Project description:Profiling combinations of histone modifications identifies gene regulatory elements in different states and discovers features controlling transcriptional and epigenetic programmes. However, efforts to map chromatin states in defined cell types are hindered by the lack of methods that can profile multiple histone modifications together with transcriptome in individual cells. Here we describe single-cell Multi-Targets and mRNA sequencing (scMTR-seq), which enables simultaneous profiling of six histone modifications and transcriptome in single cells. As a proof of concept, we apply scMTR-seq to uncover the dynamics of chromatin state change during human endoderm differentiation. We also use scMTR-seq to produce lineage-resolved chromatin maps and gene regulatory networks in mouse blastocysts, revealing striking epigenetic asymmetries at gene regulatory regions between the three embryo lineages. We identify the transcription factor Trps1 as a potential repressor in epiblast cells of trophectoderm-associated enhancer networks and their target genes. Together, scMTR-seq enables investigation of combinatorial epigenetic modalities in low-cell number and heterogeneous samples.

Project description:Profiling combinations of histone modifications identifies gene regulatory elements in different states and discovers features controlling transcriptional and epigenetic programmes. However, efforts to map chromatin states in defined cell types are hindered by the lack of methods that can profile multiple histone modifications together with transcriptome in individual cells. Here we describe single-cell Multi-Targets and mRNA sequencing (scMTR-seq), which enables simultaneous profiling of six histone modifications and transcriptome in single cells. As a proof of concept, we apply scMTR-seq to uncover the dynamics of chromatin state change during human endoderm differentiation. We also use scMTR-seq to produce lineage-resolved chromatin maps and gene regulatory networks in mouse blastocysts, revealing striking epigenetic asymmetries at gene regulatory regions between the three embryo lineages. We identify the transcription factor Trps1 as a potential repressor in epiblast cells of trophectoderm-associated enhancer networks and their target genes. Together, scMTR-seq enables investigation of combinatorial epigenetic modalities in low-cell number and heterogeneous samples.

Project description:To understand epigenetic mechanisms underlying CD8 T cell differentiation, we performed ChIP-seq of 4 histone modifications (H3K4me1, H3K4me3, H3K27ac, H3K27me3) and ATAC-seq to probe chromatin states and accessibility. We identified subset-specific regulatory elements (enhancers and promoters) from chromatin states and predicted key transcription factors from accessible regulatory regions using ATAC-seq.

Project description:How histone intrinsic sequence variation or regulatory modifications regulate nucleosome interactions with transcription remain unclear. To clarify this question, we examined how histone variants and histone modifications assemble in the Arabidopsis thaliana genome, identifying a limited number of chromatin states that divide euchromatin and heterochromatin in biologically significant subdomains. We showed that histone variants were as significant as histone modifications to determine the composition of chromatin states. The loss of function of the chromatin remodeler DECREASED IN DNA METHYLATION (DDM1) prevented the exchange between the histone variants H2A.Z and H2A.W over transposons resulting in their enrichment in chromatin states found only on proteins coding genes in the wild type. Hence, the dynamics of histone H2A variants exchange impacted the definition and distribution of chromatin states. We propose that dynamics of histone variants control the organization of histone modifications into chromatin states to achieve landmarks that signify the ability for transcription. Chromatin immunoprecipitation DNA-sequencing (ChIP-seq) for histone H2A variants and histone modifications in seedlings .

Project description:How histone intrinsic sequence variation or regulatory modifications regulate nucleosome interactions with transcription remain unclear. To clarify this question, we examined how histone variants and histone modifications assemble in the Arabidopsis thaliana genome, identifying a limited number of chromatin states that divide euchromatin and heterochromatin in biologically significant subdomains. We showed that histone variants were as significant as histone modifications to determine the composition of chromatin states. The loss of function of the chromatin remodeler DECREASED IN DNA METHYLATION (DDM1) prevented the exchange between the histone variants H2A.Z and H2A.W over transposons resulting in their enrichment in chromatin states found only on proteins coding genes in the wild type. Hence, the dynamics of histone H2A variants exchange impacted the definition and distribution of chromatin states. We propose that dynamics of histone variants control the organization of histone modifications into chromatin states to achieve landmarks that signify the ability for transcription. Chromatin immunoprecipitation sequencing (ChIP-seq) for histone H2A variants and histone modifications in Col0 and ddm1(-/-) .

Project description:Epigenetic inheritance of gene expression states enables a single genome to maintain distinct cellular identities. How histone modifications contribute to this process remains unclear. Using global chromatin perturbations and local, time-controlled modulation of transcription, we establish the existence of epigenetic memory of transcriptional activation for genes that can be silenced by the Polycomb group. This property emerges during cell differentiation and allows genes to be stably switched following a transient transcriptional stimulus. This transcriptional memory state at Polycomb targets operates in cis; however, rather than relying solely on read-and-write propagation of histone modifications, the memory is also linked to the strength of activating input opposing Polycomb proteins and therefore varies with the cellular context. Our data and computational simulations suggest a model whereby transcriptional memory arises from double-negative feedback between Polycomb-mediated silencing and active transcription. Epigenetic memory at Polycomb targets thus depends not only on histone modifications but also on the gene-regulatory network and underlying identity of a cell.

Project description:Epigenetic inheritance of gene expression states enables a single genome to maintain distinct cellular identities. How histone modifications contribute to this process remains unclear. Using global chromatin perturbations and local, time-controlled modulation of transcription, we establish the existence of epigenetic memory of transcriptional activation for genes that can be silenced by the Polycomb group. This property emerges during cell differentiation and allows genes to be stably switched following a transient transcriptional stimulus. This transcriptional memory state at Polycomb targets operates in cis; however, rather than relying solely on read-and-write propagation of histone modifications, the memory is also linked to the strength of activating input opposing Polycomb proteins and therefore varies with the cellular context. Our data and computational simulations suggest a model whereby transcriptional memory arises from double-negative feedback between Polycomb-mediated silencing and active transcription. Epigenetic memory at Polycomb targets thus depends not only on histone modifications but also on the gene-regulatory network and underlying identity of a cell.

Project description:Epigenetic inheritance of gene expression states enables a single genome to maintain distinct cellular identities. How histone modifications contribute to this process remains unclear. Using global chromatin perturbations and local, time-controlled modulation of transcription, we establish the existence of epigenetic memory of transcriptional activation for genes that can be silenced by the Polycomb group. This property emerges during cell differentiation and allows genes to be stably switched following a transient transcriptional stimulus. This transcriptional memory state at Polycomb targets operates in cis; however, rather than relying solely on read-and-write propagation of histone modifications, the memory is also linked to the strength of activating input opposing Polycomb proteins and therefore varies with the cellular context. Our data and computational simulations suggest a model whereby transcriptional memory arises from double-negative feedback between Polycomb-mediated silencing and active transcription. Epigenetic memory at Polycomb targets thus depends not only on histone modifications but also on the gene-regulatory network and underlying identity of a cell.

Project description:Epigenetic inheritance of gene expression states enables a single genome to maintain distinct cellular identities. How histone modifications contribute to this process remains unclear. Using global chromatin perturbations and local, time-controlled modulation of transcription, we establish the existence of epigenetic memory of transcriptional activation for genes that can be silenced by the Polycomb group. This property emerges during cell differentiation and allows genes to be stably switched following a transient transcriptional stimulus. This transcriptional memory state at Polycomb targets operates in cis; however, rather than relying solely on read-and-write propagation of histone modifications, the memory is also linked to the strength of activating input opposing Polycomb proteins and therefore varies with the cellular context. Our data and computational simulations suggest a model whereby transcriptional memory arises from double-negative feedback between Polycomb-mediated silencing and active transcription. Epigenetic memory at Polycomb targets thus depends not only on histone modifications but also on the gene-regulatory network and underlying identity of a cell.

Project description:Epigenetic states defined by chromatin can be maintained through mitotic cell division. However, it remains unknown how histone-based information is transmitted. Here we combine nascent chromatin capture (NCC) and triple-SILAC labelling to track histone modifications and histone variants during DNA replication and across the cell cycle. We show that post-translational modifications (PTMs) are transmitted with parental histones to newly replicated DNA. Di- and tri-methylation marks are diluted two-fold upon DNA replication, as a consequence of new histone deposition. Importantly, within one cell cycle all PTMs are restored. In general, new histones are modified to mirror the parental histones. However, H3K9me3 and H3K27me3 are propagated by continuous modification of parental and new histones, because the establishment of these marks extends over several cell generations. Together, our results reveal how histone marks propagate and demonstrate that chromatin states oscillate within the cell cycle.