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Antimicrobial Agents and Chemotherapy, November 2005, p. 4733-4738, Vol. 49, No. 11
0066-4804/05/$08.00+0     doi:10.1128/AAC.49.11.4733-4738.2005
Copyright © 2005, American Society for Microbiology. All Rights Reserved.

Molecular Mechanisms of ß-Lactam Resistance Mediated by AmpC Hyperproduction in Pseudomonas aeruginosa Clinical Strains

Carlos Juan,¹ María D. Maciá,¹ Olivia Gutiérrez,¹ Carmen Vidal,² José L. Pérez,¹ and Antonio Oliver^1*

Servicio de Microbiología,¹ Unidad de Secuenciación, Hospital Son Dureta, Palma de Mallorca, Spain²

Received 3 May 2005/ Returned for modification 11 August 2005/ Accepted 13 August 2005

Top Abstract Introduction Materials and Methods Results Discussion References

 
The molecular mechanisms of ß-lactam resistance mediated by AmpC hyperproduction in natural strains of Pseudomonas aeruginosa were investigated in a collection of 10 isogenic, ceftazidime-susceptible and -resistant pairs of isolates, each sequentially recovered from a different intensive care unit patient treated with ß-lactams. All 10 ceftazidime-resistant mutants hyperproduced AmpC (ß-lactamase activities were 12- to 657-fold higher than those of the parent strains), but none of them harbored mutations in ampR or the ampC-ampR intergenic region. On the other hand, six of them harbored inactivating mutations in ampD: four contained frameshift mutations, one had a CT mutation, creating a premature stop codon, and finally, one had a large deletion, including the complete ampDE region. Complementation studies revealed that only three of the six ampD mutants could be fully transcomplemented with either ampD- or ampDE-harboring plasmids, whereas one of them could be transcomplemented only with ampDE and two of them (including the mutant with the deletion of the ampDE region and one with an ampD frameshift mutation leading to an ampDE-fused open reading frame) could not be fully transcomplemented with any of the plasmids. Finally, one of the four mutants with no mutations in ampD could be transcomplemented, but only with ampDE. Although the inactivation of AmpD is found to be the most frequent mechanism of AmpC hyperproduction in clinical strains, our findings suggest that for certain types of mutations, AmpE plays an indirect role in resistance and that there are other unknown genes involved in AmpC hyperproduction, with at least one of them apparently located close to the ampDE operon.

Top Abstract Introduction Materials and Methods Results Discussion References

 
Pseudomonas aeruginosa is a ubiquitous versatile environmental microorganism that is the leading cause of opportunistic human infections (34). This pathogen is frequently involved in acute nosocomial infections, especially affecting patients in intensive care units (ICU) with mechanical-ventilation-associated pneumonia or burn wound infections, both of which are associated with a high mortality rate (26, 35). P. aeruginosa is also the major cause of chronic respiratory infections in patients with cystic fibrosis (CF) and other underlying chronic respiratory diseases (9, 25, 27).

P. aeruginosa resistance development during antimicrobial therapy, mediated by the selection of mutations in certain chromosomal genes, is a frequent problem with major consequences, especially when it affects critical patients in the ICU or chronically colonized patients, in whom this problem is amplified due to the high prevalence of hypermutable strains (5, 7, 10, 14, 23, 31). The most relevant mechanism for the development of resistance to the antipseudomonal penicillins (such as ticarcillin or piperacillin) and cephalosporins (such as ceftazidime) is the selection of mutations leading to the hyperproduction of the chromosomal cephalosporinase AmpC (8, 21, 23). AmpC is a group I, class C ß-lactamase present in most Enterobacteriaceae and in P. aeruginosa and other nonfermenting gram-negative bacilli (2, 22). With the exception of those in Escherichia coli and Shigella spp., ß-lactamase is produced at low basal levels, but its expression is inducible by certain ß-lactams, specially cefoxitin and imipenem. During treatment with ß-lactams, resistant mutants showing constitutive high levels of AmpC production are frequently selected, leading to therapeutic failure (8, 37).

There are several genes involved in ampC induction, a process that is intimately linked to peptidoglycan recycling (28). This system was first characterized for Enterobacteriaceae (Enterobacter cloacae and Citrobacter freundii) and was later found to be conserved also in P. aeruginosa (17, 18, 24). Of the genes involved, ampR, which is contiguous to ampC but divergently transcribed, encodes a transcriptional regulator of the LysR family that is required for ß-lactamase induction (12, 20). ampG encodes a transmembrane protein that functions as a permease for 1,6-anhydromurapeptides, which are thought to be the signal molecules involved in ampC induction (6, 15). ampD encodes a cytosolic N-acetyl-anhydromuramil-L-alanine amidase that hydrolyzes 1,6-anhydromurapeptides, acting as a repressor of ampC expression (11, 19), and ampE, which forms the bicistronic ampDE operon together with ampD, encodes a cytoplasmic membrane protein thought to act as a sensory transducer molecule required for induction (13).

Mutational inactivation of ampD and specific point mutations on ampR are the main mechanisms found to lead to the hyperproduction of AmpC, and consequently to ß-lactam resistance, in Enterobacteriaceae (16, 19, 33). As for P. aeruginosa, although ampD inactivation in a few strains and a specific point mutation in ampR (Asp135Asn) in one strain have also been associated with ß-lactamase overproduction, the investigation of a limited number of mutant strains has revealed interesting differences, such as the absence of mutations either in ampD or in ampR in some AmpC-hyperproducing strains (1, 3, 18).

The objectives of the present work were (i) to characterize the mutations responsible for AmpC hyperproduction in a large collection of P. aeruginosa clinical strains isolated from ICU patients and (ii) to find out whether ampE (as part of the ampDE operon) has an indirect role in resistance or whether, on the contrary, only ampD is involved in the AmpC hyperproduction phenotype. For this purpose, complementation studies using plasmids harboring either ampD alone or the complete ampDE operon were conducted with all the ceftazidime-resistant strains.

Top Abstract Introduction Materials and Methods Results Discussion References

 
Bacterial strains and susceptibility testing. A total of 10 pairs of ceftazidime-susceptible and -resistant (8-fold increase in MICs) P. aeruginosa clinical isolates were studied. Each pair of isolates was sequentially recovered from clinical samples (bronchial aspirates and wound infections in 9 cases and 1 case, respectively) from each of the 10 patients admitted to the ICU between September 2002 and November 2003 as part of a study of the epidemiology of P. aeruginosa antibiotic resistance in this setting (14). For two of the patients, two sequential mutants, each with increased ceftazidime resistance, were recovered. The 10 patients from which the ceftazidime-resistant mutants were isolated had been previously treated or were under treatment with either ceftazidime, cefepime, or piperacillin-tazobactam. The paired isolates from each of the patients were documented to be isogenic by pulsed-field gel electrophoresis, and each of the 10 pairs studied was found to belong to a different clone in the previous work (14). Bacterial identification and initial susceptibility testing were performed with the Wider system (Francisco Soria Melguizo, Madrid, Spain) (4). Additionally, ceftazidime MICs were determined by the Etest method (AB Biodisk, Solna, Sweden) according to the manufacturer's recommendations.

ß-Lactamase assays and determination of expression of efflux pumps. Specific ß-lactamase activity (nanomoles of nitrocefin hydrolyzed per minute per milligram of protein) was determined spectrophotometrically on crude sonic extracts as previously described (30). For induction experiments, before the preparation of the crude sonic extracts, the strains were grown in the presence of 50 µg/ml cefoxitin for 3 hours. In all cases, the mean values of ß-lactamase activity obtained in two independent experiments were considered. Based on the analysis of the results from the duplicate experiments, differences in ß-lactamase activities above twofold were considered significant. To evaluate the possible presence of other ß-lactamases in addition to AmpC in the studied strains, two different approaches were followed. (i) The inhibition of ß-lactamase activity after the incubation of crude extracts for 15 min in 50 µM cloxacillin, a class C ß-lactamase inhibitor (22), was tested. Representative ß-lactamase extracts from classes A (TEM-1), B (VIM-2), C (PAO1 induced with cefoxitin), and D (OXA-40) were used as controls and for procedure standardization. ß-Lactamase activities were measured after cloxacillin treatment as described above, and a >95% reduction of nitrocefin hydrolysis was considered a positive result for class C ß-lactamases and negative for classes A, B, and D. (ii) Isoelectric focusing (IEF) of crude sonic extracts using Phast gels (pH gradient, 3 to 9) in a Phast system apparatus (Pharmacia AB, Uppsala, Sweden) was performed for all the ceftazidime-susceptible (with and without cefoxitin induction) and -resistant pairs of isolates.

The levels of expression of mexB and mexF were determined by real-time PCR for the 10 pairs of ceftazidime-susceptible and -resistant isolates and PAO1 (as a control) by following a modified protocol previously described by Oh et al. (29). Briefly, total RNA from logarithmic-phase-grown cultures was obtained with the RNeasy mini kit (QIAGEN, Hilden, Germany) and was adjusted to a final concentration of 50 ng/µl. Purified RNA (50 ng) was then used for one-step reverse transcription- and real-time PCR amplification using the QuantiTect SYBR green reverse transcription-PCR kit (QIAGEN, Hilden, Germany) in the SmartCycler II (Cepheid, Sunnyvale, CA). Previously described conditions and primers MxB-U and MxB-L, MxF-U and MexF-L, and RpsL-1 and RpsL-2 were used for the amplification of mexB, mexF, and rpsL (used as references to calculate the relative amounts of mRNA of efflux pump proteins), respectively (29). In all cases, the mean values of mRNA expression obtained in three experiments were considered.

PCR amplification and sequencing of ampD, ampE, ampR, and the ampR-ampC intergenic region. PCR amplification of ampD, ampE, and ampR (including the ampR-ampC intergenic region) was performed on whole DNA extracts (DNeasy tissue kit; QIAGEN, Hilden, Germany) from both the ceftazidime-susceptible and the ceftazidime-resistant isolates from each of the 10 pairs of P. aeruginosa strains. Primers ADF (5'-GTACGCCTGCTGGACGATG-3') and ADR (5'-GAGGGCAGATCCTCGACCAG-3') were used to amplify a 0.9-kb DNA fragment containing the complete ampD gene and its promoter region (17). AEF (5'-GCCTGGACCCGAACGAAC-3') and AER (5'-TCAGAGGAACAGCGCGCAG-3') were used to amplify a 1.2-kb fragment containing the complete ampE gene (17), and ARF (5'-GTCGACCCAGTGCCTTCAGG-3') and ARR (5'-CTCGAGAGCGAGATCGTTGC-3') were used to amplify a 1.4-kb fragment containing ampR and the ampR-ampC intergenic region (24). Two independent PCR products for each isolate and gene were sequenced on both strands. The BigDye Terminator kit (PE-Applied Biosystems) was used for performing the sequencing reactions that were analyzed with the ABI Prism 3100 DNA sequencer (PE-Applied Biosystems).

Cloning of ampD and ampDE and complementation studies. For cloning ampD, the PAO1 wild-type gene was PCR amplified using primers ADF_BHI and ADR_BHI (the above-described primers ADF and ADR to which a tail containing a BamHI restriction site was added). For cloning the whole ampDE operon, the same forward primer (ADF_BHI) and the reverse primer AER_BHI (the above-described AER to which a tail containing a BamHI restriction site was added) were used. PCR products were ligated to plasmid pGEM-T to obtain pGTAD or pGTADE, which were transformed into the E. coli XL1-Blue strain made competent by CaCl₂. Transformants were selected in 50 µg/ml ampicillin-MacConkey agar plates. ampD or ampDE fragments obtained from three independent experiments were fully sequenced to ascertain the absence of mutations in the cloned fragments produced during PCR amplification. Plasmid DNA from pGTAD or pGTADE digested with either BamHI or EcoRI, respectively, was ligated to plasmid pUCP24 (36), which was digested with the same enzymes to obtain plasmids pUCPAD and pUCPADE, which were transformed into E. coli XL1-Blue. Transformants were selected in 20 µg/ml gentamicin-MacConkey agar plates. In both cases, recombinant plasmids with DNA inserts with an orientation opposite to that of the LacZ promoter were selected. Plasmids pUCPAD, pUCPADE, and pUCP24 were then electroporated into the different ceftazidime-resistant strains or PAO1 (as a control) as previously described (32). Transformants were selected in 50 µg/ml gentamicin-Luria-Bertani (LB) agar plates. Ceftazidime MICs and ß-lactamase activity were determined to evaluate the complementation of the AmpC hyperproduction phenotype.

Nucleotide sequence accession number. The GenBank accession number for the ampDE-fused open reading frame of AmpC-hyperproducing strain JGS2A1 is DQ114494.

Top Abstract Introduction Materials and Methods Results Discussion References

 
Ceftazidime MICs and the basal and induced ß-lactamase activities of the 10 paired ceftazidime-susceptible and -resistant isogenic clinical strains are shown in Table 1. The increase in ceftazidime MICs of the resistant mutants ranged from 8- to 42-fold. For two of the patients, two-step ceftazidime-resistant mutants were sequentially recovered, and therefore, three isolates for each of the patients are shown in Table 1.

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TABLE 1. Ceftazidime MICs, specific ß-lactamase activity, results for complementation with pUCPAD and pUCPADE, and ampD mutations of the 10 pairs of ceftazidime-susceptible and ceftazidime-resistant isogenic clinical strains

All the susceptible isolates had an inducible AmpC production phenotype, with induced/basal ß-lactamase activity ratios ranging from 11 to 88. In all cases, ceftazidime resistance was associated with a significant increase in basal ß-lactamase activities that ranged 12- to 657-fold higher than those of the susceptible strains, demonstrating the presence of an AmpC hyperproduction phenotype (Table 1). For both patients with two-step ceftazidime-resistant mutants, only the second resistant isolates (MBQ1C5 and OFC2I4) were associated with AmpC hyperproduction. Five of the 10 studied resistant mutants retained a certain degree of inducibility (induced/basal ß-lactamase activity ratios were >2), whereas the other five were apparently fully derepressed mutants.

The presence of additional ß-lactamases besides AmpC in the studied strains was ruled out by the cloxacillin inhibition test and IEF as described in Materials and Methods. Briefly, the ß-lactamase activity of crude sonic extracts was inhibited by cloxacillin in all cases, and in IEF, no ß-lactamase bands were detected in the basal extracts from ceftazidime-susceptible isolates and a single pI 8 to 9 ß-lactamase band was detected in both cefoxitin-induced extracts from the susceptible isolates and basal extracts from the resistant mutants.

The contribution of the hyperproduction of efflux pumps to the ceftazidime resistance phenotype was explored as well in the 10 pairs of isolates. As expected, no significant differences were documented in the expression of mexB or mexF between the ceftazidime-susceptible isolates and the ceftazidime-resistant mutants hyperproducing AmpC. Nevertheless, for one the pairs (JSG1H9-JSG2A1), both isolates hyperexpressed MexAB-OprM (mexB mRNA levels were sixfold higher than those of PAO1), a finding that could explain the higher ceftazidime MICs (6 and >256 µg/ml for JSG1H9 and JSG2A1, respectively) than those for the other pairs of isolates (Table 1). Regarding the two cases in which two-step ceftazidime-resistant mutants were documented, the first-step mutation not related to AmpC hyperproduction was found to be associated with the hyperexpression of MexEF-OprN, showing strains MBQ1B2 and OFC2H1 to have 5- and 11-fold-higher levels of mexF mRNA, respectively, than those of their respective susceptible parent strains.

Characterization of the mutations leading to AmpC hyperproduction. The presence of mutations responsible for the AmpC hyperproduction phenotype was investigated by the sequencing of ampD, ampE, ampR, and the ampC-ampR intergenic region of both ceftazidime-susceptible and -resistant isolates. None of the resistant isolates contained any mutations in ampR or the ampC-ampR intergenic region compared with their isogenic susceptible isolates. On the other hand, 6 of the 10 AmpC-hyperproducing mutants contained inactivating mutations in ampD (Table 1). Interestingly, the five AmpC-hyperproducing mutants that retained certain inducibility included the four strains with no mutations in ampD but only one of the six strains with mutations in this gene. Four of the strains harbored ampD frameshift mutations produced by a 1-bp insertion or deletion (Table 1). Strain MQB1C5 contained a CT mutation on nucleotide (nt) 463 of ampD, creating a premature stop codon. Finally, strain OFC2I4 had a large deletion, including the complete ampDE region, not present in its susceptible pair (OFC2G5) or in the isolate with an intermediate resistance level isolated from the same patient (OFC2H1). This deletion was associated with the loss of an approximately 25-kb DNA fragment from one of the SpeI restriction fragments in the pulsed-field gel electrophoresis analysis (not shown). PCR amplification using ampD and ampE primers as well as two sets of internal primers (one for each gene) consistently failed for strain OFC2I4. Finally, PCR mapping, using primers based on the published PAO1 sequence (34), of an 11-kb fragment surrounding the ampDE region (from nt 5057716 to 5068746 of the PAO1 sequence, including hypothetical proteins PA4517 to PA4524) confirmed as well that the complete region was conserved (identical structure to that of PAO1) in the susceptible strain and completely absent in OFC2I4.

Complementation of ampD-deficient mutants with plasmids harboring wild-type ampD (pUCPAD) or wild-type ampDE (pUCPADE). Complementation of the AmpC hyperproduction phenotype was evaluated by comparing the ceftazidime MICs and ß-lactamase activities of transformant colonies harboring pUCPAD or pUCPADE with those of transformants harboring pUCP24. For strains JCM2C2, MSC2A9, and MQB1C5, ceftazidime MICs and basal ß-lactamase activities were restored back to wild-type levels when the strains harbored either pUCPAD or pUCPADE (Table 1). On the other hand, the AmpC hyperproduction phenotype of strain BCL2A8 was transcomplemented only by pUCPADE and not by pUCPAD. The only apparent difference in the ampD-inactivating mutation from this strain compared to those of the above strains with a positive pUCPAD complementation is that the inactivating mutation is located much earlier in the coding sequence (Table 1).

Finally, two of the strains (JSG2A1 and OFC2I4) harboring inactivating mutations in ampD could not be fully transcomplemented either with pUCPAD or with pUCPADE (Table 1). Nevertheless, for both strains, a partial complementation of the increased ß-lactamase activities was documented only with pUCPADE, but the partial complementation of ß-lactamase activities was not accompanied by a reduction of ceftazidime MICs. The presence of additional mutations in secondary loci may be responsible for the obtained results, although the particularity of the documented ampD mutations for both strains could also explain the results. As for strain OFC2I4, harboring a large deletion including the complete ampDE region, the failure of plasmid pUCPADE to fully transcomplement the AmpC hyperproduction phenotype could suggest that a secondary locus involved in ampC expression is located close to ampDE, and therefore, a single genetic event (deletion) could be responsible for the phenotype. On the other hand, the ampD mutation of strain JSG2A1 was also particularly different from the other frameshift mutations documented. The 1-bp insertion in ampD from this strain was located in nt 481 close to the 3' end of the 564-nt coding sequence of ampD. Since (i) ampE is read in the +3 frame compared to ampD, (ii) a stop codon is not created by the frameshift mutation, and (iii) the stop and start codons of both genes are overlapped, a single open reading frame containing ampD (with the last 28 codons modified) and the complete ampE gene is originated. Therefore, the coding sequence predicts the creation of a hybrid protein containing both AmpD (with the last 28 amino acids modified) and the regular AmpE. Given the different cellular locations of AmpD (cytosol) and AmpE (cytoplasmic membrane), the role of this potential hybrid protein is difficult to predict, although one of the possibilities, supported by the negative complementation results, could be that this hybrid protein is not functional for ampC repression and exhibits a dominant negative effect when wild-type AmpD/AmpE is present. To explore the possibility of this ampD mutation being dominant, the ampDE region of JSG2A1 was cloned as described for PAO1, and the resulting plasmid (pUCPADE_JSG) was transformed into the reference strain PAO1. Since neither the ß-lactamase activity nor the ceftazidime MIC was modified in strain PAO1 harboring pUCPADE_JSG, the results were apparently inconsistent with the AmpC hyperproduction phenotype that was expected to occur if the mutation was truly dominant.

Complementation of AmpC-hyperproducing mutants with no mutations in the ampDE region with plasmid pUCPAD or pUCPADE. None of the strains for which ampD-inactivating mutations were not documented could be transcomplemented with pUCPAD, although a slight decrease in ß-lactamase activity was documented for some of the mutants harboring the plasmid (Table 1). The slight decrease in the ß-lactamase activities of the mutant strains was more apparent when the strains harbored pUCPADE, and remarkably, for one of them (MSF2F5), a positive complementation result was obtained with this plasmid, with ceftazidime MICs being restored to the wild-type levels.

Top Abstract Introduction Materials and Methods Results Discussion References

 
Although specific point mutations in ampR may lead to the constitutive hyperexpression of AmpC, our results for the strains from ICU patients, together with those previously obtained in the CF setting (1, 3), strengthen the observation that this is a very infrequent mechanism of ß-lactam resistance in natural strains of P. aeruginosa. On the other hand, the in vitro inactivation of ampD has been found to confer a partially derepressed phenotype in strain PAO1, leading to a moderate (approximately 35-fold-higher) basal level but hyperinducible AmpC expression (18). The involvement of ampD inactivation in AmpC hyperproduction has been previously studied in a limited number of clinical strains of P. aeruginosa (1, 18). Bagge et al. found the interruption of ampD by an insertion sequence in two CF AmpC-hyperproducing clinical isolates, but none of the three in vitro or in vivo ceftazidime-resistant variants from two other clinical strains contained any inactivating mutation in ampD (1). Similarly, Langaee et al. found no ampD-inactivating mutations in any of the four strains hyperproducing AmpC (18). Our results with a large collection of isogenic ceftazidime-susceptible and -resistant pairs of isolates from ICU patients treated with ß-lactams show that ampD inactivation is the most frequent mechanism for AmpC hyperproduction in clinical strains but also reveal a complex multifactorial picture of the regulation of ß-lactamase expression in P. aeruginosa.

Whereas the role of AmpD as a repressor of ß-lactamase expression is clear, we still have very limited information on the role of the other component, AmpE, encoded by the bicistronic ampDE operon. ampE encodes a cytoplasmic membrane protein thought to act as a sensory transducer molecule required for induction (13). In addition to having this function, AmpE can modulate ampC repression in hyperproducing strains in the absence of inducers, as our results show for the first time. In this sense, for several mutant strains, including some with and some without ampD-inactivating mutations, the production of both AmpD and AmpE from a plasmid repressed ß-lactamase expression more readily than the production of AmpD alone, reaching, in some cases, the extreme results of full complementation of the hyperproduction phenotype with pUCPADE in the absence of pUCPAD complementation. It seems clear that the role of AmpE in ampC repression is not decisive by itself, since the inactivation of ampE alone did not determine the derepression of ampC in the E. coli model of expression of the E. cloacae chromosomal ß-lactamase used by Honore et al. (13). This finding is also supported by the fact that none of the 10 P. aeruginosa AmpC-hyperproducing mutants studied harbored inactivating mutations just in ampE. Nevertheless, our complementation results for the mutants with and without AmpD-inactivating mutations could be the consequence of an indirect role of AmpE in ampC repression/derepression; the polarity of ampD-inactivating mutations over ampE expression, the role of AmpDE fusion proteins produced by the 1-bp insertion of ampD-inactivating mutations (such as that of strain JSG2A1), and the potential effect of AmpE as a transducer molecule in the activity of other yet-unknown gene products involved in ß-lactamase expression are among the important future research directions opened by this work. Regarding the last point, the completely sequenced chromosome of strain PAO1 (34) contains two additional ampD homologues (PA0807 and PA5485) for which implications in ß-lactamase expression are currently being explored by our group. Furthermore, the lack of full complementation of the AmpC hyperproduction phenotype of strain OFC2I4 (harboring a large deletion, including the complete ampDE operon and surrounding regions) with pUCPAD or pUCPADE may suggest that other genes involved in the regulation of the chromosomal cephalosporinase are located close to the ampDE operon.

In summary, our findings show that AmpD inactivation is the most frequent mechanism leading to AmpC hyperproduction in P. aeruginosa clinical strains but also suggest that for certain types of mutations, AmpE plays an indirect role in ß-lactam resistance and that there are several unknown genes involved in AmpC hyperproduction, with at least one of them apparently located close to the ampDE operon.

 
This work was partially supported by the Red Española de Investigación en Patología Infecciosa (REIPI), grant C03-014, from the Ministerio de Sanidad of Spain.

 
* Corresponding author. Mailing address: Servicio de Microbiología, Hospital Son Dureta, C. Andrea Doria No. 55, 07014 Palma de Mallorca, Spain. Phone: 34 971 175 185. Fax: 34 971 175 185. E-mail: aoliver{at}hsd.es.

Top Abstract Introduction Materials and Methods Results Discussion References

 

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Antimicrobial Agents and Chemotherapy, November 2005, p. 4733-4738, Vol. 49, No. 11
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