# | Rank | Similarity | Title + Abs. | Year | PMID |
|---|---|---|---|---|---|
| 0 | 1 | 2 | 3 | 4 | 5 |
| 558 | 0 | 0.9813 | Thiamine pyrophosphate riboswitches are targets for the antimicrobial compound pyrithiamine. Thiamine metabolism genes are regulated in numerous bacteria by a riboswitch class that binds the coenzyme thiamine pyrophosphate (TPP). We demonstrate that the antimicrobial action of the thiamine analog pyrithiamine (PT) is mediated by interaction with TPP riboswitches in bacteria and fungi. For example, pyrithiamine pyrophosphate (PTPP) binds the TPP riboswitch controlling the tenA operon in Bacillus subtilis. Expression of a TPP riboswitch-regulated reporter gene is reduced in transgenic B. subtilis or Escherichia coli when grown in the presence of thiamine or PT, while mutant riboswitches in these organisms are unresponsive to these ligands. Bacteria selected for PT resistance bear specific mutations that disrupt ligand binding to TPP riboswitches and derepress certain TPP metabolic genes. Our findings demonstrate that riboswitches can serve as antimicrobial drug targets and expand our understanding of thiamine metabolism in bacteria. | 2005 | 16356850 |
| 746 | 1 | 0.9810 | Novel antimicrobial 3-phenyl-4-phenoxypyrazole derivatives target cell wall lipid intermediates with low mammalian cytotoxicity. The growing crisis of antimicrobial resistance (AMR) underscores the critical need for innovative antimicrobial discoveries. Novel antibiotics targeting the bacterial cell wall remain an attractive area of research, due to their conservation and essentiality in bacteria and their absence in eukaryotic cells. Antibiotics targeting lipid II are of special interest due to the reduced potential for target modification of lipid components and their surface accessibility to inhibitors. In this study, we identified 3-phenyl-4-phenoxypyrazole analogues named PYO12 and PYO12a with bactericidal activity against gram-positive bacteria and low cytotoxicity for different types of mammalian cells. Gram-negative bacteria were resistant to PYO12 activity through extrusion of this compound via efflux pumps. Exposure to PYO12 induces expression of genes involved in resistance to antimicrobials targeting the cell wall, suggesting that PYO12 acts via binding to lipid II or other lipid intermediates involved in peptidoglycan or teichoic acid biosynthesis. Antagonism of PYO12 antibacterial activity by undecaprenyl-pyrophosphate supports the idea that PYO12 may bind to the lipid moiety of lipid II blocking the shuttling of peptidoglycan precursors across the cytoplasmic membrane. These findings open opportunities to further develop these compounds as antibiotics targeting bacterial cell wall synthesis. | 2025 | 41083642 |
| 726 | 2 | 0.9806 | Regulation of antimicrobial resistance by extracytoplasmic function (ECF) sigma factors. Extracytoplasmic function (ECF) sigma factors are a subfamily of σ(70) sigma factors that activate genes involved in stress-response functions. In many bacteria, ECF sigma factors regulate resistance to antimicrobial compounds. This review will summarize the ECF sigma factors that regulate antimicrobial resistance in model organisms and clinically relevant pathogens. | 2017 | 28153747 |
| 8210 | 3 | 0.9804 | Bacterial sensing of antimicrobial peptides. Antimicrobial peptides (AMPs) form a crucial part of human innate host defense, especially in neutrophil phagosomes and on epithelial surfaces. Bacteria have a variety of efficient resistance mechanisms to human AMPs, such as efflux pumps, secreted proteases, and alterations of the bacterial cell surface that are aimed to minimize attraction of the typically cationic AMPs. In addition, bacteria have specific sensors that activate AMP resistance mechanisms when AMPs are present. The prototypical Gram-negative PhoP/PhoQ and the Gram-positive Aps AMP-sensing systems were first described and investigated in Salmonella typhimurium and Staphylococcus epidermidis, respectively. Both include a classical bacterial two-component sensor/regulator system, but show many structural, mechanistic, and functional differences. The PhoP/PhoQ regulon controls a variety of genes not necessarily limited to AMP resistance mechanisms, but apparently aimed to combat innate host defense on a broad scale. In contrast, the staphylococcal Aps system predominantly upregulates AMP resistance mechanisms, namely the D-alanylation of teichoic acids, inclusion of lysyl-phosphati-dylglycerol in the cytoplasmic membrane, and expression of the putative VraFG AMP efflux pump. Notably, both systems are crucial for virulence and represent possible targets for antimicrobial therapy. | 2009 | 19494583 |
| 506 | 4 | 0.9802 | A kiss of death--proteasome-mediated membrane fusion and programmed cell death in plant defense against bacterial infection. Eukaryotes have evolved various means for controlled and organized cellular destruction, known as programmed cell death (PCD). In plants, PCD is a crucial regulatory mechanism in multiple physiological processes, including terminal differentiation, senescence, and disease resistance. In this issue of Genes & Development, Hatsugai and colleagues (pp. 2496-2506) demonstrate a novel plant defense strategy to trigger bacteria-induced PCD, involving proteasome-dependent tonoplast and plasma membrane fusion followed by discharge of vacuolar antimicrobial and death-inducing contents into the apoplast. | 2009 | 19884251 |
| 611 | 5 | 0.9799 | The Staphylococcus aureus FASII bypass escape route from FASII inhibitors. Antimicrobials targeting the fatty acid synthesis (FASII) pathway are being developed as alternative treatments for bacterial infections. Emergence of resistance to FASII inhibitors was mainly considered as a consequence of mutations in the FASII target genes. However, an alternative and efficient anti-FASII resistance strategy, called here FASII bypass, was uncovered. Bacteria that bypass FASII incorporate exogenous fatty acids in membrane lipids, and thus dispense with the need for FASII. This strategy is used by numerous Gram-positive low GC % bacteria, including streptococci, enterococci, and staphylococci. Some bacteria repress FASII genes once fatty acids are available, and "constitutively" shift to FASII bypass. Others, such as the major pathogen Staphylococcus aureus, can undergo high frequency mutations that favor FASII bypass. This capacity is particularly relevant during infection, as the host supplies the fatty acids needed for bacteria to bypass FASII and thus become resistant to FASII inhibitors. Screenings for anti-FASII resistance in the presence of exogenous fatty acids confirmed that FASII bypass confers anti-FASII resistance among clinical and veterinary isolates. Polymorphisms in S. aureus FASII initiation enzymes favor FASII bypass, possibly by increasing availability of acyl-carrier protein, a required intermediate. Here we review FASII bypass and consequences in light of proposed uses of anti-FASII to treat infections, with a focus on FASII bypass in S. aureus. | 2017 | 28728970 |
| 730 | 6 | 0.9798 | How intracellular bacteria survive: surface modifications that promote resistance to host innate immune responses. Bacterial pathogens regulate the expression of virulence factors in response to environmental signals. In the case of salmonellae, many virulence factors are regulated via PhoP/PhoQ, a two-component signal transduction system that is repressed by magnesium and calcium in vitro. PhoP/PhoQ-activated genes promote intracellular survival within macrophages, whereas PhoP-repressed genes promote entrance into epithelial cells and macrophages by macropinocytosis and stimulate epithelial cell cytokine production. PhoP-activated genes include those that alter the cell envelope through structural alterations of lipopolysaccharide and lipid A, the bioactive component of lipopolysaccharide. PhoP-activated changes in the bacterial envelope likely promote intracellular survival by increasing resistance to host cationic antimicrobial peptides and decreasing host cell cytokine production. | 1999 | 10081503 |
| 9160 | 7 | 0.9795 | Interference in Bacterial Quorum Sensing: A Biopharmaceutical Perspective. Numerous bacteria utilize molecular communication systems referred to as quorum sensing (QS) to synchronize the expression of certain genes regulating, among other aspects, the expression of virulence factors and the synthesis of biofilm. To achieve this process, bacteria use signaling molecules, known as autoinducers (AIs), as chemical messengers to share information. Naturally occurring strategies that interfere with bacterial signaling have been extensively studied in recent years, examining their potential to control bacteria. To interfere with QS, bacteria use quorum sensing inhibitors (QSIs) to block the action of AIs and quorum quenching (QQ) enzymes to degrade signaling molecules. Recent studies have shown that these strategies are promising routes to decrease bacterial pathogenicity and decrease biofilms, potentially enhancing bacterial susceptibility to antimicrobial agents including antibiotics and bacteriophages. The efficacy of QSIs and QQ enzymes has been demonstrated in various animal models and are now considered in the development of new medical devices against bacterial infections, including dressings, and catheters for enlarging the therapeutic arsenal against bacteria. | 2018 | 29563876 |
| 8145 | 8 | 0.9795 | Emerging role for RNA-based regulation in plant immunity. Infection by phytopathogenic bacteria triggers massive changes in plant gene expression, which are thought to be mostly a result of transcriptional reprogramming. However, evidence is accumulating that plants additionally use post-transcriptional regulation of immune-responsive mRNAs as a strategic weapon to shape the defense-related transcriptome. Cellular RNA-binding proteins regulate RNA stability, splicing or mRNA export of immune-response transcripts. In particular, mutants defective in alternative splicing of resistance genes exhibit compromised disease resistance. Furthermore, detection of bacterial pathogens induces the differential expression of small non-coding RNAs including microRNAs that impact the host defense transcriptome. Phytopathogenic bacteria in turn have evolved effector proteins to inhibit biogenesis and/or activity of cellular microRNAs. Whereas RNA silencing has long been known as an antiviral defense response, recent findings also reveal a major role of this process in antibacterial defense. Here we review the function of RNA-binding proteins and small RNA-directed post-transcriptional regulation in antibacterial defense. We mainly focus on studies that used the model system Arabidopsis thaliana and also discuss selected examples from other plants. | 2013 | 23163405 |
| 199 | 9 | 0.9794 | Activation of Imd pathway in hemocyte confers infection resistance through humoral response in Drosophila. Upon microbial invasion the innate immune system of Drosophila melanogaster mounts a response that comes in two distinct but complimentary forms, humoral and cellular. A screen to find genes capable of conferring resistance to the Gram-positive Staphylococcus aureus upon ectopic expression in immune response tissues uncovered imd gene. This resistance was not dependent on cellular defenses but rather likely a result of upregulation of the humoral response through increased expression of antimicrobial peptides, including a Toll pathway reporter gene drosomycin. Taken together it appears that Imd pathway is capable of playing a role in resistance to the Gram-positive S. aureus, counter to notions of traditional roles of the Imd pathway thought largely to responsible for resistance to Gram-negative bacteria. | 2013 | 23261474 |
| 200 | 10 | 0.9794 | Drosophila Toll is activated by Gram-positive bacteria through a circulating peptidoglycan recognition protein. Microbial infection activates two distinct intracellular signalling cascades in the immune-responsive fat body of Drosophila. Gram-positive bacteria and fungi predominantly induce the Toll signalling pathway, whereas Gram-negative bacteria activate the Imd pathway. Loss-of-function mutants in either pathway reduce the resistance to corresponding infections. Genetic screens have identified a range of genes involved in these intracellular signalling cascades, but how they are activated by microbial infection is largely unknown. Activation of the transmembrane receptor Toll requires a proteolytically cleaved form of an extracellular cytokine-like polypeptide, Spätzle, suggesting that Toll does not itself function as a bona fide recognition receptor of microbial patterns. This is in apparent contrast with the mammalian Toll-like receptors and raises the question of which host molecules actually recognize microbial patterns to activate Toll through Spätzle. Here we present a mutation that blocks Toll activation by Gram-positive bacteria and significantly decreases resistance to this type of infection. The mutation semmelweis (seml) inactivates the gene encoding a peptidoglycan recognition protein (PGRP-SA). Interestingly, seml does not affect Toll activation by fungal infection, indicating the existence of a distinct recognition system for fungi to activate the Toll pathway. | 2001 | 11742401 |
| 504 | 11 | 0.9793 | Activation of Dithiolopyrrolone Antibiotics by Cellular Reductants. Dithiolopyrrolone (DTP) natural products are broad-spectrum antimicrobial and anticancer prodrugs. The DTP structure contains a unique bicyclic ene-disulfide that once reduced in the cell, chelates metal ions and disrupts metal homeostasis. In this work we investigate the intracellular activation of the DTPs and their resistance mechanisms in bacteria. We show that the prototypical DTP holomycin is reduced by several bacterial reductases and small-molecule thiols in vitro. To understand how bacteria develop resistance to the DTPs, we generate Staphylococcus aureus mutants that exhibit increased resistance to the hybrid DTP antibiotic thiomarinol. From these mutants we identify loss-of-function mutations in redox genes that are involved in DTP activation. This work advances the understanding of how DTPs are activated and informs development of bioreductive disulfide prodrugs. | 2025 | 39665630 |
| 9059 | 12 | 0.9793 | Validation of Suitable Carrier Molecules and Target Genes for Antisense Therapy Using Peptide-Coupled Peptide Nucleic Acids (PNAs) in Streptococci. Antisense peptide nucleic acids (PNAs) targeting genes involved in metabolism or virulence are a possible means to treat infections or to investigate pathogenic bacteria. Potential targets include essential genes, virulence factor genes, or antibiotic resistance genes. For efficient cellular uptake, PNAs can be coupled to cell-penetrating peptides (CPPs). CPPs are peptides that serve as molecular transporters and are characterized by a comparably low cytotoxicity. So far, there is only limited information about CPPs that mediate PNA uptake by Gram-positive bacteria. Here, we describe two methods to identify suitable CPP-antisense PNA conjugates, novel carrier molecules, and efficient target genes for streptococcal species and to evaluate their antimicrobial efficiency. | 2020 | 32430835 |
| 585 | 13 | 0.9792 | Genetic susceptibility to intracellular infections: Nramp1, macrophage function and divalent cations transport. Nramp1 is one of the few host resistance genes that have been characterized at the molecular level. Nramp1 is an integral membrane protein expressed in the lysosomal compartment of macrophages and is recruited to the membrane of bacterial phagosomes where it affects intracellular microbial replication. Nramp1 is part of a very large gene family conserved from bacteria and man that codes for transporters of divalent cations transporters. We propose that Nramp1 affects the intraphagosomal microbial replication by modulating divalent cations content in this organelle. Both mammalian and bacterial transporters may compete for the same substrate in the phagosomal space. | 2000 | 10679418 |
| 766 | 14 | 0.9792 | The essential inner membrane protein YejM is a metalloenzyme. Recent recurrent outbreaks of Gram-negative bacteria show the critical need to target essential bacterial mechanisms to fight the increase of antibiotic resistance. Pathogenic Gram-negative bacteria have developed several strategies to protect themselves against the host immune response and antibiotics. One such strategy is to remodel the outer membrane where several genes are involved. yejM was discovered as an essential gene in E. coli and S. typhimurium that plays a critical role in their virulence by changing the outer membrane permeability. How the inner membrane protein YejM with its periplasmic domain changes membrane properties remains unknown. Despite overwhelming structural similarity between the periplasmic domains of two YejM homologues with hydrolases like arylsulfatases, no enzymatic activity has been previously reported for YejM. Our studies reveal an intact active site with bound metal ions in the structure of YejM periplasmic domain. Furthermore, we show that YejM has a phosphatase activity that is dependent on the presence of magnesium ions and is linked to its function of regulating outer membrane properties. Understanding the molecular mechanism by which YejM is involved in outer membrane remodeling will help to identify a new drug target in the fight against the increased antibiotic resistance. | 2020 | 33082366 |
| 198 | 15 | 0.9791 | The Drosophila immune defense against gram-negative infection requires the death protein dFADD. Drosophila responds to Gram-negative infections by mounting an immune response that depends on components of the IMD pathway. We recently showed that imd encodes a protein with a death domain with high similarity to that of mammalian RIP. Using a two-hybrid screen in yeast, we have isolated the death protein dFADD as a molecule that associates with IMD. Our data show that loss of dFADD function renders flies highly susceptible to Gram-negative infections without affecting resistance to Gram-positive bacteria. By genetic analysis we show that dFADD acts downstream of IMD in the pathway that controls inducibility of the antibacterial peptide genes. | 2002 | 12433364 |
| 8273 | 16 | 0.9791 | Targeting quorum sensing and competence stimulation for antimicrobial chemotherapy. Bacterial resistance to antibiotics is now a serious problem, with traditional classes of antibiotics having gradually become ineffective. New drugs are therefore needed to target and inhibit novel pathways that affect the growth of bacteria. An important feature in the survival of bacteria is that they coordinate their efforts together as a colony via secreted auto-inducing molecules. Competence stimulating peptides (CSPs) are among the quorum sensing pheromones involved in this coordination. These peptides activate a two-component system in gram-negative bacteria, binding to and activating a histidine kinase receptor called ComD, which phosphorylates a response regulator called ComE, leading to gene expression and induction of competence. Competent bacteria are able to take up exogenous DNA and incorporate it into their own genome. By this mechanism bacteria are able to acquire and share genes encoding antibiotic resistance. Despite having been studied for over 30 years, this pathway has only recently begun to be explored as a novel approach to modulating bacterial growth. Antagonists of ComD might block the signaling cascade that leads to competence, while overstimulation of ComD might also reduce bacterial growth. One possible approach to inhibiting ComD is to examine peptide sequences of CSPs that activate ComD and attempt to constrain them to bioactive conformations, likely to have higher affinity due to pre-organization for recognition by the receptor. Thus, small molecules that mimic an alpha helical epitope of CSPs, the putative ComD binding domain, have been shown here to inhibit growth of bacteria such as S. pneumoniae. Such alpha helix mimetics may be valuable clues to antibacterial chemotherapeutic agents that utilize a new mechanism to control bacterial growth. | 2012 | 22664089 |
| 331 | 17 | 0.9790 | MmpS4 promotes glycopeptidolipids biosynthesis and export in Mycobacterium smegmatis. The MmpS family (mycobacterial membrane protein small) includes over 100 small membrane proteins specific to the genus Mycobacterium that have not yet been studied experimentally. The genes encoding MmpS proteins are often associated with mmpL genes, which are homologous to the RND (resistance nodulation cell division) genes of Gram-negative bacteria that encode proteins functioning as multidrug efflux system. We showed by molecular genetics and biochemical analysis that MmpS4 in Mycobacterium smegmatis is required for the production and export of large amounts of cell surface glycolipids, but is dispensable for biosynthesis per se. A new specific and sensitive method utilizing single-chain antibodies against the surface-exposed glycolipids was developed to confirm that MmpS4 was dispensable for transport to the surface. Orthologous complementation demonstrated that the MmpS4 proteins are exchangeable, thus not specific to a defined lipid species. MmpS4 function requires the formation of a protein complex at the pole of the bacillus, which requires the extracytosolic C-terminal domain of MmpS4. We suggest that MmpS proteins facilitate lipid biosynthesis by acting as a scaffold for coupled biosynthesis and transport machinery. | 2010 | 21062372 |
| 8204 | 18 | 0.9790 | Cecropins contribute to Drosophila host defense against a subset of fungal and Gram-negative bacterial infection. Cecropins are small helical secreted peptides with antimicrobial activity that are widely distributed among insects. Genes encoding Cecropins are strongly induced upon infection, pointing to their role in host defense. In Drosophila, four cecropin genes clustered in the genome (CecA1, CecA2, CecB, and CecC) are expressed upon infection downstream of the Toll and Imd pathways. In this study, we generated a short deletion ΔCecA-C removing the whole cecropin locus. Using the ΔCecA-C deficiency alone or in combination with other antimicrobial peptide (AMP) mutations, we addressed the function of Cecropins in the systemic immune response. ΔCecA-C flies were viable and resisted challenge with various microbes as wild-type. However, removing ΔCecA-C in flies already lacking 10 other AMP genes revealed a role for Cecropins in defense against Gram-negative bacteria and fungi. Measurements of pathogen loads confirm that Cecropins contribute to the control of certain Gram-negative bacteria, notably Enterobacter cloacae and Providencia heimbachae. Collectively, our work provides the first genetic demonstration of a role for Cecropins in insect host defense and confirms their in vivo activity primarily against Gram-negative bacteria and fungi. Generation of a fly line (ΔAMP14) that lacks 14 immune inducible AMPs provides a powerful tool to address the function of these immune effectors in host-pathogen interactions and beyond. | 2022 | 34791204 |
| 8207 | 19 | 0.9790 | Functional amyloid proteins confer defence against predatory bacteria. Bdellovibrio bacteriovorus is a predatory bacterium that non-selectively preys on Gram-negative bacteria by invading the prey-cell periplasm, leaching host nutrients and ultimately lysing the infected cell to exit and find a new host(1,2). The predatory life cycle of B. bacteriovorus is, in many ways, comparable to a bacteriophage. However, unlike phage defence, defence against B. bacteriovorus has not been widely investigated. Here we screened a collection of diverse Escherichia coli strains for resistance to B. bacteriovorus and identified that roughly one-third of strains robustly defended against predation by producing curli fibres. Curli fibres are oligomers of the functional amyloid protein CsgA, which is exceptionally durable(3). Using genetics and microscopy, we demonstrate that curli fibres provide a barrier that protects susceptible cells independent of genes required for biofilm formation. This barrier further protected E. coli against attack by the predatory bacterium Myxococcus xanthus and select phages. Bioinformatic analysis of bacterial amyloids showed these systems are diverse and widespread in diderm bacteria (those with both inner and outer membranes). One of these, an evolutionarily distinct amyloid encoded by Pseudomonas aeruginosa, also protected against B. bacteriovorus. This work establishes that functional amyloids defend bacteria against a wide range of threats. | 2025 | 40604283 |