Project description:Salmonella invasion of non-phagocytic cells is a dynamic process that requires the translocation of effector proteins into host cells by a type III secretion system (T3SS1) encoded on Salmonella pathogenicity island 1 (SPI1). The signals involved in T3SS1 induction in vivo are not known, but SPI1-induced invasive Salmonella can be prepared by growth in synthetic media. Here we compared two different methods of preparing SPI1-induced bacteria by using a combination of transcriptome analysis, a single-cell reporter assay and intracellular gene expression analysis to reveal clear differences between these two bacterial populations that are reflected in their ability to interact with cultured epithelial cells. Invasion efficiency and intracellular replication were greater for bacteria grown with aeration to late-log phase compared to those grown without aeration to stationary phase. No significant differences in SPI1 regulon expression were revealed by transcriptome analysis. By contrast, surface appendage and stress response genes were considerably changed. Single cell analyses of gene expression revealed variation in the frequency of SPI1-induced bacteria and a correlation between SPI1-induction and the presence of flagella. The expression of virulence genes following invasion of cultured epithelial cells was also found to be predetermined by pre-invasion growth conditions. Key words: epithelial, flagella, invasion, motility, Salmonella-containing vacuole, treatment of shaking versus treatment of static growth conditions for St-SL1344

Project description:Glyceraldehyde-3-phopshate dehydrogenase (GAPDH) is well-known for its involvement in numerous non-metabolic processes inside the mammalian cells. Alternative functions of prokaryotic GAPDH are mainly deduced from its extracellular localization and the ability to bind to selected host proteins. Data on its participation in intracellular bacterial processes are scarce as there is so far only one study dealing with this issue. We previously reported several evidence that the GAPDH homologue of Francisella tularensis, GapA, might also exert additional non-enzymatic functions. To follow up our former observation, here we decided to find out GapA’s interacting partners within the bacterial proteome to explore its new roles at the intracellular level. The quantitative proteomics approach based on stable isotope labelling of amino acids in cell culture (SILAC) in combination with affinity purification and mass spectrometry enabled us to identify 18 proteins potentially interacting with GapA, six of those interactions were further confirmed by alternative methods. Half of the identified proteins were involved in non-metabolic processes. Further analysis together with the quantitative label-free comparative analysis of proteomes isolated from the wild-type strain and strain with deleted gapA gene suggests that the GapA is implicated in DNA repair processes. The absence of GapA promotes secretion of its most potent interaction partner, the hypothetical protein with peptidase propeptide domain (PepSY) indicating its impact on subcellular distribution of some proteins.

Project description:Antibodies against DnaD and DnaB were used to immunoprecipitate genome bound complexes of these proteins in fast growing and slow growing cells as well as in two strains with a constitutively induced Pxis promoter or repressed Pxis promoter. CHIP-chip analysis was then carried out to determine their sites of interaction in vivo. CHI-chip analysis was carried out by Oxford Gene Technology (OGT) wwho also designed and prepared the arrays. Antibodies against DnaD and DnaB were used to immunoprecipitate genome bound complexes of these proteins in fast growing and slow growing cells, as well as in two strains with a constitutively induced Pxis promoter or repressed Pxis promoter. CHIP-chip microarray analysis was carried out by OGT who obtained the raw data. Data were visualized in CHIP Browser provided by OGT.

Project description:Scaling up the functioning of synthetic circuits from microplates to bioreactors is far from trivial to achieve. We here test the scalability performance of a previously developed growth switch for increasing product yields in bacteria, based on external control of RNA polymerase expression. We show that, in liter-scale bioreactors operating in fed-batch mode, growth-arrested Escherichia coli cells are able to convert glucose to glycerol at an increased yield. A multi-omics quantification of the physiology of the cells shows that apart from acetate production, few metabolic side-effects occur, while a number of specific responses to growth slow-down and growth arrest are launched on the transcriptional level. These responses include the downregulation of genes involved in growth-associated processes, such as amino acid and nucleotide metabolism and translation, and the upregulation of heat shock genes. Interestingly, these transcriptional responses are buffered on the proteomic level, probably due to the strong decrease of the total mRNA concentration after the diminution of transcriptional activity and the absence of growth dilution of proteins. This transforms the growth-arrested cells in “bags of proteins“ with a functioning metabolism. More generally, the analysis shows that physiological characterization of bacterial cells hosting a synthetic circuit may reveal complex patterns of adaptation on different time-scales, dynamically interacting with the bioreactor environment.

Project description:The transcription profile of Candida glabrata grown under two different Niacin limitation conditions were determined. Condition 1 is comparing log phase C. glabrata cells (O.D. 0.5-0.6) grown in synthetic medium containing 0.016 uM versus 3.25 uM nicotinic acid (NA), a common form of Niacin. The NA concentration of 3.25 uM is the standard concentration in synthetic complete (SC) medium. Condition 2 is comparing log phase C. glabrata cells (O.D. 0.4-0.6) grown in 3 individual human urine samples (supplemented with 2% glucose) versus in SC medium. Keywords: transcriptional profiling by microarray GSM151863, GSM151869 are dye-swap experiment #1 and GSM151880, GSM151881 are dye-swap experiment #2 for Niacin limitation condition 1. GSM151934, GSM152116 are dye-swap experiment #1, GSM152118, GSM152119 are dye-swap experiment #2 and GSM152130, GSM152131 are dye-swap experiment #3 for Niacin limitation condition 2.

Project description:This data contained within this entry was produced as part of a study that included differential RNA-sequencing and microarray analysis. The results of the latter two have also been deposited in GEO Duplicate cultures of Propionibacterium acnes strain KPA171202 were grown exponentially in Holland Synthetic Medium (Holland et al.1979. J Appl Bacteriol 47: 383), which supports reproducible anaerobic growth. Samples were taken following subculture with and without potassium downshift (i.e. removal from medium).

Project description:Two genetic selection systems that couple metabolite hydroxylation or methylation of small molecules to growth of Escherichia coli are presented in this study. One system targets pterin-dependent hydroxylation (tBPt) while another focuses on S-adenosylmethionine-dependent methylation (SAM). Using adaptive laboratory evolution with growth selection, these two systems are demonstrated to not only achieve in vivo directed evolution of enzymes involved in human hormone biosynthesis but also reveal non-intuitive host factors that elude existing synthetic biology approaches. Raw sequencing data for the relevant strains generated in this study are presented here.

Project description:Citramalate is a chemical of potential industrial importance. Efficient fermentations have been developed using recombinant E. coli as the chassis. The experiments explore the transcriptional reprogramming that occurs upon induction of citramalate production.

Project description:The phi X 174 bacteriophage was first sequenced in 1977, and has since become the most widely used standard in molecular biology and next-generation sequencing. However, with the advent of affordable DNA synthesis and de novo gene design, we considered whether we could engineer a synthetic genome, termed SynX, specifically tailored for use as a universal molecular standard. The SynX genome encodes 21 synthetic genes that can be in vitro transcribed to generate matched mRNA controls, and in vitro translated to generate matched protein controls. This enables the use of SynX as a matched control to compare across genomic, transcriptomic and proteomic experiments. The synthetic genes provide qualitative controls that measure sequencing accuracy across k-mers, GC-rich and repeat sequences, as well as act as quantitative controls that measure sensitivity and quantitative accuracy. We show how the SynX genome can measure DNA sequencing, evaluate gene expression in RNA sequencing experiments, or quantify proteins in mass spectrometry. Unlike previous spike-in controls, the SynX DNA, RNA and protein controls can be independently and sustainably prepared by recipient laboratories using common molecular biology techniques, and widely shared as a universal molecular standard.

Project description:We generated a collection of 13 plasmids, with each plasmid containing a variant of a CRISPR protospacer targeted by spacer 8 of the E. coli CRISPR-I array. We transformed the plasmids as a pool into delta cas3 E. coli cells expressing all other cas genes constitutively. We then transformed these cells with either an empty vector or a plasmid expressing the Cas3 nuclease. DNA surrounding the protospacers was PCR-amplified and sequenced.