# | Rank | Similarity | Title + Abs. | Year | PMID |
|---|---|---|---|---|---|
| 0 | 1 | 2 | 3 | 4 | 5 |
| 9926 | 0 | 1.0000 | beta-Lactamases of gram-negative bacteria: new challenges for new drugs. The major emphasis in new drug design within the beta-lactam family has been on compounds less susceptible to hydrolysis by beta-lactamases and on combinations containing an enzyme-labile drug plus a beta-lactamase inhibitor. The introduction of such new compounds into clinical use has been followed by the discovery of novel mechanisms of resistance among gram-negative bacteria. These include the appearance of new enzymes, many of which are derivatives of older beta-lactamases. In addition, genes for certain broad-spectrum enzymes previously restricted to chromosomal sites have moved onto plasmids. There is now a greater appreciation of how alterations in enzyme expression--either alone or in concert with changes in drug permeation--can also lead to resistance. Clearly, recent events in the development of new beta-lactam agents have led to a new phase in the understanding of beta-lactam resistance. | 1992 | 1600011 |
| 4835 | 1 | 0.9999 | Genetic and biochemical basis of resistance of Enterobacteriaceae to beta-lactam antibiotics. Resistance to beta-lactam drugs is usually determined by genes mediating the production of beta-lactamases. These genes can be located on resistance plasmids or on the chromosome. Resistance to drugs which have been available for many years is mostly transposable. Although the origin of these genes is not known, it is possible to draw a hypothetical flow diagram of the evolution of resistance genes in general. The mechanism of resistance although mediated in Gram-negative bacteria mostly by beta-lactamases cannot be simply described as the hydrolytic function of the enzyme. It is a complex interaction involving the affinity of the drug for the target and the lactamase, the amount of drug in the periplasmic space, the amount of enzyme and the number of lethal target sites. Usually one of these factors is predominant. | 1986 | 3491818 |
| 4429 | 2 | 0.9999 | General mechanisms of resistance to antibiotics. Resistance to antimicrobial agents may result from intrinsic properties of organisms, through mutation and through plasmid- and transposon-specified genes. beta-Lactam resistance is most frequently associated with one or more chromosomal- or plasmid-specified beta-lactamases. Recently, mutations modifying penicillin-binding proteins have been detected with increased frequency as a cause of beta-lactam resistance. Mixed mechanisms, reduced permeability and tolerance are other causes of resistance. Aminoglycoside resistance always involves some modification of drug uptake, most often due to a variety of enzymes modifying these compounds. Reduced uptake is a primary cause of resistance in anaerobic bacteria and bacteria growing anaerobically, some strains of Pseudomonas aeruginosa, and mutants that arise during antimicrobial therapy and are defective in energy-generation systems. Resistance to other antimicrobial agents is presented in tabular form. | 1988 | 3062000 |
| 4253 | 3 | 0.9998 | Molecular mechanisms of polymyxin resistance and detection of mcr genes. Antibiotic resistance is an ever-increasing global problem. Major commercial antibiotics often fail to fight common bacteria, and some pathogens have become multi-resistant. Polymyxins are potent bactericidal antibiotics against gram-negative bacteria. Known resistance to polymyxin includes intrinsic, mutational and adaptive mechanisms, with the recently described horizontally acquired resistance mechanisms. In this review, we present several strategies for bacteria to develop enhanced resistance to polymyxins, focusing on changes in the outer membrane, efflux and other resistance determinants. Better understanding of the genes involved in polymyxin resistance may pave the way for the development of new and effective antimicrobial agents. We also report novel in silico tested primers for PCR assay that may be able distinguish colistin-resistant isolates carrying the plasmid-encoded mcr genes and will assist in combating the spread of colistin resistance in bacteria. | 2019 | 30439931 |
| 4832 | 4 | 0.9998 | Antibiotic resistance of Pseudomonas species. Pseudomonas species are highly versatile organisms with genetic and physiologic capabilities that allow them to flourish in environments hostile to most pathogenic bacteria. Within the lung of the patient with cystic fibrosis, exposed to a number of antimicrobial agents, highly resistant clones of Pseudomonas are selected. These may have acquired plasmid-mediated genes encoding a variety of beta-lactamases or aminoglycoside modifying enzymes. Frequently these resistance determinants are on transposable elements, facilitating their dissemination among the population of bacteria. Mutations in chromosomal genes can also occur, resulting in constitutive expression of normally repressed enzymes, such as the chromosomal cephalosporinase of Pseudomonas aeruginosa or Pseudomonas cepacia. These enzymes may confer resistance to the expanded-spectrum beta-lactam drugs. Decreased cellular permeability to the beta-lactams and the aminoglycosides also results in clinically significant antibiotic resistance. The development of new drugs with anti-Pseudomonas activity, beta-lactam agents and the quinolones, has improved the potential for effective chemotherapy but has not surpassed the potential of the organisms to develop resistance. | 1986 | 3701534 |
| 4836 | 5 | 0.9998 | Genes and spectrum: the theoretical limits. Antibiotic resistance can result either from mutations within a chromosomal gene or from mobile genes imported from outside. In the last 15 years, some of these mobile genes have shown a propensity to adapt to successive antibiotic challenges, the most versatile being the class A beta-lactamases. The TEM and SHV beta-lactamase nuclei, usually after one initial critical mutation, allow a series of successive mutations that increase the spectrum to hydrolyze most cephalosporins. The class C beta-lactamases also show some versatility; while it migrates from the chromosome, subtle changes can occur in the gene to broaden the spectrum. Trimethoprim resistance has shown less adaptability in gram-negative bacteria, but in gram-positive organisms the plasmid has captured the chromosomal dihydrofolate reductase of Staphylococcus epidermidis, and a minimal number of changes have occurred that decrease the binding of trimethroprim. Other resistance mechanisms appear less adaptable, relying rather on the importation of new genes to cope with new challenges. | 1998 | 9710668 |
| 9899 | 6 | 0.9998 | Evolution of extended-spectrum beta-lactamases by mutation. Antimicrobial resistance genes in pathogenic bacteria belong to the most rapidly evolving DNA sequences, which results in an enormous structural diversity of resistance effectors. Structural modifications of resistance genes by mutation and recombination, together with a multitude of events that stimulate their mobility and expression, allow microorganisms to survive in environments saturated with antimicrobial agents of various types and generations. Genes coding for beta-lactamases in Gram-negative bacteria are a fascinating example of this multifocal and multidirectional evolution, with the extended-spectrum beta-lactamases (ESBLs) being one of the most spectacular 'achievements'. Some of the ESBLs known today are 'ready-to-use' enzymes in their natural producers but these are often of low pathogenic potential, or none at all. The problem appears upon mobilisation of a gene encoding such an ESBL, and its acquisition and sufficient expression by a more virulent organism. Many ESBLs are generated by mutations in genes coding for broad-spectrum enzymes, which have been mobile since at least the 1960s and which have disseminated very widely in populations of pathogenic bacteria. Strong selection pressure exerted by antimicrobial use, especially with newer-generation beta-lactam antibiotics, efficiently promotes these two modes of ESBL emergence and subsequent spread. It also stimulates further evolution of ESBLs by accumulation of other mutations with an astonishing variety of effects on beta-lactamase structure and activity. Remarkably, more than 300 natural ESBL variants have been identified since the mid-1980s but in-vitro studies suggest that ESBL evolution has certainly not come to an end; they may also help in predicting future developments. The aim of this review is to briefly overview the role of various mutations in ESBL evolution. | 2008 | 18154525 |
| 4254 | 7 | 0.9998 | The forgotten Gram-negative bacilli: what genetic determinants are telling us about the spread of antibiotic resistance. Gram-negative bacilli have become increasingly resistant to antibiotics over the past 2 decades due to selective pressure from the extensive use of antibiotics in the hospital and community. In addition, these bacteria have made optimum use of their innate genetic capabilities to extensively mutate structural and regulatory genes of antibiotic resistance factors, broadening their ability to modify or otherwise inactivate antibiotics in the cell. The great genetic plasticity of bacteria have permitted the transfer of resistance genes on plasmids and integrons between bacterial species allowing an unprecedented dissemination of genes leading to broad-spectrum resistance. As a result, many Gram-negative bacilli possess a complicated set of genes encoding efflux pumps, alterations in outer membrane lipopolysaccharides, regulation of porins and drug inactivating enzymes such as beta-lactamases, that diminish the clinical utility of today's antibiotics. The cross-species mobility of these resistance genes indicates that multidrug resistance will only increase in the future, impacting the efficacy of existing antimicrobials. This trend toward greater resistance comes at a time when very few new antibiotics have been identified capable of controlling such multi-antibiotic resistant pathogens. The continued dissemination of these resistance genes underscores the need for new classes of antibiotics that do not possess the liability of cross-resistance to existing classes of drugs and thereby having diminished potency against Gram-negative bacilli. | 2006 | 16359640 |
| 4248 | 8 | 0.9998 | Phage Display Technique: A Novel Medicinal Approach to Overcome An tibiotic Resistance by Using Peptide-Based Inhibitors Against β-Lactamases. The emergence of antibiotic resistance in bacteria is a serious threat with enormous social and economic implications. The distribution of resistance genes/markers through horizontal gene transfer leads to the dissemination of resistant strains in different parts of the world. The resistant bacteria acquire the ability to overcome resistance by different modes amongst which the expression of β-lactamases is a major factor. The β-lactamase enzymes cleave the amide bond of the β-lactam antibiotics, which constitute about one-third of the antibiotics used all over the world. In a quest to control the spread of resistant bacteria, advanced generations of antibiotics are used either alone or in combination with inhibitors. However, these antibiotics and inhibitors also contain β-lactam ring in their structure and hence are prone to be hydrolyzed by β-lactamase enzymes in the near future. Thus, the severity of the problem is manifested due to the paucity of novel non-β-lactam core containing antibiotics in the drug development stage. One approach to overcome these shortcomings is to use peptide-based inhibitors. Here, we describe the potential use of phage display technique to screen commercially available libraries to pan against β-lactamase enzymes. The main advantage of using peptide-based inhibitors is that the bacteria will not be able to recruit pre-existing defense mechanisms and it will take a long time to evolve a new mechanism in its defense against peptide-based inhibitors. | 2017 | 27465983 |
| 9927 | 9 | 0.9998 | Induction of beta-lactamase enzymes: clinical applications for the obstetric-gynecologic patient. The emergence of bacteria resistant to antibiotics has resulted in intensive research for new and improved beta-lactam antibiotics. Many improvements in antimicrobial agents are based on a knowledge of the mechanism responsible for resistance. This has led to the development of new extended-spectrum antibiotic compounds. However, several features have been noted since the development of extended-spectrum antibiotics, such as the rapid development of bacterial resistance, the induction of beta-lactamase enzyme activity by these stable antibiotics, failure to detect induced enzyme activity and resistance in the laboratory, and beta-lactam antagonism. The resistance of bacteria to antimicrobial agents has obvious impact on the selection of appropriate therapy against infections caused by these pathogens. Gram-negative anaerobic bacteria, such as Bacteroides fragilis and Bacteroides bivius, are organisms frequently recovered from women whose initial therapy for pelvic infection failed. The transfer of antimicrobial resistance in bacteria indicates that these organisms have a system for the spread of such resistance. Therefore determination of antimicrobial susceptibilities and prompt eradication of isolates from infected patients are necessary to delay the emergence of resistant organisms. | 1987 | 3548378 |
| 9778 | 10 | 0.9998 | Antibiotic class with potent in vivo activity targeting lipopolysaccharide synthesis in Gram-negative bacteria. Here, we describe the identification of an antibiotic class acting via LpxH, a clinically unexploited target in lipopolysaccharide synthesis. The lipopolysaccharide synthesis pathway is essential in most Gram-negative bacteria and there is no analogous pathway in humans. Based on a series of phenotypic screens, we identified a hit targeting this pathway that had activity on efflux-defective strains of Escherichia coli. We recognized common structural elements between this hit and a previously published inhibitor, also with activity against efflux-deficient bacteria. With the help of X-ray structures, this information was used to design inhibitors with activity on efflux-proficient, wild-type strains. Optimization of properties such as solubility, metabolic stability and serum protein binding resulted in compounds having potent in vivo efficacy against bloodstream infections caused by the critical Gram-negative pathogens E. coli and Klebsiella pneumoniae. Other favorable properties of the series include a lack of pre-existing resistance in clinical isolates, and no loss of activity against strains expressing extended-spectrum-β-lactamase, metallo-β-lactamase, or carbapenemase-resistance genes. Further development of this class of antibiotics could make an important contribution to the ongoing struggle against antibiotic resistance. | 2024 | 38579010 |
| 4834 | 11 | 0.9998 | A retrospective view of beta-lactamases. The discovery of a penicillinase (later shown be a beta-lactamase) 50 years ago in Oxford came from the thought that the resistance of many Gram-negative bacteria to Fleming's penicillinase might be due to their production of a penicillin-destroying enzyme. The emergence of penicillinase-producing staphylococci in the early 1950s, particularly in hospitals, raised the question whether the medical value of penicillin would decline. The introduction of new semi-synthetic penicillins and cephalosporins in the 1960s began to reveal many beta-lactamases distinguishable by their different substrate profiles. In this period it was established that genes encoding beta-lactamases from Gram-negative bacilli could be carried from one organism to another on plasmids and also that penicillin inhibited a transpeptidase involved in bacterial cell wall synthesis. During the last two decades a number of these enzymes have been purified and the genes encoding them have been cloned. Much has now been learned, with the aid of powerful modern techniques, about their structures, their active sites, their relationship to penicillin-sensitive proteins in bacteria and to their likely evolution. Further knowledge may contribute to a more rational approach to chemotherapy in this area. Experience suggests that a need for new substances will continue. | 1991 | 1875234 |
| 4313 | 12 | 0.9998 | Molecular epidemiology of clinically significant antibiotic resistance genes. Antimicrobials were first introduced into medical practice a little over 60 years ago and since that time resistant strains of bacteria have arisen in response to the selective pressure of their use. This review uses the paradigm of the evolution and spread of beta-lactamases and in particular beta-lactamases active against antimicrobials used to treat Gram-negative infections. The emergence and evolution particularly of CTX-M extended-spectrum beta-lactamases (ESBLs) is described together with the molecular mechanisms responsible for both primary mutation and horizontal gene transfer. Reference is also made to other significant antibiotic resistance genes, resistance mechanisms in Gram-negative bacteria, such as carbepenamases, and plasmid-mediated fluoroquinolone resistance. The pathogen Staphylococcus aureus is reviewed in detail as an example of a highly successful Gram-positive bacterial pathogen that has acquired and developed resistance to a wide range of antimicrobials. The role of selective pressures in the environment as well as the medical use of antimicrobials together with the interplay of various genetic mechanisms for horizontal gene transfer are considered in the concluding part of this review. | 2008 | 18311156 |
| 9774 | 13 | 0.9998 | A naturally inspired antibiotic to target multidrug-resistant pathogens. Gram-negative bacteria are responsible for an increasing number of deaths caused by antibiotic-resistant infections(1,2). The bacterial natural product colistin is considered the last line of defence against a number of Gram-negative pathogens. The recent global spread of the plasmid-borne mobilized colistin-resistance gene mcr-1 (phosphoethanolamine transferase) threatens the usefulness of colistin(3). Bacteria-derived antibiotics often appear in nature as collections of similar structures that are encoded by evolutionarily related biosynthetic gene clusters. This structural diversity is, at least in part, expected to be a response to the development of natural resistance, which often mechanistically mimics clinical resistance. Here we propose that a solution to mcr-1-mediated resistance might have evolved among naturally occurring colistin congeners. Bioinformatic analysis of sequenced bacterial genomes identified a biosynthetic gene cluster that was predicted to encode a structurally divergent colistin congener. Chemical synthesis of this structure produced macolacin, which is active against Gram-negative pathogens expressing mcr-1 and intrinsically resistant pathogens with chromosomally encoded phosphoethanolamine transferase genes. These Gram-negative bacteria include extensively drug-resistant Acinetobacter baumannii and intrinsically colistin-resistant Neisseria gonorrhoeae, which, owing to a lack of effective treatment options, are considered among the highest level threat pathogens(4). In a mouse neutropenic infection model, a biphenyl analogue of macolacin proved to be effective against extensively drug-resistant A. baumannii with colistin-resistance, thus providing a naturally inspired and easily produced therapeutic lead for overcoming colistin-resistant pathogens. | 2022 | 34987225 |
| 4427 | 14 | 0.9998 | Mechanisms of quinolone action and microbial response. Over the years, chromosomal mapping of the bacterial genome of Escherichia coli has demonstrated that many loci are associated with quinolone resistance, which is mainly a result of chromosomal mutation or alteration of the quantity or type of porins in the outer membrane of Gram-negative bacteria. There has been one report of a small and confined episode of plasmid-mediated resistance to fluoroquinolones, which did not appear to persist. With the increasingly widespread use of an expanding range of fluoroquinolone antibiotics, a range and mix in individual bacterial isolates of the different mechanisms of resistance to fluoroquinolones will undoubtedly be encountered amongst clinically significant bacteria. Currently, transferable resistance is extremely rare and most resistant bacteria arise from clonal expansion of mutated strains. However, it is conceivable that in the future, horizontal gene transfer may become a more important means of conferring resistance to fluoroquinolones. | 2003 | 12702701 |
| 4830 | 15 | 0.9998 | Mechanisms of resistance to quinolones. The increased use of fluoroquinolones has led to increasing resistance to these antimicrobials, with rates of resistance that vary by both organism and geographic region. Resistance to fluoroquinolones typically arises as a result of alterations in the target enzymes (DNA gyrase and topoisomerase IV) and of changes in drug entry and efflux. Mutations are selected first in the more susceptible target: DNA gyrase, in gram-negative bacteria, or topoisomerase IV, in gram-positive bacteria. Additional mutations in the next most susceptible target, as well as in genes controlling drug accumulation, augment resistance further, so that the most-resistant isolates have mutations in several genes. Resistance to quinolones can also be mediated by plasmids that produce the Qnr protein, which protects the quinolone targets from inhibition. Qnr plasmids have been found in the United States, Europe, and East Asia. Although Qnr by itself produces only low-level resistance, its presence facilitates the selection of higher-level resistance mutations, thus contributing to the alarming increase in resistance to quinolones. | 2005 | 15942878 |
| 4833 | 16 | 0.9998 | Emerging mechanisms of fluoroquinolone resistance. Broad use of fluoroquinolones has been followed by emergence of resistance, which has been due mainly to chromosomal mutations in genes encoding the subunits of the drugs' target enzymes, DNA gyrase and topoisomerase IV, and in genes that affect the expression of diffusion channels in the outer membrane and multidrug-resistance efflux systems. Resistance emerged first in species in which single mutations were sufficient to cause clinically important levels of resistance (e.g., Staphylococcus aureus and Pseudomonas aeruginosa). Subsequently, however, resistance has emerged in bacteria such as Campylobacter jejuni, Escherichia coli, and Neisseria gonorrhoeae, in which multiple mutations are required to generate clinically important resistance. In these circumstances, the additional epidemiologic factors of drug use in animals and human-to-human spread appear to have contributed. Resistance in Streptococcus pneumoniae, which is currently low, will require close monitoring as fluoroquinolones are used more extensively for treating respiratory tract infections. | 2001 | 11294736 |
| 4443 | 17 | 0.9998 | Cellular Studies of an Aminoglycoside Potentiator Reveal a New Inhibitor of Aminoglycoside Resistance. Aminoglycosides are a group of broad-spectrum antibiotics that have been used in the clinic for almost a century. The rapid spread of bacterial genes coding for aminoglycoside-modifying enzymes has, however, dramatically decreased the utility of aminoglycosides. We have previously reported several aminoglycoside potentiators that work by inhibiting aminoglycoside N-6'-acetyltransferase, one of the most common determinants of aminoglycoside resistance. Among these, prodrugs that combine the structure of an aminoglycoside with that of pantothenate into one molecule are especially promising. We report here a series of cellular studies to investigate the activity and mechanism of action of these prodrugs further. Our results reveal a new aminoglycoside resistance inhibitor, as well as the possibility that these prodrugs are transformed into more than one inhibitor in bacteria. We also report that the onset of the potentiators is rapid. Their low cell cytotoxicity, good stability, and potentiation of various aminoglycosides, against both Gram-positive and Gram-negative bacteria, make them interesting compounds for the development of new drugs. | 2018 | 30059603 |
| 9902 | 18 | 0.9998 | Bacterial death comes full circle: targeting plasmid replication in drug-resistant bacteria. It is now common for bacterial infections to resist the preferred antibiotic treatment. In particular, hospital-acquired infections that are refractory to multiple antibiotics and ultimately result in death of the patient are prevalent. Many of the bacteria causing these infections have become resistant to antibiotics through the process of lateral gene transfer, with the newly acquired genes encoding a variety of resistance-mediating proteins. These foreign genes often enter the bacteria on plasmids, which are small, circular, extrachromosomal pieces of DNA. This plasmid-encoded resistance has been observed for virtually all classes of antibiotics and in a wide variety of Gram-positive and Gram-negative organisms; many antibiotics are no longer effective due to such plasmid-encoded resistance. The systematic removal of these resistance-mediating plasmids from the bacteria would re-sensitize bacteria to standard antibiotics. As such, plasmids offer novel targets that have heretofore been unexploited clinically. This Perspective details the role of plasmids in multi-drug resistant bacteria, the mechanisms used by plasmids to control their replication, and the potential for small molecules to disrupt plasmid replication and re-sensitize bacteria to antibiotics. An emphasis is placed on plasmid replication that is mediated by small counter-transcript RNAs, and the "plasmid addiction" systems that employ toxins and antitoxins. | 2005 | 15750634 |
| 4402 | 19 | 0.9998 | Mechanisms of antimicrobial resistance in Stenotrophomonas maltophilia: a review of current knowledge. Introduction: Stenotrophomonas maltophilia is a prototype of bacteria intrinsically resistant to antibiotics. The reduced susceptibility of this microorganism to antimicrobials mainly relies on the presence in its chromosome of genes encoding efflux pumps and antibiotic inactivating enzymes. Consequently, the therapeutic options for treating S. maltophilia infections are limited.Areas covered: Known mechanisms of intrinsic, acquired and phenotypic resistance to antibiotics of S. maltophilia and the consequences of such resistance for treating S. maltophilia infections are discussed. Acquisition of some genes, mainly those involved in co-trimoxazole resistance, contributes to acquired resistance. Mutation, mainly in the regulators of chromosomally-encoded antibiotic resistance genes, is a major cause for S. maltophilia acquisition of resistance. The expression of some of these genes is triggered by specific signals or stressors, which can lead to transient phenotypic resistance.Expert opinion: Treatment of S. maltophilia infections is difficult because this organism presents low susceptibility to antibiotics. Besides, it can acquire resistance to antimicrobials currently in use. Particularly problematic is the selection of mutants overexpressing efflux pumps since they present a multidrug resistance phenotype. The use of novel antimicrobials alone or in combination, together with the development of efflux pumps' inhibitors may help in fighting S. maltophilia infections. | 2020 | 32052662 |