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:Antibiotic resistance is one of the most pressing threats to human health, yet recent work highlights how loss of resistance may also drive pathogenesis in some bacteria. In two recent studies, we found that in vitro beta-lactam antibiotic and nutrient stresses faced during infection selected for the genetic inactivation of the Pseudomonas aeruginosa (Pa) antibiotic efflux pump mexEFoprN. Unexpectedly, efflux pump mutations increased Pa virulence during infection; however, neither the prevalence of efflux pump inactivating mutations in real human infections, nor the mechanisms driving increased virulence of efflux pump mutants were known. We hypothesized that human infection would select for efflux pump mutations that drive increased virulence in Pa clinical isolates. Using genome sequencing of hundreds of Pa clinical isolates, we show that mexEFoprN efflux pump inactivating mutations are enriched in Pa cystic fibrosis isolates relative to Pa intensive care unit clinical isolates. Combining RNA-seq, metabolomics, genetic approaches, and infection models we show that efflux pump mutants increase expression of two key Pa virulence factors, elastase and rhamnolipids, which increased Pa virulence and lung damage during both acute and chronic infections. We show that increased virulence factor production was driven by increased Pseudomonas quinolone signal levels, and this mechanism of increased virulence held true in both a representative ICU clinical isolate and the notorious CF Pa Liverpool epidemic strain. Together, our findings suggest that mutations inactivating antibiotic resistance mechanisms could increase patient mortality and morbidity.

Project description:Candida auris is an emerging fungal pathogen known for its high resistance to fluconazole, the most commonly prescribed antifungal. However, the genetic regulators of fluconazole susceptibility remain insufficiently understood in C. auris. Using a pooled screen of piggyBac (PB) transposition mutants, we identify significant enrichment of mitochondrial genes whose inactivation causes reduced fluconazole susceptibility. Genome-wide genetic interaction analysis of a representative mitochondrial gene-deleted mutant, pet309Δ, implicates that mitochondrial dysfunction reduces fluconazole susceptibility by enhancing Cdr1 efflux activity post-transcriptionally and through the vacuolar calcium pump homolog Cdt1. We further demonstrate that Cdt1, beyond its canonical calcium-pumping function, mediates fluconazole efflux, evidenced by its fluconazole-induced, calcineurin-dependent plasma membrane localization and dependence on ATP hydrolysis. Additionally, Cdt1 accelerates the evolution of fluconazole resistance, and its transcript levels correlate with susceptibility across clinical isolates. Our findings define a novel role for Cdt1 in fluconazole efflux in C. auris.

Project description:Pseudomonas aeruginosa is an opportunistic human pathogen, which is ubiquitous in the environment. The environmental versatility of P. aeruginosa is often attributed to a large arsenal of active efflux pumps, low permeability of the outer membrane and extensive regulatory networks. In this study, we analyzed putative functional interplay between polyspecific drug efflux pumps of Resistance-Nodulation-Division (RND) superfamily of proteins and GacSA two-component regulatory system. RND transporters are the major contributors to antibiotic resistance and survival under various environmental stresses, whereas GacSA is a global regulator and governs critical lifestyles during human colonization. We found that the inactivation of either RND pumps or gacS induces broad, partially overlapping responses in lifestyle, virulence and metabolic programs that are more pronounced during exponential than stationary phase. GacSA and RND efflux pumps induced opposite responses in gene expression of P. aeruginosa, whereas the overexpression of GacS was additive with the deletion of efflux pumps in gene expression and under growth conditions typically associated with human infections such as elevated temperature and iron deprivation. We conclude that RND efflux and GacSA networks partially overlap with each other.

Project description:Constitutive overexpression of the Mdr1 efflux pump is an important mechanism of acquired drug resistance in the yeast Candida albicans. The zinc cluster transcription factor Mrr1 is a central regulator of MDR1 expression, but other transcription factors have also been implicated in MDR1 regulation. To better understand how MDR1-mediated drug resistance is achieved in this important fungal pathogen, we studied the interdependence of Mrr1 and two other MDR1 regulators, Upc2 and Cap1, in the control of MDR1 expression. A mutated, constitutively active Mrr1 could upregulate MDR1 and confer drug resistance in the absence of Upc2 or Cap1. On the other hand, Upc2 containing a gain-of-function mutation only slightly activated the MDR1 promoter, and this activation depended on the presence of a functional MRR1 gene. In contrast, a C-terminally truncated, activated form of Cap1 could upregulate MDR1 in a partially Mrr1-independent fashion. The induction of MDR1 expression by toxic chemicals occurred independently of Upc2, but required the presence of Mrr1 and also partially depended on Cap1. Transcriptional profiling and in vivo DNA binding studies showed that a constitutively active Mrr1 binds to and upregulates most of its direct target genes in the presence or absence of Cap1. Therefore, Mrr1 and Cap1 cooperate in the environmental induction of MDR1 expression in wild-type C. albicans, but gain-of-function mutations in either of the two transcription factors can independently mediate efflux pump overexpression and drug resistance. We endeavored to determine how the function of a gain-of-function allele of MRR1 (shown to confer high-level azole resistance) is affected when the CAP1 gene is disrupted.

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:In this study, we investigated the role of efflux pump genes in linezolid resistance. M. tuberculosis H37Rv cultures were exposed to sub-inhibitory concentrations of linezolid (¼ MIC) for 24 hours, and transcriptomic analysis was performed to identify upregulated genes. Of the 120 genes involved in cell wall processes, 9/120 (7.5%) were efflux pump genes, primarily belonging to the ATP-binding cassette (ABC), major facilitator superfamily (MFS), resistance nodulation division (RND), and small multidrug resistance (SMR) families. qRT-PCR, performed at 1/2, 1/4 and 1/8 MIC of linezolid, confirmed the RNA-seq results, showing that 8/9 (88.88%) of the efflux pump genes were upregulated at 1/8 MIC of linezolid, indicating that this concentration is optimal for studying efflux pump activity. These findings not only identify 1/8 MIC as optimum concentration for efflux pump studies after linezolid exposure, they also highlight the significant role of efflux pumps in linezolid resistance, providing potential targets for further research on efflux pumps in clinical isolates of M. tuberculosis.

Project description:Antibiotic resistance continues to rise as a global health threat. Novel anti-virulence strategies diminish the drive for evolutionary pressure, but still hinder a pathogen’s ability to infect a host. Treatment of the highly virulent Pseudomonas aeruginosa strain PA14 with virulence inhibitors (R-2 and R-6) elicited widely varying transcriptional profiles. Of interest, expression of a family of resistance-nodulation-division (RND) efflux pumps implicated in the intrinsic drug resistance of P. aeruginosa, was significantly altered by R-2 and R-6 treatment. While structurally similar, these inhibitors caused differential expression of various RND efflux pumps within the Mex family—R-2 treatment stimulated expression of mexEF-oprN while R-6 treatment led to increased mexAB-oprM expression. Further expansion into a small library of virulence inhibitors revealed chemical motifs that trigger increases in RND efflux pump expression. Additionally, activation of these efflux pumps suggests low accumulation of virulence inhibitors in WT PA14. Treatment of an efflux pump-deficient strain with R-2 or R-6 resulted in inhibition of several virulence factors, for example R-2 was found to abolish swimming motility. Collectively, treatment with either R-2 or R-6 gives rise to a convoluted transcriptomic response, confounded by the impact of efflux pump expression on the system. However, understanding the moieties that lead to high expression of the efflux pumps enables further rational design of novel virulence inhibitors that do not cause RND efflux pump activation.

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.