# | Rank | Similarity | Title + Abs. | Year | PMID |
|---|---|---|---|---|---|
| 0 | 1 | 2 | 3 | 4 | 5 |
| 4849 | 0 | 1.0000 | Active site loops of membrane-anchored metallo-β-lactamases from environmental bacteria determine cephalosporinase activity. Antimicrobial resistance is a significant global public health threat that limits treatment options for bacterial infections. This situation is aggravated by the environmental spread of β-lactamase genes. In particular, metallo-β-lactamases (MBLs) hydrolyze almost all available β-lactam antibiotics, including late-generation cephalosporins and carbapenems. Among MBLs, the New Delhi metallo-β-lactamase (NDM-1) of subclass B1 has shown the most ominous dissemination. NDM variants are the only MBLs of clinical importance that are membrane-anchored, a sub-cellular localization that endows them with high stability under conditions of metal limitation. However, antibiotic resistance predates modern antibiotic usage, and environmental bacteria serve as reservoirs for resistance genes. Here, we report the biochemical and structural characterization of two membrane-bound MBLs: CJO-1 and CIM-2, from Chryseobacterium joostei and Chryseobacterium indologenes, respectively. Both MBLs confer β-lactam resistance on producer bacterial strains and hydrolyze several antibiotics, although with impaired efficiency compared to NDM-1. Crystal structures reveal differences, compared to previously studied B1 MBLs, in the active site loops and their dynamic properties that impact activity. Specifically, a hindered access to the active site with the contribution of a Tyr residue in loop L10 and the presence of a positively charged Lys residue in loop L3 limit hydrolysis of cephalosporins with charged C3 substituents. Some of these novel features are preserved in other MBLs from Chryseobacterium spp. These findings suggest that Chryseobacterium spp. could act as reservoirs of MBL genes, while informing on the diversity of structure-function relationships and dynamic behaviors within the B1 subclass of these enzymes. | 2025 | 40548716 |
| 4670 | 1 | 0.9998 | Novel Antibiotic Resistance Genes Identified by Functional Gene Library Screening in Stenotrophomonas maltophilia and Chryseobacterium spp. Bacteria of Soil Origin. As one of the most diverse habitats of microorganisms, soil has been recognised as a reservoir of both antibiotics and the antibiotic resistance genes (ARGs). Bacteria naturally inhabiting soil or water often possess innate ARGs to counteract the chemical compounds produced by competitors living in the same environment. When such bacteria are able to cause infections in immunocompromised patients, their strong innate antibiotic resistance mechanisms make treatment difficult. We generated functional gene libraries using antibiotic-resistant Stenotrophomonas maltophilia and Chryseobacterium spp. bacteria isolated from agricultural soils in Lithuania to select for the genetic determinants responsible for their resistance. We were able to find novel variants of aminoglycoside and β-lactam resistance genes, with β-lactamases isolated from the Chryseobacterium spp. functional gene library, one of which is a variant of IND-like metallo-β-lactamase (MBL) IND-17 and the other of which is a previously uncharacterised MBL we named CHM (Chryseobacterium metallo β-lactamase). Our results indicate that soil microorganisms possess a diversity of ARG variants, which could potentially be transferred to the clinical setting. | 2023 | 37047008 |
| 5059 | 2 | 0.9997 | Site-selective modifications by lipid A phosphoethanolamine transferases linked to colistin resistance and bacterial fitness. Genes encoding lipid A modifying phosphoethanolamine transferases (PETs) are genetically diverse and can confer resistance to colistin and antimicrobial peptides. To better understand the functional diversity of PETs, we characterized three canonical mobile colistin resistance (mcr) alleles (mcr-1, -3, -9), one intrinsic pet (eptA), and two mcr-like genes (petB, petC) in Escherichia coli. Using an isogenic expression system, we show that mcr-1 and mcr-3 confer similar phenotypes of decreased colistin susceptibility with low fitness costs. mcr-9, which is phylogenetically closely related to mcr-3, and eptA only provide fitness advantages in the presence of sub-inhibitory concentrations of colistin and significantly reduce fitness in media without colistin. PET-B and PET-C were phenotypically distinct from bonafide PETs; neither impacted colistin susceptibility nor caused considerable fitness cost. Strikingly, we found for the first time that different PETs selectively modify different phosphates of lipid A; MCR-1, MCR-3, and PET-C selectively modify the 4'-phosphate, whereas MCR-9 and EptA modify the 1-phosphate. However, 4'-phosphate modifications facilitated by MCR-1 and -3 are associated with lowered colistin susceptibility and low toxicity. Our results suggest that PETs have a wide phenotypic diversity and that increased colistin resistance is associated with specific lipid A modification patterns that have been largely unexplored thus far. IMPORTANCE: Rising levels of resistance to increasing numbers of antimicrobials have led to the revival of last resort antibiotic colistin. Unfortunately, resistance to colistin is also spreading in the form of mcr genes, making it essential to (i) improve the identification of resistant bacteria to allow clinicians to prescribe effective drug regimens and (ii) develop new combination therapies effective at targeting resistant bacteria. Our results demonstrate that PETs, including MCR variants, are site-selective in Escherichia coli and that site-selectivity correlates with the level of susceptibility and fitness costs conferred by certain PETs. Site selectivity associated with a given PET may not only help predict colistin resistance phenotypes but may also provide an avenue to (i) improve drug regimens and (ii) develop new combination therapies to better combat colistin-resistant bacteria. | 2024 | 39611852 |
| 9928 | 3 | 0.9997 | The emergence and implications of metallo-beta-lactamases in Gram-negative bacteria. The increase in Gram-negative broad-spectrum antibiotic resistance is worrisome, particularly as there are few, if any, ''pipeline'' antimicrobial agents possessing suitable activity against Pseudomonas spp. or Acinetobacter spp. The increase in resistance will be further enhanced by the acquisition of metallo-beta-lactamase (MBL) genes that can potentially confer broad-spectrum beta-lactam resistance. These genes encode enzymes that can hydrolyse all classes of beta-lactams and the activity of which cannot be neutralised by beta-lactamase inhibitors. MBL genes are often associated with aminoglycoside resistant genes and thus bacteria that possess MBL genes are often co-resistant to aminoglycosides, further compromising therapeutic regimes. Both types of genes can be found as gene cassettes carried by integrons that in turn are embedded within transposons providing a highly ambulatory genetic element. The dissemination of MBL genes is typified by the spread of blaVIM-2, believed to originate from a Portuguese patient in 1995, and is now present in over 20 counties. The increase in international travel is likely to be a contributory factor for the ascendancy of mobile MBL genes as much as the mobility among individual bacteria. Fitness, acquisition and host dependency are key areas that need to be addressed to enhance our understanding of how antibiotic resistance spreads. There is also a pressing need for new, and hopefully novel, compounds active against pan-resistant Gram-negative bacteria--a growing problem that needs to be addressed by both government and industry. | 2005 | 16209700 |
| 4860 | 4 | 0.9997 | The rise of carbapenem-resistant Acinetobacter baumannii. Acinetobacter spp. are Gram-negative bacteria that have become one of the most difficult pathogens to treat. The species A. baumannii, largely unknown 30 years ago, has risen to prominence particularly because of its ability to cause infections in immunocompromised patients. It is now a predominant pathogen in many hospitals as it has acquired resistance genes to virtually all antibiotics capable of treating Gram-negative bacteria, including the fluoroquinolones and the cephalosporins. Some members of the species have accumulated these resistance genes in large resistance islands, located in a "hot-spot" within the bacterial chromosome. The only conventional remaining treatment options were the carbapenems. However, A. baumannii possesses an inherent class D β-lactamase gene (blaOXA-51-like) that can have the ability to confer carbapenem resistance. Additionally, mechanisms of carbapenem resistance have emerged that derive from the importation of the distantly related class D β-lactamase genes blaOXA-23 and blaOXA-58. Although not inducible, the expression of these genes is controlled by mobile promoters carried on ISAba elements. It has also been found that other resistance genes including the chromosomal class C β-lactamase genes conferring cephalosporin resistance are controlled in the same manner. Colistin is now considered to be the final drug capable of treating infections caused by carbapenem-resistant A. baumannii; however, strains are now being isolated that are resistant to this antibiotic as well. The increasing inability to treat infections caused by A. baumannii ensures that this pathogen more than ranks with MRSA or Clostridium difficile as a threat to modern medicine. | 2013 | 22894617 |
| 4838 | 5 | 0.9997 | Cooperative resistance varies among β-lactamases in E. coli, with some enabling cross-protection and sustained extracellular activity. β-lactamases confer bacteria resistance to β-lactam antibiotics, and interestingly, this protective effect can extend to neighboring susceptible cells. However, knowledge of this cooperative resistance remains limited. Here, we investigated the underlying factors of cooperative resistance to assess commonalities and differences among the highly diverse group of β-lactamases. We first analyzed β-lactamase genes from 2637 Escherichia coli genomes, followed by experimental characterization of seven prevalent β-lactamase genes. Larger plasmids, particularly conjugative ones, commonly encoded β-lactamases. All seven genes had strong wildtype promoters, and plasmid-based expression rescued more susceptible bacteria than chromosomal expression. Cooperative resistance positively correlated with β-lactamase activity and minimal inhibitory concentrations. Cross-protection could be established between different β-lactamase producers, challenging the effectiveness of therapies combining β-lactams. Extracellular activity varied among β-lactamases and, when high, resulted in a legacy resistance effect in the environment. These findings advance our understanding of β-lactam resistance and highlight important implications for antibiotic treatment strategies. | 2025 | 40595357 |
| 4671 | 6 | 0.9997 | Detection by metagenomic functional analysis and improvement by experimental evolution of β-lactams resistance genes present in oil contaminated soils. The spread of antibiotic resistance genes has become a global health concern identified by the World Health Organization as one of the greatest threats to health. Many of antimicrobial resistance determinants found in bacterial pathogens originate from environmental bacteria, so identifying the genes that confer resistance to antibiotics in different habitats is mandatory to better understand resistance mechanisms. Soil is one of the most diverse environments considered reservoir of antimicrobial resistance genes. The aim of this work is to study the presence of genes that provide resistance to antibiotics used in clinical settings in two oil contaminated soils by metagenomic functional analysis. Using fosmid vectors that efficiently transcribe metagenomic DNA, we have selected 12 fosmids coding for two class A β-lactamases, two subclass B1 and two subclass B3 metallo-β-lactamases, one class D β-lactamase and three efflux pumps that confer resistance to cefexime, ceftriaxone, meropenem and/or imipenem. In some of them, detection of the resistance required heterologous expression from the fosmid promoter. Although initially, these environmental genes only provide resistance to low concentrations of antibiotics, we have obtained, by experimental evolution, fosmid derivatives containing β-lactamase ORFs with a single base substitution, which substantially increase their β-lactamase activity and resistance level. None of the mutations affect β-lactamase coding sequences and are all located upstream of them. These results demonstrate the presence of enzymes that confer resistance to relevant β-lactams in these soils and their capacity to rapidly adapt to provide higher resistance levels. | 2022 | 35768448 |
| 4848 | 7 | 0.9997 | BioF is a novel B2 metallo-β-lactamase from Pseudomonas sp. isolated from an on-farm biopurification system. Antimicrobial resistance represents a major global health concern and environmental bacteria are considered a source of resistance genes. Carbapenems are often used as the last antibiotic option to treat multidrug-resistant bacteria. Metallo-β-lactamases (MBLs) are able to render resistance to almost all β-lactam antibiotics, including carbapenems. Unfortunately, there are no inhibitors against MBLs for clinical use. Subclass B2 MBLs are the only enzymes working as strict carbapenemases, under-represented, encoded in chromosome genes and only functional as mono-zinc enzymes. Despite current efforts in MBLs inhibitor development, B2 carbapenemase activity is especially difficult to suppress, even in vitro. In this study we characterized BioF, a novel subclass B2 MBL identified in a new environmental Pseudomonas sp. strain isolated from an on-farm biopurification system (BPS). Although bla(BioF) is most likely a chromosomal gene, it is found in a genomic island and may represent a step previous to the horizontal transmission of B2 genes. The new B2 MBL is active as a mono-zinc enzyme and is a potent carbapenemase with incipient activity against some cephalosporins. BioF activity is not affected by excess zinc and is only inhibited at high metal chelator concentrations. The discovery and characterization of B2 MBL BioF as a potent carbapenemase in a BPS bacterial isolate emphasizes the importance of exploring antibiotic resistances existing in the environmental microbiota under the influence of human activities before they could emerge clinically. | 2022 | 34725905 |
| 4845 | 8 | 0.9997 | The changing epidemiology of resistance. Antibiotic resistance is now a linked global problem. Dispersion of successful clones of multidrug resistant (MDR) bacteria is common, often via the movement of people. Local evolution of MDR bacteria is also important under the pressure of excessive antibiotic use, with horizontal gene transfer providing the means by which genes such as bla(CTX-M) spread amongst different bacterial species and strains. Beta-lactamase production is a common resistance mechanism in Gram-negative bacteria, and the rapid dissemination of novel genes reflects their evolution under the selective pressure of antibiotic usage. Many Enterobacteriaceae now carry broad-spectrum beta-lactamases such as CTX-M, with particular genotypes associated with different geographical regions. The spread of these enzymes has compromised the clinical utility of a number of beta-lactam classes and with the spread of genes such as bla(KPC), carbapenems may be increasingly compromised in the future. High-level fluoroquinolone resistance (mainly caused by gyrA mutations) has also been shown to be associated with CTX-M and CMY-type enzymes, commonly due to co-carriage on conjugative plasmids of the gene for the aminoglycoside-inactivating enzyme AAC-6(1)-Ib-cr and qnr genes (which confer low-level resistance), allowing the easy selection of gyrA mutants in the host strain. Resistance in Gram-positive bacteria is also widely distributed and increasing, with the emergence of community-associated methicillin-resistant Staphylococcus aureus (MRSA) blurring the distinction between hospital and community strains. Antibiotic use and environmental factors all have a role in the emergence and spread of resistance. This article reviews some of the new mechanisms and recent trends in the global spread of MDR bacteria. | 2009 | 19675017 |
| 5022 | 9 | 0.9997 | HIV Drugs Inhibit Transfer of Plasmids Carrying Extended-Spectrum β-Lactamase and Carbapenemase Genes. Antimicrobial-resistant (AMR) infections pose a serious risk to human and animal health. A major factor contributing to this global crisis is the sharing of resistance genes between different bacteria via plasmids. The WHO lists Enterobacteriaceae, such as Escherichia coli and Klebsiella pneumoniae, producing extended-spectrum β-lactamases (ESBL) and carbapenemases as "critical" priorities for new drug development. These resistance genes are most often shared via plasmid transfer. However, finding methods to prevent resistance gene sharing has been hampered by the lack of screening systems for medium-/high-throughput approaches. Here, we have used an ESBL-producing plasmid, pCT, and a carbapenemase-producing plasmid, pKpQIL, in two different Gram-negative bacteria, E. coli and K. pneumoniae Using these critical resistance-pathogen combinations, we developed an assay using fluorescent proteins, flow cytometry, and confocal microscopy to assess plasmid transmission inhibition within bacterial populations in a medium-throughput manner. Three compounds with some reports of antiplasmid properties were tested; chlorpromazine reduced transmission of both plasmids and linoleic acid reduced transmission of pCT. We screened the Prestwick library of over 1,200 FDA-approved drugs/compounds. From this, we found two nucleoside analogue drugs used to treat HIV, abacavir and azidothymidine (AZT), which reduced plasmid transmission (AZT, e.g., at 0.25 μg/ml reduced pCT transmission in E. coli by 83.3% and pKpQIL transmission in K. pneumoniae by 80.8% compared to untreated controls). Plasmid transmission was reduced by concentrations of the drugs which are below peak serum concentrations and are achievable in the gastrointestinal tract. These drugs could be used to decolonize humans, animals, or the environment from AMR plasmids.IMPORTANCE More and more bacterial infections are becoming resistant to antibiotics. This has made treatment of many infections very difficult. One of the reasons this is such a large problem is that bacteria are able to share their genetic material with other bacteria, and these shared genes often include resistance to a variety of antibiotics, including some of our drugs of last resort. We are addressing this problem by using a fluorescence-based system to search for drugs that will stop bacteria from sharing resistance genes. We uncovered a new role for two drugs used to treat HIV and show that they are able to prevent the sharing of two different types of resistance genes in two unique bacterial strains. This work lays the foundation for future work to reduce the prevalence of resistant infections. | 2020 | 32098822 |
| 4844 | 10 | 0.9997 | Genetic basis of molecular mechanisms in β-lactam resistant gram-negative bacteria. Antibiotic-resistant bacteria are considered one of the major global threats to human and animal health. The most harmful among the resistant bacteria are β-lactamase producing Gram-negative species (β-lactamases). β-lactamases constitute a paradigm shift in the evolution of antibiotic resistance. Therefore, it is imperative to present a comprehensive review of the mechanisms responsible for developing antimicrobial resistance. Resistance due to β-lactamases develops through a variety of mechanisms, and the number of resistant genes are involved that can be transferred between bacteria, mostly via plasmids. Over time, these new molecular-based resistance mechanisms have been progressively disclosed. The present review article provides information on the recent findings regarding the molecular mechanisms of resistance to β-lactams in Gram-negative bacteria, including CTX-M-type ESBLs with methylase activity, plasmids harbouring phages with β-lactam resistance genes, the co-presence of β-lactam resistant genes of unique combinations and the presence of β-lactam and non-β-lactam antibiotic-resistant genes in the same bacteria. Keeping in view, the molecular level resistance development, multifactorial and coordinated measures may be taken to counter the challenge of rapidly increasing β-lactam resistance. | 2021 | 34119627 |
| 9914 | 11 | 0.9997 | Identification of host genetic factors modulating β-lactam resistance in Escherichia coli harbouring plasmid-borne β-lactamase through transposon-sequencing. Since β-lactam antibiotics are widely used, emergence of bacteria with resistance to them poses a significant threat to society. In particular, acquisition of genes encoding β-lactamase, an enzyme that degrades β-lactam antibiotics, has been a major contributing factor in the emergence of bacteria that are resistant to β-lactam antibiotics. However, relatively few genetic targets for killing these resistant bacteria have been identified to date. Here, we used a systematic approach called transposon-sequencing (Tn-Seq), to screen the Escherichia coli genome for host genetic factors that, when mutated, affect resistance to ampicillin, one of the β-lactam antibiotics, in a strain carrying a plasmid that encodes β-lactamase. This approach enabled not just the isolation of genes previously known to affect β-lactam resistance, but the additional loci skp, gshA, phoPQ and ypfN. Individual mutations in these genes modestly but consistently affected antibiotic resistance. We have identified that these genes are not only implicated in β-lactam resistance by itself but also play a crucial role in conditions associated with the expression of β-lactamase. GshA and phoPQ appear to contribute to β-lactam resistance by regulating membrane integrity. Notably, the overexpression of the uncharacterized membrane-associated protein, ypfN, has been shown to significantly enhance β-lactam resistance. We applied the genes identified from the screening into Salmonella Typhimurium and Pseudomonas aeruginosa strains, both critical human pathogens with antibiotic resistance, and observed their significant impact on β-lactam resistance. Therefore, these genes can potentially be utilized as therapeutic targets to control the survival of β-lactamase-producing bacteria. | 2025 | 40231449 |
| 9921 | 12 | 0.9997 | Identification of Multiple Low-Level Resistance Determinants and Coselection of Motility Impairment upon Sub-MIC Ceftriaxone Exposure in Escherichia coli. Resistance to third-generation cephalosporins among Gram-negative bacteria is a rapidly growing public health threat. Among the most commonly used third-generation cephalosporins is ceftriaxone. Bacterial exposure to sublethal or sub-MIC antibiotic concentrations occurs widely, from environmental residues to intermittently at the site of infection. Quality of ceftriaxone is also a concern, especially in low- and middle-income countries, with medicines having inappropriate active pharmaceutical ingredient (API) content or concentration. While focus has been largely on extended-spectrum β-lactamases and high-level resistance, there are limited data on specific chromosomal mutations and other pathways that contribute to ceftriaxone resistance under these conditions. In this work, Escherichia coli cells were exposed to a broad range of sub-MICs of ceftriaxone and mutants were analyzed using whole-genome sequencing. Low-level ceftriaxone resistance emerged after as low as 10% MIC exposure, with the frequency of resistance development increasing with concentration. Genomic analyses of mutants revealed multiple genetic bases. Mutations were enriched in genes associated with porins (envZ, ompF, ompC, and ompR), efflux regulation (marR), and the outer membrane and metabolism (galU and pgm), but none were associated with the ampC β-lactamase. We also observed selection of mgrB mutations. Notably, pleiotropic effects on motility and cell surface were selected for in multiple independent genes, which may have important consequences. Swift low-level resistance development after exposure to low ceftriaxone concentrations may result in reservoirs of bacteria with relevant mutations for survival and increased resistance. Thus, initiatives for broader surveillance of low-level antibiotic resistance and genomic resistance determinants should be pursued when resources are available. IMPORTANCE Ceftriaxone is a widely consumed antibiotic used to treat bacterial infections. Bacteria, however, are increasingly becoming resistant to ceftriaxone. Most work has focused on known mechanisms associated with high-level ceftriaxone resistance. However, bacteria are extensively exposed to low antibiotic concentrations, and there are limited data on the evolution of ceftriaxone resistance under these conditions. In this work, we observed that bacteria quickly developed low-level resistance due to both novel and previously described mutations in multiple different genes upon exposure to low ceftriaxone concentrations. Additionally, exposure also led to changes in motility and the cell surface, which can impact other processes associated with resistance and infection. Notably, low-level-resistant bacteria would be missed in the clinic, which uses set breakpoints. While they may require increased resources, this work supports continued initiatives for broader surveillance of low-level antibiotic resistance or their resistance determinants, which can serve as predictors of higher risk for clinical resistance. | 2021 | 34787446 |
| 5058 | 13 | 0.9997 | Widespread Fosfomycin Resistance in Gram-Negative Bacteria Attributable to the Chromosomal fosA Gene. Fosfomycin is a decades-old antibiotic which is being revisited because of its perceived activity against many extensively drug-resistant Gram-negative pathogens. FosA proteins are Mn(2+) and K(+)-dependent glutathione S-transferases which confer fosfomycin resistance in Gram-negative bacteria by conjugation of glutathione to the antibiotic. Plasmid-borne fosA variants have been reported in fosfomycin-resistant Escherichia coli strains. However, the prevalence and distribution of fosA in other Gram-negative bacteria are not known. We systematically surveyed the presence of fosA in Gram-negative bacteria in over 18,000 published genomes from 18 Gram-negative species and investigated their contribution to fosfomycin resistance. We show that FosA homologues are present in the majority of genomes in some species (e.g., Klebsiella spp., Enterobacter spp., Serratia marcescens, and Pseudomonas aeruginosa), whereas they are largely absent in others (e.g., E. coli, Acinetobacter baumannii, and Burkholderia cepacia). FosA proteins in different bacterial pathogens are highly divergent, but key amino acid residues in the active site are conserved. Chromosomal fosA genes conferred high-level fosfomycin resistance when expressed in E. coli, and deletion of chromosomal fosA in S. marcescens eliminated fosfomycin resistance. Our results indicate that FosA is encoded by clinically relevant Gram-negative species and contributes to intrinsic fosfomycin resistance.IMPORTANCE There is a critical need to identify alternate approaches to treat infections caused by extensively drug-resistant (XDR) Gram-negative bacteria. Fosfomycin is an old antibiotic which is routinely used for the treatment of urinary tract infections, although there is substantial interest in expanding its use to systemic infections caused by XDR Gram-negative bacteria. In this study, we show that fosA genes, which encode dimeric Mn(2+)- and K(+)-dependent glutathione S-transferase, are widely distributed in the genomes of Gram-negative bacteria-particularly those belonging to the family Enterobacteriaceae-and confer fosfomycin resistance. This finding suggests that chromosomally located fosA genes represent a vast reservoir of fosfomycin resistance determinants that may be transferred to E. coli Furthermore, they suggest that inhibition of FosA activity may provide a viable strategy to potentiate the activity of fosfomycin against XDR Gram-negative bacteria. | 2017 | 28851843 |
| 4839 | 14 | 0.9997 | beta-Lactamases: protein evolution in real time. The evolution and spread of bacteria resistant to beta-lactam antibiotics has progressed at an alarming rate. Bacteria may acquire resistance to a given drug by mutation of pre-existing genes or by the acquisition of new genes from other bacteria. One ongoing example of these mechanisms is the evolution of new variants of the TEM and SHV beta-lactamases with altered substrate specificity. | 1998 | 9746943 |
| 9932 | 15 | 0.9997 | Beta-lactam resistance mechanisms in gram-negative bacteria. Beta-lactam antibiotics are commonly used to treat a variety of bacterial infections. Gram-negative bacteria have evolved several resistance mechanisms including altered permeability and beta-lactamase production. New trends in resistance are emerging amongst clinical isolates which may reflect the choice of beta-lactam employed. | 1986 | 2856616 |
| 4545 | 16 | 0.9997 | Beta-lactamases in lactic acid bacteria: Dual role in antimicrobial resistance spread and environmental detoxification of antibiotic residues. Lactic acid bacteria (LAB) are widely used in food production and as probiotics. However, their potential role in the spreading of antimicrobial resistance (AMR) remains underexplored. A major AMR mechanism is the production of beta-lactamases, which is well-documented in most pathogenic bacteria; the diversity and functionality of these enzymes in LAB are less understood. Here, we explored the genomic diversity of beta-lactamase genes in LAB in a broad range of publicly available LAB genomes. Our findings revealed the presence of two distinct types of beta-lactamase genes in LAB: ampC-type beta-lactamases (class C), likely developed within LAB lineages, and bla(TEM)-type (class A), potentially acquired via HGT. Phylogenetic and structural analysis revealed similarities between LAB-derived ampC genes and clinically relevant class C beta-lactamases, while bla(TEM)-type genes were identified to be often flanked by mobility-related genetic elements, indicating a potential for horizontal gene transfer (HGT). Molecular docking studies further showed that LAB beta-lactamases may hydrolyze a broad spectrum of beta-lactam antibiotics, particularly aminopenicillins and cephalosporins. These findings will contribute to the broader field of AMR research, highlighting the importance of monitoring beta-lactamase production by LAB and its implications for food safety, bioremediation of beta-lactam antibiotic residues in wastewater and agro-industrial effluents. | 2025 | 40651383 |
| 4847 | 17 | 0.9997 | Escherichia coli β-Lactamases: What Really Matters. Escherichia coli strains belonging to diverse pathotypes have increasingly been recognized as a major public health concern. The β-lactam antibiotics have been used successfully to treat infections caused by pathogenic E. coli. However, currently, the utility of β-lactams is being challenged severely by a large number of hydrolytic enzymes - the β-lactamases expressed by bacteria. The menace is further compounded by the highly flexible genome of E. coli, and propensity of resistance dissemination through horizontal gene transfer and clonal spread. Successful management of infections caused by such resistant strains requires an understanding of the diversity of β-lactamases, their unambiguous detection, and molecular mechanisms underlying their expression and spread with regard to the most relevant information about individual bacterial species. Thus, this review comprises first such effort in this direction for E. coli, a bacterial species known to be associated with production of diverse classes of β-lactamases. The review also highlights the role of commensal E. coli as a potential but under-estimated reservoir of β-lactamases-encoding genes. | 2016 | 27065978 |
| 4324 | 18 | 0.9997 | Characterization of Antibiotic Resistance in Shewanella Species: An Emerging Pathogen in Clinical and Environmental Settings. Antibiotic resistance is increasing at an alarming rate worldwide, in large part due to their misuse and improper disposal. Antibiotics administered to treat human and animal diseases, including feed supplements for the treatment or prevention of disease in farm animals, have contributed greatly to the emergence of a multitude of antibiotic-resistant pathogens. Shewanella is one of many bacteria that have developed antibiotic resistance, and in some species, multiple-antibiotic resistance (MAR). Shewanella is a rod-shaped, Gram-negative, oxidase-positive, and H(2)S-producing bacterium that is naturally found in the marine environment. In humans, Shewanella spp. can cause skin and soft tissue infections, septicemia, cellulitis, osteomyelitis, and ear and wound infections. Some Shewanella have been shown to be resistant to a variety of antibiotics, including beta-lactams, aminoglycoside, quinolones, third- or fourth-generation cephalosporins, and carbapenems, due to the presence of genes such as the bla(OXA)-class D beta-lactamase-encoding gene, bla(AmpC)-class-C beta-lactamase-encoding gene, and the qnr gene. Bacteria can acquire and transmit these genes through different horizontal gene-transmission mechanisms such as transformation, transduction, and conjugation. The genes for antibiotic resistance are present on Shewanella chromosomes and plasmids. Apart from this, heavy metals such as arsenic, mercury, cadmium, and chromium can also increase antibiotic resistance in Shewanella due to co-selection processes such as co-resistance, cross resistance, and co-regulation mechanisms. Antibiotics and drugs enter Shewanella spp. through pores or gates in their cell wall and may be ejected from the bacteria by efflux pumps, which are the first line of bacterial defense against antibiotics. Multiple-drug resistant Shewanella can be particularly difficult to control. This review focuses on the phenotypic and genomic characteristics of Shewanella that are involved in the increase in antimicrobial resistance in this bacterium. | 2025 | 40431288 |
| 4569 | 19 | 0.9996 | Effect of oxygen on antimicrobial resistance genes from a one health perspective. Bacteria must face and adapt to a variety of physicochemical conditions in the environment and during infection. A key condition is the concentration of dissolved oxygen, proportional to the partial pressure of oxygen (PO(2)), which is extremely variable among environmental biogeographical areas and also compartments of the human and animal body. Here, we sought to understand if the phenotype of resistance determinants commonly found in Enterobacterales can be influenced by oxygen pressure. To do so, we have compared the MIC in aerobic and anaerobic conditions of isogenic Escherichia coli strains containing 136 different resistance genes against 8 antibiotic families. Our results show a complex landscape of changes in the performance of resistance genes in anaerobiosis. Certain changes are especially relevant for their intensity and the importance of the antibiotic family, like the large decreases in resistance observed against ertapenem and fosfomycin among bla(VIM) β-lactamases and certain fos genes, respectively; however, the bla(OXA-48) β-lactamase from the clinically relevant pOXA-48 plasmid conferred 4-fold higher ertapenem resistance in anaerobiosis. Strong changes in resistance patterns in anaerobiosis were also conserved in Klebsiella pneumoniae. Our results suggest that anaerobiosis is a relevant aspect that can affect the action and selective power of antibiotics for specific AMRs in different environments. | 2025 | 40286623 |