Inhibitors of ß-Lactamases. New Life of ß-Lactam Antibiotics.

ß-Lactam antibiotics account for about 60% of all produced antibiotics. Due to a high activity and minimal side effects, they are the most commonly used class of antibacterial drugs for the treatment of various infectious diseases of humans and animals, including severe hospital infections. However, the emergence of bacteria resistant to ß-lactams has led to the clinical inefficiency of these antibiotics, and as a result, their use in medicine has been limited. The search for new effective ways for overcoming the resistance to ß-lactam antibiotics is an essential task. The major mechanism of bacterial resistance is the synthesis of ß-lactamases (BLs) that break the antibiotic ß-lactam ring. Here, we review specific inhibitors of serine ß-lactamases and metallo-ß-lactamases and discuss approaches for creating new inhibitors that would prolong the "life" of ß-lactams.

[Scaffold hopping computational approach for searching novel ß-lactamase inhibitors]. / Virtual'nyi skrining s ispol'zovaniem izmeneniia strukturnogo ostova ligandov dlia poiska novykh ingibitorov ß-laktamaz.

We present a novel computational ligand-based virtual screening approach with scaffold hopping capabilities for the identification of novel inhibitors of ß-lactamases which confer bacterial resistance to ß-lactam antibiotics. The structures of known ß-lactamase inhibitors were used as query ligands, and a virtual in silico screening a database of 8 million drug-like compounds was performed in order to select the ligands with similar shape and charge distribution. A set of numerical descriptors was used such as chirality, eigen spectrum of matrices of interatomic distances and connectivity together with higher order moment invariants that showed their efficiency in the field of pattern recognition but have not yet been employed in drug discovery. The developed scaffold-hopping approach was applied for the discovery of analogues of four allosteric inhibitors of serine ß-lactamases. After a virtual in silico screening, the effect of two selected ligands on the activity of TEM type ß-lactamase was studied experimentally. New non-ß-lactam inhibitors were found that showed more effective inhibition of ß-lactamases compared to query ligands.

Bacterial Enzymes and Antibiotic Resistance.

The resistance of microorganisms to antibiotics has been developing for more than 2 billion years and is widely distributed among various representatives of the microbiological world. Bacterial enzymes play a key role in the emergence of resistance. Classification of these enzymes is based on their participation in various biochemical mechanisms: modification of the enzymes that act as antibiotic targets, enzymatic modification of intracellular targets, enzymatic transformation of antibiotics, and the implementation of cellular metabolism reactions. The main mechanisms of resistance development are associated with the evolution of superfamilies of bacterial enzymes due to the variability of the genes encoding them. The collection of all antibiotic resistance genes is known as the resistome. Tens of thousands of enzymes and their mutants that implement various mechanisms of resistance form a new community that is called "the enzystome." Analysis of the structure and functional characteristics of enzymes, which are the targets for different classes of antibiotics, will allow us to develop new strategies for overcoming the resistance.

[Bacterial TEM-type serine beta-lactamases: structure and analysis of mutations]. / Bakterial'nye serinovye beta-laktamazy TEM-tipa: struktura i analiz mutatsii.

Beta-lactamases (EC 3.5.2.6) represent a superfamily containing more than 2,000 members: it includes genetically and functionally different bacterial enzymes capable to destroy the beta-lactam antibiotics. The most common are beta-lactamases of molecular class A with serine in the active center. Among them, TEM-type beta-lactamases are of particular interest from the viewpoint of studying the mechanisms of the evolution of resistance due to their broad polymorphism. To date, more than 200 sequences of TEM-type beta-lactamases have been described and more than 60 structures of different mutant forms have been presented in Protein Data Bank. We have considered the main structural features of the enzymes of this type with particular attention to the analysis of key drug resistance and the secondary mutations, their location relative to the active center and the surface of the protein globule. We have developed the BlaSIDB database (www.blasidb.org) which is an open information resource combining available data on 3D structures, amino acid sequences and nomenclature of the corresponding forms of beta-lactamases.

Novel non-ß-lactam inhibitor of ß-lactamase TEM-171 based on acylated phenoxyaniline.

The microbial resistance to antibiotics is a genuine global threat. Consequently, a search of new inhibitors remains of acute importance due to the increasing spread of multidrug resistance. Here we present a new type of non-ß-lactam ß-lactamase inhibitor PA-34 based on natural phenoxyaniline, identified using computer-assisted screening of scaffolds related to those of known low-affinity inhibitors. The compound displays reversible competitive inhibition of bacterial ß-lactamase TEM-171, with a Ki of 88 µM. Using enzyme kinetics, infra-red spectroscopy, fluorescence quenching and computer docking, we propose that the inhibitor binds at the entrance to the enzyme active site. This is a novel inhibition mechanism compared to binding covalently to the catalytic serine in the active site or non-covalently to the allosteric site. The residues involved in binding the inhibitor are conserved among molecular class A ß-lactamases. The identified compound and its proposed binding mode may have a potential for a regulation of the catalytic activity of a wide range of class A ß-lactamases. We also hypothesise that the presented route for finding non-ß-lactam compounds may be an effective and durable approach for combating bacterial antibiotic resistance.

[Investigation the role of mutations M182T and Q39K in structure of beta-lactamase TEM-72 by molecular dynamics method]. / Izuchenie roli mutatsii M182T i Q39K v strukture beta-laktamazy TEM-72 metodom molekuliarnoi dinamiki.

Synthesis of b-lactamases is one of the common mechanisms of bacterial resistance to b-lactam antibiotics including penicillins and cephalosporins. The widespread use of antibiotics results in appearance of numerous extended-spectrum b-lactamase variants or resistance to inhibitors. Mutations of 92 residues of TEM type were found. Several mutations are the key mutations that determine the extension of spectrum of substrates. However, roles of the most associated mutations, located far from active site, remain unknown. We have investigated the role of associated mutations in structure of b-lactamase TEM-72, which contain two key mutation (G238S, E240K) and two associated mutations (Q39K, M182T) by means of simulation of molecular dynamics. The key mutation lead to destabilization of the protein globule, characterized by increased mobility of amino acid residues at high temperature of modelling. Mutation M182T lead to stabilization protein, whereas mutation Q39K is destabilizing mutation. It seems that the last mutation serves for optimization of conformational mobility of b-lactamase and may influence on enzyme activity.

The Use of Atomic Force Microscopy for 3D Analysis of Nucleic Acid Hybridization on Microarrays.

Oligonucleotide microarrays are considered today to be one of the most efficient methods of gene diagnostics. The capability of atomic force microscopy (AFM) to characterize the three-dimensional morphology of single molecules on a surface allows one to use it as an effective tool for the 3D analysis of a microarray for the detection of nucleic acids. The high resolution of AFM offers ways to decrease the detection threshold of target DNA and increase the signal-to-noise ratio. In this work, we suggest an approach to the evaluation of the results of hybridization of gold nanoparticle-labeled nucleic acids on silicon microarrays based on an AFM analysis of the surface both in air and in liquid which takes into account of their three-dimensional structure. We suggest a quantitative measure of the hybridization results which is based on the fraction of the surface area occupied by the nanoparticles.

Recombinant horseradish peroxidase: production and analytical applications.

Horseradish peroxidase is a key enzyme in bio- and immunochemical analysis. New approaches in functional expression of the peroxidase gene in E. coli cells and the subsequent refolding of the resulting protein yield a recombinant enzyme that is comparable in its spectral and catalytic characteristics to the native plant peroxidase. Genetic engineering approaches allow production of recombinant peroxidase conjugates with both protein antigens and Fab antibody fragments. The present article reviews the use of recombinant horseradish peroxidase as the marker enzyme in ELISA procedures as well as in amperometric sensors based on direct electron transfer.

[Conjugates of streptavidin with gold nanoparticles for the visualization of dna single interactions on the silicon surface].

The potential of the method of scanning electron microscopy (SEM) to visualize the results of individual acts of DNA and oligonucleotides hybridization using gold nanoparticles as label was investigated. Molecule of biotin was introduced into DNA or oligonucleotide, and then it was detected in DNA duplex using a conjugate of streptavidin with gold nanoparticles. Effective imaging of DNA duplexes was possible using a conjugate prepared by covalent binding.. The detection limit of the model oligonucleotide of 19 bases was 20 pg.

[Implementation of scanning probe microscopy for the solution of molecular diagnostics tasks].

We present new approaches to improve the efficiency of DNA by scanning probe microscopy using a highly specific hybridization on affine surfaces and nanostructures of gold as a labels. Scanning probe microscopy allows to register of individual acts of hybridization by the detection of gold labels on the surface affinity followed by automatic calculation of the total.

Multiplex PCR for joint amplification of carbapenemase genes of molecular classes A, B, and D.

Here we present a method for joint amplification of genes of carbapenemases of molecular classes A, B, and D for hybridization analysis on DNA microarrays. Using new-generation DNA polymerase KAPA2G Fast (KAPA Biosystems, USA) together with optimization of the conditions for the multiplex PCR with 20 primer pairs allowed us to carry out joint amplification of full-length genes of seven different types of carbapenemases (KPC, VIM, IMP, SPM, SIM, GIM, and OXA) with simultaneous inclusion of biotin as a label. Yield of the labeled PCR product sufficient for further analysis by microarray hybridization was achieved 40 min after the start of the reaction. This reduced the total duration of DNA identification techniques, including sample preparation stage, to 4 h. The method for gene identification by DNA microarrays with the improved stage of amplification of specific carbapenemase genes was tested with clinical strains of gram-negative bacteria Pseudomonas aeruginosa, Acinetobacter baumannii, and Enterobacteriaceae spp. with different sensitivity towards carbapenems according to phenotyping tests. All clinical strains of A. baumannii resistant to carbapenems were found to have genes of OXA-type carbapenemases (subtypes OXA-51, OXA-23, OXA-40, and OXA-58), and clinical strains of P. aeruginosa resistant to carbapenems were found to possess the gene of VIM-type metallo-beta-lactamase (subtype VIM-2). When testing clinical strains sensitive to carbapenems, carbapenemase genes were not detected. Thus, the method of identifying carbapenemase genes on DNA microarrays is characterized by high accuracy and can be used in clinical microbiology laboratories for express diagnostics of resistance to carbapenems.

Multiparametric determination of genes and their point mutations for identification of beta-lactamases.

More than half of all currently used antibiotics belong to the beta-lactam group, but their clinical effectiveness is severely limited by antibiotic resistance of microorganisms that are the causative agents of infectious diseases. Several mechanisms for the resistance of Enterobacteriaceae have been established, but the main one is the enzymatic hydrolysis of the antibiotic by specific enzymes called beta-lactamases. Beta-lactamases represent a large group of genetically and functionally different enzymes of which extended-spectrum beta-lactamases (ESBLs) pose the greatest threat. Due to the plasmid localization of the encoded genes, the distribution of these enzymes among the pathogens increases every year. Among ESBLs the most widespread and clinically relevant are class A ESBLs of TEM, SHV, and CTX-M types. TEM and SHV type ESBLs are derived from penicillinases TEM-1, TEM-2, and SHV-1 and are characterized by several single amino acid substitutions. The extended spectrum of substrate specificity for CTX-M beta-lactamases is also associated with the emergence of single mutations in the coding genes. The present review describes various molecular-biological methods used to identify determinants of antibiotic resistance. Particular attention is given to the method of hybridization analysis on microarrays, which allows simultaneous multiparametric determination of many genes and point mutations in them. A separate chapter deals with the use of hybridization analysis on microarrays for genotyping of the major clinically significant ESBLs. Specificity of mutation detection by means of hybridization analysis with different detection techniques is compared.

Characterization of antigenic properties of horseradish peroxidase with monoclonal antibodies.

Monoclonal antibodies (mcAbs) specific to alkaline isoenzymes of horseradish peroxidase were used to characterize the antigenic properties of horseradish peroxidase. The results of a competitive binding assay indicated that monoclonal antibodies can be divided into three groups directed against distinct parts of the protein. The interaction of monoclonal antibodies with native and modified horseradish peroxidase showed also three different patterns of reactivity. Antibodies from groups I and II are directed against epitopes which are conformational and formed by tertiary structure elements. Epitopes recognized by these antibodies are sensitive to heme removal or partial denaturation of peroxidase. Antibodies from group III bind specifically with epitopes consisting of primary or secondary structure elements. The antigenic determinants recognized by antibodies from group III PO(1) and 36F(9) were shown to be linear (continuous) and formed by amino acid residues 261-267 and 271-277, respectively, as determined by the peptide scanning method (PEPSCAN). The location of revealed linear antigenic determinants in the molecular structure of peroxidase is analyzed.