Project description:Efflux pumps of the resistance-nodulation-division (RND) superfamily, particularly the AcrAB-TolC and MexAB-OprM, besides mediating intrinsic and acquired resistance, also intervene in bacterial pathogenicity. Inhibitors of such pumps could restore activities of antibiotics and curb bacterial virulence. Here, we identify pyrrole-based compounds that boost antibiotic activity in Escherichia coli and Pseudomonas aeruginosa by inhibiting their archetype RND transporters. The discovered efflux pump inhibitors (EPIs) inhibit the efflux of fluorescent probes, attenuate persister formation, and diminish resistant mutant development. Molecular docking and biophysical studies revealed that the EPIs bind to AcrB. EPIs also possess an anti-pathogenic potential and attenuate P. aeruginosa virulence in vivo. The excellent efficacy of the EPI-antibiotic combination was evidenced in animal lung infection and sepsis protection models. These findings indicate that EPIs discovered herein with no off-target effects and negligible toxicity are potential antibiotic adjuvants to address life-threatening bacterial infections.

Project description:The Pseudomonas aeruginosa quorum-sensing (QS) systems contribute to bacterial homeostasis and pathogenicity. Although the AraC family transcription factor VqsM has been characterized to control the production of virulence factors and QS signaling molecules, its detailed regulatory mechanisms still remain elusive. Here, we report that VqsM directly binds to the lasI promoter region, and thus regulates its expression. To identify additional targets of VqsM in P. aeruginosa PAO1, we performed chromatin immunoprecipitation followed by high-throughput DNA sequencing (ChIP-seq) which detected 48 enriched loci harboring VqsM-binding peaks in P. aeruginosa genome. The direct regulation of these genes by VqsM has been confirmed by Electrophoretic mobility shift assays (EMSAs) and quantitative real-time polymerase chain reactions (qRT-PCR). A VqsM-binding motif is found by using MEME suite and verified by footprint assays in vitro. In addition, VqsM directly binds to the promoter regions of antibiotic resistance regulator NfxB and the master type III system regulator ExsA. Notably, the vqsM mutant displayed more resistance to two types of antibiotics and promoted bacterial survival in a mouse model, compared to the wild type PAO1 strain. Collectively, this work provides new cues to better understand the detailed regulatory networks of QS systems, T3SS, and antibiotic resistance. Pseudomonas aeruginosa MAPO1 containing empty pAK1900 or pAK1900-VqsM-VSV

Project description:In light of the antibiotic crisis, emerging strategies to sensitize bacteria to available antibiotics should be explored. Several studies on the mechanisms of killing suggest that bactericidal antibiotic activity is enforced through the generation of reactive oxygen species (ROS lethality hypothesis). Here, we artificially manipulated the redox homeostasis of the model opportunistic pathogen Pseudomonas aeruginosa using specific enzymes that catalyze either the formation or oxidation of NADH. Increased NADH levels led to the activation of antibiotic efflux pumps and high levels of antibiotic resistance. However, higher NADH levels also resulted in increased intracellular ROS and amplified antibiotic killing. Our results demonstrate that growth inhibition and killing activity are mediated via different mechanisms. Furthermore, the profound changes in bioenergetics produced low virulence phenotypes characterized by reduced inter-bacterial signaling controlled pathogenicity traits. Our results pave the way for a more effective infection resolution and add an anti-virulence strategy to maximize chances to combat devastating P. aeruginosa infections while reducing the overall use of antibiotics.

Project description:Pseudomonas aeruginosa is one of the most common pathogens in hospital-acquired infection, which is tightly controlled by a multi-layered regulatory network including quorum sensing system (QS), type VI secretion system (T6SS) and resistance to host immunity. In the present study, we found that a PA3880 gene, which encodes an unknown protein, acted as a regulator of anaerobic metabolism, response to oxidative stress and virulence in P. aeruginosa. More than thirty PA3880 homologs were found in other bacterial genomes, indicating that PA3880 was widely distributed in bacterial kingdom with a conserved function. Deletion of PA3880 gene changed expression of more than seven hundred genes, including a group of virulence genes under both aerobic and anaerobic conditions. To further study the mechanisms of PA3880-mediated regulation on virulence, we utilized bacterial two-hybrid assay and found that PA3880 protein directly interacted with QS regulator MvfR and anaerobic regulator Anr. Loss of PA3880 protein significantly blunted the pathogenicity of P. aeruginosa, resulting in increased survival, decreased bacterial burdens, muffled inflammatory response, and less lung injuries in mice. Mechanistically, we identified that Cys44 was a critical site for full function of PA3880 to influence alveolar macrophage phagocytosis and bacterial clearance. We also found that AnvM directly interacted with host receptors TLR2 and TLR5, which might lead to activation of host immune response. Hence, we named PA3880 as anvM (anaerobic and virulence modulator). The present characterization of anvM will help to uncover new targets and strategies to treat P. aeruginosa infections.

Project description:Virulent bacteriophages (or phages) are viruses that specifically infect and lyse a bacterial host. When multiple phages co-infect a bacterial host, the extent of lysis, dynamics of bacteria-phage and phage-phage interactions are expected to vary. The objective of this study is to identify the factors influencing the interaction of two virulent phages with different Pseudomonas aeruginosa growth states (planktonic, an infected epithelial cell line, and biofilm) by measuring the bacterial time-kill and individual phage replication kinetics. A single administration of phages effectively reduced P. aeruginosa viability in planktonic conditions and infected human lung cell cultures, but phage-resistant variants subsequently emerged. In static biofilms, the phage combination displayed initial inhibition of biofilm dispersal, but sustained control was achieved only by combining phages and meropenem antibiotic. In contrast, adherent biofilms showed tolerance to phage and/or meropenem, suggesting a spatiotemporal variation in the phage-bacterial interaction. The kinetics of adsorption of each phage to P. aeruginosa during single- or co-administration were comparable. However, the phage with the shorter lysis time depleted bacterial resources early and selected a specific nucleotide polymorphism that conferred a competitive disadvantage and cross-resistance to the second phage. The extent and strength of this phage-phage competition and genetic loci conferring phage resistance, are, however, P. aeruginosa genotype dependent. Nevertheless, adding phages sequentially resulted in their unimpeded replication with no significant increase in bacterial host lysis. These results highlight the interrelatedness of phage-phage competition, phage resistance and specific bacterial growth state (planktonic/biofilm) in shaping the interplay among P. aeruginosa and virulent phages.

Project description:The Pseudomonas aeruginosa quorum-sensing (QS) systems contribute to bacterial homeostasis and pathogenicity. Although the AraC family transcription factor VqsM has been characterized to control the production of virulence factors and QS signaling molecules, its detailed regulatory mechanisms still remain elusive. Here, we report that VqsM directly binds to the lasI promoter region, and thus regulates its expression. To identify additional targets of VqsM in P. aeruginosa PAO1, we performed chromatin immunoprecipitation followed by high-throughput DNA sequencing (ChIP-seq) which detected 48 enriched loci harboring VqsM-binding peaks in P. aeruginosa genome. The direct regulation of these genes by VqsM has been confirmed by Electrophoretic mobility shift assays (EMSAs) and quantitative real-time polymerase chain reactions (qRT-PCR). A VqsM-binding motif is found by using MEME suite and verified by footprint assays in vitro. In addition, VqsM directly binds to the promoter regions of antibiotic resistance regulator NfxB and the master type III system regulator ExsA. Notably, the vqsM mutant displayed more resistance to two types of antibiotics and promoted bacterial survival in a mouse model, compared to the wild type PAO1 strain. Collectively, this work provides new cues to better understand the detailed regulatory networks of QS systems, T3SS, and antibiotic resistance.

Project description:Although Pseudomonas aeruginosa is an opportunistic pathogen that does not often naturally infect alternate hosts such as plants, the plant-P. aeruginosa model has become a widely recognized system for identifying new virulence determinants and studying pathogenesis of this organism. Here we examine how both host factors and P. aeruginosa PAO1 gene expression are affected in planta after infiltration into incompatible and compatible cultivars of tobacco (Nicotiana tabacum L.) Nicotiana tabacum has a resistance gene (N) against tobacco mosaic virus; and although resistance to PAO1 infection correlated to the presence of a dominant N-gene, our data suggests that it is not a factor in resistance against Pseudomonas. We did observe that the resistant tobacco cultivar had higher basal levels of salicylic acid, and a stronger salicylic acid response upon infiltration of PAO1. Salicylic acid acts as a signal to activate defense responses in plants, limiting the spread of the pathogen and preventng access to nutrients. It has also been shown to have direct virulence modulating effects on P. aeruginosa. We also examined host effects on the pathogen by analyzing global gene expression profiles of bacteria removed from the intracellular fluid of the two plant hosts. We discovered that the availability of micronutrients, particularly sulfate and Pi, are important factors in in planta pathogenesis, and that the amounts of these nutrients made available to the bacteria may in turn have an effect on virulence gene expression. Indeed, there are several reports suggesting that P. aeruginosa virulence is influenced in mammalian hosts by the availability of iron and by levels of O2. Experiment Overall Design: Pseudomonas aeruginosa cells were removed from leaf tissue 24 hours post-infiltration and RNA was directly extracted from these cells. Comparisons are between cells removed from a susceptible cultivar of Nicotiana tabacum (cv. Samsun) and a resistant cultivar (cv. Xanthi). Three biological replicates per cultivar were analyzed.

Project description:In the arms race of bacterial pathogenesis, bacteria produce an array of toxins and virulence factors that disrupt host processes while hosts respond with immune countermeasures. One key virulence mediator of the ubiquitous, opportunistic, extracellular pathogen Pseudomonas aeruginosa is the iron-binding siderophore pyoverdin (PMID:10722571;PMID: 8550201). The mechanisms used by pyoverdin to acquire iron from the host remain incompletely elucidated. Here we demonstrate that mitochondria represent an important target for iron acquisition and that exposure to this toxin results in loss of mitochondrial membrane potential, altered mitochondrial dynamics, and mitophagy in both Caenorhabditis elegans and mammalian cells. We also show that animal mitophagy protects the consequences of siderophore activity, conferring resistance to pyoverdin-mediated host killing. In C. elegans, the conserved autophagic genes bec-1/BECN1 and lgg-1/LC3, and the mitophagic regulator pink-1/PINK1 are required for iron chelator-elicited mitochondrial turnover and provide protection against iron sequestration by P. aeruginosa, likely by ameliorating the mitochondrial damage. While autophagic mechanisms have been implicated in the destruction of intracellular bacteria via a process called “xenophagy” (PMID: 24005326), our findings represent the first report of resistance to an extracellular pathogen being conferred by authentic autophagic activity that targets host organelles.

Project description:Pseudomonas aeruginosa is a Gram-negative bacterium that is notorious for infections in the airway of cystic fibrosis (CF) subjects. Often, these infections become chronic, leading to higher morbidity and mortality rates. Bacterial quorum sensing (QS) coordinates the expression of virulence factors and the formation of biofilms at a population level. QS has become the focus of attention for development of alternatives to antimicrobials targeting P. aeruginosa infections. However, a better understanding of the bacteria-host interaction, and the role of QS in infection, is required. In this study, we set up a new P. aeruginosa infection model, using 2D airway organoids derived from healthy and CF individuals. Using dual RNA-sequencing, we dissected their interaction, focusing on the role of QS. As expected, P. aeruginosa induced epithelial inflammation. However, QS signaling did not affect the epithelial airway cells. The epithelium influenced several infection-related processes of P. aeruginosa, including metabolic changes, induction of type 3 and type 6 secretion systems (T3SS and T6SS), and increased expression of antibiotic resistance genes, including mexXY efflux pump and several porins. Interestingly, the epithelium influenced the regulation by QS of the type 2 (T2SS) and T6SS. Finally, we compared our model with in vivo P. aeruginosa transcriptomic datasets, from samples directly isolated from the airways of CF subjects. This shows that our model recapitulates important aspects of in vivo infection, like enhanced denitrification, betaine/choline metabolism, increased antibiotic resistance, as well as an overall decrease of motility-related genes. This relevant infection model is interesting for future investigations, helping to reduce the burden of P. aeruginosa infections in CF.

Project description:The widespread presence of antibiotic-resistant bacteria in the environment has been recognized as an important emerging environmental contaminant. Hospital wards, as a special public indoor environment, are of great concern for the risks associated with this emerging environmental contaminant. Pseudomonas aeruginosa, a common nosocomial bacterium, is a contamination risk in the hospital environment due to its drug resistance and transmission of virulence factors. Notably, the antimicrobial peptide-sensing two-component system (TCS) ParRS and CprRS have been implicated in dynorphin-induced signaling, but the underlying Manuscript2 mechanism has remained elusive. In this study, we performed proteomic analysis to systematically investigate the contributions of ParRS and CprRS to P. aeruginosa pathogenesis and dynorphin-induced resistance to polymyxins. Additionally, we characterized the significance of the extracellular sensor domains of ParS and CprS in dynorphin perception. Furthermore, through structural biology, we identified additional TCS sensors with similar extracellular domain conformations, which also directly interacted with dynorphin in vitro. This suggests convergent evolution in different bacterial TCSs for host-derived synthetic peptide signal transmitting. Our findings establish a link between CAMPs resistance associated TCSs and virulence regulation of common nosocomial bacteria. This further illustrates the danger of this emerging contaminant for the environment and humans.