Project description:Transposon insertion site sequencing (TIS) is a powerful method for associating genotype to phenotype. However, all TIS methods described to date use short nucleotide sequence reads which cannot uniquely determine the locations of transposon insertions within repeating genomic sequences where the repeat units are longer than the sequence read length. To overcome this limitation, we have developed a TIS method using Oxford Nanopore sequencing technology that generates and uses long nucleotide sequence reads; we have called this method LoRTIS (Long Read Transposon Insertion-site Sequencing). This experiment data contains sequence files generated using Nanopore and Illumina platforms. Biotin1308.fastq.gz and Biotin2508.fastq.gz are fastq files generated from nanopore technology. Rep1-Tn.fastq.gz and Rep1-Tn.fastq.gz are fastq files generated using Illumina platform. In this study, we have compared the efficiency of two methods in identification of transposon insertion sites.

Project description:The yeast Saccharomyces cerevisiae is a highly powerful model for systems genetics. While the advent of ordered deletion libraries has considerably facilitated yeast screening, it has also narrowed the diversity of screenable variants and precluded the exploration of the non-coding genome. Here, we present a versatile, time- and work-efficient method to functionally explore the yeast genome at an unprecedented throughput and resolution, using saturated transposon mutagenesis coupled to high-throughput sequencing. SAturated Transposon Analysis in Yeast (SATAY) allows the one-step mapping of all genetic loci in which a transposon can be inserted without disrupting a function necessary for cell growth. SATAY is especially suited to discover loci important for growth in various conditions. Here, we demonstrate that SATAY can be used to (2) reveal genetic interactions in single and multiple mutant strains, (1) reveal drug-resistant and -sensitive mutants, (3) detect not only essential genes, but also essential functional protein domains, and (4) generate not only null alleles, but also other informative genetic variants. Thus SATAY allows to easily explore the yeast genome at an unprecedented resolution and throughput.

Project description:In order to study the effects of a mutation to the transcriptional termination regulator Rho (referred to as rho*), we made use of expression microarrays to observe the direct and indirect effects of rho* on gene expression. In addition, we used arrays to map the fitness of strains from transposon mutagenized libraries under four conditions, showing that in each case the majority of genes with significant fitness effects were dependent on the genotype at rho. For expression arrays, we performed two-color microarrays comparing transcript levels in rho* and wild type cells during exponential growth in glucose minimal media. For selection experiments, transposon insertions were mapped through selective amplification of genomic regions adjacent to them. We then measured the fitness effects of insertions throughout the genome using two-color microarrays, comparing amplified DNA from a population grown under a selective condition of interest to an isogenic control population grown under a reference condition (glucose minimal media). All arrays were performed in duplicate, and the source material for the duplicates came from separate biological replicates.

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:The aim of the experiment was to assay every gene in the Escherichia coli genome to identify those that contribute to competition with Pseudomonas aeruginosa. A library of transposon-insertion mutants was grown overnight either alone or together with an equal starting number of P. aeruginosa cells. The experiment was also conducted in the presence or absence of glucose to interrogate the effect of a plentiful supply of carbon source. DNA sequencing was then used to reveal the locations of the transposons in every mutant. By comparing the numbers of each mutant between conditions, information can be gained about the relative fitness of that mutant under the conditions tested.

Project description:This sample was prepared with a modified version of the Tn4001 transposon commonly used in Mycoplasmas. This transposon is described to work more efficiently in Mycoplasma agalactiae and, by extension, in other Mycoplasma species. This sample was prepared transforming this bacteria with a newly designed transposon named pMTnGm-SynMyco to test its efficiency by Transposon Sequencing tracked by deep sequencing.

Project description:Lipid intermediates derived from sphingolipid metabolism are crucial regulators of mitochondrial function from yeast to humans. Among these intermediates, trans-2-hexadecenal (t-2hex) within the sphingolipid degradation pathway exhibits remarkable efficiency in inducing mitochondria-mediated cell death. In yeast cell cultures, the addition of t-2-hex triggers complete disintegration of the mitochondrial network, leading to subsequent cell death. This effect is particularly pronounced in yeast cells lacking the activity of the t-2-hex degrading enzyme, Hfd1. However, the molecular mechanisms of t-2-hex induction of mitochondrial dysfunction are completely unknown. In this project, we want to exploit the unprecedented power of yeast genetics to unveil novel genetic determinants involved in t-2-hex's pro-apoptotic function. To accomplish this, we employed the SATAY method, which combines saturated transposon mutagenesis with high-throughput sequencing to functionally explore the yeast genome. In our screening approach, hfd1 mutant cells harboring a plasmid-encoded inducible MiniDs transposon were induced by galactose, resulting in extensive integration of the transposon throughout the yeast genome. Cells with the plasmid excised and the transposon genomically integrated were pooled together, creating a high-density transposon library comprising approximately 2.3E+06 independent insertion mutants. Subsequently, the pooled mutant library was subjected to treatment with the mitochondria-mediated death inducer, t-2-hexadecenal. As a control, cells were also incubated with the solvent dimethyl sulfoxide (DMSO), in which hexadecenal is dissolved. Following the treatments, cells were collected for genomic DNA extraction and digestion, using restriction enzymes with frequent four-base pair recognition sites. The resulting library fragments were circularized using T4 DNA ligase, and the transposon-genome junctions were selectively amplified through PCR with outward-facing primers specific to the transposon. Finally, the pooled and purified amplicons were subjected to massive sequencing on an Illumina MiSeq platform. The obtained sequences were then aligned to the reference genome of Saccharomyces cerevisiae, allowing for the mapping of transposon insertions and the calculation of transposon counts per gene. This project enabled the identification of genes required for the resistance and toxicity to t-2hex.

Project description:Most bacteria can form biofilms, which typically have a life cycle from cells initially attaching to a surface before aggregation and growth produces biomass and an extracellular matrix before finally cells disperse. To maximise fitness at each stage of this life cycle, and given the different events taking place within a biofilm, temporal regulation of gene expression is essential. We recently described the genes required for optimal fitness over time during biofilm formation in Escherichia coli using a massively parallel transposon mutagenesis approach called TraDIS-Xpress. We have now repeated this study in Salmonella enterica serovar Typhimurium to determine the similarities and differences in biofilm formation through time between these species. This work deepens understanding of the core requirements for biofilm formation in the Enterobacteriaceae whilst also identifying some genes with specialised roles in biofilm formation in each species.

Project description:The aim of the experiment was to assay every gene in the E. coli genome to identify those that contribute to increased or decreased susceptibility to the beta-lactam antibiotic meropenem. A library of transposon-insertion mutants was grown overnight in the presence or absence of a range of concentrations of meropenem. Different concentrations of IPTG were also used to promote expression from a transposon-encoded promoter to assay the effects of increased transcription for each gene. DNA sequencing was then used to reveal the locations of the transposons in every mutant. By comparing the numbers of each mutant between conditions, information can be gained about the relative fitness of that mutant under the conditions tested.

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.