Project description:Biofilms undergo a life cycle where cells attach to a surface, grow and produce a structured community before dispersing to seed biofilms in new environments. Progression through this life cycle requires controlled temporal gene expression to maximise fitness at each stage. Previous studies have focused on the essential genome for the formation of a mature biofilm, but here we present an insight into the genes involved at different stages of biofilm formation. We used TraDIS-Xpress (a massively parallel transposon mutagenesis using transposon-located promoters to assay expression of all genes in the genome) to determine how gene essentiality and expression affects the fitness of E. coli growing as a biofilm on glass beads after 12, 24 and 48 hours. An E. coli transposon mutant library of approximately 800,000 unique mutants was grown on glass beads, and a planktonic sample was taken alongside this at each time point to compare gene essentiality and expression at each time point.

Project description:This study investigates the mechanisms employed by Salmonella to colonise and establish itself on fresh produce at critical timepoints following infection. We established an alfalfa infection model and compared the findings to those obtained from glass surfaces. Our research revealed dynamic changes in the pathways associated with biofilm formation over time, with distinct plant-specific and glass-specific mechanisms for biofilm formation, alongside the identification of shared genes playing pivotal roles in both contexts.

Project description:Expression of efflux pumps is a key feature of most cells which are resistant to multiple antibiotics. This study used TraDIS-Xpress, a genome wide transposon mutagenesis technology to identify genes in Escherichia coli and Salmonella Typhimurium involved in drug efflux and its regulation. We exposed mutant libraries to the canonical efflux substrate acriflavine in the presence and absence of the efflux inhibitor phenylalanine-arginine β-naphthylamide. Comparisons between conditions identified efflux specific and drug specific responses. Known efflux associated genes were easily identified including: AcrAB-TolC, MarA, RamA and SoxS confirming specificity of the response. Further genes encoding cell envelope maintenance enzymes and products involved with stringent response activation, DNA housekeeping, respiration and glutathione biosynthesis were also identified as affecting efflux activity in both species. We identified a conserved set of pathways crucial for efflux activity in these experimental conditions which expands the list of genes known to impact efflux efficacy.

Project description:To identify novel genes modulating Candida albicans biofilm formation, a screen of 2451 overexpression strains allowed us to identify 16 genes whose overexpression significantly reduced biofilm formation. Genome-wide expression and binding analyses were conducted upon overexpression of ZCF15 and ZCF26 and wild type planktonic and biofilm cells were performed. This study has identified new sets of biofilm regulators, including ZCF15 and ZCF26 whose specific role in metabolic remodelling during C. Albicans biofilm development. Triplicates data of RNAseq data are provided here with 6 conditions including the ZCF15 and ZCF16 cases mentioned here above

Project description:We used TraDIS-Xpress to determine the mechanism of action of a novel antimicrobial compound. We found that it inhibits lipid IVA biosynthesis in both Escherichia coli and Salmonella enterica serovar Typhimurium. We also were able to determine mechanisms of synergy with colistin, through ATP biosynthesis and the BasSR signalling system.

Project description:Mapping of transposon mutant library in Enterococcus faecium during growth in Brain Heart Infusion (BHI) broth and in a semi-static biofilm model. The goal of this study was to identify factors that play a role in E. faecium biofilm formation by selection of transposon insertion mutants that lost the capacity to form biofilm in vitro.

Project description:Bacteria growing as surface-adherent biofilms are better able to withstand chemical and physical stresses than their unattached, planktonic counterparts. Using transcriptional profiling and quantitative PCR, we observed a previously uncharacterized gene, yjfO, to be upregulated during Escherichia coli MG1655 biofilm growth in a chemostat on serine-limited defined medium. A yjfO mutant, developed through targeted insertion mutagenesis, and a yjfO-complemented strain, were obtained for further characterization. While bacterial surface colonization levels (CFU/cm2) were similar in all three strains, the mutant strain exhibited reduced microcolony formation when observed in flow cells, and greatly enhanced flagellar motility on soft (0.3%) agar. Complementation of yjfO restored microcolony formation and flagellar motility to wild type levels. Cell surface hydrophobicity and twitching motility were unaffected by the presence or absence of yjfO. In contrast to the parent strain, biofilms from the mutant strain were less able to resist acid and peroxide stresses. yjfO had no significant effect on E. coli biofilm susceptibility to alkali or heat stress. Planktonic cultures from all three strains showed similar responses to these stresses. Regardless of the presence of yjfO, planktonic E. coli withstood alkali stress better than biofilm populations. Complementation of yjfO restored viability following exposure to peroxide stress, but did not restore acid resistance. Based on its influence on biofilm formation, stress response, and effects on motility, we propose renaming the uncharacterized gene, yjfO, as bsmA (biofilm stress and motility). Transcriptional profiling of duplicate biofilm and planktonic cultures of E. coli MG1655 grown in serine-limited MOPS minimal media.

Project description:Background: Biofilm formation by Salmonella species enhances the capacity of these pathogenic bacteria to survive stresses that are commonly encountered within food processing and during host infection. The persistence of Salmonella within the food chain has become a major health concern, as biofilms can serve as a reservoir to contaminate food products. While the molecular mechanisms required for the survival of bacteria on surfaces are not fully understood, transcriptional studies of other bacteria have demonstrated that biofilm growth triggers the expression of specific sets of genes, compared with planktonic cells. Until now, most transcriptomic studies of Salmonella have focused on the effect of infection-relevant stressors on virulence and on comparing mutant and wild-type (WT). However little is known about the physiological responses taking place inside a Salmonella biofilm. Results: We have determined the transcriptomic and proteomic profiles of biofilms of Salmonella enterica serovar Typhimurium. We discovered that 124 of detectable proteins were differentially expressed in the biofilm compared with planktonic cells, and that 10% (433 genes) of S. Typhimurium genes showed a biofilm-specific pattern of transcription (i.e. a 2-fold or more change in the biofilm compared with planktonic cells). The genes that were significantly up-regulated implicated specific cellular processes in biofilm development including amino acid metabolism, cell motility, global regulation and tolerance to stress. We found that the most highly down-regulated genes in the biofilm were located on Salmonella Pathogenicity Island 2 (SPI2), but that a functional SPI2 secretion system regulator (ssrA) was required for WT biofilm formation. We identified STM0341 as a gene of unknown function that was needed for WT biofilm growth. Genes involved in tryptophan (trp) biosynthesis and transport were up-regulated in the biofilm. Deletion of trpE led to a decrease in bacterial attachment and we show that this biofilm defect is restored by exogenous tryptophan or indole. Conclusion: Biofilm growth of S. Typhimurium causes distinct changes in gene and protein expression. Our results show that aromatic amino acids make an important contribution to biofilm formation, and reveal that SPI2 genes, required for virulence in host cells, show opposing patterns of expression to biofilm-specific genes in S. Typhimurium. Overnight cultures of SL1344 grown in CFA broth were standardized to achieve an initial concentration of 10^6 CFU ml-1 and injected into a stirring influent flask containing 5 L of pre-warmed (25C) sterile CFA medium. The inoculated influent was then pumped through silicon tubing (5 mm internal diameter, Samco Silicon Products Ltd.) at 60 ml h-1 using a peristaltic pump (Minipulse 3, Gilson). The bacteria were allowed to flow through the closed system and either attach to a vertical piece of silicon tubing (1 meter length, 16 mm internal diameter, Samco Silicon Products Ltd.) or flow out into a waste reservoir. The tubing was positioned vertically to collect biofilm cells adherent to the tubing and minimise collecting bacteria that had simply sedimented. Possible backflow of media or bacteria into the influent from the silicon tubing was eliminated using media breaks. Samples taken to determine the pH of the medium or bacterial cell counts were removed via a media port located near the effluent and influent vessel, respectively. Planktonic cells were removed after 72 h of growth from the influent vessel to avoid any contamination with biofilm cells. The entire system was kept at a constant temperature of 25C and biofilm cells were isolated after 72 h of growth. All planktonic and biofilm samples were isolated from the same experimental system and used for both RNA and protein isolation. For this study, four biological replicates were performed at four different dates (Jun25, Jul5, Jul16, Oct11; as indicated in the sample title). For the dual-colour microarray hybridisations, we used Salmonella genomic DNA as the comparator which also acted as the control for spot quality. Individual labelled cDNA samples (RNA) were hybridised up to 4 times (technical replicates).

Project description:Transcriptional analysis of Clostridium difficile R20291 in biofilm formation, planktonic state and grown on blood agar RNA sequencing was performed on Clostridium difficile R20291 in three different conditions: Biofilm formation, plantonic state and grown on blood agar plates. Each condtion has 3 replicates.

Project description:Biofilm formation is an important virulence trait of the pathogenic yeast Candida albicans. Large-scale genetics strategies aimed at identifying genes involved in biofilm development are hampered by lack of a complete sexual cycle in this diploid yeast in addition to the tedious generation of homozygous gene-deletion mutants. Gene overexpression is an attractive alternative strategy for large-scale phenotypic analyses and gene-function studies. We combined gene overexpression, strain barcoding and microarray profiling to screen a library of 531 C. albicans conditional overexpression strains (~10% of the genome) for genes affecting i) planktonic cell fitness and ii) biofilm development in mixed-population experiments. We found 5 genes whose overexpression affects planktonic strain fitness, including RAD53, RAD51, PIN4, orf19.2781, all encoding (or predicted to encode) regulators of DNA-damage response or cell-cycle progression and SFL2, involved in filamentous growth. We identified 16 and 4 genes (out of 531) whose overexpression respectively increases and decreases strain occupancy within the multi-strain biofilm. Strikingly, strains with increased abundance in the multi-strain biofilm were significantly enriched for genes encoding cell wall proteins (10 genes), including the glycosylphosphatidylinositol (GPI)-anchored proteins Pga15, Pga19, Pga22, Pga59, Pga32 and Pga41. Data validation experiments using either individually- or competitively-grown overexpression and/or the respective knock-out strains revealed that the identified genes differently contribute to biofilm formation during specific stages of biofilm development, including increased or decreased substrate adherence (IHD1, PGA32, PGA37, PGA15, PGA22, PGA59 and PGA19) or biofilm biomass growth and cohesion (PGA15, PGA59 and PGA22). In line with the hypothesis that cell wall genes contribute to biofilm development, we show that strains overexpressing PGA15 or PGA22 display altered cell wall structures. Our study reveals that cell wall proteins are important actors during C. albicans biofilm formation and illustrates the powerful use of signature tagging in conjunction with gene overexpression for the identification of genes involved in processes pertaining to C. albicans virulence. A total of 8 samples are included in this study. For fitness profiling of planktonic cells, 2 biological replicates were analyzed (samples Pool_Fitness_planktonic_rep1 and Pool_Fitness_planktonic_rep2). For quantification of strain abundance during biofilm formation, 6 biological replicates were analyzed (Pool_Biofilm_rep1, Pool_Biofilm_rep2, Pool_Biofilm_rep3, Pool_Biofilm_rep4, Pool_Biofilm_rep5, Pool_Biofilm_rep6). Genomic DNA was purified and used as template to PCR-amplify barcodes, which were then used as probes for microarray hybridization. This experiment was done twice independently. For quantification of strain abundance during multi-strain biofilm formation, strain pools were grown in minimal GHAUM medium with or without doxycycline, each inoculum was then diluted to an OD600 of 1 in fresh minimal GHAUM medium with or without doxycycline and left at room temperature for 30 min, to allow further overexpression. Plastic slides (ThermanoxM-bM-^DM-"; Nunc) were immersed in the inoculum for 30 min at room temperature to allow adhesion of cells to the plastic substrate. The plastic slides were then transferred to the glass vessel of a 40-mL incubation chamber. This vessel has two glass tubes inserted to drive the entry of medium and air, while used medium is evacuated through a third tube. The flow of medium is controlled by a recirculation pump (IsmatecM-BM-.) set at 0.6 mL.min-1 and pushed by pressured air supplied at 105 Pa, conditions minimizing planktonic phase growth and promoting biofilm formation. The chambers with the plastic substrate were incubated at 37C and biofilms were grown for 40h followed by genomic DNA extraction, barcode amplification and differential labeling (dox-treated samples with Cy5, untreated samples with Cy3) and hybridization to barcode microarrays.