middle East, Europe, and Asia; there were no isolates from North America. Except for 2 isolates, the isolates investigated in this study belonged to European clones I or II. Clustering of A. baumannii isolates was determined by MLST and PFGE; our collection was composed of 13 PFGE types corresponding to 9 STs. Eight STs were identified among the OXA-23–producing A. baumannii; the most common STs were ST22/ST2 found in France (n = 2), Vietnam, New Caledonia, Thailand, Australia, Reunion, South Africa, and Tahiti. Spread of bla OXA-23–positive A. baumannii isolates that belong to clone ST22 has been demonstrated in South Korea ( 25 ). Analysis of the target site of bla OXA-23 acquisition showed that in the same clone, such as ST22, acquisition of the Tn2006 composite transposon had occurred at different positions in the A. baumannii genome, which suggested that Tn2006-mediated acquisition of bla OXA-23 may occur as independent events, or that Tn2006 is a structure that is mobile in a given genome. A single clone could have different genetic structures at the origin of the bla OXA-23 acquisition. We showed that the bla OXA-23 gene associated with Tn2006 could be located on the chromosome or a plasmid. This result agrees with our recent findings, which showed that Tn2006 is capable of transposition ( 13 ). We have also observed that 5 isolates with different sequence types (STNew1, ST25) harbored a similar 130-kb plasmid. The same strains with the same genetic structure were identified in 8 countries in different parts of the world. In conclusion, the current worldwide dissemination of the bla OXA-23 gene is driven by >7 MLST types associated with different genetic structures and plasmids. We have identified complex and dynamic spreading of bla OXA-23 that will be difficult to control because this spread is not associated with a single entity.