Project description:Dynamic 3D chromatin conformation is a critical mechanism for gene regulation during development and disease. Despite this, profiling of 3D genome structure from complex tissues with cell-type specific resolution remains challenging. Recent efforts have demonstrated that cell-type specific epigenomic features can be resolved in complex tissues using single-cell assays. However, it remains unclear whether single-cell Chromatin Conformation Capture (3C) or Hi-C profiles can effectively identify cell types and reconstruct cell-type specific chromatin conformation maps. To address these challenges, we have developed single-nucleus methyl-3C sequencing (sn-m3C-seq) to capture chromatin organization and DNA methylation information and robustly separate heterogeneous cell types. Applying this method to >4,200 single human brain prefrontal cortex cells, we reconstruct cell-type specific chromatin conformation maps from 14 cortical cell types. These datasets reveal the genome-wide association between cell-type specific chromatin conformation and differential DNA methylation, suggesting pervasive interactions between epigenetic processes regulating gene expression.

Project description:Mammalian interphase chromosomes interact with the nuclear lamina (NL) through hundreds of large Lamina Associated Domains (LADs). We report a method to map NL contacts genome-wide in single human cells. Analysis of ~400 maps reveals a core architecture of gene-poor LADs that contact the NL with high cell-to-cell consistency, interspersed by LADs with more variable NL interactions. The variable contacts are more sensitive to a change in genome ploidy than the consistent contacts. Single-cell maps indicate that NL contacts involve multivalent interactions over hundreds of kilobases. Moreover, we observe extensive intra-chromosomal coordination of NL contacts, even over tens of megabases. Such coordinated loci exhibit preferential interactions as detected by Hi-C. Finally, single-cell gene expression and chromatin accessibility analysis shows that loci with consistent NL contacts are expressed at lower levels and are more consistently inaccessible than loci with lower contact frequencies. These results highlight fundamental principles of single cell chromatin organization. Hi-C Data

Project description:Three-dimensional (3D) chromatin structure plays a crucial role in development and diseases, which are associated with transcriptional changes. However, given the heterogeneity in single-cell chromatin architecture and transcription, the regulatory relationship between 3D chromatin structure and gene expression is difficult to explain based on the cell populations. Here we developed a single-cell multimodal omics method for simultaneously detecting chromatin architecture and mRNA expression by sequencing (scCARE-seq). Applying scCARE-seq to examine chromatin architecture and transcription from naïve to primed single mouse embryonic stem cells (mESCs), we observed correlated changes between 3D chromatin structure and expression in the cell fate transition. In addition, we defined cell cycle phase of each cell through chromatin architecture extracted by CARE-seq, and found that periodic changes in chromatin architecture were in parallel with transcription during the cell cycle. These findings indicate that scCARE-seq allows comprehensive analysis of chromatin architecture and transcription in the same single cell.

Project description:We developed a new single cell sequencing method to simultaneously sequence methylome and transcriptome for mouse DRG neurons Integrative analysis of transcription and methylation at single cell level

Project description:The genome is organized into self-interacting chromatin domains containing genes and the cis-regulatory elements controlling their expression. How these domains form and how elements within them interact is unknown. We have developed Tri-C, a sensitive, high-resolution Chromosome Conformation Capture (3C) approach to identify concurrent chromatin interactions in single cells. Combining Tri-C with conventional 3C and polymer modeling, we show that, rather than folding into stable pre-formed loops, self-interacting domains form dynamic compartmentalized chromatin structures, delimited by CTCF/Cohesin boundaries. Within these tissue-specific domains, all regions of chromatin contact each other, but preferential structures are formed in which multiple enhancers and promoters interact simultaneously. Flanking CTCF/Cohesin-bound elements are excluded from these interactions and form distinct structures. These observations are best explained by a dynamic loop extrusion mechanism and subsequent stabilization of enhancer-promoter interactions, rather than the current view of long-range interactions occurring via the formation of discrete pre-formed chromatin loops.

Project description:We developed a tunable ligation technology to alter beads used for to capture mRNA for single-cell RNA sequencing (e.g. Drop-seq); we call this technique droplet assisted RNA targeting by single cell sequencing, or DART-seq. In the study, we applied the new technology to capture viral genome transcripts of recombinant type 3 Dearing orthoreovirus infecting murine L929 cells. In addition to capture of targeted viral gene transcripts, we were also able to simultaneosly pull-down polyadenylated mRNA from the L929 cells to observe host-pathogen interactions. We also applied the technology to efficiently measure natively paired heavy and light chain amplicons from B lymphocyte cells in a collection of human peripheral blood mononuclear cells.

Project description:Here we present a new version of the DamID method that allows efficient capturing of protein-DNA interactions and mRNA output from the same single cell. With this protocol, we have measured the direct impact of spatial genome positioning and chromatin accessibility on mRNA output in human haploid cells

Project description:Here we present a new version of the DamID method that allows efficient capturing of protein-DNA interactions and mRNA output from the same single cell. With this protocol, we have measured the direct impact of spatial genome positioning and chromatin accessibility on mRNA output in mouse embryonic stem cells

Project description:Mammalian interphase chromosomes interact with the nuclear lamina (NL) through hundreds of large Lamina Associated Domains (LADs). We report a method to map NL contacts genome-wide in single human cells. Analysis of ~400 maps reveals a core architecture of gene-poor LADs that contact the NL with high cell-to-cell consistency, interspersed by LADs with more variable NL interactions. The variable contacts are more sensitive to a change in genome ploidy than the consistent contacts. Single-cell maps indicate that NL contacts involve multivalent interactions over hundreds of kilobases. Moreover, we observe extensive intra-chromosomal coordination of NL contacts, even over tens of megabases. Such coordinated loci exhibit preferential interactions as detected by Hi-C. Finally, single-cell gene expression and chromatin accessibility analysis shows that loci with consistent NL contacts are expressed at lower levels and are more consistently inaccessible than loci with lower contact frequencies. These results highlight fundamental principles of single cell chromatin organization.

Project description:Deep proteome data in the single-cell multi-omics analysis of single mouse oocytes.