Project description:The abundant RNA modification pseudouridine (Ψ) has been mapped transcriptome-wide by chemically modifying pseudouridines with carbodiimide and detecting the resulting reverse transcription stops in high-throughput sequencing. However, these methods have limited sensitivity and specificity, in part due to the use of reverse transcription stops. We sought to use mutations rather than just stops in sequencing data to identify pseudouridine sites. Here, we identify reverse transcription conditions that allow read-through of carbodiimide-modified pseudouridine (CMC-Ψ), and we show that pseudouridines in carbodiimide-treated human ribosomal RNA have context-dependent mutation and stop rates in high-throughput sequencing libraries prepared under these conditions. Furthermore, accounting for the context-dependence of mutation and stop rates can enhance the detection of pseudouridine sites. Similar approaches could contribute to the sequencing-based detection of many RNA modifications.

Project description:Pseudouridines have context-dependent mutation and stop rates in high-throughput sequencing

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Project description:We applied a multiplexed genomic tethering assay (Brueckner, Epigenetics Chromatin, 2016; PMID:27777628) to elucidate the function of ACF1, the large subunit of the ACF nucleosome sliding complex in drosophila Kc167 cells. Targeting a Gal4DBD-ACF1 fusion to several hundred integrated reporters revealed a context-dependent repressive effect which is modulated by gene activity and chromatin state.

Project description:Chromatin proteins control gene activity in a concerted manner. We developed a high-throughput assay to study the effects of the local chromatin environment on the regulatory activity of a protein of interest. The assay combines a previously reported multiplexing strategy based on barcoded randomly integrated reporter genes (Akhtar, Cell, 2013; PMID: 23953119) with Gal4-mediated tethering of the protein of interest. We applied the assay to Drosophila Heterochromatin protein 1a (HP1a), which is mostly known as a repressive protein working by a chromatin compaction mechanism but has also been linked to transcriptional activation. Probing the effects of HP1a in more than one thousand genomic locations revealed that HP1a is a potent repressor able to silence even highly expressing loci. However, the local chromatin context can modulate HP1a function. In pericentromeric regions, HP1a-induced repression was enhanced by two-fold. In regions marked by a H3K36me3-rich chromatin signature linked to transcriptional elongation, HP1a-dependent silencing was significantly decreased. We found no evidence for an activating function of HP1a in our experimental system. Furthermore, we did not observe stable transmission of repression over mitotic divisions after loss of targeted HP1a recruitment in any of the loci examined. The multiplexed tethered reporter assay will be a useful tool to dissect combinatorial regulatory interactions in chromatin.

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Project description:Interventions: Gold Standard:Reference methods: 1. Total exome sequencing (WES) 2. Multiple fluorescence PCR capillary electrophoresis (PCR-STR); Comparison method: comparison of similar kits;Index test:Information of reagents to be examined: (1) Product name: Human solid Tumor Multi-gene Mutation Combined Detection Kit (high-throughput sequencing method); (2) Packing specification: 48 test/box; (3) Storage conditions: Kit 1 was stored at -25~-15?, Kit 2 at -85~-70?, Kit 3 at 2-8 ?, kit 4 at 10-30 ?; (4)&# Primary outcome(s): Non-small cell lung cancer/colorectal cancer/gastrointestinal stromal tumor/stomach cancer/glioma/thyroid cancer/breast cancer/ovarian cancer/melanoma/cholangiocarcinoma/urothelial carcinoma/prostate cancer/other malignant solid tumor genes Study Design: Sequential

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