Project description:Natural RNA polymerase aptamers regulate transcription in E. coli [3' RACE]

Project description:Natural RNA polymerase aptamers regulate transcription in E. coli

Project description:In search for RNA signals that modulate transcription via direct interaction with RNA polymerase (RNAP) we deep-sequenced an E. coli genomic library enriched for RNAP-binding RNAs. Many natural RNAP-binding aptamers, termed RAPs, were mapped to the genome. Over 60% of E. coli genes carry RAPs in their mRNA. Combining in vitro and in vivo approaches we characterized a subset of RAPs (iRAPs) that promote Rho-dependent transcription termination. A representative iRAP within the coding region of the essential gene, nadD, greatly reduces its transcriptional output in stationary phase and under oxidative stress, demonstrating that iRAPs control gene expression in response to changing growth conditions. The mechanism of iRAPs involves active uncoupling of transcription and translation, making the nascent RNA accessible to Rho. iRAPs encoded in the antisense strand also promote gene expression by reducing transcriptional interference. In essence, our work uncovers a broad class of cis-acting RNA signals that globally control bacterial transcription.

Project description:In search for RNA signals that modulate transcription via direct interaction with RNA polymerase (RNAP) we deep-sequenced an E. coli genomic library enriched for RNAP-binding RNAs. Many natural RNAP-binding aptamers, termed RAPs, were mapped to the genome. Over 60% of E. coli genes carry RAPs in their mRNA. Combining in vitro and in vivo approaches we characterized a subset of RAPs (iRAPs) that promote Rho-dependent transcription termination. A representative iRAP within the coding region of the essential gene, nadD, greatly reduces its transcriptional output in stationary phase and under oxidative stress, demonstrating that iRAPs control gene expression in response to changing growth conditions. The mechanism of iRAPs involves active uncoupling of transcription and translation, making the nascent RNA accessible to Rho. iRAPs encoded in the antisense strand also promote gene expression by reducing transcriptional interference. In essence, our work uncovers a broad class of cis-acting RNA signals that globally control bacterial transcription.

Project description:To investigate the relationship between RNA polymerase binding and transcription ChIP-seq on the common house-keeping SigmaD and RNA polymerase beta subunit were coupled with RNA-seq at various growth phases of Escherichia coli in rich media.

Project description:Inorganic polyphosphate (polyP) is synthesized by bacteria in response to various stresses, but the mechanism of its regulation is unknown. Mutants of Escherichia coli lacking the RNA polymerase-binding transcription factor dksA are defective in polyP synthesis after a nutrient limitation stress, and this defect is reversed in a dksA greA mutant. In this work, we used RNA sequencing to compare transcription in wild-type, dksA, and dksA greA strains of E. coli before and after nutrient limitation, to identify genes whose expression pattern correlates with ability to synthesize polyP.

Project description:RNA Sequencing of wild type Eschrichia coli and a RNA polymerase mutant isolated from deep stationary phase

Project description:Expression level of whole genome genes in Escherichia coli CC72 at early-exponential phase, and 10 min, 20 min and 45 min after osmotic stress. Venus was fused to the 3' end of rpoC in E. coli MG1655 to localize RNA polymerase as reported previously (C. Cagliero and D. J. Jin, 2013).

Project description:Despite the well-established significance of transcription factors (TFs) in pathogenesis, their utilization as pharmacological targets has been limited by the inherent challenges mainly associated with modulating their protein-protein and protein-DNA interactions. The lack of defined small-molecule binding pockets and the nuclear localization of TFs makes neither small molecule inhibitors nor neutral antibodies suitable in blocking TF interactions. Aptamers are short oligonucleotides exhibiting high affinity and specificity for a diverse range of targets. The large molecular weights, expansive blocking surfaces and efficient cellular internalization make aptamers as a compelling molecular tool for traditional TF interaction modulators. Here, we report a structure-guided design strategy called Blocker-SELEX for developing inhibitory aptamers (iAptamer) that selectively block TF interactions. Our approach led to the discovery of an iAptamer that cooperatively disrupts SCAF4/SCAF8-RNA Polymerase II (RNAP2) interactions, thus dysregulates RNAP2 dependent gene expression and splicing, leading to the impairing of cell proliferation. This approach was further applied to develop iAptamers efficiently block WDR5-MYC interaction. Together, our study highlights the potential of Blocker-SELEX in developing iAptamers that effectively disrupt TF interactions, and the generated iAptamers hold promising implications as chemical tools in studying biological functions of TF interactions and the potential for nucleic acids drug development.

Project description:Transcription profile of Escherichia coli cells in mono-species pure biofilms was compared to that of E. coli cells in E. coli-Stenotrophomonas maltophilia dual-species biofilms. E. coli cells were separated from dual-species biofilms before total RNA extraction to eliminate possible cross hybridization from S. maltophilia transcripts. The separation method was developed by combining the use of reagent RNAlater and immuno-magnetic separation. Pure E. coli biofilms were processed with the same separation protocol before RNA extraction.