Antimicrobial Agents and Chemotherapy, November 2004, p . 4438-4440, Vol . 48, No . 11

Plasmid-Mediated Carbapenem-Hydrolyzing Enzyme KPC-2 in an Enterobacter sp.

Ashfaque Hossain,^1,2 M . J . Ferraro,³ R . M . Pino,³ R . B . Dew III,³ E . S . Moland,^1,2 T . J . Lockhart,^1,2 K . S . Thomson,^1,2 R . V . Goering,² and N . D . Hanson^1,2*

Center for Research in Anti-Infectives and Biotechnology,¹ Department of Medical Microbiology and Immunology, Creighton University School of Medicine, Omaha, Nebraska,² Massachusetts General Hospital, Boston, Massachusetts³

Received 12 February 2004/ Returned for modification 16 May 2004/ Accepted 6 July 2004

KPC-2 differs from KPC-1 by a single amino acid change of serine to glycine at position 175, while KPC-3 differs from both KPC-1 and KPC-2 by a single amino acid substitution of tyrosine for histidine at position 272 (9; Young et al., 43rd ICAAC) . Genes encoding these enzymes can be of either chromosomal or plasmidic origin (5, 9) .

In recent years, Enterobacter spp . have been recognized as increasingly important opportunistic pathogens particularly in debilitated and hospitalized patients (8) . In this report, we describe an Enterobacter strain with reduced susceptibility to imipenem cultured on multiple occasions from a patient with sepsis . The reduced imipenem susceptibility was associated with the plasmid-encoded carbapenem-hydrolyzing enzyme, KPC-2 . It was of epidemiologic relevance that the patient had received prior therapy with multiple antibiotics but not a carbapenem .

In 2001, four isolates of a strain of an Enterobacter sp . were obtained from blood (three isolates) and sputum (one isolate) from a patient admitted to a Boston hospital with sepsis after endoscopic retrograde cholangiopancreatography . Prior to the detection of these isolates, the patient had a very complicated hospital course, including initial sepsis with Escherichia coli which cleared after treatment with the combination of ampicillin, gentamicin, and metronidazole, a regimen which was later switched to levofloxacin and gentamicin . The Enterobacter sepsis was treated with amikacin, ceftazidime, metronidazole, and quinupristin-dalfopristin . The patient died, with the cause of death being attributed to myocardial infarction secondary to gram-negative septicemia secondary to a perforated duodenum .

The isolates were identified as Enterobacter cloacae by using a Vitek Legacy system (bioMérieux, St Louis, Mo.) and as Enterobacter asburiae by using a Phoenix system (Becton Dickinson, Baltimore, Md.) and API 20E strips (bioMérieux) . This ambiguity in identification by systems available to clinical microbiology laboratories was not resolved with the supplementary conventional test (methyl red test), by sequencing the chromosomal ampC ß-lactamase gene, or by 16S rRNA gene sequencing (MIDI labs, Newark, Del.) . The methyl red test was negative, indicating that the strain was E . cloacae . However, the sequence of the chromosomal ampC ß-lactamase closely resembled that of the ACT-1 ß-lactamase (97% similarity; GenBank accession no . U58495) and the chromosomal ampC gene of E . asburiae (94% similarity; GenBank accession no . AJ311172) . The ACT-1 ß-lactamase is considered to be derived from the chromosomal ampC ß-lactamase of E . asburiae (7) . Therefore, we finally decided to describe the strain as an Enterobacter sp . The closest match by 16S rRNA gene sequencing was Enterobacter sp . strain MS 412 (99% similarity, accession no . AY297788) .

Antibiotic susceptibilities and ß-lactamase phenotypes were determined by using TREK microdilution panels (Westlake, Ohio) (Table 1) . Carbapenem-hydrolyzing ß-lactamase activity and inhibition characteristics were determined by spectrophotometric hydrolysis assays using 100 µM imipenem as the substrate and 500 µM clavulanate and 250 µM EDTA as the inhibitors . Isoelectric focusing (IEF) was performed on polyacrylamide gels containing ampholines (pH range, 3.5 to 9.5) with crude ß-lactamase extracts to determine isoelectric points (pIs) and general inhibitor characteristics . The genetic relatedness of the isolates was analyzed by pulse field gel electrophoresis with XbaI (10) .

 
Plasmid DNA preparations were obtained by using an alkaline lysis technique (1) . The conjugal transfer of plasmids was carried out in mixed broth cultures with the sodium azide-resistant Escherichia coli strain J53AzR as the recipient and Luria-Bertani agar plates containing 150 µg of sodium azide/ml and 2 µg of ertapenem/ml as selection media . The transconjugants were analyzed for plasmid content and by PCR for the presence of bla_KPC-2 . Primers KPC1F (5'-GCTACACCTAGCTCCACCTTC-3') and KPC3R (5'-TGGAGGGCCAATAGATGATT-3') designed from the bla_KPC-1 gene (AF297554) were used for the detection and sequencing of the carbapenemase gene .

The Enterobacter sp . isolates exhibited elevated imipenem MICs of 8 µg/ml, which is intermediate by NCCLS interpretive criteria (Table 1) . Crude enzyme preparations demonstrated carbapenem hydrolyzing activity in spectrophotometric hydrolysis assays . IEF showed three bands, focusing at 9.2, 6.9, and 5.4 . The band with a pI value of 6.9 was not inhibited well by either cloxacillin or clavulanate and hydrolyzed 1 µg of imipenem/ml on IEF gel overlay (data not shown) . KPC-specific PCR and sequencing demonstrated the presence of bla_KPC-2 in the Enterobacter isolates . Each Enterobacter isolate had an identical plasmid profile, consisting of four plasmids of approximately 65, 9, 4.2, and 4.0 kb in size (Fig . 1) . Pulse field gel electrophoresis profiles of the isolates were identical, suggesting that the isolates were probably of the same strain . Only the high-molecular-weight plasmid was transferred by conjugation . PCR and antibiotic susceptibility assays of the transconjugant indicated that bla_KPC-2 was carried by the 65-kb plasmid (Fig . 1) . The transconjugant was susceptible to imipenem (MIC, 1 µg/ml) . The specific activities of crude cell lysates from the Enterobacter strain and the Escherichia coli transconjugants with imipenem as substrate were 37.59 and 17.08 nmol/min/mg of protein, respectively (Table 1) . These data indicated that production of the carbapenem-hydrolyzing enzyme KPC-2 contributed to the reduced imipenem susceptibility of the Enterobacter sp .

 
It is intriguing that the strain exhibited reduced susceptibility to imipenem even though the patient from whom the strain was isolated was not treated with a carbapenem . Certain class B carbapenemase enzymes are often physically associated with aminoglycoside resistance genes, and evolution of carbapenem resistance following treatment with aminoglycosides has been predicted (6; R . E . Mendes, J . Riberio, M . Castanheira, M . Toleman, H . S . Sader, R . N . Jones, and T . R . Walsh, Abstr . 43rd Intersci . Conf . Antimicrob . Agents Chemother., abstr . C1-661, 2003) . However, it is not known whether such an association exists for class A carbapenemases, such as KPC-type enzymes . Another possible explanation is that therapy with other ß-lactam agents was responsible . The occurrence of class A carbapenem-hydrolyzing enzymes in clinical isolates that predated the use of carbapenems suggested that other ß-lactam antibiotics may also select for their spread in clinical environments (6) .

A recent preliminary report indicated bla_KPC-2 to be chromosomal in E . cloacae (S . Petrell, M . Renard, R . Bismuth, V . Jarlier, and W . Sougakoff, Abstr . 13th Eur . Congr . Clin . Microbiol . Infect . Dis., abstr . 0288, 2003) . However, this is the first report of detection of the plasmid-encoded carbapenem-hydrolyzing enzyme KPC-2 in an Enterobacter sp . The detection of KPC-2 in Klebsiella oxytoca, Escherichia coli, Salmonella enterica serovar Typhimurium, and an Enterobacter sp . in a short period of time after the first detection of this enzyme in K . pneumoniae (4, 9, 12) indicates the potential of bla_KPC-2 to spread among clinical enterobacteria . The detection of this resistance mechanism in an Enterobacter strain is particularly disturbing, because carbapenems are one of the few remaining therapies for infections caused by high-level AmpC- or extended-spectrum ß-lactamase-producing Enterobacter spp . (2) . Loss of the carbapenems would jeopardize the therapy for serious infections caused by a major nosocomial pathogen . Studies to determine the prevalence, sources, and selection pressures responsible for the occurrence of this and other plasmid-encoded carbapenem-hydrolyzing ß-lactamases among clinically relevant gram-negative organisms are urgently needed due to the importance of this drug class in the treatment of serious infections .

1. Hanson, N . D., E . S . Moland, A . Hossain, S . A . Neville, I . B . Gosbell, and K . S . Thomson. 2002 . Unusual Salmonella enterica serotype Typhimurium isolate producing CMY-7, SHV-9 and OXA-30 ß-lactamases . J . Antimicrob . Chemother . 49:1011-1014.
2. Jones, R . N., D . J . Biedenbach, and A . C . Gales. 2003 . Sustained activity and spectrum of selected extended-spectrum ß-lactams (carbapenems and cefepime) against Enterobacter spp . and ESBL-producing Klebsiella spp.: report from the SENTRY antimicrobial surveillance program (USA, 1997-2000) . Int . J . Antimicrob . Agents 21:1-7.
3. Livermore, D . M. 2002 . The impact of carbapenemases on antimicrobial development and therapy . Curr . Opin . Investig . Drugs 3:218-224.
4. Miriagou, V., L . S . Tzouvelekis, S . Rossiter, E . Tzelepi, F . J . Angulo, and J . M . Whichard. 2003 . Imipenem resistance in a Salmonella clinical strain due to plasmid-mediated class A carbapenemase KPC-2 . Antimicrob . Agents Chemother . 47:1297-1300.
5. Poirel, L., and P . Nordmann. 2002 . Acquired carbapenem-hydrolyzing ß-lactamases and their genetic support . Curr . Pharm . Biotechnol . 3:117-127.
6. Queenan, A . M., C . Torres-Viera, H . S . Gold, Y . Carmeli, G . M . Eliopoulos, R . C . Moellering, Jr., J . P . Quinn, J . Hindler, A . A . Medeiros, and K . Bush. 2000 . SME-type carbapenem-hydrolyzing class A ß-lactamases from geographically diverse Serratia marcescens strains . Antimicrob . Agents Chemother . 44:3035-3039.
7. Rottman, M., Y . Benzerara, B . Hanau-Bercot, C . Bizet, A . Philippon, and G . Arlet. 2002 . Chromosomal ampC genes in Enterobacter species other than Enterobacter cloacae, and ancestral association of the ACT-1 plasmid-encoded cephalosporinase to Enterobacter asburiae . FEMS Microbiol . Lett . 210:87-92.
8. Sanders, W . E., Jr., and C . C . Sanders. 1997 . Enterobacter spp.: pathogens poised to flourish at the turn of the century . Clin . Microbiol . Rev . 10:220-241.
9. Smith Moland, E., N . D . Hanson, V . L . Herrera, J . A . Black, T . J . Lockhart, A . Hossain, J . A . Johnson, R . V . Goering, and K . S . Thomson. 2003 . Plasmid-mediated, carbapenem-hydrolysing ß-lactamase, KPC-2, in Klebsiella pneumoniae isolates . J . Antimicrob . Chemother . 51:711-714.
10. Wiener, J., J . P . Quinn, P . A . Bradford, R . V . Goering, C . Nathan, K . Bush, and R . A . Weinstein. 1999 . Multiple antibiotic-resistant Klebsiella and Escherichia coli in nursing homes . JAMA 281:517-523.
11. Yigit, H., A . M . Queenan, G . J . Anderson, A . Domenech-Sanchez, J . W . Biddle, C . D . Steward, S . Alberti, K . Bush, and F . C . Tenover. 2001 . Novel carbapenem-hydrolyzing ß-lactamase, KPC-1, from a carbapenem-resistant strain of Klebsiella pneumoniae . Antimicrob . Agents Chemother . 45:1151-1161.
12. Yigit, H., A . M . Queenan, J . K . Rasheed, J . W . Biddle, A . Domenech-Sanchez, S . Alberti, K . Bush, and F . C . Tenover. 2003 . Carbapenem-resistant strain of Klebsiella oxytoca harboring carbapenem-hydrolyzing ß-lactamase KPC-2 . Antimicrob . Agents Chemother . 47:3881-3889.

Free Online Full-text Article

What Is Botulism?, What Is Nitrification?, What Is Pcr?, What Is Functional Genomics?, What Is Fermentation?, a, Microorganism, n, Microbe, e, Microbes, r, Bacteriology, o, Microorganisms, n, Yeasts, r, Cryptococci, e, Thermophile, n, Antimicrobials, n, Rhizobacter, a, Micrococci, c, Streptococci, o, Bacteria, r, Escherichia coli, e, Yeasts, s, Escherichia coli, i, Penicillin, o, Multidrug resistant, a, Sepsis, s, Escherichia coli, o, S. cerevisiae, c, Escherichia coli, c, Pediococci, n, Salmonella typhimurium, n, Escherichia coli, s, Microbial




 

© 2005 Transgalactic Ltd (manufacturer of Bioscreen C software) | Privacy Statement | P.O. Box 1393, 00101 Helsinki, Finland, phone: +358 9 85172920, fax: +358 9 8749481, e-mail: microbiology@bionewsonline.com
 

Last modified: May 25, 2005