Characterization of β-lactamase activity using isothermal titration calorimetry

BackgroundHydrolysis of β-lactam antibiotic by β-lactamase is the most common mechanism of β-lactam resistance in clinical isolates. Timely detection and characterization of β-lactamases are therefore of utmost biomedical importance. Conventional spectrophotometric method is time-consuming and cannot provide thermodynamic information on β-lactamases.MethodsA new assay was developed for the study of β-lactamase activity in protein solutions (Metallo-β-lactamase L1) and in clinical bacterial cells, based on heat-flow changes derived from enzymatic hydrolysis of β-lactams using isothermal titration calorimetry.Results(1) The thermokinetic parameters of three antibiotics (penicillin G, cefazolin and imipenem) and the inhibition constant of an azolylthioacetamide inhibitor were determined using the calorimetric assay. The results from the calorimetric assays were consistent with the data from the spectrophotometric assay. (2) The values of heat change in the calorimetric assay using two clinical Escherichia coli strains correlated well with their antibiotic susceptibility results from the broth dilution experiment. The subtypes of β-lactamase were also determined in the calorimetric assay.ConclusionsThe ITC assay is a reliable and fast method to study β-lactamase enzyme kinetics and inhibition. It can also provide thermodynamic information on antibiotic hydrolysis, which has been taken advantage of in this work to study β-lactamase activity in two clinical Escherichia coli isolates.General significanceAs the first calorimetric study of β-lactamase activity, it may provide a new assay to assist biomedical validation of new β-lactamase inhibitors, and also has potential applications on rapid antibiotic susceptibility testing and screening β-lactamase producing bacteria.     

产AmpC酶阴沟肠杆菌的基因分析及其耐药性

探讨昆明地区阴沟肠杆菌的耐药性及与结构基因ampC和调节基因ampD的相关性。通过K-B法检测阴沟肠杆菌的药敏情况,头孢西丁三维试验检测AmpC酶,PCR法扩增ampC和ampD基因。结果显示74株阴沟肠杆菌经头孢西丁三维试验检测,产AmpC酶的有17株,检出率为22.3%,而且产酶菌株抗生素敏感率低于非产酶菌株。ampC基因扩增阳性率为89.2%(66/74);64株ampD基因阳性率为86.5%(64/74)。实验证实昆明地区产酶阴沟肠杆菌耐药状况严重,与结构基因ampC和调节基因ampD密切相关。     

大肠埃希菌高产AmpC酶的检测及耐药性分析

目的了解深圳市人民医院高产AmpC酶大肠埃希菌的存在现状及其耐药性。方法采用Tris-ED-TA纸片裂菌法检测148株大肠埃希菌的AmpC酶。用琼脂稀释法测定产酶株对11种抗生素的最低抑菌浓度（MIC）。结果 148株大肠埃希菌中6株检出AmpC酶,检出率为4.1%。所有产AmpC酶大肠埃希菌对亚胺培南敏感,MIC为0.12～0.25μg/ml;对头孢吡肟的MIC值也较低,为0.5～32.0μg/ml,仅1株耐头孢吡肟。所有产AmpC酶大肠埃希菌对头孢西丁耐药,MIC为32～128μg/ml;对氨苄西林/舒巴坦、阿莫西林/克拉维酸和哌拉西林/他唑巴坦等加酶抑制剂复合物耐药性较强。结论深圳市人民医院大肠埃希菌高产AmpC酶检出率为4.1%。产酶株对多种抗生素耐药性较高。     

Pollutant-induced modulation in conformation and β-lactamase activity of human serum albumin

Structural changes in human serum albumin (HSA) induced by the pollutants 1-naphthol, 2-naphthol and 8-quinolinol were analyzed by circular dichroism, fluorescence spectroscopy and dynamic light scattering. The alteration in protein conformational stability was determined by helical content induction (from 55 to 75%) upon protein-pollutant interactions. Domain plasticity is responsible for the temperature-mediated unfolding of HSA. These findings were compared to HSA-hydrolase activity. We found that though HSA is a monomeric protein, it shows heterotropic allostericity for β-lactamase activity in the presence of pollutants, which act as K- and V-type non-essential activators. Pollutants cause conformational changes and catalytic modifications of the protein (increase in β-lactamase activity from 100 to 200%). HSA-pollutant interactions mediate other protein-ligand interactions, such as HSA-nitrocefin. Therefore, this protein can exist in different conformations with different catalytic properties depending on activator binding. This is the first report to demonstrate the catalytic allostericity of HSA through a mechanistic approach. We also show a correlation with non-microbial drug resistance as HSA is capable of self-hydrolysis of β-lactam drugs, which is further potentiated by pollutants due to conformational changes in HSA.     

The evolution of cefotaximase activity in the TEM β-lactamase

The development of a molecular-level understanding of drug resistance through β-lactamase is critical not only in designing newer-generation antibacterial agents but also in providing insight into the evolutionary mechanisms of enzymes in general. In the present study, we have evaluated the effect of four drug resistance mutations (A42G, E104K, G238S, and M182T) on the cefotaximase activity of the TEM-1 β-lactamase. Using computational methods, including docking and molecular mechanics calculations, we have been able to correctly identify the relative order of catalytic activities associated with these four single point mutants. Further analyses suggest that the changes in catalytic efficiency for mutant enzymes are correlated to structural changes within the binding site. Based on the energetic and structural analyses of the wild-type and mutant enzymes, structural rearrangement is suggested as a mechanism of evolution of drug resistance through TEM β-lactamase. The present study not only provides molecular-level insight into the effect of four drug resistance mutations on the structure and function of the TEM β-lactamase but also establishes a foundation for a future molecular-level analysis of complete evolutionary trajectory for this class of enzymes.     

2010年广州地区淋球菌耐药监测结果分析

目的了解广州地区淋球菌对抗生素耐药性的变化及PPNG和TRNG的流行趋势。方法用琼脂稀释法测定头孢曲松、大观霉素、环丙沙星、阿奇霉素和四环素的最低抑菌浓度（MIC）;用纸片碘量法检测β-内酰胺酶。结果83株淋球菌检出PPNG24株（28．9％）、TRNG50株（60．2％）、环丙沙星耐药率高达98．8％,高度耐药株（MIC≥16mg／L）43株（51．8％）,而76株淋球菌中阿奇霉素耐药株11株（14．5％）,均未出现对头孢曲松、大观霉素耐药的菌株,抗菌活性强。结论合理规范使用抗生素及动态监测淋球菌耐药性变迁是临床减少淋球菌耐药菌株出现的有效办法。     

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.     

外科手术切口感染大肠埃希菌的耐药性分析

目的分析外科手术切口中大肠埃希菌的感染率及耐药性,为临床合理用药提供科学依据。方法对2009年6月至2010年9月外科患者手术切口标本中分离的大肠埃希菌耐药情况进行分析,并对产超广谱β-内酰胺酶（ESBLs）菌株进行表型确证试验。结果 140株大肠埃希菌中,产ESBLs菌株的检出率为42.14%;产ESBLs菌株对一～四代头孢菌素、广谱青霉素、氟哇诺酮类及氨基糖苷类抗菌药物具有较高的耐药率;非产ESBLs菌株对青霉素类以外的抗菌药物具有较高的敏感率;产ESBLs菌株对大多数抗菌药物的耐药率明显高于非产ESBLs菌株（P〈0.05）。结论外科手术切口术后大肠埃希菌的感染较严重,且产ESBLs菌株多药耐药明显,临床应加强监测与控制。     

Diazabicyclooctanes (DBOs): a potent new class of non-β-lactam β-lactamase inhibitors

The β-lactams have been among the most successful classes of antibacterial agents for the past half century. However, a disturbing increase in resistance to β-lactams has been noted among Gram-negative bacteria, which is attributable to β-lactamase enzymes not within the spectrum of currently marketed β-lactams or β-lactam/β-lactamase inhibitor combinations. Diazabicyclooctanes (DBOs) were first investigated as β-lactam mimics in the mid-1990s by chemists at Hoechst Marion Roussel (now part of Sanofi-Aventis) and proved to be a rich source of β-lactamase inhibitors (BLI). Two members of this novel series of highly potent, broad spectrum BLIs are now in clinical development and their properties are reviewed here.     

Secretion of active β-lactamase to the medium mediated by the Escherichia coli haemolysin transport pathway

An in frame gene fusion containing the coding region for mature β-lactamase and the 3′-end of hylA encoding the haemolysin secretion signal, was constructed under the control of a lac promoter. The resulting 53 kDa hybrid protein was specifically secreted to the external medium in the presence of the haemolysin translocator proteins, HlyB and HlyD. The specific activity of the β-lactamase portion of the secreted protein (measured by the hydrolysis of penicillin G), approximately 1 U/μg protein, was close to that of authentic, purified TEM-β-lactamase. This is an important example of a hybrid protein that is enzymatically active, and secreted via the haemolysin pathway. Previous studies have indicated that haemolysin is secreted directly into the medium, bypassing the periplasm, to which β-lactamase is normally targeted. This study indicated, therefore, that normal folding of an active β-lactamase, can occur, at least when fused to the HlyA C-terminus, without the necessity of entering the periplasm. Despite the secretion of approximately 5 μg/ml levels of the active β-lactamase fusion into the medium, there was maximally only a 50% detectable increase in the LD₅₀ for resistance to ampicillin at the individual cell level. This result suggests that, normally, resistance to ampicillin requires a high concentration of the enzyme close to killing targets, i.e. in the periplasm, in order to achieve significant levels of protection.     

The study of the role of mutations M182T and Q39K in the TEM-72 β-lactamase structure by the molecular dynamics method

Synthesis of β-lactamases is one of the common mechanisms of bacterial resistance to β-lactam antibiotics such as penicillins and cephalosporins. The widespread use of antibiotics resulted in appearance of numerous extended-spectrum β-lactamase variants or inhibitor-resistant β-lactamases. In TEM type β-lactamases mutations of 92 residues have been described. Several mutations are functionally important and they determine the extended substrate specificity. However, roles of the most so-called associated mutations, located far from the active site, remain unknown. We have investigated the role of associated mutations in structure of β-lactamase TEM-72, which contains two key mutations (G238S, E240K) and two associated mutations (Q39K, M182T) by means of molecular dynamics simulation. Appearance of the key mutations (in 238 and 240 positions) caused destabilization of the protein globule, characterized by increased mobility of amino acid residues. Associated mutations (Q39K, M182T) exhibited opposite effect on the protein structure. The mutation M182T stabilized, while the mutation Q39K destabilized the protein. It appears that the latter mutation promoted optimization of the conformational mobility of β-lactamase and may influence the enzyme activity.     

摩根摩根菌β-内酰胺酶检测及耐药性分析

目的了解摩根摩根菌临床分离株产超广谱β-内酰胺酶（ESBLs）、头孢菌素酶（AmpC）、金属酶（MBLs）、碳青霉烯酶（KPC）情况,并分析其对17种常见抗菌药物的耐药性。方法 ESBLs和AmpC及MBLs采用三维试验检测,碳青霉烯酶采用改良Hodge试验进行检测,并以K-B法测定17种常见抗菌药物的耐药性。结果 102株摩根摩根菌单产ESBLs 15株,检出率为14.71%;单产AmpC 8株,检出率为7.84%;单产金属β-内酰胺酶（MBLs）3株,检出率为2.94%;所有菌株中未检出碳青霉烯酶（KPC）;同产ESBLs及AmpC 6株,检出率为5.88%;未发现其他双产酶菌株。摩根摩根菌非产酶分离株对17种抗生素的耐药率均低于50.0%;摩根摩根菌产酶分离株对亚胺培南、美罗培南培南的耐药率低于15.0%,与非产酶菌株相比,差异无统计学意义（P〉0.05）;对其余抗生素的耐药率均明显高于非产酶菌株（P〈0.05）。同产ESBLs＋AmpC与耐亚胺培南摩根摩根菌分离株呈多重耐药。结论我院摩根摩根菌分离株产生多种β-内酰胺酶,且对常用抗生素耐药性比较严重,建议临床医师合理使用抗生素,以免耐药菌株的产生。     

β-Lactamase Formation and Resistance of Proteus morganii to Various Penicillins and Cephalosporins

Ten strains of Proteus morganii were selected and the production of β-lactamase was studied. The cellular level of β-lactamase from P. morganii was regulated by the concentration of the inducer in the growth media, and the enzyme activity appeared within 10 min while its highest value was obtained 2 hr after the addition of benzylpenicillin as the inducer. The resistance level to cephaloridine was generally related to the amount of β-lactamase activity among the ten strains of P. morganii, but no relation was found between the ampicillin susceptibilities and the amounts of β-lactamase in their cell-free preparations. The maximum rate of hydrolysis of cephalosporin C and several other derivatives of 7-aminocephalosporanic acid by a crude enzyme was five times higher than that of benzylpenicillin. Semisynthetic penicillins were resistant to hydrolysis and exhibited competitive inhibition. Among the semisynthetic penicillins, dicloxacillin and carbenicillin were powerful competitive inhibitors of the β-lactamase from P. morganii.     

In vitro recombination of non-homologous genes can result in gene fusions that confer a switching phenotype to cells

Regulation of protein activity is central to the complexity of life. The ability to regulate protein activity through exogenously added molecules has biotechnological/biomedical applications and offers tools for basic science. Such regulation can be achieved by establishing a means to modulate the specific activity of the protein (i.e. allostery). An alternative strategy for intracellular regulation of protein activity is to control the amount of protein through effects on its production, accumulation, and degradation. We have previously demonstrated that the non-homologous recombination of the genes encoding maltose binding protein (MBP) and TEM1 β-lactamase (BLA) can result in fusion proteins in which β-lactamase enzyme activity is allosterically regulated by maltose. Here, through use of a two-tiered genetic selection scheme, we demonstrate that such recombination can result in genes that confer maltose-dependent resistance to β-lactam even though they do not encode allosteric enzymes. These 'phenotypic switch' genes encode fusion proteins whose accumulation is a result of a specific interaction with maltose. Phenotypic switches represent an important class of proteins for basic science and biotechnological applications in vivo.     

An active β-lactamase is a part of an orchestrated cell wall stress resistance network of Bacillus subtilis and related rhizosphere species

A hallmark of the Gram-positive bacteria, such as the soil-dwelling bacterium Bacillus subtilis, is their cell wall. Here, we report that d -leucine and flavomycin, biofilm inhibitors targeting the cell wall, activate the β-lactamase PenP. This β-lactamase contributes to ampicillin resistance in B. subtilis under all conditions tested. In contrast, both Spo0A, a master regulator of nutritional stress, and the general cell wall stress response, differentially contribute to β-lactam resistance under different conditions. To test whether β-lactam resistance and β-lactamase genes are widespread in other Bacilli, we isolated Bacillus species from undisturbed soils, and found that their genomes can encode up to five β-lactamases with differentiated activity spectra. Surprisingly, the activity of environmental β-lactamases and PenP, as well as the general stress response, resulted in a similarly reduced lag phase of the culture in the presence of β-lactam antibiotics, with little or no impact on the logarithmic growth rate. The length of the lag phase may determine the outcome of the competition between β-lactams and β-lactamases producers. Overall, our work suggests that antibiotic resistance genes in B. subtilis and related species are ancient and widespread, and could be selected by interspecies competition in undisturbed soils.     

Identification of a β-lactamase inhibitory protein variant that is a potent inhibitor of Staphylococcus PC1 β-lactamase

β-Lactamase inhibitory protein (BLIP) binds and inhibits a diverse collection of class A β-lactamases. Widespread resistance to β-lactam antibiotics currently limits the treatment strategies for Staphylococcus infections. The goals of this study were to determine the binding affinity of BLIP for Staphylococcus aureus PC1 β-lactamase and to identify mutants that alter binding affinity. The BLIP inhibition constant (K_i) for PC1 β-lactamase was measured at 350 nM, and isothermal titration calorimetry experiments indicated a binding constant (K_d) of 380 nM. Twenty-three residue positions in BLIP that contact β-lactamase were randomized, and phage display was used to sort the libraries for tight binders to immobilized PC1 β-lactamase. The BLIP_K74G mutant was the dominant clone selected, and it was found to inhibit the PC1 β-lactamase with a K_i of 42 nM, while calorimetry indicated a K_d of 26 nM. Molecular modeling studies suggested that BLIP binds weakly to the PC1 β-lactamase due to the presence of alanine at position 104 of PC1. This position is occupied by glutamate in the TEM-1 enzyme, where it forms a salt bridge with the BLIP residue Lys74 that is important for the stability of the complex. This hypothesis was confirmed by showing that the PC1_A104E enzyme binds BLIP with 15-fold greater affinity than wild-type PC1 β-lactamase. Kinetic measurements indicated similar association rates for all complexes with variation in affinity due to altered dissociation rate constants, suggesting that changes in short-range interactions are responsible for the altered binding properties of the mutants.     

Novel peptide inhibiting both TEM-1 β-lactamase and penicillin-binding proteins

9G4H9, a catalytic antibody displaying β-lactamase-like activity, has been developed by the anti-idiotypic approach using β-lactamase as the first antigen. Thus 9G4H9 represents the 'internal image' of β-lactamase. We selected a cyclic peptide anchored to a bacteriophage M13 library using 9G4H9 as the target. Pep90 is a cyclic heptapeptide enclosed between two cysteine residues. We showed that Pep90 could inhibit both TEM-1 β-lactamase (K(i) = 333 μm) and several penicillin-binding proteins (IC?? values ranging from 6-62 μm). We determined that the tryptophan residue of Pep90 is of crucial importance for its inhibitory activity. Using Pep90 as a scaffold, we generated a new class of peptidomimetics that retained inhibitory activity towards TEM-1 β-lactamase.     

Anaerobic bacteria and antibiotics: What kind of unexpected resistance could I find in my laboratory tomorrow?

The purpose of this article is to set out some important considerations on the main emerging antibiotic resistance patterns among anaerobic bacteria. The first point concerns the Bacteroides fragilis group and its resistance to the combination of β-lactam+β-lactamase inhibitor. When there is overproduction of cephalosporinase, it results in increased resistance to the β-lactams while maintaining susceptibility to β-lactams/β-lactamase inhibitor combinations. However, if another resistance mechanism is added, such as a loss of porin, resistances to β-lactam+β-lactamase inhibitor combinations may occur. The second point is resistance to metronidazole occurring due to nim genes. PCR detection of nim genes alone is not sufficient for predicting resistance to metronidazole; actual MIC determinations are required. Therefore, it can be assumed that other resistance mechanisms can also be involved. Although metronidazole resistance remains rare for the B. fragilis group, it has nevertheless been detected worldwide and also been observed spreading to other species. In some cases where there is only a decreased susceptibility, clinical failures may occur. The last point concerns resistance of Clostridium species to glycopeptides and lipopeptides. Low levels of resistance have been detected with these antibiotics. Van genes have been detected not only in clostridia but also in other species. In conclusion, antibiotic resistance involves different mechanisms and affects many anaerobic species and is spreading worldwide. This demonstrates the need to continue with antibiotic resistance testing and surveys in anaerobic bacteria.     

同时产多种基因型ESBLs肺炎克雷伯菌的分析

目的分析汕头大学医学院第一附属医院临床分离的肺炎克雷伯菌同时产多种基因型ESBLs的情况。方法采用PCR扩增对产ESBLs的肺炎克雷伯菌初步分型,然后PCR扩增阳性产物克隆测序分析,脉冲场凝胶电泳（PFGE）分型;用浓度梯度法检测10种抗菌药物对同时产多种基因型ESBLs的肺炎克雷伯菌的最低抑菌浓度（MIC）。结果83株产ESBLs的肺炎克雷伯菌中,发现9株同时产TEM、SHV和CTX-M型,测序结果为CTX-M-3、TEM-1及多种SHV型（SHV12及SHV28）。将这9株细菌作PFGE分析,结果共被分成7个型。药敏结果表明,9株菌除对亚胺培南敏感外,对氨曲南、头孢曲松、头孢噻肟、头孢他啶、丁胺卡那和四环素均高度耐药,对哌拉西林／三唑巴坦、头孢吡肟、环丙沙星极少菌株敏感。结论发现CTX—M-3超广谱-及多种SHV型超广谱-和TEM-1广谱β-内酰胺酶基因同时存在该院临床分离的肺炎克雷伯菌中,耐药十分严重,应引起重视。     

Evolution of antibiotic resistance: several different amino acid substitutions in an active site loop alter the substrate profile of β-lactamase

In order to understand how TEM-1 β-lactamase substrate specificity can be altered by mutation, amino acid residues 161 through to 170 were randomly mutagenized to sample all possible amino acid substitutions. The 161–170 region includes a portion of an omega loop structure, which is involved in the formation of the active-site pocket. The percentage of random sequences that provide bacterial resistance to either ampicillin or to the extended-spectrum cephalosporin ceftazidime was determined. It was found that the sequence requirements for wild-type levels of ampicillin resistance are much more stringent than the sequence requirements for ceftazidime resistance. Surprisingly, more than 50% of all amino acid substitutions in the 161-170 region result in levels of ceftazidime resistance at least three times greater than wild type. In addition, by increasing the level of the selection for ceftazidime resistance, substitutions that result in a greater than 100-fold increase in ceftazidime resistance were identified. Characterization of altered β-lactamase enzymes indicated that while their catalytic efficiency (K_cat/K_m) for ceftazidime hydrolysis is higher, the enzymes are poorly expressed relative to wild-type TEM-1 β-lactamase.