Project description: Not available

Project description:Microarray analysis was used to identify changes in the level of transcription of genes in P. aeruginosa drip flow biofilms in response to ciprofloxacin and tobramycin exposure. This data was evaluated and used to select strains that carry transposon mutations in genes that might play a role in antibiotic tolerance of biofilms. The strains were evaluated for defects in biofilm tolerance.

Project description:Microarray analysis was used to identify changes in the level of transcription of genes in P. aeruginosa drip flow biofilms in response to ciprofloxacin and tobramycin exposure. This data was evaluated and used to select strains that carry transposon mutations in genes that might play a role in antibiotic tolerance of biofilms. The strains were evaluated for defects in biofilm tolerance. Four drip flow biofilm conditions with three replicates each: (1) baseline controls at 72 hours, (2) tobramycin treated for 12 hours past baseline, (3) ciprofloxacin treated for 12 hrs past baseline, and (4) no treatment for 12 hrs past baseline.

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Project description:Biofilms are the most common cause of bacterial infections in humans and notoriously hard to treat due to their ability to withstand antibiotics and host immune defenses. To overcome the current lack of effective antibiofilm therapies and guide future design, the identification of novel gene targets is crucial. In this regard, transcriptional regulators have been proposed as promising targets for antimicrobial drug design, since they simultaneously affect multiple genes, typically lack human orthologs, and can be inactivated by small molecules that prevent dimerization. Therefore, a Transposon insertion sequencing approach was employed to systematically identify regulatory genes phenotypically affecting biofilm growth in Pseudomonas aeruginosa PA14. A screen of a pool of 300,000 transposon insertion mutants identified 349 genes involved in biofilm growth on hydroxy apatite, including 47 regulators. Detection of 19 regulatory genes participating in well-established biofilm pathways validated the results. An additional 28 novel prospective biofilm regulators suggested the requirement of multiple one-component transcriptional regulators. Defect phenotypes were confirmed for five one-component transcriptional regulators PA14_43720, PA14_56430, PA14_36180, arsR and merD as well as the protein kinase yeaG, which have not been implicated in biofilm growth before. Promisingly, the transcriptional regulator PA14_43720 displayed a conserved role in biofilm growth since its ortholog in P. aeruginosa strain PAO1 was also required for biofilm growth. Overall, our results highlighted that the gene network driving biofilm growth is complex and involves regulators beyond the primarily studied groups of two-component systems and cyclic diguanylate signaling proteins.

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Project description:Biofilms are ubiquitous in natural, medical, and engineering environments. While most antibiotics that primarily aim to inhibit cell growth may result in bacterial drug resistance, biofilm inhibitors do not affect cell growth and there is less chance of developing resistance. This work sought to identify novel, non-toxic and potent biofilm inhibitors from Streptomyces bacteria for reducing the biofilm formation of Pseudomonas aeruginosa PAO1. Out of 4300 Streptomyces strains, one species produced and secreted peptide(s) to inhibit P. aeruginosa biofilm formation by 93% without affecting the growth of planktonic cells. Global transcriptome analyses (DNA microarray) revealed that the supernatant of the Streptomyces 230 strain induced phenazine, pyoverdine, and pyochelin synthesis genes. Electron microscopy showed that the supernatant of Streptomyces 230 strain reduced the production of polymeric matrix in P. aeruginosa biofilm cells, while the Streptomyces species enhanced swarming motility of P. aeruginosa. Therefore, current study suggests that Streptomyces bacteria are an important resource of biofilm inhibitors as well as antibiotics.