Carbapenemases of Chryseobacterium (Flavobacterium) meningosepticum: distribution of blaB and characterization of a novel metallo-beta-lactamase gene, blaB3, in the type strain, NCTC 10016.

Genes encoding carbapenemases in 15 reference strains of Chryseobacterium (Flavobacterium) meningosepticum from the United Kingdom National Collection of Type Cultures and in one recent clinical isolate were investigated. All the strains hydrolyzed imipenem, but their levels of resistance to carbapenems varied, with imipenem and meropenem MICs ranging from 2 to >32 microg/ml. The blaB gene, which encodes a molecular-class B carbapenemase, was detected in only six reference strains and in clinical isolate 97/P/5448. The gene from 97/P/5448 had 98% nucleotide identity with the published sequence of blaB (from strain NCTC 10585) and was designated blaB2. A distinct carbapenemase gene, designated blaB3, was cloned from the type strain of C. meningosepticum, NCTC 10016. blaB3 had an open reading frame of 750 bp with 82% nucleotide identity to blaB and blaB2 and encoded a beta-lactamase of 249 amino acids, including the putative signal peptide. This beta-lactamase showed 87.6 and 86.7% amino acid homology with BlaB and BlaB2, respectively. blaB3 was detected in one other reference strain besides NCTC 10016, but the genetic basis of the carbapenemase activity detected in the other seven reference strains was not defined. Thus, neither blaB nor blaB3 was ubiquitous in the strains of C. meningosepticum studied, indicating that the reference strains may represent more than one bacterial species, each with its own intrinsic metallo-beta-lactamase. Further taxonomic studies of C. meningosepticum are necessary to resolve this topic. Chryseobacterium spp. are environmental organisms and occasional opportunist pathogens. They apparently represent a reservoir of diverse metallo-beta-lactamases, which potentially spread to gram-negative bacteria of greater clinical significance.

Outbreak of infections caused by Pseudomonas aeruginosa producing VIM-1 carbapenemase in Greece.

Resistance to imipenem and meropenem was observed in 211 (16.5%) isolates of Pseudomonas aeruginosa recovered in a Greek university hospital during 1996 to 1998. In six isolates selected from throughout this period, high-level resistance to both carbapenems (MICs >/= 128 microg/ml) was associated with production of the class B beta-lactamase VIM-1. bla(VIM)-bearing isolates belonged to serotype O:12 and were indistinguishable by pulsed-field gel electrophoresis.

Antimicrobial resistance amongst Klebsiella spp. collected from intensive care units in Southern and Western Europe in 1997-1998.

A 1994 survey of 35 intensive care units (ICUs) in Western and Southern Europe found extended-spectrum beta-lactamases (ESBLs) in 220/966 (23%) klebsiellae. A follow-up survey from May 1997 to October 1998 collected klebsiellae from 24 ICUs, including 23 that participated in 1994. Twenty-one ICUs sent 433 eligible isolates, of which 110 (25%) had ESBLs. The prevalence of ESBLs had not changed significantly from 1994 but the proportion of ESBL-producers resistant to piperacillin/tazobactam had risen from 31% to 63% (P < 0.001), and most of this resistance was high level (MICs >/= 128 + 4 mg/L). The proportion of Klebsiella oxytoca isolates hyperproducing K1 beta-lactamase rose from 8% in 1994 to 21% in 1997-1998 (P < 0. 001). Most klebsiellae (99%) were very susceptible to meropenem (mode MIC 0.03 mg/L) but three had decreased susceptibility (MICs 2-4 mg/L). These could not hydrolyse carbapenems. Aminoglycoside resistance was not significantly changed in prevalence from 1994; ciprofloxacin resistance occurred in 31% of ESBL-producers in both years, but had increased among non-producers (2% in 1994 versus 7% in 1997-1998, P < 0.001).

Effect of conalbumin on the activity of Syn 2190, a 1,5 dihydroxy-4-pyridon monobactam inhibitor of AmpC beta-lactamases.

Syn 2190, a 1,5 dihydroxy-4-pyridon monobactam inhibitor of AmpC enzymes, was tested against beta-lactamase-producing bacteria with piperacillin, piperacillin-tazobactam and ceftazidime as partner drugs. In the presence of conalbumin as an iron chelator, Syn 2190 potentiated these drugs against most AmpC producers, although Klebsiella spp. with plasmidic AmpC enzymes were an exception. Potentiation was much weaker without conalbumin, suggesting that Syn 2190 exploits a ferric uptake pathway, as do catecholic cephalosporins. Syn 2190 had little ability to potentiate partner drugs against strains with other beta-lactamase types but, with conalbumin, increased the activity of piperacillin-tazobactam against Escherichia coli transconjugants producing various class A or D enzymes.

Interactions of beta-lactamases with sanfetrinem (GV 104326) compared to those with imipenem and with oral beta-lactams.

Sanfetrinem is a trinem beta-lactam which can be administered orally as a hexatil ester. We examined whether its beta-lactamase interactions resembled those of the available carbapenems, i.e., stable to AmpC and extended-spectrum beta-lactamases but labile to class B and functional group 2f enzymes. The comparator drugs were imipenem, oral cephalosporins, and amoxicillin. MICs were determined for beta-lactamase expression variants, and hydrolysis was examined directly with representative enzymes. Sanfetrinem was a weak inducer of AmpC beta-lactamases below the MIC and had slight lability, with a kcat of 0.00033 s(-1) for the Enterobacter cloacae enzyme. Its MICs for AmpC-derepressed E. cloacae and Citrobacter freundii were 4 to 8 microg/ml, compared with MICs of 0.12 to 2 microg/ml for AmpC-inducible and -basal strains; MICs for AmpC-derepressed Serratia marcescens and Morganella morganii were not raised. Cefixime and cefpodoxime were more labile than sanfetrinem to the E. cloacae AmpC enzyme, and AmpC-derepressed mutants showed much greater resistance; imipenem was more stable and retained full activity against derepressed mutants. Like imipenem, sanfetrinem was stable to TEM-1 and TEM-10 enzymes and retained full activity against isolates and transconjugants with various extended-spectrum TEM and SHV enzymes, whereas these organisms were resistant to cefixime and cefpodoxime. Sanfetrinem, like imipenem and cefixime but unlike cefpodoxime, also retained activity against Proteus vulgaris and Klebsiella oxytoca strains that hyperproduced potent chromosomal class A beta-lactamases. Functional group 2f enzymes, including Sme-1, NMC-A, and an unnamed enzyme from Acinetobacter spp., increased the sanfetrinem MICs by up to 64-fold. These enzymes also compromised the activities of imipenem and amoxicillin but not those of the cephalosporins. The hydrolysis of sanfetrinem was examined with a purified Sme-1 enzyme, and biphasic kinetics were found. Finally, zinc beta-lactamases, including IMP-1 and the L1 enzyme of Stenotrophomonas maltophilia, conferred resistance to sanfetrinem and all other beta-lactams tested, and hydrolysis was confirmed with the IMP-1 enzyme. We conclude that sanfetrinem has beta-lactamase interactions similar to those of the available carbapenems except that it is a weaker inducer of AmpC types, with some tendency to select derepressed mutants, unlike imipenem and meropenem.

Unusual tazobactam-sensitive AmpC beta-lactamase from two Escherichia coli isolates.

Two Escherichia coli isolates were studied. MIC patterns and hydrolysis assays suggested that they hyperproduced AmpC beta-lactamase, but synergy between ceftazidime and tazobactam was greater than between ceftazidime and Ro 48-1256, whereas the converse pattern is typical of AmpC hyperproducers. Studies with purified beta-lactamase from one of the isolates confirmed that tazobactam was a 100-fold stronger inhibitor than for the classical E. coli AmpC enzyme. Moreover, in contrast to typical AmpC types, the new enzyme had greater affinity for cephaloridine than for benzylpenicillin.