Project description:Acute myeloid leukemia (AML) is a set of heterogeneous myeloid malignancies hallmarked by mutations in epigenetic modifiers, transcription factors and kinases that can cause epigenetic reshaping. It is unclear whether those mutations drive chromatin 3D structure alteration and contribute to oncogenic dysregulation in AML. By performing Hi-C and whole genome sequencing in 21 primary AML and healthy donors’ samples, we identified recurrent AML- or subtype-specific alteration of compartments, TADs, and chromatin loops. To study the impact on gene regulation, we performed RNA-Seq, ATAC-Seq and CUT&TAG for CTCF, H3K27ac, and H3K27me3 in the same samples. We observed dysregulation of many AML-related genes, represented by MYCN, MEIS1, WT1, ERG, MYC GATA3, BCL11B and IKZF2, intimately linked to the recurrent gain of loops and switch of compartment or TAD, alongside acquisition of AML-specific enhancer or repressor. Further, we profiled structure variations using WGS and Hi-C data to reconstruct the cancer 3D genome, by which we identified structure variation-induced neo-loops and enhancer-hijacking events. Furthermore, through conducting whole genome bisulfite sequencing in patient samples, we found altered methylation correlated with A/B compartment switch, and loss of CTCF insulation due to hypermethylation, leading to extensive gain of loops in AML. By treating the AML cells with DNA hypomethylation agent 5-azacytidine, the altered chromatin structure and gene expression can be restored, with switched compartment reverted and gained loops dissociated, alongside compromised AML cell proliferation, overall providing insights into AML treatment through therapeutic restoration of chromatin structure.

Project description:Acute myeloid leukemia (AML) is a set of heterogeneous myeloid malignancies hallmarked by mutations in epigenetic modifiers, transcription factors and kinases that can cause epigenetic reshaping. It is unclear whether those mutations drive chromatin 3D structure alteration and contribute to oncogenic dysregulation in AML. By performing Hi-C and whole genome sequencing in 21 primary AML and healthy donors’ samples, we identified recurrent AML- or subtype-specific alteration of compartments, TADs, and chromatin loops. To study the impact on gene regulation, we performed RNA-Seq, ATAC-Seq and CUT&TAG for CTCF, H3K27ac, and H3K27me3 in the same samples. We observed dysregulation of many AML-related genes, represented by MYCN, MEIS1, WT1, ERG, MYC GATA3, BCL11B and IKZF2, intimately linked to the recurrent gain of loops and switch of compartment or TAD, alongside acquisition of AML-specific enhancer or repressor. Further, we profiled structure variations using WGS and Hi-C data to reconstruct the cancer 3D genome, by which we identified structure variation-induced neo-loops and enhancer-hijacking events. Furthermore, through conducting whole genome bisulfite sequencing in patient samples, we found altered methylation correlated with A/B compartment switch, and loss of CTCF insulation due to hypermethylation, leading to extensive gain of loops in AML. By treating the AML cells with DNA hypomethylation agent 5-azacytidine, the altered chromatin structure and gene expression can be restored, with switched compartment reverted and gained loops dissociated, alongside compromised AML cell proliferation, overall providing insights into AML treatment through therapeutic restoration of chromatin structure.

Project description:Acute myeloid leukemia (AML) is a set of heterogeneous myeloid malignancies hallmarked by mutations in epigenetic modifiers, transcription factors and kinases that can cause epigenetic reshaping. It is unclear whether those mutations drive chromatin 3D structure alteration and contribute to oncogenic dysregulation in AML. By performing Hi-C and whole genome sequencing in 21 primary AML and healthy donors’ samples, we identified recurrent AML- or subtype-specific alteration of compartments, TADs, and chromatin loops. To study the impact on gene regulation, we performed RNA-Seq, ATAC-Seq and CUT&TAG for CTCF, H3K27ac, and H3K27me3 in the same samples. We observed dysregulation of many AML-related genes, represented by MYCN, MEIS1, WT1, ERG, MYC GATA3, BCL11B and IKZF2, intimately linked to the recurrent gain of loops and switch of compartment or TAD, alongside acquisition of AML-specific enhancer or repressor. Further, we profiled structure variations using WGS and Hi-C data to reconstruct the cancer 3D genome, by which we identified structure variation-induced neo-loops and enhancer-hijacking events. Furthermore, through conducting whole genome bisulfite sequencing in patient samples, we found altered methylation correlated with A/B compartment switch, and loss of CTCF insulation due to hypermethylation, leading to extensive gain of loops in AML. By treating the AML cells with DNA hypomethylation agent 5-azacytidine, the altered chromatin structure and gene expression can be restored, with switched compartment reverted and gained loops dissociated, alongside compromised AML cell proliferation, overall providing insights into AML treatment through therapeutic restoration of chromatin structure.

Project description:Acute myeloid leukemia (AML) is a set of heterogeneous myeloid malignancies hallmarked by mutations in epigenetic modifiers, transcription factors and kinases that can cause epigenetic reshaping. It is unclear whether those mutations drive chromatin 3D structure alteration and contribute to oncogenic dysregulation in AML. By performing Hi-C and whole genome sequencing in 21 primary AML and healthy donors’ samples, we identified recurrent AML- or subtype-specific alteration of compartments, TADs, and chromatin loops. To study the impact on gene regulation, we performed RNA-Seq, ATAC-Seq and CUT&TAG for CTCF, H3K27ac, and H3K27me3 in the same samples. We observed dysregulation of many AML-related genes, represented by MYCN, MEIS1, WT1, ERG, MYC GATA3, BCL11B and IKZF2, intimately linked to the recurrent gain of loops and switch of compartment or TAD, alongside acquisition of AML-specific enhancer or repressor. Further, we profiled structure variations using WGS and Hi-C data to reconstruct the cancer 3D genome, by which we identified structure variation-induced neo-loops and enhancer-hijacking events. Furthermore, through conducting whole genome bisulfite sequencing in patient samples, we found altered methylation correlated with A/B compartment switch, and loss of CTCF insulation due to hypermethylation, leading to extensive gain of loops in AML. By treating the AML cells with DNA hypomethylation agent 5-azacytidine, the altered chromatin structure and gene expression can be restored, with switched compartment reverted and gained loops dissociated, alongside compromised AML cell proliferation, overall providing insights into AML treatment through therapeutic restoration of chromatin structure.

Project description:We recently used in situ Hi-C to create kilobase-resolution 3D maps of mammalian genomes. Here, we combine these with new Hi-C, microscopy, and genome-editing experiments to study the physical structure of chromatin fibers, domains, and loops. We find that the observed contact domains are inconsistent with the equilibrium state for an ordinary condensed polymer. Combining Hi-C data and novel mathematical theorems, we show that contact domains are also not consistent with a fractal globule. Instead, we use physical simulations to study two models of genome folding. In one, intermonomer attraction during polymer condensation leads to formation of an anisotropic "tension globule." In the other, CTCF and cohesin act together to extrude loops during interphase. Both models are consistent with the observed contact domains and with the observation that contact domains tend to form inside loops. However, the extrusion model explains a far wider array of observations, such as why loops tend not to overlap and why the CTCF-binding motifs at pairs of loop anchors lie in the convergent orientation. Finally, we perform 13 genome-editing experiments examining the effect of altering CTCF-binding sites on chromatin folding. The convergent rule correctly predicts the affected loop in every case. Moreover, the extrusion model accurately predicts in silico the 3D maps resulting from each experiment using only the location of CTCF-binding sites in the WT. Thus, we show that it is possible to disrupt, restore, and move loops and domains using targeted mutations as small as a single base pair. in situ Hi-C and HYbrid Capture Hi-C (Hi-C2) were used to probe the three-dimensional structure of the genome in two different human cell types before and after genome editing.

Project description:TADs, CTCF loop domains, and A/B compartments have been identified as important structural and functional components of 3D chromatin organization, yet the relationship between these features is not well understood. Using high-resolution Hi-C and HiChIP we show that Drosophila chromatin is organized into domains we term compartmental domains that correspond precisely with A/B compartments at high resolution. We find that transcriptional state is a major predictor of Hi-C contact maps in several eukaryotes tested, including C. elegans and A. thaliana. Architectural proteins insulate compartmental domains by reducing interaction frequencies between neighboring regions in Drosophila, but CTCF loops do not play a distinct role in this organism. In mammals, compartmental domains exist alongside CTCF loop domains to form topological domains. The results suggest that compartmental domains are responsible for domain structure in all eukaryotes, with CTCF playing an important role in domain formation in mammals.

Project description:We use in situ Hi-C to probe the three-dimensional architecture of genomes, constructing haploid and diploid maps of nine cell types. The densest, in human lymphoblastoid cells, contains 4.9 billion contacts, achieving 1-kilobase resolution. We find that genomes are partitioned into local domains, which are associated with distinct patterns of histone marks and segregate into six subcompartments. We identify ~10,000 loops. These loops frequently link promoters and enhancers, correlate with gene activation, and show conservation across cell types and species. Loop anchors typically occur at domain boundaries and bind CTCF. CTCF sites at loop anchors occur predominantly (>90%) in a convergent orientation, with the asymmetric motifs ‘facing’ one another. The inactive X-chromosome splits into two massive domains and contains large loops anchored at CTCF-binding repeats. in situ Hi-C and dilution Hi-C were used to probe the three-dimensional structure of the genome in eight diverse human cell types and one mouse cell type

Project description:CCCTC-binding factor (CTCF) is an architectural protein involved in the three-dimensional organization of chromatin. In this study, we systematically assayed the 3D genomic contact profiles of hundreds of CTCF binding sites in multiple tissues with high-resolution 4C-seq. We find both developmentally stable and dynamic chromatin loops. As recently reported, our data also suggest that chromatin loops preferentially form between CTCF binding sites oriented in a convergent manner. To directly test this, we used CRISPR-Cas9 genome editing to delete core CTCF binding sites in three loci, including the CTCF site in the Sox2 super-enhancer. In all instances, CTCF and cohesin recruitment were lost, and chromatin loops with distal CTCF sites were disrupted or destabilized. Re-insertion of oppositely oriented CTCF recognition sequences restored CTCF and cohesin recruitment, but did not re-establish chromatin loops. We conclude that CTCF binding polarity plays a functional role in the formation of higher order chromatin structure. 4C-seq was performed on a large number of viewpoints in E14 embryonic stem cells, neural precursor cells and primary fetal liver cells

Project description:We report the application of Hi-C technology for high-throughput profiling of LUAD and normal tissues. By obtaining over three billion bases of sequence from chromatin immunoprecipitated DNA, we generated genome-wide chromatin-state maps of LUAD. We found the main conversion type of compartment is A→B in tumor tissues, 216 tumor-specific TADs and 41 distinct enhancer-promoter loops in tumor tissue. And these chromatin structure variations are mainly on chromosome 3. We also found 5 most important genes (SYT16, NCEH1, NXPE3, MB21D2, and DZIP1L), which were detected in both A→B compartment, TADs and chromatin loops.

Project description:Rearrangements of the mixed lineage leukemia (MLLr) gene are frequently associated with both pediatric and adult leukemia. However, the treatment options for these aggressive MLLr leukemias are limited due to the genomic complexity and dynamics of 3D structure in oncogene transcription and leukemia development. Here, we use Micro-C and transcriptome profiling to examine the MLLr-driven aberrant 3D genome architecture in gene-edited MLL-AF9 AML samples with biologically matched healthy donors. Recurrent and MLLr-specific alterations in A/B compartments, topologically associating domains and chromatin loops were identified. RNA sequencing in the same AML samples also revealed extensive and recurrent MLLr-specific promoter–enhancer and promoter–silencer loops. Overall, this study highlights the critical regulatory elements and provides rational and effective targeting strategy in MLLr AML.