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Antimicrobial Agents and Chemotherapy, January 2006, p. 355-358, Vol. 50, No. 1
0066-4804/06/$08.00+0     doi:10.1128/AAC.50.1.355-358.2006
Copyright © 2006, American Society for Microbiology. All Rights Reserved.

bla_IMP-9 and Its Association with Large Plasmids Carried by Pseudomonas aeruginosa Isolates from the People's Republic of China

Jianhui Xiong,^1,2 Michael F. Hynes,³ Huifen Ye,² Huiling Chen,² Yinmei Yang,² Fatima M'Zali,⁴ Peter M. Hawkey,^1* the Guangzhou Antibiotic Resistance Study Group

Division of Immunity and Infection, University of Birmingham, Edgbaston, Birmingham B15 2TT, United Kingdom,¹ Department of Laboratory Medicine, 1st Municipal People's Hospital of Guangzhou, 510180 Guangzhou, People's Republic of China,² Department of Biological Sciences, University of Calgary, Calgary, Alberta T2N 1N4, Canada,³ Division of Microbiology, University of Leeds, LS2 9JT Leeds, United Kingdom⁴

Received 13 May 2005/ Returned for modification 5 July 2005/ Accepted 22 October 2005

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A novel plasmid-mediated metallo-ß-lactamase (IMP-9) is described in seven isolates of Pseudomonas aeruginosa from Guangzhou, China, isolated in 2000. The gene was carried on a large (450-kb) IncP-2 conjugative plasmid. This is the first report of carriage of bla_IMP genes on such large plasmids.

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Acquired ß-lactamase genes in Pseudomonas aeruginosa are often associated with transposons and integrons and carried on R plasmids, which can be classified into 13 incompatibility groups (P1 to 13) with a wide range of sizes (8 to 483 kb). The IncP2 plasmids are described as particularly common in P. aeruginosa (50% of the transmissible plasmids), are very large, and are distributed worldwide (13).

Carriage of metallo-ß-lactamase (MBL) genes of the bla_IMP or bla_VIM type has been reported infrequently on plasmids in P. aeruginosa. A limited number of bla_IMP/VIM genes, such as bla_IMP-1, _-3, _-10, and _-12 and bla_VIM-2, have been reported on plasmids with a size range of 31 to 56 kb in P. aeruginosa or P. putida (5, 10, 11, 15, 20, 24). Some studies have failed to find plasmids in carbapenem-resistant P. aeruginosa even though the resistance marker was transferred by conjugation (16).

The carbapenem resistance rates in P. aeruginosa isolates in the city of Guangzhou, China, have been reported to be 16 to 18% during the period 1998 to 2001, according to a multicenter surveillance of antibiotic resistance in nosocomial isolates from that area (25).

In this report, we describe the identification of a new variant of the IMP-type plasmid-mediated MBL gene in carbapenem-resistant isolates of P. aeruginosa from that area.

In the year 2000, a total of 301 clinically significant and nonduplicated P. aeruginosa isolates were collected from the 12 participating centers, and 54 isolates from 11 centers were found to be resistant to imipenem by disk screening (zone diameter, 17 mm) (Clinical and Laboratory Standards Institute [formerly National Committee on Clinical and Laboratory Standards]); 29 of them were randomly selected as representative isolates from each of the 11 centers. The standard strains used in this study as quality controls or for conjugation and plasmid incompatibility testing are listed in Table 1. The PCR primers used are listed in Table 2.

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TABLE 1. Bacterial strains used in this study

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TABLE 2. Oligonucleotide primers used for PCR amplification and sequencing in this study

By the Etest MBL (AB BIODISK, Solna, Sweden), 19 of the 29 P. aeruginosa isolates were positive for production of MBL. Seven of the 29 isolates screened with PCR primers IMP-1 and -2 were positive. No bla_VIM genes were detected in the 29 isolates. The discrepancy between the results of Etest MBL (19/29 positive) and PCR (7/19) could be explained by the presence of carbapenemases other than IMP- or VIM-type enzymes.

The bla_IMP-positive isolates were found to carry a new bla_IMP variant, named bla_IMP-9, as identified by direct sequencing of both strands of the PCR amplicon with primers IMP-13 and IMP-15 (3). It was 82 to 91% homologous to other bla_IMP alleles, and its product was 78 to 91% identical to the other IMP-type enzymes (http://www.ncbi.nlm.nih.gov/). In isolate 96, the bla_IMP-9 gene was found to be carried on a gene cassette inserted between a 5'- and a 3'-conserved segment typical of sul-1-associated integrons, as determined by PCR mapping and sequencing with primers listed in Table 2 (EMBL/GenBank accession number AY033653). The integron cassette array included five gene cassettes: aacA4bla_IMP-9aacA4catB8bla_OXA-10. The bla_IMP-9 gene was found in an identical genetic context in the other six bla_IMP-positive isolates.

Interestingly, 59be of the bla_IMP-9 gene cassette is most closely related (only one nucleotide difference, position 776 GC in AB074437) to that of bla_IMP-11 (89% homologous to bla_IMP-9) found in P. aeruginosa from Japan (S. Iyobe et al., unpublished data), while it was more divergent (83% homology) from that of bla_IMP-5, despite a higher similarity (91%) in their ß-lactamase genes.

Nucleotide sequence analysis of the amplicon obtained from isolate 96 showed a hybrid P_ant promoter identical to that of In1 in R46 (17) and also to that carried by the bla_IMP-4 gene-containing integron described in a Citrobacter youngae from the same area (7).

The ß-lactam MICs determined by the agar dilution method (19) and clinical data of the seven bla_IMP-carrying P. aeruginosa isolates are shown in Table 3. Interestingly, upon MIC testing some isolates appeared to be carbapenem intermediate or even susceptible and meropenem appeared to be consistently more active than imipenem against those isolates. The isolates were sensitive or borderline resistant to ciprofloxacin, amikacin, or gentamicin. All seven bla_IMP-positive isolates were also resistant to potassium tellurite, with MICs of 10^–3 M by a quantitative method (23).

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TABLE 3. Susceptibility profiles and MBL production of blaIMP-9-carrying P. aeruginosa isolates and their transconjugants

Conjugal transfer of resistance (1) to carbapenems and other ß-lactams was demonstrated with four of the bla_IMP-9-carrying P. aeruginosa isolates with P. aeruginosa NCTC 50814 as the recipient, but not with Escherichia coli UB1637/R (4). In all cases, the transfer of bla_IMP-9 was confirmed by Southern hybridization with a specific probe and PCR amplification with primers IMP-1 and -2 (Fig. 1A and B and data not shown). Resistance to tellurite was also transferred. Tellurite MICs for transconjugants were higher than that for recipient strain NCTC 50814 (10^–4 M versus 10^–5 M), although they were lower than those for donors (see above).

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FIG. 1. Plasmids (A), hybridization profiles (B), and sizing of plasmids (C) of IMP-9-producing P. aeruginosa isolates and their transconjugants. The plasmids were prepared by a modification of the Eckhardt method. (A) Plasmid patterns of the isolates of 96 and its transconjugants, 121 and 67. (B) Hybridization profiles of plasmid preparations from panel A with digoxigenin-labeled specific probes. (C) Sizing of plasmid pOZ176 on the basis of the published sizes of the standard plasmids from R. leguminosarum strains 3841, LRS39401, and VF39 and A. tumefaciens C58.

The plasmid content of P. aeruginosa 96 and its transconjugant was investigated by a modification of the Eckhardt method for isolation of large plasmids (8, 9). The size of the plasmids carried by P. aeruginosa 96 and by its transconjugant 96T was almost the same as that of the larger plasmid of Agrobacterium tumefaciens C58 (pAtC58 [543 kb]), the D plasmid (pRL10JI) of Rhizobium leguminosarum 3841 (488 kb), and the D plasmid (ca. 500 kb) of R. leguminosarum VF39 by visual estimation (Fig. 1C). From the plotted standard curve, the size of the plasmid was determined to be about 450 to 500 kb and the plasmid was designated pOZ176.

IncP group incompatibility tests (22) showed that pOZ176 and an IncP9-carrying plasmid (R2) could be transferred reciprocally and could replicate in the same cell. Their coreplication was confirmed by the phenotypic changes in resistance markers, plasmid profile, and PCR detection of the bla_IMP gene. In contrast, introduction of pOZ176 eliminated the IncP2 plasmid from P. aeruginosa PAO1(pBS31), P. putida ML4262(pBS228), and P. putida ML4262(R2) (Table 1), as confirmed by changes in the properties of the transconjugants. Furthermore, to test for the possibility of plasmid hybridization and incompatibility between IncP2 plasmids, P. aeruginosa 96 was crossed with PU21 (12) and PU21(pOZ176) was then crossed with PAO2003(CAM) (containing an IncP2 plasmid encoding functions for camphor degradation) (2), and PAO2003 was used as a control. Loss of the Cam⁺ phenotype (14) was observed in 90% of the resulting transconjugants, indicating the incompatibility of the IncP2 plasmids from P. aeruginosa PAO2003 and 96. However, the phenotypes of both CAM and pOZ176 were also found in some of the transconjugants, which suggests the possibility of generation of CAM-pOZ176 recombinant plasmids; such IncP2 hybrid plasmid formation was first reported in P. aeruginosa in 1974 (12). The evidence for pOZ176 being an IncP2 plasmid is as follows: (i) pOZ176 mediates transferable tellurite resistance (13); (ii) pOZ176 was not stable with an IncP2 plasmid and was able to form a recombinant plasmid with a Cam⁺ plasmid (IncP2), possibly via homologous DNA recombination or transposon-mediated cointegration (14); and (iii) the plasmid is large with a limited host range (13).

Randomly amplified polymorphic DNA typing (18) showed that the seven bla_IMP-positive isolates from four hospitals were nonclonal, except isolates 96 and 121, which were from the same hospital and ward. This finding, together with identification of the bla_IMP-9 gene on a transferable plasmid, suggests that spreading of carbapenem resistance mediated by IMP-9 MBL in P. aeruginosa in our area is largely due to horizontal transfer of the gene, most likely on a large R plasmid similar to pOZ176.

 
We thank the members of 12 medical centers, namely, H. Ye, S. Pan, D. Chen, H. Li, D. Su,Y. Wei, D. Xu, S. Lu, F. Lai, Z. Xiao, and D. Shen. We particularly thank G. A. Jacoby, D. M. Livermore, and C. M. Thomas for providing strains and helpful discussion. Our thanks also go to the L. Piddock group, J. P. W. Young, A. Hanes, T. Walsh, A. Simm, R. Hall, A. Chanawong, X. H. Zou, AB BIODISK, and the Japan MAFF Gene Bank.

DNA sequencing was supported by BBSRC grant 6/JIF3209. We thank the Guangzhou Government for funding this study (grant 98-Z-01-022).

 
* Corresponding author. Mailing address: Health Protection Agency, West Midlands Public Health Laboratory, Birmingham Heartlands and Solihull NHS Trust, Bordesley Green East, Birmingham B9 5SS, United Kingdom. Phone: 44 (0) 121 424 1240. Fax: 44 (0) 121 772 6229. E-mail: peter.hawkey{at}heartofengland.nhs.uk.

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Antimicrobial Agents and Chemotherapy, January 2006, p. 355-358, Vol. 50, No. 1
0066-4804/06/$08.00+0     doi:10.1128/AAC.50.1.355-358.2006
Copyright © 2006, American Society for Microbiology. All Rights Reserved.

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This Article Abstract Full Text (PDF) Alert me when this article is cited Alert me if a correction is posted Services Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Reprints and Permissions Copyright Information Books from ASM Press MicrobeWorld Citing Articles Citing Articles via HighWire Citing Articles via Google Scholar Google Scholar Articles by Xiong, J. Search for Related Content PubMed PubMed Citation Articles by Xiong, J.