Project description:The global characterization of transcriptional regulatory networks almost exclusively uses in vivo conditions, thereby providing a snapshot on multiple regulatory interactions at the same time. To complement these approaches, we developed and applied a method for characterizing bacterial promoters genome-wide by in vitro transcription coupled to transcriptome sequencing specific for native 5'-ends of transcripts. This method, called ROSE (run-off transcription/RNA-sequencing), only requires chromosomal DNA, ribonucleotides, RNA polymerase (RNAP) core enzyme, and a specific sigma factor, recognizing the corresponding promoters, which have to be analyzed. ROSE was performed on E. coli K-12 MG1655 genomic DNA using Escherichia coli RNAP holoenzyme (including σ70) and yielded 3226 transcription start sites, 2167 of which were also identified in in vivo studies, and 598 were new. Many new promoters not yet identified by in vivo experiments might be repressed under the tested conditions. Complementary in vivo experiments with E. coli K-12 strain BW25113 and isogenic transcription factor gene knockout mutants of fis, fur, and hns were used to test this hypothesis. Comparative transcriptome analysis demonstrated that ROSE could identify bona fide promoters that were apparently repressed in vivo. In this sense, ROSE is well-suited as a bottom-up approach for characterizing transcriptional networks in bacteria and ideally complementary to top-down in vivo transcriptome studies.

Project description:We report the genome-wide effects of blocking the interaction between the sigma-54 bacterial transcriptional enhancer with its cognate promoter in E. coli under nitrogen-starvation conditions.

Project description:Neonatal meningitis and neurocomplications are often a complication of neonatal bacterial bloodstream infections. As distinct bacterial organisms may cause different disease outcomes, we assessed two separate bacterial infections: E. coli and S. agalactiae (GBS). In this study we assessed differences in immune response within the brain tissue of neonates and the effect of gamma delta T cells to the brain during bacterial infection. As gamma delta T cells are resident to tissues, and can contribute to bacterial infections, we compared wild-type and TCRdKO mice, which lack gamma delta T cells, in two infections models: E. coli and GBS.

Project description:Despite the overwhelming information about sRNAs, one of the biggest challenges in the sRNA field is characterizing sRNA targetomes. Thus, we develop a novel method to identify RNAs that interact with a specific sRNA, regardless of the type of regulation (positive or negative) or targets (mRNA, tRNA, sRNA). This method is called MAPS: MS2 affinity purification coupled with RNA sequencing. As proof of principle, we identified RNAs bound to RybB, a well-characterized E. coli sRNA.

Project description:Despite the overwhelming information about sRNAs, one of the biggest challenges in the sRNA field is characterizing sRNA targetomes. Thus, we develop a novel method to identify RNAs that interact with a specific sRNA, regardless of the type of regulation (positive or negative) or targets (mRNA, tRNA, sRNA). This method is called MAPS: MS2 affinity purification coupled with RNA sequencing. As proof of principle, we identified RNAs bound to RyhB, a well-characterized E. coli sRNA.

Project description:Despite the overwhelming information about sRNAs, one of the biggest challenges in the sRNA field is characterizing sRNA targetomes. Thus, we develop a novel method to identify RNAs that interact with a specific sRNA, regardless of the type of regulation (positive or negative) or targets (mRNA, tRNA, sRNA). This method is called MAPS: MS2 affinity purification coupled with RNA sequencing. As proof of principle, we identified RNAs bound to RybB, a well-characterized E. coli sRNA. Identification of RNAs co-purified with MS2-RybB in a rne131 ΔrybB strain. RybB (without MS2) was used as control

Project description:Despite the overwhelming information about sRNAs, one of the biggest challenges in the sRNA field is characterizing sRNA targetomes. Thus, we develop a novel method to identify RNAs that interact with a specific sRNA, regardless of the type of regulation (positive or negative) or targets (mRNA, tRNA, sRNA). This method is called MAPS: MS2 affinity purification coupled with RNA sequencing. As proof of principle, we identified RNAs bound to RyhB, a well-characterized E. coli sRNA. Identification of RNAs co-purified with MS2-RyhB in a rne131 ?ryhB strain. RyhB (without MS2) was used as control

Project description:These data were obtained using a recently-developed high throughput method to probe regional RNA accessibility by mimicking in vivo antisense hybridization. The method (INTERFACE) is an engineered RNA system (for use in E. coli) that exploits conserved bacterial mechanisms of translational stalling and Rho-dependent transcription termination mechanisms to quantify RNA hybridization (via an asRNA targeting an RNA region of interest) via a transcriptional elongation response. We first establish the high throughput system by evaluating the accessibility profile of a well-characterized gI intron (overexpressed). We then apply this method with bioinformatics and machine learning approaches to profile over 900 RNA-interaction interfaces in 71 validated, but largely mechanistically under-characterized, sRNAs of Escherichia coli, in the presence and absence of a global regulator, Hfq. Importantly, we showcase the utility of INTERFACE in detecting RNA regions whose hybridization is Hfq-sensitive, finding two thirds of tested sRNAs with Hfq dependency. Further, we identify in vivo hybridization patterns that hallmark functional regions in 16 well-characterized sRNAs and couple these insights to a computational target prediction algorithm to identify novel mRNA targets for six under-characterized and two well-characterized sRNAs.

Project description:We integrated RNAP binding regions (RBRs) and mRNA transcript abundance to determine segments of contiguous transcription originating from promoter regions. To measure RBRs at a genome scale, we employed a ChIP-chip method to E. coli K-12 MG1655 grown in the presence or absence of rifampicin under multiple growth conditions using antibody against E. coli RNAP beta subunit.

Project description:Promoter recognition by bacterial RNA polymerase is mediated by ? subunits, which assemble transiently to RNA polymerase core enzyme (E) during transcription initiation. ? subunits drive transcription of specific sets of genes by allowing RNA polymerase to interact with different promoter sequences. However, ?70, the housekeeping ? subunit, and ?S, an alternative ? subunit mainly active during slow growth and in response to cellular stresses, appear to recognize almost identical promoter sequences, raising the question of how promoter selectivity is achieved in the bacterial cell. To identify?sequence determinants for selective promoter recognition, we performed a run-off/microarray experiment (ROMA): in vitro transcription experiments were carried out with RNA polymerase saturated either with ?70 (E?70) or with ?S (E?S) using the whole Escherichia coli genome as DNA template, and transcript levels were determined by microarray analysis. We found that several genes associated with bacterial growth (e.g., ribosomal operons) were transcribed more efficiently by E?70. In contrast, E?S transcribed preferentially genes involved in stress responses, secondary metabolism, as well as regulatory RNAs and intergenic regions with yet unknown function. Genes preferentially recognized in vitro by E?S showed reduced expression in a??S-deficient mutant strain of E. coli. Sequence comparison of E?70- versus E?S –dependent promoters confirms that the presence of a -35 sequence and the relative location of UP elements affect promoter interaction with either form of RNA polymerase, and suggests that a G/C bias in the -2/+1 nucleotides would favour efficient promoter recognition by E?70. We have performed in vitro transcription experiments with either E?70 or E?S, using the whole E. coli genome as template, to identify promoter regions selectively recognized by two forms of RNA polymerase by using E.coli genome 2.0 GeneChips.