Project description:Proof-of-concept of a new method involving the limited digestion and subsequent ligation of intramolecular RNA structures in situ followed by deep sequencing Proof-of-concept of RPL in S. cerevisiae and H. sapiens tissue culture

Project description:Proof-of-concept of a new method involving the limited digestion and subsequent ligation of intramolecular RNA structures in situ followed by deep sequencing

Project description:We used one of the RNA-DNA proximity ligation approaches, RedC, for the analysis of an RNA-DNA interactome of microbial cells. We assess the distribution of main RNA types — mRNA, tRNA and rRNA — along the genomes of E.coli, B.subtilis, and thermophilic archaea T. adornatum.

Project description:Rapid advances in high-throughput DNA sequencing technologies are accelerating the pace of research into personalized medicine. While methods for variant discovery and genotyping from whole genome sequencing (WGS) datasets have been well established, linking variants together into a single haplotype remains a challenge. An understanding of complete haplotypes of an individual will help clarify the consequences of inheriting multiple alleles in combination, identify novel disease associations, and augment studies of gene regulation. Although numerous methods have been developed to reconstruct haplotypes from WGS data, chromosome-span haplotypes at high resolution have been difficult to obtain. Here we present a novel method to accurately reconstruct chromosome-span haplotypes from proximity-ligation and DNA shotgun sequencing. We demonstrate the utility of this approach in producing high-resolution chromosome-span haplotype phasing in mouse and human. While proximity-ligation based methods were originally designed to investigate spatial organization of the genome, our results lend support for their use as a general tool for haplotyping in the future. Hi-C experiments in two replicates of Human GM12878 Lymphoblastoid cells and two replicates of F123 mouse ES cells (4 total samples)

Project description:Rapid advances in high-throughput DNA sequencing technologies are accelerating the pace of research into personalized medicine. While methods for variant discovery and genotyping from whole genome sequencing (WGS) datasets have been well established, linking variants together into a single haplotype remains a challenge. An understanding of complete haplotypes of an individual will help clarify the consequences of inheriting multiple alleles in combination, identify novel disease associations, and augment studies of gene regulation. Although numerous methods have been developed to reconstruct haplotypes from WGS data, chromosome-span haplotypes at high resolution have been difficult to obtain. Here we present a novel method to accurately reconstruct chromosome-span haplotypes from proximity-ligation and DNA shotgun sequencing. We demonstrate the utility of this approach in producing high-resolution chromosome-span haplotype phasing in mouse and human. While proximity-ligation based methods were originally designed to investigate spatial organization of the genome, our results lend support for their use as a general tool for haplotyping in the future.

Project description:Whole-genome Haplotype Reconstruction using Proximity-ligation and Shotgun Sequencing

Project description:We report Proximity Ligation Assisted ChIP-sequencing (PLAC-seq), a method for comprehensive detection of long-range interactions associated with proteins of interest. PLAC-seq requires up to 500-fold less starting material compared to ChIA-PET and using experimentally determined input as control precisely reveals protein associated interaction upto single-element resolution. Application of PLAC-seq to mouse embryonic stem cells revealed a comprehensive map of regulatory interactions.

Project description: Not available

Project description:Employing proximity-dependent ligation techniques to estimate EcR/Usp molecular partners in Drosophila

Project description:Non-canonical DNA structures at eukaryotic centromeres can resolve the CENP-B paradox