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Antimicrobial Agents and Chemotherapy, June 2007, p. 2179-2184, Vol. 51, No. 6
0066-4804/07/$08.00+0     doi:10.1128/AAC.01600-06
Copyright © 2007, American Society for Microbiology. All Rights Reserved.

Identification of the Novel Narrow-Spectrum ß-Lactamase SCO-1 in Acinetobacter spp. from Argentina

Laurent Poirel,^1, Stéphane Corvec,^1,2, Melina Rapoport,³ Pauline Mugnier,¹ Alejandro Petroni,³ Fernando Pasteran,³ Diego Faccone,³ Marcelo Galas,³ Henri Drugeon,² Vincent Cattoir,¹ and Patrice Nordmann^1*

Service de Bactériologie-Virologie, Hôpital de Bicêtre, Assistance Publique/Hôpitaux de Paris, Faculté de Médecine Paris-Sud, Université Paris XI, K.-Bicêtre, Paris, France,¹ Laboratoire de Bactériologie-Virologie, Hygiène Hospitalière, CHU, Nantes, France,² Servicio Antimicrobianos, Depertamento Bacteriologia, Instituto Nacional de Enfermedades Infecciosas-ANLIS Carlos G. Malbran, Ciudad Autonoma de Buenos Aires, Argentina³

Received 22 December 2006/ Returned for modification 15 February 2007/ Accepted 23 March 2007

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By studying the ß-lactamase content of several Acinetobacter spp. isolates from Argentina, producing the expanded-spectrum ß-lactamases (ESBL) VEB-1a or PER-2, a novel Ambler class A ß-lactamase gene was identified. It encoded the narrow-spectrum ß-lactamase SCO-1, whose activity was inhibited by clavulanic acid. SCO-1 hydrolyzes penicillins at a high level and cephalosporins and carbapenems at a very low level. ß-Lactamase SCO-1 was identified from unrelated VEB-1a-positive or PER-2-positive Acinetobacter spp. isolates recovered from three hospitals. The bla_SCO-1 gene was apparently located on a plasmid of ca. 150 kb from all cases but was not associated with any ESBL-encoding gene. The G+C content of the bla_SCO gene was 52%, a value that does not correspond to that of the A. baumannii genome (39%). ß-Lactamase SCO-1 shares 47% amino acid identity with CARB-5 and ca. 40% with the enzymes TEM, SHV, and CTX-M. A gene encoding a putative resolvase was identified downstream of the bla_SCO-1 gene, but its precise way of acquisition remains to be determined.

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Whereas many ß-lactamases are being increasingly reported worldwide, the repertoire of acquired narrow-spectrum penicillinases remains limited among gram-negative bacteria. They are mostly of the Ambler class A and of the TEM, SHV, and CARB types (1). The most recently identified plasmid-encoded class A narrow-spectrum ß-lactamase, LAP-1, has been identified together with the quinolone resistance determinant QnrS1 in Enterobacter cloacae isolates (17). Production of narrow-spectrum Ambler class A ß-lactamases is common in members of the family Enterobacteriaceae but has been very rarely reported for Acinetobacter spp., including ß-lactamases TEM-1 (7), TEM-2 (4), and CARB-5 (15), conferring additional resistance to carboxy- and ureidopenicillins.

By analyzing the ß-lactamase content of expanded-spectrum-ß-lactamase (ESBL)-producing Acinetobacter isolates collected from several hospitals in Argentina from October 2000 to July 2005 (of which several coproduce the carbapenem-hydrolyzing oxacillinase OXA-58 [20]), we have identified a novel gene encoding a narrow-spectrum ß-lactamase (14). Thus, the aim of the present study was to characterize the biochemical properties of this novel ß-lactamase and the genetic context of the gene.

(This study was presented in part at the 46th Interscience Conference on Antimicrobial Agents and Chemotherapy, San Francisco, CA, 2006 [20a].)

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Bacterial strains. Thirteen Acinetobacter spp. isolates were first identified with an API20NE system (bioMérieux, Marcy l'Etoile, France). Those isolates produced ESBL PER-2 (n = 6) or VEB-1a (n = 6) (16, 21). Four isolates also produced the carbapenem-hydrolyzing oxacillinase OXA-58 (13, 22). In addition, a single isolate that produced OXA-58 but which was ESBL negative was included in the study. Further analyses were performed to confirm identification of the isolates at the species level by sequencing the rrs gene, followed by a phylogenetic analysis, as described previously (5) (Table 1). Genomic DNA of Acinetobacter johnsonii producing the ESBL VEB-1a was used for cloning experiments (Table 1). Escherichia coli TOP10 was the host for cloning experiments, and azide-resistant E. coli J53 and A. baumannii CIP7010T or A. baumannii BM4547 were used as recipient strains for conjugation and transformation experiments (9, 19).

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TABLE 1. Features of the Acinetobacter isolates included in this study

Susceptibility testing. Antibiotic-containing disks were used for routine antibiograms performed by disk diffusion testing (Sanofi-Diagnostic Pasteur, Marnes-la-Coquette, France), as previously described (16). MICs were determined by an agar dilution technique as described previously (3). MICs of ß-lactams were then determined alone or in combination with a fixed concentration of clavulanic acid (4 µg/ml) or tazobactam (4 µg/ml) and interpreted according to the guidelines of the CLSI (3).

PCR and hybridization experiments. Total DNA of A. baumannii isolates was extracted as described previously (16). Southern hybridizations were performed as described by Sambrook et al. (22), using an ECL nonradioactive labeling and detection kit (Amersham Pharmacia Biotech, Orsay, France). Screening of the bla_SCO-1 gene among our strains was performed by PCR using primers SCO-1A (5'-GGCGGCTATCGCGCTAAAGC-3') and SCO-1B (5'-TGGCAGCGTTCCTTTCCTCC-3'), and this PCR product was used as the specific probe for detection of the bla_SCO-1 gene, as described previously (19).

Cloning experiments, recombinant plasmid analysis, and DNA sequencing. Total DNA of VEB-1a-positive Acinetobacter johnsonii isolate 7037 was BamHI or EcoRI restricted, ligated into the corresponding sites of plasmid pBK-CMV, and then used to transform the E. coli TOP10 reference strain, as described previously (16). Recombinant plasmids were selected onto Trypticase soy (TS) agar plates containing amoxicillin (30 µg/ml) and kanamycin (30 µg/ml). The cloned DNA fragments of the p7037-B2 and p7007-E1 recombinant plasmids were sequenced on both strands with an ABI 3100 sequencer (Applied Biosystems, Foster City, CA). The nucleotide and deduced amino acid sequences were analyzed and compared to sequences available over the Internet at the National Center for Biotechnology Information website (http://www.ncbi.nlm.nih.gov).

Genetic support. Plasmid DNAs of the bla_SCO-1-positive isolates were extracted using the Kieser method (10). E. coli NCTC50192, harboring four plasmids of 154, 66, 38, and 7 kb, was used as the size marker for plasmids. Transformation assays were performed by electroporation with plasmid extracts from the bla_SCO-1-positive isolates identified in that study as donors and either E. coli J53, A. baumannii CIP7010T, or A. baumannii BM4547 as recipient strains, as described previously (8). Selection was performed on agar plates supplemented with amoxicillin (30 µg/ml) for E. coli or supplemented with ticarcillin (30 µg/ml) for A. baumannii.

ß-Lactamase purification and isoelectric focusing analysis. Cultures of E. coli DH10B(p7037-B2) were grown overnight at 37°C in 4 liters of TS broth containing amoxicillin (30 µg/ml) and kanamycin (30 µg/ml). ß-Lactamase was purified by ion-exchange chromatography. Briefly, the bacterial suspension was sonicated, cleared by ultracentrifugation, treated with DNase, and dialyzed against 20 mM Tris-HCl buffer (pH 8.0). This extract was loaded on a Q-Sepharose column, and the ß-lactamase-containing fractions were eluted with a gradient of NaCl. The same procedure was repeated using a 20 mM Tris-HCl buffer (pH 7.0). Finally, the fractions containing the highest ß-lactamase activity were pooled and concentrated using an ultrafiltration filter tip (Sartorius, Goettingen, Germany). The purity of the enzyme was estimated by sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis analysis (22).

Isoelectric focusing (IEF) analysis was performed with an ampholine polyacrylamide gel (pH 3.5 to 9.5), as described previously (16), using purified enzyme. The focused ß-lactamases were detected by overlaying the gel with 1 mM nitrocefin (Oxoid, Dardilly, France) in 100 mM phosphate buffer (pH 7.0).

Kinetic measurements. Purified ß-lactamase was used for kinetic measurements performed at 30°C with 100 mM sodium phosphate (pH 7.0), with an ULTROSPEC 2000 model UV spectrophotometer (Amersham Pharmacia Biotech) (18, 19). Fifty percent inhibitory concentrations (IC₅₀s) were determined for clavulanic acid and tazobactam. Various concentrations of inhibitors were preincubated with the purified enzyme for 3 min at 30°C to determine the concentrations that reduced the hydrolysis rate of 100 µM benzylpenicillin by 50%. The specific activity of the purified ß-lactamase from E. coli DH10B(p7037-B2) was obtained as described previously in 100 mM sodium phosphate (pH 7.0), using 100 µM benzylpenicillin as the substrate (18, 19). One unit of enzyme activity was defined as the activity which hydrolyzed 1 µmol of benzylpenicillin per min per mg of protein. The total protein content was measured with a protein assay kit (Bio-Rad, Ivry-sur-Seine, France).

Nucleotide sequence accession number. The nucleotide sequence data reported in this work have been deposited in the GenBank nucleotide database under accession number EF063111.

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Cloning and sequencing of the ß-lactamase gene. In the course of cloning the bla_VEB-1a gene (work in progress) and its surrounding sequences from A. johnsonii 7037, recombinant E. coli strains were obtained that, surprisingly, gave a narrow-spectrum and clavulanic acid-inhibited ß-lactam resistance profile. PCR assays specific for the bla_TEM, bla_SHV, bla_LAP, and bla_CARB genes did not give positive results with those recombinant strains. Sequence analysis of the 7,193-bp cloned BamHI fragment of recombinant plasmid p7037-B2 obtained from isolate 7037 and exhibiting resistance to penicillins revealed an 867-bp-long open reading frame (ORF) encoding a 288-amino-acid preprotein. This protein had a ß-lactamase-like amino acid sequence named SCO-1 and possessed the STFK and SDN structural elements characteristic of the active site of Ambler class A ß-lactamases (Fig. 1) (1). In addition, it possessed an RTG motif in box VII of the Ambler class A ß-lactamases that has been identified in some CARB-type ß-lactamases (CARB-5, CARB-8, and RTG-1), whereas other CARB derivatives usually possess an RSG motif (2, 9, 11). The G+C content of bla_SCO-1 was 52%, whereas it is 39% for the whole genome of A. baumannii (6). ß-Lactamase SCO-1 was distantly related to all other class A ß-lactamases. The highest percentage of amino acid identity was 47% with CARB-5 (and similar percentages with other CARB ß-lactamases), whereas it shared only 40% identity with CTX-M enzymes and 40%, 40%, and 37% with TEM-1, LAP-1, and SHV-1, respectively (Fig. 2).

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FIG. 1. Sequence alignment of the amino acid sequences of ß-lactamases SCO-1, CARB-5, TEM-1, SHV-1, and LAP-1. Dashes indicate amino acids which are lacking in the corresponding sequence. Critical residues that are involved in the extension of the substrate profile in TEM or SHV enzymes are in bold type. Gray-shaded amino acids represent conserved residues. The box VII is bracketed. ß-Lactamases are numbered according to the Ambler classification (1).

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FIG. 2. Dendrogram obtained for representative Ambler class A ß-lactamases by neighbor-joining analysis. The alignment used for tree calculation was performed with ClustalX. Branch lengths are drawn to scale and are proportional to the number of amino acid changes. The distance along the vertical axis has no significance. The scale bar represents 10% differences in amino acid sequences. Only the bootstrap values greater than 85% are indicated. The amino acid identities of each ß-lactamase to SCO-1 are indicated in square brackets. The acquired narrow-spectrum ß-lactamases in gram-negative bacteria are ROB-1, CARB-2, LAP-1, TEM-1, SHV-1, and SCO-1, whereas the others are either naturally occurring ones or extended-spectrum ß-lactamases.

Antibiotic susceptibility. A. johnsonii 7037 was resistant to kanamycin, tobramycin, amikacin, gentamicin, rifampin, and sulfonamides. It remained susceptible to chloramphenicol, tetracycline, fosfomycin, nalidixic acid, and fluoroquinolones (data not shown). Its resistance pattern toward ß-lactams included most penicillins, expanded-spectrum cephalosporins, cephamycins, and aztreonam. This isolate was fully susceptible to imipenem and meropenem and also to the ß-lactam/inhibitor combinations such as amoxicillin/clavulanate, ticarcillin/clavulanate, and piperacillin-tazobactam. MICs of ß-lactams for E. coli DH10B(p7037-B2) were consistent with the production of a clavulanic acid-inhibited and narrow-spectrum ß-lactamase that spared expanded-spectrum cephalosporins and carbapenems (Table 2).

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TABLE 2. MICs of ß-lactams for selected strainsa

Biochemical properties of ß-lactamase SCO-1. IEF analysis showed that E. coli DH10B(p7037-B2) had a ß-lactamase activity with a pI value of 5.5 (data not shown), also detected from a culture extract of A. johnsonii isolate 7037. The specific activity of purified ß-lactamase SCO-1 for benzylpenicillin was 300 U/mg protein^–1. Its overall recovery was 80%, with a 60-fold purification factor. The purity of the enzyme was estimated to be more than 95%, according to SDS gel electrophoresis analysis (data not shown). Kinetic parameters of SCO-1 showed its narrow-spectrum activity against ß-lactams, including mostly penicillins, and to a lesser extent against cephalothin, ceftazidime, and cefepime. Cephamycins and monobactams were not hydrolyzed, but a very weak hydrolysis of imipenem was noticed (Table 3). IC₅₀ determinations performed with benzylpenicillin as a substrate showed that SCO-1 activity was inhibited by clavulanic acid (IC₅₀, 0.3 µM) and tazobactam (IC₅₀, 1.2 µM).

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TABLE 3. Kinetic parameters of purified ß-lactamase SCO-1

Genetic environment of bla_SCO-1. Sequencing of the entire inserts of plasmids p7037-E1 (containing a bla_SCO-1 and EcoRI fragment from isolate 7037) and p7037-B2, obtained from isolate 7037 and p7037-B2 from A. johnsonii 7037, revealed several ORFs. Analysis of the sequences located just upstream of the bla_SCO-1 gene identified, in the opposite orientation, a gene encoding a putative glycosyl hydrolase sharing 51% amino acid identity with that identified in the genome of Pseudomonas putida KT2440 (12). The distance separating this gene from the bla_SCO-1 ß-lactamase gene was 161 bp. Putative –35 (TGCATA) and –10 (TAAAAC) promoter sequences separated by 17 bp were identified upstream of the bla_SCO-1 structural gene. Downstream of the bla_SCO-1 gene, a tnpR-like gene encoding a putative resolvase was identified that shared 92% amino acid identity with one identified in the antibiotic resistance island of A. baumannii strain AYE (6). Downstream of the putative glycosyl hydrolase-encoding gene, a putative umuDC-type operon was identified that contained two genes encoding UmuD and UmuC-like proteins that shared 44% amino acid identity with those of E. coli and 60% with those of Roseobacter sp. (NCBI RefSeq ZP_01058401) (Fig. 2). Those umuD and umuC genes organized as an operon involved in the SOS response, together with the recA gene (23). Downstream of the putative umuDC operon, a gene encoding a putative resolvase exhibiting 68% amino acid identity to a similar protein identified on a plasmid in a Yersinia enterocolitica strain was identified (24). Then, a gene encoding a protein exhibiting 85% amino acid identity to the OrfA transposase subunit of IS5 was identified.

Distribution of the bla_SCO-1 gene among ESBL-producing Acinetobacter spp. isolates. Since the bla_SCO-1 gene was identified from a bla_VEB-1a-positive isolate, we searched for this gene in a collection made up of other bla_VEB-1a or bla_PER-2-positive Acinetobacter spp. isolates from Argentina. Six VEB-1a-positive isolates (one of them coproducing ß-lactamase OXA-58), six PER-2-positive isolates (three of them coproducing OXA-58), and a single ESBL-negative but OXA-58-positive isolate recovered in different hospitals from different cities of Argentina during a 4-year period were tested (Table 1). PCR results indicated that 9 out of these 13 isolates were positive for the bla_SCO-1 gene (Table 1). The bla_SCO-1-positive isolates corresponded to different Acinetobacter species.

Genetic support of the ß-lactamase determinant. Conjugation experiments did not lead to a transfer of any plasmid encoding ß-lactamase SCO-1 from different Acinetobacter spp. isolates to E. coli recipient strains. Attempts to transform a bla_SCO-1-carrying plasmid into A. baumannii recipient strains by electroporation remained unsuccessful. However, plasmid analysis showed that all the bla_SCO-1-positive Acinetobacter isolates (which are either PER-2 or VEB-1a producers) possessed a similarly sized plasmid of ca. 150 kb that hybridized with the bla_SCO-1-specific probe (Fig. 3) but did not cohybridize with the bla_VEB-1a- or the bla_PER-2-specific probe (data not shown). Thus, it is possible that a plasmid with a similar backbone harbored the bla_SCO-1 gene in all these Acinetobacter spp. isolates.

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FIG. 3. Plasmid content analysis of the Acinetobacter spp. isolates. (A) Ethidium bromide-stained electrophoresis pattern of undigested plasmids and (B) corresponding Southern hybridization assay using a blaSCO-1-specific probe. Lane numbers 1 to 13 refer to strains described in Table 1.

Top ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 
This study identified a novel class A ß-lactamase that had a weak amino acid identity to known ß-lactamases. ß-Lactamase SCO-1 constitutes one of the few acquired narrow-spectrum ß-lactamases described so far in gram-negative bacteria. It possesses a clavulanic acid-inhibited narrow-spectrum hydrolysis toward ß-lactams. Detailed analysis of its amino acid sequence showed that SCO-1 shared some structural identities with the CARB-type ß-lactamases, possessing in particular an RTG motif which has already been identified in several carbenicillinases such as ß-lactamases RTG-1, CARB-5, and CARB-8. SCO-1 hydrolyzes mostly penicillins but also weakly ceftazidime and imipenem, which may suggest the possibility that other SCO variants may extend their substrate profile toward these substrates, as already observed for TEM- and SHV-type ß-lactamases. Further experiments will be performed to evaluate this ability in vitro.

Analysis of the surrounding sequences of the bla_SCO-1 gene showed that it was not part of a gene cassette and was not associated with integron features. However, a gene encoding a putative resolvase was associated at its 3' extremity that could indicate that the bla_SCO-1 gene could be part of a transposon.

Interestingly, we showed here that the bla_SCO-1 gene has disseminated in different Acinetobacter species. It seems very likely that dissemination of this gene could be linked to the spread of a single plasmid among all these isolates. It is noteworthy that the bla_SCO-1 gene has been identified in cases from other Argentinean hospitals which are very distantly localized; Buenos Aires, for example, is distant (1,300 km) from the province of Rio Negro. Overall, these observations suggest the likelihood of a widespread diffusion for a bla_SCO-1-positive plasmid in Argentina that could also be identified in other South American countries. The impact (although quite moderate) of SCO-1 production under conditions of reduced susceptibility to expanded-spectrum cephalosporins may enhance the selection of Acinetobacter isolates exhibiting resistance to these molecules, such as those presented in this study and expressing acquired ESBLs.

Although the Acinetobacter isolates studied possessed other ß-lactamase genes (bla_VEB-1a, bla_PER-2, and bla_OXA-58), the corresponding ß-lactamase genes were not located on the same bla_SCO-1-positive plasmid. This observation is in accordance with the fact that our isolates were either positive or negative for bla_SCO-1 independently of the presence of genes encoding broad-spectrum ß-lactamases OXA-58, VEB-1a, and PER-2. This observation raises the question of the selection agent, if any, at the origin of the presence (or persistence) of the bla_SCO-1 plasmid in Acinetobacter spp. isolates that are resistant to most (if not all) ß-lactams, whereas SCO-1 possesses a narrow-spectrum of hydrolysis.

Epidemiological studies may be conducted to search for the bla_SCO-1 gene in ticarcillin-resistant Acinetobacter isolates and to better estimate its prevalence. In addition, searching for this novel ß-lactamase gene in other gram-negative bacteria (Enterobacteriaceae, Pseudomonas spp., etc.) and in other countries should help to evaluate whether the identification of this novel ß-lactamase gene truly corresponds to the emergence of a novel resistance determinant.

 
This work was funded by a grant from the Ministère de l'Education Nationale et de la Recherche (UPRES-EA3539), Université Paris XI, France, and mostly by grants from the European Community (6th PCRD, LSHM-CT-2005-018705).

We thank the WHONET-Argentina network for their permanent efforts in the detection of emergent resistance mechanisms. We also thank Sandrine Bernabeu for technical assistance.

L.P. is a researcher from the INSERM (Paris, France).

 
* Corresponding author. Mailing address: Service de Bactériologie-Virologie, Hôpital de Bicêtre, 78 rue du Général Leclerc, 94275 Le Kremlin-Bicêtre cedex, France. Phone: 33-1-45-21-36-32. Fax: 33-1-45-21-63-40. E-mail: nordmann.patrice{at}bct.aphp.fr

Published ahead of print on 9 April 2007.

L.P. and S.C. contributed equally to this work.

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Antimicrobial Agents and Chemotherapy, June 2007, p. 2179-2184, Vol. 51, No. 6
0066-4804/07/$08.00+0     doi:10.1128/AAC.01600-06
Copyright © 2007, American Society for Microbiology. All Rights Reserved.

This article has been cited by other articles:

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• Partridge, S. R., Arlet, G. (2007). Genetic Environment of ISEcp1 and blaACC-1. Antimicrob. Agents Chemother. 51: 2658-2659 [Full Text]  

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