Project description:Septoria leaf blotch is a worldwide threat for wheat and mainly controlled by the application of synthetic fungicides. The fungal pathogen responsible for this disease, Zymoseptoria tritici, was shown as highly adaptable to its host plant, but also to fungicide challenge. Over the past decades it developed resistance to most fungicides due to target site modifications. Recently isolated strains showed cross-resistance to diverse fungicides and to unrelated drugs, suggesting a resistance mechanism that seems rarer in phytopathogenic fungi, known as multidrug resistance (MDR) in other organisms. In this study we show for two Z. tritici MDR strains, MDR6 and MDR7, enhanced prochloraz efflux sensitive to the modulators amitryptiline and chlorpromazine. Efflux was also inhibited by verapamil in the MDR7strain. Transcriptomics revealed several overexpressed transporter genes in both MDR strains, out of which the expression of the MgMFS1 transporter gene was the strongest and constitutively high in tested MDR field strains. Its inactivation in the MDR6 strain abolished resistance to fungicides with different modes of action revealing its involvement in the MDR phenomenon in Z. tritici. A total of four strains were compared, two sensitive (IPO323, S6) and two MDR strains (09-ASA-3apz; 09-CB01) with three replicates each. All strains were grown in liquid YPD medium to exponential growth.

Project description:Septoria leaf blotch is a worldwide threat for wheat and mainly controlled by the application of synthetic fungicides. The fungal pathogen responsible for this disease, Zymoseptoria tritici, was shown as highly adaptable to its host plant, but also to fungicide challenge. Over the past decades it developed resistance to most fungicides due to target site modifications. Recently isolated strains showed cross-resistance to diverse fungicides and to unrelated drugs, suggesting a resistance mechanism that seems rarer in phytopathogenic fungi, known as multidrug resistance (MDR) in other organisms. In this study we show for two Z. tritici MDR strains, MDR6 and MDR7, enhanced prochloraz efflux sensitive to the modulators amitryptiline and chlorpromazine. Efflux was also inhibited by verapamil in the MDR7strain. Transcriptomics revealed several overexpressed transporter genes in both MDR strains, out of which the expression of the MgMFS1 transporter gene was the strongest and constitutively high in tested MDR field strains. Its inactivation in the MDR6 strain abolished resistance to fungicides with different modes of action revealing its involvement in the MDR phenomenon in Z. tritici.

Project description:Proteolysis targeting chimeras (PROTACs) are bifunctional molecules that induce selective protein degradation by linking an E3 ubiquitin ligase enzyme to a target protein. Here we used transporter-focused and genome-wide CRISPR/Cas9 as well as a barcoded solute carriere (SLC)-focused cDNA libraray to screen for transporters that are involved in the resistance or sensitivity to BET- and SLC9-targeting PROTACs.

Project description:Targeting the bicarbonate transporter SLC4A4 overcomes immunosuppression and immunotherapy resistance in pancreatic cancer

Project description:Drug efflux is a common resistance mechanism found in bacteria and cancer cells. Although several structures of drug efflux pumps are available, they provide only limited functional information on the phenomenon of drug efflux. Here, we performed deep mutational scanning (DMS) on the bacterial ATP binding cassette (ABC) transporter EfrCD from Enterococcus faecalis to determine the drug efflux activity profile of more than 1400 single variants

Project description:<p>Bacteria can resist antibiotics and toxic substances within demanding ecological settings, such as low oxygen, extreme acid, and during nutrient starvation. MdtEF, a proton motive force-driven efflux pump from the resistance-nodulation-cell division (RND) superfamily, is upregulated in these conditions but its molecular mechanism is unknown. Here, we report cryo-electron microscopy structures of Escherichia coli multidrug transporter MdtF within native-lipid nanodiscs, including a single-point mutant with an altered multidrug phenotype and associated substrate-bound form. We reveal that drug binding domain and channel conformational plasticity likely governs substrate polyspecificity, analogous to its closely related, constitutively expressed counterpart, AcrB. Whereas we discover distinct transmembrane state transitions within MdtF, which create a more engaged proton relay network, altered drug transport allostery and an acid-responsive increase in efflux efficiency. Physiologically, this could provide a means of xenobiotic and toxic metabolite disposal within remodelled cell membranes that presage encounters with acid stresses, as endured in the gastrointestinal tract.&nbsp;</p>

Project description:The objective of the current study was to understand the glutaraldehyde resistance mechanisms in P. fluorescens and P. aeruginosa biofilms. Glutaraldehyde is a common biocide used in various industries to control the microbial growth. Recent reports of emergence of glutaraldehyde resistance in several bacterial species motivated this study to understand the genetic factors responsible got glutaraldehyde resistance. Using a combination of phenotypic assays, chemical genetic assays and RNA-seq, we demonstrate that novel efflux pump, polyamine biosynthesis, lipid biosynthesis and phosphonate degradation play significant role in glutaraldehyde resistance and post-glutaraldehyde recovery of Psudomonad biofilms. Examination of P. fluorescens 72 h biofilm transcriptome was elucidated upon exposure to glutaraldehyde. The results were confirmed using qRT--PCR and chemical genetic appraoches in P. fluorescens and P. aeruginosa.

Project description:The objective of the current study was to understand the glutaraldehyde resistance mechanisms in P. fluorescens and P. aeruginosa biofilms. Glutaraldehyde is a common biocide used in various industries to control the microbial growth. Recent reports of emergence of glutaraldehyde resistance in several bacterial species motivated this study to understand the genetic factors responsible got glutaraldehyde resistance. Using a combination of phenotypic assays, chemical genetic assays and RNA-seq, we demonstrate that novel efflux pump, polyamine biosynthesis, lipid biosynthesis and phosphonate degradation play significant role in glutaraldehyde resistance and post-glutaraldehyde recovery of Psudomonad biofilms.

Project description:Bacterial resistance to antibiotics (AB) such as β-lactams, fluoroquinolones, and aminoglycosides often emerges through mutations that alter AB targets, reduce membrane permeability, or increase the activity of AB-modifying enzymes and efflux pumps. Yet the physiological costs associated with AB resistance remain poorly understood. In Caulobacter vibrioides, a ∆tipR mutant that which constitutively upregulates the RND pump AcrAB2nodT, displays heightened sensitivity to copper (Cu), revealing a physiological vulnerability driven by the energetic burden imposed by excessive efflux activity. Deletion of acrAB2nodT in the ∆tipR background restored Cu resistance to wild-type levels, confirming the role of pump overexpression in metal sensitivity. Morphological and microscopy analyses revealed that pump overexpression leads to cell envelope defects and compromised fitness. To disentangle the effects of pump abundance from efflux activity, we engineered an AcrB2 transport-impaired mutant. This variant also rescued Cu resistance, demonstrating that high expression and active transport contribute to the observed toxicity. Notably, this sensitivity was not limited to Cu; the ∆tipR mutant also exhibited increased susceptibility to other transition metals, including zinc (Zn), nickel (Ni) and cadmium (Cd), suggesting a broader vulnerability linked to metal stress. Mechanistically, pump overexpression depleted the proton motive force, reduced ATP levels, and impaired motility, all of which are essential for Cu stress adaptation. This physiological tradeoff highlights the importance of precise efflux regulation and reveals a potential therapeutic vulnerability: targeting the cost of pump upregulation could enhance the efficacy of antimicrobial treatments.

Project description:Standard chemotherapy for lung cancer often leads to drug resistance, posing a significant clinical challenge. A major mechanism of resistance is overexpression of P-glycoprotein (P-gp), encoded by the human ATP-binding cassette subfamily B member 1 (hABCB1) gene, functioning as a drug efflux transporter. In this study, we aimed to investigate the dual role of hABCB1 overexpression in mediating resistance to chemotherapy and natural killer (NK) cell-mediated cytotoxicity in lung cancer.