Site-saturation mutagenesis of position V117 in OXA-1 β-lactamase: effect of side chain polarity on enzyme carboxylation and substrate turnover

Class D β-lactamases pose an emerging threat to the efficacy of β-lactam therapy for bacterial infections. Class D enzymes differ mechanistically from other β-lactamases by the presence of an active-site N-carboxylated lysine that serves as a general base to activate the serine nucleophile for attack. We have used site-saturation mutagenesis at position V117 in the class D β-lactamase OXA-1 to investigate how alterations in the environment around N-carboxylated K70 affect the ability of that modified residue to carry out its normal function. Minimum inhibitory concentration analysis of the 20 position 117 variants demonstrates a clear pattern of charge and polarity effects on the level of ampicillin resistance imparted on Escherichia coli (E. coli). Substitutions that introduce a negative charge (D, E) at position 117 reduce resistance to near background levels, while the positively charged K and R residues maintain the highest resistance levels of all mutants. Treatment of the acidic variants with the fluorescent penicillin BOCILLIN FL followed by SDS-PAGE shows that they are active for acylation by substrate but deacylation-deficient. We used a novel fluorescence anisotropy assay to show that the specific charge and hydrogen-bonding potential of the residue at position 117 affect CO(2) binding to K70, which in turn correlates to deacylation activity. These conclusions are discussed in light of the mechanisms proposed for both class D β-lactamases and BlaR β-lactam sensor proteins and suggest a reason for the preponderance of asparagine at the V117-homologous position in the sensors.     

Evolution of Broad Spectrum β-Lactam Resistance in an Engineered Metallo-β-lactamase

The extensive use and misuse of antibiotics during the last seven decades has led to the evolution and global spread of a variety of resistance mechanisms in bacteria. Of high medical importance are β-lactamases, a group of enzymes inactivating β-lactam antibiotics. Metallo-β-lactamases (MBLs) are particularly problematic because of their ability to act on virtually all classes of β-lactam antibiotics. An engineered MBL (evMBL9) characterized by low level activity with several β-lactam antibiotics was constructed and employed as a parental MBL in an experiment to examine how an enzyme can evolve toward increased activity with a variety of β-lactam antibiotics. We designed and synthesized a mutant library in which the substrate activity profile was varied by randomizing six active site amino acid residues. The library was expressed in Salmonella typhimurium, clones with increased resistance against seven different β-lactam antibiotics (penicillin G, ampicillin, cephalothin, cefaclor, cefuroxime, cefoperazone, and cefotaxime) were isolated, and the MBL variants were characterized. For the majority of the mutants, bacterial resistance was significantly increased despite marked reductions in both mRNA and protein levels relative to those of parental evMBL9, indicating that the catalytic activities of these mutant MBLs were highly increased. Multivariate analysis showed that the majority of the mutant enzymes were generalists, conferring increased resistance against most of the examined β-lactams.     

Paradoxical effect of inserting, in Enterococcus faecalis penicillin-binding protein 5, an amino acid box responsible for low affinity for penicillin in Enterococcus faecium

Penicillin-binding proteins 5 (PBP5s) of enterococci are structurally and immunologically related proteins that are characterized by their low affinity for penicillin. For this reason, they are mainly involved in penicillin resistance, due essentially to their ability to take over the function of all other PBPs already bound and inhibited by the beta-lactam. It has been demonstrated that penicillin resistance in enterococci is acquired either by overproduction of PBP5 or by the presence of specific amino acid sequences in the protein that further decrease the affinity for penicillin. In particular, a specific amino acid box (ANNGA) previously identified in Enterococcus faecium is responsible for the high penicillin resistance displayed by this species. Here, we describe the insertion of the PBP5 amino acid box ANNGA in Enterococcus faecalis, an enterococcal species usually more sensitive to penicillin, by site-directed mutagenesis. Mutagenized PBP5 was re-introduced into a pbp5 mutant of E. faecalis obtained by insertion of transposon Tn916. Data indicate that this amino acid box brings about no reduction in penicillin sensitivity in the recipient E. faecalis strain, but, paradoxically, dramatically lowers the penicillin minimal inhibitory concentration caused by the native PBP5. We deduce that, although enterococcal PBP5s are a family of closely related proteins as far as biological function is concerned, differences exist in their three-dimensional structure that affect penicillin affinity.     

Drug resistance of Enterococcus species isolated from the urogenital system

Despite low virulence of enterococci, they have become important nosocomial pathogens. This has been correlated with the increased use of broad-spectrum antibiotics, particularly cephalosporins. Many strains of enterococci exhibit multiple drug resistance; the most important being high-level resistance (HLR) to penicillin (MIC > 100 mg/l) and gentamicin (MIC > 500 mg/l and 2000 mg/l) and/or streptomycin (MIC > 2000 mg/l). The investigation was performed on 92 strains, isolated from genito-urinary tract and recognised as Enterococcus sp. All strains were obtained from several microbiological laboratories of Gdańsk, Gdynia and Tczew. On biochemical reaction profiles species of enterococci were identified as: E. faecalis (72.8%), E. faecalis varians (9.8%), E. durans (7.6%) and E. faecium (9.8%). The minimal inhibitory concentration (MICs) of penicillin, ampicillin, azlocillin, imipenem, gentamicin, amicacin, ciprofioxacin and vancomycin were determined by the agar dilution method. None of these 92 enterococcal strains was vancomycin resistant. 22.2% of E. faecium and 7.5% of E. faecalis showed high-level resistance to penicillin. None of these strains were produced beta-lactamase. High-level resistance to streptomycin and gentamicin was detected. Both--high-level resistance to streptomycin and gentamicin--were found in 6% E. faecalis; 11.1% E. faecalis varians and 22.2% E. faecium.     

Identification of a streptococcal penicillin-binding protein that reacts very slowly with penicillin.

Penicillin-binding protein (PBP) 5 of Streptococcus faecium ATCC 9790 has an unusually low affinity for penicillin (50% binding occurred at a penicillin level of 8 micrograms/ml after 60 min of incubation, and the protein only became labeled after 20 min of incubation with high concentrations of radioactive penicillin). PBPs with similar properties are carried by strains of Streptococcus durans, Streptococcus faecalis, and Streptococcus lactis but not by strains of groups A, B, C, and G streptococci or Streptococcus pneumoniae. The strains carrying the slow-reacting PBP demonstrated a sensitivity to penicillin that was several hundred times lower than that of strains not carrying it. Spontaneous mutants with minimal inhibitory concentrations of penicillin of 20, 40, and 80 micrograms/ml were isolated from S. faecium ATCC 9790. They all showed a dramatic increase in the amount of slow-reacting PBP produced. Mutants with increased penicillin resistance were also isolated from wild-type strains of S. durans, S. faecalis, and S. faecium. All of them carried a greater amount of the slow-reacting PBP than that carried by the parent. Finally, it was found that resistant S. faecium ATCC 9790 mutants grew normally in the presence of penicillin concentrations that were far above that saturating all PBPs except PBP 5. Cell growth was, on the contrary, inhibited by a penicillin concentration that saturated the slow-reacting PBP by 90%. This penicillin dose was equal to the minimal inhibitory concentration.     

血流感染粪肠球菌和屎肠球菌的临床分布及耐药研究

回顾性分析上海市某三甲医院血培养阳性标本中粪肠球菌和屎肠球菌的临床分布及对抗菌药物的耐药特征,为临床治疗其所致感染奠定基础。收集上海市某三甲医院2012年2月—2016年9月血流感染患者血液标本中的粪肠球菌和屎肠球菌,采用法国生物梅里埃公司的VITEK 2Compact全自动细菌鉴定和药敏分析系统进行细菌鉴定及药敏测定,研究细菌临床分布特点及对常用抗菌药物的耐药特征。共分离获得30株粪肠球菌和17株屎肠球菌。粪肠球菌样本主要来自泌尿科、消化科和血液科,所占比例分别为13.33%、16.67%和10.00%。粪肠球菌对青霉素、氨苄西林、环丙沙星、左氧氟沙星、四环素和红霉素的耐药率分别为13.33%、10.00%、36.67%、33.33%、66.67%和60.00%。屎肠球菌样本主要来自消化科(29.41%),其对以上抗菌药物的耐药率分别为88.24%、82.35%、88.24%、76.47%、23.53%和70.59%。屎肠球菌对青霉素、氨苄西林、环丙沙星和左氧氟沙星的耐药率显著高于粪肠球菌,而对四环素的耐药率显著低于粪肠球菌。两者均对替加环素、利奈唑胺和万古霉素敏感,但万古霉素对屎肠球菌的最低抑菌浓度显著低于粪肠球菌。结果提示,屎肠球菌对青霉素、氨苄西林、环丙沙星、左氧氟沙星的耐药率高于屎肠球菌,对万古霉素敏感,且其万古霉素最低抑菌浓度低于粪肠球菌。本研究为治疗这两种细菌所致感染的经验性用药提供了数据支持。     

Identification of New Delhi metallo-β-lactamase gene (NDM-1) from a clinical isolate of Acinetobacter junii in China

New Delhi metallo-β-lactamase-1 (NDM-1) is a novel type of metallo-β-lactamase (MBL) responsible for bacterial resistance to β-lactam antibiotics. Acinetobacter junii was previously shown to possess a MBL phenotype; however, the genes responsible for this phenotype were not identified. In this study, we reported the identification of NDM-1 gene in a clinical isolate of A. junii from a child patient in China, which was resistant to all β-lactams except aztreonam but sensitive to aminoglycosides and quinolones. The cloned NDM-1 gene contained an open reading frame of 813 bp and had a nucleotide sequence 99.9% identical (812/813) to reported NDM-1 genes carried by Acinetobacter baumannii , Enterococcus faecium , Escherichia coli , and Klebsiella pneumoniae . Recombinant NDM-1 protein was successfully expressed in E.?coli BL21, and antibiotic sensitivities of the NDM-1-producing E.?coli were largely similar to the A.?junii 1454 isolate. The findings of this study raise attention to the emergence and spread of NDM-1-carrying bacteria in China.     

Improved activity and pH stability of E. coli ATCC 11105 penicillin acylase by error-prone PCR

Penicillin G acylase is the key enzyme used in the industrial production of β-lactam antibiotics. This enzyme hydrolyzes penicillin G and related β-lactam antibiotics releasing 6-aminopenicillanic acid, which is an intermediate in the production of semisynthetic penicillins. To improve the enzymatic activity of Escherichia coli penicillin acylase, sequential rounds of error-prone polymerase chain reaction were applied to the E. coli pac gene. After the second round of evolution, the best mutant M2234 with enhanced activity was selected and analyzed. DNA sequence analyses of M2234 revealed that one amino acid residue (K297I), located far from the center of the catalytic pocket, was changed. This mutant (M2234) has a specific activity 4.0 times higher than the parent enzyme and also displayed higher stability at pH 10.     

Antibiotic resistance genes in the bacteriophage DNA fraction of environmental samples

Antibiotic resistance is an increasing global problem resulting from the pressure of antibiotic usage, greater mobility of the population, and industrialization. Many antibiotic resistance genes are believed to have originated in microorganisms in the environment, and to have been transferred to other bacteria through mobile genetic elements. Among others, β-lactam antibiotics show clinical efficacy and low toxicity, and they are thus widely used as antimicrobials. Resistance to β-lactam antibiotics is conferred by β-lactamase genes and penicillin-binding proteins, which are chromosomal- or plasmid-encoded, although there is little information available on the contribution of other mobile genetic elements, such as phages. This study is focused on three genes that confer resistance to β-lactam antibiotics, namely two β-lactamase genes (blaTEM and blaCTX-M9) and one encoding a penicillin-binding protein (mecA) in bacteriophage DNA isolated from environmental water samples. The three genes were quantified in the DNA isolated from bacteriophages collected from 30 urban sewage and river water samples, using quantitative PCR amplification. All three genes were detected in the DNA of phages from all the samples tested, in some cases reaching 104 gene copies (GC) of blaTEM or 102 GC of blaCTX-M and mecA. These values are consistent with the amount of fecal pollution in the sample, except for mecA, which showed a higher number of copies in river water samples than in urban sewage. The bla genes from phage DNA were transferred by electroporation to sensitive host bacteria, which became resistant to ampicillin. blaTEM and blaCTX were detected in the DNA of the resistant clones after transfection. This study indicates that phages are reservoirs of resistance genes in the environment.     

Compensatory evolution of pbp mutations restores the fitness cost imposed by β-lactam resistance in Streptococcus pneumoniae

The prevalence of antibiotic resistance genes in pathogenic bacteria is a major challenge to treating many infectious diseases. The spread of these genes is driven by the strong selection imposed by the use of antibacterial drugs. However, in the absence of drug selection, antibiotic resistance genes impose a fitness cost, which can be ameliorated by compensatory mutations. In Streptococcus pneumoniae, β-lactam resistance is caused by mutations in three penicillin-binding proteins, PBP1a, PBP2x, and PBP2b, all of which are implicated in cell wall synthesis and the cell division cycle. We found that the fitness cost and cell division defects conferred by pbp2b mutations (as determined by fitness competitive assays in vitro and in vivo and fluorescence microscopy) were fully compensated by the acquisition of pbp2x and pbp1a mutations, apparently by means of an increased stability and a consequent mislocalization of these protein mutants. Thus, these compensatory combinations of pbp mutant alleles resulted in an increase in the level and spectrum of β-lactam resistance. This report describes a direct correlation between antibiotic resistance increase and fitness cost compensation, both caused by the same gene mutations acquired by horizontal transfer. The clinical origin of the pbp mutations suggests that this intergenic compensatory process is involved in the persistence of β-lactam resistance among circulating strains. We propose that this compensatory mechanism is relevant for β-lactam resistance evolution in Streptococcus pneumoniae.     

Characterization of β-lactamase enzyme activity in bacterial lysates using MALDI-mass spectrometry

Plasmid-encoded β-lactamases are a major reason for antibiotic resistance in gram negative bacteria. These enzymes hydrolyze the β-lactam ring structure of certain β-lactam antibiotics, consequently leading to their inactivation. The clinical situation demands for specific first-line antibiotic therapy combined with a quick identification of bacterial strains and their antimicrobial susceptibility. Strategies for the identification of β-lactamase activity are often cumbersome and usually lack sensitivity and specificity. The current work demonstrates that matrix assisted laser desorption/ionization mass spectrometry (MALDI-MS) is an ideal tool for these analytical investigations. Herein, we describe a fast and specific assay to determine β-lactamase activity in bacterial lysates. The feasibility of the analytical read-out was demonstrated on a MALDI-triple quadrupole (QqQ) and a MALDI time-of-flight (TOF) instrument, and the results allow the comparison of both approaches. The assay specifically measures enzyme-mediated, time-dependent hydrolysis of the β-lactam ring structure of penicillin G and ampicillin and inhibition of hydrolysis by clavulanic acid for clavulanic acid susceptible β-lactamases. The assay is reproducible and builds the basis for future in-depth investigations of β-lactamase activity in various bacterial strains by mass spectrometry.     

Antibiotic resistance and virulence traits in clinical and environmental Enterococcus faecalis and Enterococcus faecium isolates

This study compared virulence and antibiotic resistance traits in clinical and environmental Enterococcus faecalis and Enterococcus faecium isolates. E. faecalis isolates harboured a broader spectrum of virulence determinants compared to E. faecium isolates. The virulence traits Cyl-A, Cyl-B, Cyl-M, gel-E, esp and acm were tested and environmental isolates predominantly harboured gel-E (80% of E. faecalis and 31.9% of E. faecium) whereas esp was more prevalent in clinical isolates (67.8% of E. faecalis and 70.4% of E. faecium). E. faecalis and E. faecium isolated from water had different antibiotic resistance patterns compared to those isolated from clinical samples. Linezolid resistance was not observed in any isolates tested and vancomycin resistance was observed only in clinical isolates. Resistance to other antibiotics (tetracycline, gentamicin, ciprofloxacin and ampicillin) was detected in both clinical and water isolates. Clinical isolates were more resistant to all the antibiotics tested compared to water isolates. Multi-drug resistance was more prevalent in clinical isolates (71.2% of E. faecalis and 70.3% of E. faecium) compared to water isolates (only 5.7% E. faecium). tet L and tet M genes were predominantly identified in tetracycline-resistant isolates. All water and clinical isolates resistant to ciprofloxacin and ampicillin contained mutations in the gyrA, parC and pbp5 genes. A significant correlation was found between the presence of virulence determinants and antibiotic resistance in all the isolates tested in this study (p<0.05). The presence of antibiotic resistant enterococci, together with associated virulence traits, in surface recreational water could be a public health risk.     

Enterococci resistant to glycopeptides

Enterococci are responsible for various community- and hospital-acquired infections. Glycopeptides (vancomycin and teicoplanin) are active against these microorganisms by inhibiting cell wall synthesis through binding to cell wall precursors. Enterococcus faecium has developed multidrug resistance, including resistance to glycopeptides. Resistance to glycopeptides is due to the acquisition of an operon of genes cooperating to synthesize precursors devoid of affinity for the glycopeptides. Outbreaks were recently reported in hospital settings. These outbreaks were due to E. faecium isolates belonging to an hospital-adapted clonal complex (CC17) characterized by high level resistance to ampicillin and fluoroquinolones and frequently containing virulence factors. Outbreaks may be controlled by appropriate measures and new antibiotics are available in therapy. However, spreading of clonal strains adapted to hospitals require close surveillance.     

Antibiotic resistance and virulence factors among clinical and food enterococci isolated in Slovakia

The resistance to antibiotics and the distribution of virulence factors in enterococci isolated from traditional Slovak sheep cheese bryndza was compared with strains from human infections. The occurrence of 4 enterococcal species was observed in 117 bryndza-cheese isolates. The majority of strains were identified as E. faecium (76 %) and E. faecalis (23 %). Several strains of E. durans and 1 strain of E. hirae were also present. More than 90 % of strains isolated from 109 clinical enterococci were E. faecalis, the rest belonged to E. faecium. The resistance to 6 antimicrobial substances (ampicillin, ciprofloxacin, higher concentration of gentamicin, nitrofurantoin, tetracycline and vancomycin) was tested in clinical and food enterococci. A higher level of resistance was found in clinical than in food strains and E. faecium had a higher resistance than E. faecalis; no resistance to vancomycin was detected. The occurrence of 3 virulence-associated genes, cylA (coding for hemolysin), gelE (coding for gelatinase) and esp (coding for surface protein) was monitored. Differences were found in the distribution of cylA gene between clinical and bryndza-cheese E. faecalis strains; in contrast to clinical strains (45 %), cylA gene was detected in 22 % of food isolates. The distribution of 2 other virulence factors, gelE and esp, was not significantly different in the two groups of E. faecalis strains. cylA and gelE genes were not detected in E. faecium but more than 70 % of clinical E. faecium were positive for esp, even thought none of the 79 E. faecium cheese isolates contained this gene.     

Intramolecular transposition and inversion in plasmid R6K

Selection was made in Escherichia coli K-12 recA hosts carrying plasmid R6K for ampicillin hyperresistance. Twenty-two selected strains were found to carry mutant plasmids, which, from electron microscopy and restriction enzyme analysis, were concluded to arise by a duplication of transposon Tn2660, which confers ampicillin resistance, in all cases the duplicate transposon being in an inverted orientation with respect to the resident Tn2660. A mutant of R6K, pSJC301, which was temperature sensitive for ampicillin resistance was produced by in vitro hydroxylamine treatment of R6K deoxyribonucleic acid. A plasmid hybrid, pSJC102, was constructed by cloning the EcoRI R6K fragment carrying the wild-type beta-lactamase gene into the EcoRI site of ColE1. pSJC301 and pSJC102 were transformed into the same recA host strain to form a stable biplasmid strain. Ampicillin-hyperresistant mutants were selected from this strain and screened for plasmids with a duplication of transposon Tn2660, which occurred with equal frequency in either pSJC301 or pSJC102; of 12 characterized, all were inverse repeats of the resident transposon. All six Tn2660 inserts into pSJC301 determined temperature-sensitive ampicillin resistance, and all six inserts into pSJC102 determined wild-type ampicillin resistance, from which it was inferred that transposition of a duplicate Tn2660 occurs predominantly as an intramolecular event, at least in the multicopy R6K plasmid. In all 28 insertion mutants of R6K, there was an inversion of the deoxyribonucleic acid between the two transposons, whereas in only one of six insertion mutants of pSJC102, inversion had occurred. These results are discussed in terms of current models of transposition.     

A two-component signal-transducing system is involved in competence and penicillin susceptibility in laboratory mutants of Streptococcus pneumoniae

Penicillin resistance in Streptococcus pneumoniae has been attributed so far to the production of penicillin-binding protein (PBP) variants with decreased affinities for β-lactam antibiotics. Cefotaxime-resistant laboratory mutants, selected after several steps on increasing concentrations of this β-lactam, become deficient in transformation as well. A DNA fragment conferring both cefotaxime resistance and transformation deficiency was isolated and cloned from the mutant C306. The cefotaxime resistance associated with this resistance determinant was not accompanied with apparent changes in PBP properties, and it mapped on the chromosome distinct from the known resistance determinants, genes encoding PBP2x, PBP1a or PBP2b. Determination of a 2265 bp DNA sequence of the resistance determinant revealed two open reading frames, claR and claH, whose deduced amino acid sequence identified the corresponding proteins as the response regulator and histidine kinase receptor, respectively (members of the two families of bacterial signal-transducing proteins). Two hydrophobic peptide regions divided the histidine kinase ClaH into two putative domains: an N-terminal extracelluiar sensor part, and an intracelluiar C-terminal domain with the conserved His-226 residue, the presumed phosphorylation site. The single point mutations responsible for cefotaxime-resistance and transformation deficiency of C306 and of another two independently isolated cefotaxime-resistant mutants were each located in the C-terminal half of ClaH. A small extracellular protein, the competence factor, is required for induction of competence. Neither C306 nor the transformants obtained with the mutated claH gene produced competence factor, and exogenous competence factor could not complement the transformation deficiency, indicating that the signal-transducing system cia is involved in early steps of competence regulation.     

Reconstruction of Escherichia coli mrcA (PBP 1a) mutants lacking multiple combinations of penicillin binding proteins

Previously, we constructed a set of mutants from which eight penicillin binding protein (PBP) genes were deleted in 192 combinations from Escherichia coli (S. A. Denome, P. K. Elf, T. A. Henderson, D. E. Nelson, and K. D. Young, J. Bacteriol. 181:3981-3993, 1999). Although these mutants were constructed correctly as determined by restriction mapping and the absence of relevant protein products, we recently discovered by PCR mapping that strains from which mrcA (PBP 1a) was deleted were also missing two neighboring genes of unknown function (yrfE and yrfF). We created a new deletion mutation in mrcA and reconstructed 63 strains lacking PBP 1a and other PBP mutant combinations. The new mrcA mutants do not exhibit mucoidy, phage resistance, temperature sensitivity, growth rate defects, or antibiotic resistance, suggesting that these phenotypes require the loss of either yrfE or yrfF alone or in combination with the absence of multiple PBPs.     

Resistance to β-Lactam Antibiotics Conferred by Point Mutations in Penicillin-Binding Proteins PBP3, PBP4 and PBP6 in Salmonella enterica

Penicillin-binding proteins (PBPs) are enzymes responsible for the polymerization of the glycan strand and the cross-linking between glycan chains as well as the target proteins for β-lactam antibiotics. Mutational alterations in PBPs can confer resistance either by reducing binding of the antibiotic to the active site or by evolving a β-lactamase activity that degrades the antibiotic. As no systematic studies have been performed to examine the potential of all PBPs present in one bacterial species to evolve increased resistance against β-lactam antibiotics, we explored the ability of fifteen different defined or putative PBPs in Salmonella enterica to acquire increased resistance against penicillin G. We could after mutagenesis and selection in presence of penicillin G isolate mutants with amino-acid substitutions in the PBPs, FtsI, DacB and DacC (corresponding to PBP3, PBP4 and PBP6) with increased resistance against β-lactam antibiotics. Our results suggest that: (i) most evolved PBPs became ‘generalists” with increased resistance against several different classes of β-lactam antibiotics, (ii) synergistic interactions between mutations conferring antibiotic resistance are common and (iii) the mechanism of resistance of these mutants could be to make the active site more accessible for water allowing hydrolysis or less binding to β-lactam antibiotics.     

Cloning, sequencing and expression in Escherichia coli of the low-affinity penicillin binding protein of Enterococcus faecalis

Abstract Low-affinity penicillin binding proteins are particular membrane proteins, in several Gram-positive bacteria, which are involved in β-lactam antibiotic resistance. The structural gene for the low-affinity penicillin binding protein 5 (PBP5) of Enterococcus faecalis was cloned and sequenced. From the sequence of the 3378 bp, a 2040 bp coding region was identified. From biochemical analysis it emerges that E. faecalis PBP5 is a type II membrane protein with an uncleaved N-terminal and is composed of 679 amino acids with a molecular weight of 74055. This protein showed 48 and 33% of identity with Enterococcus hirae PBP5 and Staphylococcus aureus PBP2a, both low-affinity PBPs involved in β-lactam resistance. Anti-PBP5 antibodies cross-reacted with a membrane protein present in other species of enterococci, but the entire gene fragment cloned hybridized only with DNAs of E. faecalis strains, thus suggesting that genes coding for low-affinity PBPs of enterococci are not stictly homologous. In this experiment digoxigenin-labelled E. faecalis DNA was used.     

Inactivation kinetics of a new target of beta-lactam antibiotics

Peptidoglycan is predominantly cross-linked by serine DD-transpeptidases in most bacterial species. The enzymes are the essential targets of β-lactam antibiotics. However, unrelated cysteine LD-transpeptidases have been recently recognized as a predominant mode of peptidoglycan cross-linking in Mycobacterium tuberculosis and as a bypass mechanism conferring resistance to all β-lactams, except carbapenems such as imipenem, in Enterococcus faecium. Investigation of the mechanism of inhibition of this new β-lactam target showed that acylation of the E. faecium enzyme (Ldt(fm)) by imipenem is irreversible. Using fluorescence kinetics, an original approach was developed to independently determine the catalytic constants for imipenem binding (k(1) = 0.061 μM(-1) min(-1)) and acylation (k(inact) = 4.5 min(-1)). The binding step was limiting at the minimal drug concentration required for bacterial growth inhibition. The Michaelis complex was committed to acylation because its dissociation was negligible. The emergence of imipenem resistance involved substitutions in Ldt(fm) that reduced the rate of formation of the non-covalent complex but only marginally affected the efficiency of the acylation step. The methods described in this study will facilitate development of new carbapenems active on extensively resistant M. tuberculosis.