Project description:Chromatin-localized RNAs play diverse roles in gene regulation and nuclear architecture. Mapping genome-wide RNA-DNA interactions is possible using a variety of molecular methods, including using bridging oligonucleotides to ligate RNA and DNA in proximity. While molecular methods have progressed, a robust computational method for calling biologically meaningful RNA-DNA interactions from these data is lacking. Herein, we present RADIAnT, a reads-to-interactions pipeline for analyzing RNA-DNA ligation data. RADIAnT calls interactions against a dataset-specific, unified background which considers RNA binding site-TSS distance and genomic region bias. By scaling the background with RNA abundance, RADIAnT is sensitive enough to detect specific interactions of lowly expressed transcripts, while remaining specific enough to discount false positive interactions of highly abundant RNAs. RADIAnT outperforms previously proposed methods in the accurate recall of genome-wide Malat1-DNA interactions, and in a use-case, was utilized to identify dynamic chromatin-associated RNAs in the physiologically- and pathlologically-relevant process of endothelial-to-mesenchymal transition.

Project description:Chromatin-localized RNAs play diverse roles in gene regulation and nuclear architecture. Mapping genome-wide RNA-DNA interactions is possible using a variety of molecular methods, including using bridging oligonucleotides to ligate RNA and DNA in proximity. While molecular methods have progressed, a robust computational method for calling biologically meaningful RNA-DNA interactions from these data is lacking. Herein, we present RADIAnT, a reads-to-interactions pipeline for analyzing RNA-DNA ligation data. RADIAnT calls interactions against a dataset-specific, unified background which considers RNA binding site-TSS distance and genomic region bias. By scaling the background with RNA abundance, RADIAnT is sensitive enough to detect specific interactions of lowly expressed transcripts, while remaining specific enough to discount false positive interactions of highly abundant RNAs. RADIAnT outperforms previously proposed methods in the accurate recall of genome-wide Malat1-DNA interactions, and in a use-case, was utilized to identify dynamic chromatin-associated RNAs in the physiologically- and pathlologically-relevant process of endothelial-to-mesenchymal transition.

Project description:Within all cells, RNA molecules form complex networks of molecular interactions that are central to their function, but discovering these interactions remains challenging. Here, we introduce Oligonucleotide-mediated proximity-interactome MAPping (O-MAP), a straightforward method for elucidating the biomolecules near an RNA of interest, within its native cellular context. O-MAP uses programmable DNA probes to deliver proximity-biotinylating enzymes to a target RNA, enabling molecules within that RNA's subcellular microcompartment to be enriched by streptavidin pulldown. O-MAP induces exceptionally precise in situ biotinylation, and unlike alternative methods it enables straightforward optimization of its RNA-targeting accuracy. Using the 47S pre-ribosomal RNA and long noncoding RNA Xist as models, we develop O-MAP workflows for unbiased discovery of RNA-proximal proteins, transcripts, and genomic loci. This revealed unexpected co-compartmentalization of Xist and other chromatin-regulatory RNAs, and enabled systematic discovery of nucleolar-chromatin interactions across multiple cell lines. O-MAP uses exclusively off-the-shelf parts requiring no genetic- or cell-line engineering and is easily portable across diverse specimen-types and target RNAs. We therefore anticipate its application to a broad array of RNA phenomena.

Project description:RNA molecules can attach to chromatin and thus provide a type of epigenomic information. It remains difficult to know what RNAs are associated with chromatin and where are the genomic target loci of these RNAs. Here, we present MARGI (Mapping RNA-genome interactions), a technology to massively reveal native RNA-chromatin interactions from unperturbed cells. The gist of this technology is to ligate chromatin-associated RNA (caRNA) with their target genomic sequence by proximity ligation, forming RNA-DNA chimeric sequences, which are converted to sequencing library for paired-end sequencing. Using MARGI, we produced RNA-genome interaction maps for human embryonic stem (ES) cells and HEK cells. MARGI revealed hundreds of chromatin-associated RNAs (caRNA), including previously known XIST, SNHG1, NEAT1, and MALAT1, as well as each caRNA's genomic interaction loci. Using a cross-species experiment, we estimated that approximately 2.2% of MARGI identified interactions are false positives. MARGI data suggested that 80-95% of interactions are proximal, where a caRNA is connected to its nearby genomic regions, 1-2% are distal, and 5-15% are inter-chromosomal. The majority of TSSs are associated with distal or inter-chromosomal caRNAs. ChIP-seq reported H3K27ac and H3K4me3 levels are positively correlated while H3K9me is negatively correlated with MARGI reported RNA attachment levels. The MARGI technology should facilitate revealing novel RNA functions and epigenomic events.

Project description:Detection of statistically robust interactions from diverse RNA-DNA ligation data [RADICL-seq]

Project description:Detection of statistically robust interactions from diverse RNA-DNA ligation data [nucRNA-seq]

Project description:Detection of statistically robust interactions from diverse RNA-DNA ligation data [ATAC-seq]

Project description:For Large White (LW) and Meishan (MS) skeletal muscle, we performed H3K27ac BL HiCHIP to establish enhancer-promoter interaction maps. We also performed GRID-seq which uses a bivalent linker to ligate RNA to DNA in situ.

Project description:Background: MicroRNAs (miRNAs) are small non-coding RNAs that regulate gene expression. Their abilyty to affect multiple gene pathways by targeting to various mRNAs makes them to an interesting class of regulators. The interplay between miRNA and mRNA has been proposed as an important process in cancer development and progression. In this study, we analyzed miRNA -mRNA interactions in bladder urothelial carcinoma. Methodology/Principal Findings: We have developed a new algorithm which is capable of identifying altered miRNA-mRNA regulation between tissues samples without preexisting stratification of groups. Microarray expression profiling of both miRNA and mRNA from the same sample were performed using a collective of 24 urothelial carcinoma and normal bladder tissue samples. Using our approach, normal and tumor tissue samples as well as different stages of tumor progression were successfully stratified. Also, we were able to analyzed individual miRNA-mRNA interactions from each patient, focusing on different miRNA families. Conclusions: Just recently, the need for tools that allow an integrative analysis of microRNA and mRNA expression data has been addressed. With this study, we provide an algorithm that considers the special nature of miRNA induced regulation and shows good specificities and sensitivities when applied to bladder cancer expression data. mRNA and microRNA expression data were analyzed together to identify bladder cancer specific micoRNA-mRNA interaction

Project description:It is increasingly evident that various RNA molecules can bind chromatin to regulate gene expression and genome organization. Here we adapted a sequencing-based technique to profile RNA-chromatin interactions at a genome-wide scale in Arabidopsis seedlings. We identified more than ten thousand RNA-chromatin interactions mediated by protein-coding RNAs, long non-coding RNAs (ncRNAs) and small ncRNAs in Arabidopsis. These RNAs preferentially target genic regions, especially exonic regions. Protein-coding RNAs primarily engage in local and cis-chromosomal interactions, whereas long ncRNAs (lncRNAs) and small ncRNAs preferentially engage in trans-chromosomal interactions. RNA-chromatin interactions tend to positively correlate with DNA-DNA interactions, suggesting a role of DNA-DNA interactions in confining RNA-chromatin interactions and/or a role of RNA-chromatin interactions in shaping genome organization at a global level. We further show that some RNA-chromatin interactions undergo alterations in response to biotic and abiotic stresses. Our study provides a global view of RNA-chromatin interactions in Arabidopsis and a rich resource for future investigation of the regulatory roles of RNAs in gene expression and genome organization.