# | Rank | Similarity | Title + Abs. | Year | PMID |
|---|---|---|---|---|---|
| 0 | 1 | 2 | 3 | 4 | 5 |
| 291 | 0 | 1.0000 | Deregulation of translation due to post-transcriptional modification of rRNA explains why erm genes are inducible. A key mechanism of bacterial resistance to macrolide antibiotics is the dimethylation of a nucleotide in the large ribosomal subunit by erythromycin resistance methyltransferases. The majority of erm genes are expressed only when the antibiotic is present and the erythromycin resistance methyltransferase activity is critical for the survival of bacteria. Although these genes were among the first discovered inducible resistance genes, the molecular basis for their inducibility has remained unknown. Here we show that erythromycin resistance methyltransferase expression reduces cell fitness. Modification of the nucleotide in the ribosomal tunnel skews the cellular proteome by deregulating the expression of a set of proteins. We further demonstrate that aberrant translation of specific proteins results from abnormal interactions of the nascent peptide with the erythromycin resistance methyltransferase-modified ribosomal tunnel. Our findings provide a plausible explanation why erm genes have evolved to be inducible and underscore the importance of nascent peptide recognition by the ribosome for generating a balanced cellular proteome. | 2013 | 23749080 |
| 293 | 1 | 0.9996 | Gene regulation by tetracyclines. Constraints of resistance regulation in bacteria shape TetR for application in eukaryotes. The Tet repressor protein (TetR) regulates transcription of a family of tetracycline (tc) resistance determinants in Gram-negative bacteria. The resistance protein TetA, a membrane-spanning H+-[tc.M]+ antiporter, must be sensitively regulated because its expression is harmful in the absence of tc, yet it has to be expressed before the drugs' concentration reaches cytoplasmic levels inhibitory for protein synthesis. Consequently, TetR shows highly specific tetO binding to reduce basal expression and high affinity to tc to ensure sensitive induction. Tc can cross biological membranes by diffusion enabling this inducer to penetrate the majority of cells. These regulatory and pharmacological properties are the basis for application of TetR to selectively control the expression of single genes in lower and higher eukaryotes. TetR can be used for that purpose in some organisms without further modifications. In mammals and in a large variety of other organisms, however, eukaryotic transcriptional activator or repressor domains are fused to TetR to turn it into an efficient regulator. Mechanistic understanding and the ability to engineer and screen for mutants with specific properties allow tailoring of the DNA recognition specificity, the response to inducer tc and the dimerization specificity of TetR-based eukaryotic regulators. This review provides an overview of the TetR properties as they evolved in bacteria, the functional modifications necessary to transform it into a convenient, specific and efficient regulator for use in eukaryotes and how the interplay between structure--function studies in bacteria and specific requirements of particular applications in eukaryotes have made it a versatile and highly adaptable regulatory system. | 2003 | 12869186 |
| 294 | 2 | 0.9996 | Status quo of tet regulation in bacteria. The tetracycline repressor (TetR) belongs to the most popular, versatile and efficient transcriptional regulators used in bacterial genetics. In the tetracycline (Tc) resistance determinant tet(B) of transposon Tn10, tetR regulates the expression of a divergently oriented tetA gene that encodes a Tc antiporter. These components of Tn10 and of other natural or synthetic origins have been used for tetracycline-dependent gene regulation (tet regulation) in at least 40 bacterial genera. Tet regulation serves several purposes such as conditional complementation, depletion of essential genes, modulation of artificial genetic networks, protein overexpression or the control of gene expression within cell culture or animal infection models. Adaptations of the promoters employed have increased tet regulation efficiency and have made this system accessible to taxonomically distant bacteria. Variations of TetR, different effector molecules and mutated DNA binding sites have enabled new modes of gene expression control. This article provides a current overview of tet regulation in bacteria. | 2022 | 34713957 |
| 296 | 3 | 0.9996 | An indigenous posttranscriptional modification in the ribosomal peptidyl transferase center confers resistance to an array of protein synthesis inhibitors. A number of nucleotide residues in ribosomal RNA (rRNA) undergo specific posttranscriptional modifications. The roles of most modifications are unclear, but their clustering in functionally important regions of rRNA suggests that they might either directly affect the activity of the ribosome or modulate its interactions with ligands. Of the 25 modified nucleotides in Escherichia coli 23S rRNA, 14 are located in the peptidyl transferase center, the main antibiotic target in the large ribosomal subunit. Since nucleotide modifications have been closely associated with both antibiotic sensitivity and antibiotic resistance, loss of some of these posttranscriptional modifications may affect the susceptibility of bacteria to antibiotics. We investigated the antibiotic sensitivity of E. coli cells in which the genes of 8 rRNA-modifying enzymes targeting the peptidyl transferase center were individually inactivated. The lack of pseudouridine at position 2504 of 23S rRNA was found to significantly increase the susceptibility of bacteria to peptidyl transferase inhibitors. Therefore, this indigenous posttranscriptional modification may have evolved as an intrinsic resistance mechanism protecting bacteria against natural antibiotics. | 2008 | 18554609 |
| 8215 | 4 | 0.9996 | Insight into Two ABC Transporter Families Involved in Lantibiotic Resistance. Antimicrobial peptides, which contain (methyl)-lanthionine-rings are called lantibiotics. They are produced by several Gram-positive bacteria and are mainly active against these bacteria. Although these are highly potent antimicrobials, some human pathogenic bacteria express specific ABC transporters that confer resistance and counteract their antimicrobial activity. Two distinct ABC transporter families are known to be involved in this process. These are the Cpr- and Bce-type ABC transporter families, named after their involvement in cationic peptide resistance in Clostridium difficile, and bacitracin efflux in Bacillus subtilis, respectively. Both resistance systems differentiate to each other in terms of the proteins involved. Here, we summarize the current knowledge and describe the divergence as well as the common features present in both the systems to confer lantibiotic resistance. | 2017 | 29404338 |
| 292 | 5 | 0.9996 | Mechanisms underlying expression of Tn10 encoded tetracycline resistance. Tetracycline-resistance determinants encoding active efflux of the drug are widely distributed in gram-negative bacteria and unique with respect to genetic organization and regulation of expression. Each determinant consists of two genes called tetA and tetR, which are oriented with divergent polarity, and between them is a central regulatory region with overlapping promoters and operators. The amino acid sequences of the encoded proteins are 43-78% identical. The resistance protein TetA is a tetracycline/metal-proton antiporter located in the cytoplasmic membrane, while the regulatory protein TetR is a tetracycline inducible repressor. TetR binds via a helix-turn-helix motif to the two tet operators, resulting in repression of both genes. A detailed model of the repressor-operator complex has been proposed on the basis of biochemical and genetic data. The tet genes are differentially regulated so that repressor synthesis can occur before the resistance protein is expressed. This has been demonstrated for the Tn10-encoded tet genes and may be a common property of all tet determinants, as suggested by the similar locations of operators with respect to promoters. Induction is mediated by a tetracycline-metal complex and requires only nanomolar concentrations of the drug. This is the most sensitive effector-inducible system of transcriptional regulation known to date. The crystal structure of the TetR-tetracycline/metal complex shows the Tet repressor in the induced, non-DNA binding conformation. The structural interpretation of many noninducible TetR mutants has offered insight into the conformational changes associated with the switch between inducing and repressing structures of TetR. Tc is buried in the core of TetR, where it is held in place by multiple contacts to the protein. | 1994 | 7826010 |
| 684 | 6 | 0.9996 | Transcriptome analysis reveals mechanisms by which Lactococcus lactis acquires nisin resistance. Nisin, a posttranslationally modified antimicrobial peptide produced by Lactococcus lactis, is widely used as a food preservative. Yet, the mechanisms leading to the development of nisin resistance in bacteria are poorly understood. We used whole-genome DNA microarrays of L. lactis IL1403 to identify the factors underlying acquired nisin resistance mechanisms. The transcriptomes of L. lactis IL1403 and L. lactis IL1403 Nis(r), which reached a 75-fold higher nisin resistance level, were compared. Differential expression was observed in genes encoding proteins that are involved in cell wall biosynthesis, energy metabolism, fatty acid and phospholipid metabolism, regulatory functions, and metal and/or peptide transport and binding. These results were further substantiated by showing that several knockout and overexpression mutants of these genes had strongly altered nisin resistance levels and that some knockout strains could no longer become resistant to the same level of nisin as that of the wild-type strain. The acquired nisin resistance mechanism in L. lactis is complex, involving various different mechanisms. The four major mechanisms are (i) preventing nisin from reaching the cytoplasmic membrane, (ii) reducing the acidity of the extracellular medium, thereby stimulating the binding of nisin to the cell wall, (iii) preventing the insertion of nisin into the membrane, and (iv) possibly transporting nisin across the membrane or extruding nisin out of the membrane. | 2006 | 16641446 |
| 563 | 7 | 0.9996 | Exit tunnel modulation as resistance mechanism of S. aureus erythromycin resistant mutant. The clinical use of the antibiotic erythromycin (ery) is hampered owing to the spread of resistance genes that are mostly mutating rRNA around the ery binding site at the entrance to the protein exit tunnel. Additional effective resistance mechanisms include deletion or insertion mutations in ribosomal protein uL22, which lead to alterations of the exit tunnel shape, located 16 Å away from the drug's binding site. We determined the cryo-EM structures of the Staphylococcus aureus 70S ribosome, and its ery bound complex with a two amino acid deletion mutation in its ß hairpin loop, which grants the bacteria resistance to ery. The structures reveal that, although the binding of ery is stable, the movement of the flexible shorter uL22 loop towards the tunnel wall creates a wider path for nascent proteins, thus enabling bypass of the barrier formed by the drug. Moreover, upon drug binding, the tunnel widens further. | 2019 | 31391518 |
| 8897 | 8 | 0.9996 | Clinically relevant mutant DNA gyrase alters supercoiling, changes the transcriptome, and confers multidrug resistance. Bacterial DNA is maintained in a supercoiled state controlled by the action of topoisomerases. Alterations in supercoiling affect fundamental cellular processes, including transcription. Here, we show that substitution at position 87 of GyrA of Salmonella influences sensitivity to antibiotics, including nonquinolone drugs, alters global supercoiling, and results in an altered transcriptome with increased expression of stress response pathways. Decreased susceptibility to multiple antibiotics seen with a GyrA Asp87Gly mutant was not a result of increased efflux activity or reduced reactive-oxygen production. These data show that a frequently observed and clinically relevant substitution within GyrA results in altered expression of numerous genes, including those important in bacterial survival of stress, suggesting that GyrA mutants may have a selective advantage under specific conditions. Our findings help contextualize the high rate of quinolone resistance in pathogenic strains of bacteria and may partly explain why such mutant strains are evolutionarily successful. IMPORTANCE: Fluoroquinolones are a powerful group of antibiotics that target bacterial enzymes involved in helping bacteria maintain the conformation of their chromosome. Mutations in the target enzymes allow bacteria to become resistant to these antibiotics, and fluoroquinolone resistance is common. We show here that these mutations also provide protection against a broad range of other antimicrobials by triggering a defensive stress response in the cell. This work suggests that fluoroquinolone resistance mutations may be beneficial under a range of conditions. | 2013 | 23882012 |
| 763 | 9 | 0.9995 | Inducing conformational preference of the membrane protein transporter EmrE through conservative mutations. Transporters from bacteria to humans contain inverted repeat domains thought to arise evolutionarily from the fusion of smaller membrane protein genes. Association between these domains forms the functional unit that enables transporters to adopt distinct conformations necessary for function. The small multidrug resistance (SMR) family provides an ideal system to explore the role of mutations in altering conformational preference since transporters from this family consist of antiparallel dimers that resemble the inverted repeats present in larger transporters. Here, we show using NMR spectroscopy how a single conservative mutation introduced into an SMR dimer is sufficient to change the resting conformation and function in bacteria. These results underscore the dynamic energy landscape for transporters and demonstrate how conservative mutations can influence structure and function. | 2019 | 31637997 |
| 8332 | 10 | 0.9995 | The bacterial LexA transcriptional repressor. Bacteria respond to DNA damage by mounting a coordinated cellular response, governed by the RecA and LexA proteins. In Escherichia coli, RecA stimulates cleavage of the LexA repressor, inducing more than 40 genes that comprise the SOS global regulatory network. The SOS response is widespread among bacteria and exhibits considerable variation in its composition and regulation. In some well-characterised pathogens, induction of the SOS response modulates the evolution and dissemination of drug resistance, as well as synthesis, secretion and dissemination of the virulence. In this review, we discuss the structure of LexA protein, particularly with respect to distinct conformations that enable repression of SOS genes via specific DNA binding or repressor cleavage during the response to DNA damage. These may provide new starting points in the battle against the emergence of bacterial pathogens and the spread of drug resistance among them. | 2009 | 18726173 |
| 4437 | 11 | 0.9995 | The activity of glycopeptide antibiotics against resistant bacteria correlates with their ability to induce the resistance system. Glycopeptide antibiotics containing a hydrophobic substituent display the best activity against vancomycin-resistant enterococci, and they have been assumed to be poor inducers of the resistance system. Using a panel of 26 glycopeptide derivatives and the model resistance system in Streptomyces coelicolor, we confirmed this hypothesis at the level of transcription. Identification of the structural glycopeptide features associated with inducing the expression of resistance genes has important implications in the search for more effective antibiotic structures. | 2014 | 25092694 |
| 8895 | 12 | 0.9995 | Loss of DNA mismatch repair genes leads to acquisition of antibiotic resistance independent of secondary mutations. Antibiotic resistant bacteria have been a rising clinical concern for decades. Beyond acquisition of alleles conferring resistance, bacteria under stress (e.g., from changing environmental conditions or mutations) can have higher intrinsic resistance to antibiotics than unstressed cells. This concern is expanded for gram-negative bacteria which have a protective outer membrane serving as an additional barrier against harmful molecules such as antibiotics. Here, we report a pathway which increases antibiotic resistance (i.e., minimum inhibitory concentration) in response to inactivation of the DNA Mismatch Repair pathway (MMR). This pathway led to increased intrinsic resistance and was independent of secondary mutations. Specifically, deletion of the DNA mismatch repair genes mutL or mutS caused resistance to various antibiotics spanning different classes, molecular sizes, and mechanisms of action in several different E. coli K-12 MG1655 strains, and in Salmonella enterica serovar Typhimurium LT2. This pathway was independent of the SOS response (severe DNA damage response). However, the patterns of resistance correlated with previously reported increases in MMR mutants in rates of homoeologous recombination, homologous recombination between non-identical DNA strands. Mutations expected to lower rates of recombination in MMR mutants also decreased the resistance to most antibiotics. Finally, we found lysis occurs in MMR mutants and may contribute to resistance to other antibiotics. Our results have demonstrated a novel mechanism that increases antibiotic resistance in direct response to loss of MMR genes, and we propose this resistance involves increased rates of homoeologous recombination and cell lysis. The increased antibiotic resistance of MMR mutants provides a path for these cells to survive in antibiotics long enough to develop more specific resistance mutations and so may contribute to the development of new clinical resistance alleles. | 2025 | 40667202 |
| 295 | 13 | 0.9995 | Large-scale chromosome flip-flop reversible inversion mediates phenotypic switching of expression of antibiotic resistance in lactococci. Bacteria can gain resistance to antimicrobials by acquiring and expressing genetic elements that encode resistance determinants such as efflux pumps and drug-modifying enzymes, thus hampering treatment of infection. Previously we showed that acquisition of spectinomycin resistance in a lactococcal strain was correlated with a reversible genomic inversion, but the precise location and the genes affected were unknown. Here we use long-read whole-genome sequencing to precisely define the genomic inversion and we use quantitative PCR to identify associated changes in gene expression levels. The boundaries of the inversion fall within two identical copies of a prophage-like sequence, located on the left and right replichores; this suggests possible mechanisms for inversion through homologous recombination or prophage activity. The inversion is asymmetrical in respect of the axis between the origin and terminus of the replication and modulates the expression of a SAM-dependent methyltransferase, whose heterologous expression confers resistance to spectinomycin in lactococci and that is up-regulated on exposure to spectinomycin. This study provides one of the first examples of phase variation via large-scale chromosomal inversions that confers a switch in antimicrobial resistance in bacteria and the first outside of Staphylococcus aureus. | 2020 | 32919223 |
| 710 | 14 | 0.9995 | The L box regulon: lysine sensing by leader RNAs of bacterial lysine biosynthesis genes. Expression of amino acid biosynthesis genes in bacteria is often repressed when abundant supplies of the cognate amino acid are available. Repression of the Bacillus subtilis lysC gene by lysine was previously shown to occur at the level of premature termination of transcription. In this study we show that lysine directly promotes transcription termination during in vitro transcription with B. subtilis RNA polymerase and causes a structural shift in the lysC leader RNA. We find that B. subtilis lysC is a member of a large family of bacterial lysine biosynthesis genes that contain similar leader RNA elements. By analogy with related regulatory systems, we designate this leader RNA pattern the "L box." Genes in the L box family from Gram-negative bacteria appear to be regulated at the level of translation initiation rather than transcription termination. Mutations of B. subtilis lysC that disrupt conserved leader features result in loss of lysine repression in vivo and loss of lysine-dependent transcription termination in vitro. The identification of the L box pattern also provides an explanation for previously described mutations in both B. subtilis and Escherichia coli lysC that result in lysC overexpression and resistance to the lysine analog aminoethylcysteine. The L box regulatory system represents an example of gene regulation using an RNA element that directly senses the intracellular concentration of a small molecule. | 2003 | 14523230 |
| 702 | 15 | 0.9995 | Cutting edge: the toll pathway is required for resistance to gram-positive bacterial infections in Drosophila. In Drosophila, the response against various microorganisms involves different recognition and signaling pathways, as well as distinct antimicrobial effectors. On the one hand, the immune deficiency pathway regulates the expression of antimicrobial peptides that are active against Gram-negative bacteria. On the other hand, the Toll pathway is involved in the defense against filamentous fungi and controls the expression of antifungal peptide genes. The gene coding for the only known peptide with high activity against Gram-positive bacteria, Defensin, is regulated by both pathways. So far, survival experiments to Gram-positive bacteria have been performed with Micrococcus luteus and have failed to reveal the involvement of one or the other pathway in host defense against such infections. In this study, we report that the Toll pathway, but not that of immune deficiency, is required for resistance to other Gram-positive bacteria and that this response does not involve Defensin. | 2002 | 11823479 |
| 8225 | 16 | 0.9995 | Basic peptide-morpholino oligomer conjugate that is very effective in killing bacteria by gene-specific and nonspecific modes. Basic peptides covalently linked to nucleic acids, or chemically modified nucleic acids, enable the insertion of such a conjugate into bacteria grown in liquid medium and mammalian cells in tissue culture. A unique peptide, derived from human T cells, has been employed in a chemical synthesis to make a conjugate with a morpholino oligonucleotide. This new conjugate is at least 10- to 100-fold more effective than previous peptides used in altering the phenotype of host bacteria if the external guide sequence methodology is employed in these experiments. Bacteria with target genes expressing chloramphenicol resistance, penicillin resistance, or gyrase A function can effectively be reduced in their expression and the host cells killed. Several bacteria are susceptible to this treatment, which has a broad range of potency. The loss in viability of bacteria is not due only to complementarity with a target RNA and the action of RNase P, but also to a non-gene-specific tight binding of the complexed nontargeted RNA to the basic polypeptide-morpholino oligonucleotide. | 2011 | 21949365 |
| 6326 | 17 | 0.9995 | Identification of novel metronidazole-inducible genes in Mycobacterium smegmatis using a customized amplification library. The incidence of antibiotic resistance in pathogenic bacteria is rising. Bacterial resistance may be a natural defense of organisms, or it may result from spontaneous mutations or the acquisition of exogenous resistance genes. We grew spontaneous metronidazole-resistant Mycobacterium smegmatis mutants on solid medium cultures and employed differential expression using a customized amplification library to analyze the global gene profiles of metronidazole-resistant mutants under hypoxic conditions. In total, 66 genes involved in metronidazole resistance were identified and functionally characterized using the gene role category of M. smegmatis. Overall, genes associated with cell wall synthesis, such as methyltransferase and glycosyltransferase, and genes encoding drug transporters were highly expressed. The genes may be involved in the natural drug resistance of mycobacteria by increasing mycobacterial cell wall permeability and the efflux pumps of active drugs. In addition, the genes may play a role in dormancy. The genes identified in this study may lead to a better understanding of the mechanisms of metronidazole resistance during dormancy. | 2008 | 18373646 |
| 8894 | 18 | 0.9995 | Genome Recombination-Mediated tRNA Up-Regulation Conducts General Antibiotic Resistance of Bacteria at Early Stage. Bacterial antibiotic resistance sets a great challenge to human health. It seems that the bacteria can spontaneously evolve resistance against any antibiotic within a short time without the horizontal transfer of heterologous genes and before accumulating drug-resistant mutations. We have shown that the tRNA-mediated translational regulation counteracts the reactive oxygen species (ROS) in bacteria. In this study, we demonstrated that isolated and subcultured Escherichia coli elevated its tRNAs under antibiotic stress to rapidly provide antibiotic resistance, especially at the early stage, before upregulating the efflux pump and evolving resistance mutations. The DNA recombination system repaired the antibiotic-induced DNA breakage in the genome, causing numerous structural variations. These structural variations are overrepresented near the tRNA genes, which indicated the cause of tRNA up-regulation. Knocking out the recombination system abolished the up-regulation of tRNAs, and coincidently, they could hardly evolve antibiotic resistance in multiple antibiotics, respectively. With these results, we proposed a multi-stage model of bacterial antibiotic resistance in an isolated scenario: the early stage (recombination-tRNA up-regulation-translational regulation); the medium stage (up-regulation of efflux pump); the late stage (resistant mutations). These results also indicated that the bacterial DNA recombination system and tRNA could be targeted to retard the bacterial spontaneous drug resistance. | 2021 | 35126332 |
| 764 | 19 | 0.9995 | Fungal ATP-binding cassette (ABC) transporters in drug resistance & detoxification. Pleiotropic drug resistance (PDR) is a well-described phenomenon occurring in fungi. PDR shares several similarities with processes in bacteria and higher eukaryotes. In mammalian cells, multidrug resistance (MDR) develops from an initial single drug resistance, eventually leading to a broad cross-resistance to many structurally and functionally unrelated compounds. Notably, a number of membrane-embedded energy-consuming ATP-binding cassette (ABC) transporters have been implicated in the development of PDR/MDR phenotypes. The yeast Saccharomyces cerevisiae genome harbors some 30 genes encoding ABC proteins, several of which mediate PDR. Therefore, yeast served as an important model organism to study the functions of evolutionary conserved ABC genes, including those mediating clinical antifungal resistance in fungal pathogens. Moreover, yeast cells lacking endogenous ABC pumps are hypersensitive to many antifungal drugs, making them suitable for functional studies and cloning of ABC transporters from fungal pathogens such as Candida albicans. This review discusses drug resistance phenomena mediated by ABC transporters in the model system S. cerevisiae and certain fungal pathogens. | 2006 | 16611035 |