Project description:Despite the growing interest in studying the mammalian genome organization, it is still challenging to map the DNA contacts genome-wide. Here we present easy Hi-C (eHi-C), a highly efficient method for unbiased mapping of 3D genome architecture. The eHi-C protocol only involves a series of enzymatic reactions and maximizes the recovery of DNA products from proximity ligation. We show that eHi-C can be performed with 0.1 million cells and yields high quality libraries comparable to Hi-C.

Project description:High-resolution mapping of the gene regulatory chromatin interactions from noisy Hi-C contact heatmaps remains a major challenge in 3D genome research due to the complex bias structure and severe data sparsity. Here we present DeepLoop, which addresses this problem by combining a rigorous bias correction strategy (HiCorr) and deep learning-based signal enhancement techniques. We demonstrated that DeepLoop can robustly identify high-resolution chromatin interactions from low-depth and single cell Hi-C data. With DeepLoop, we for the first-time mapped the genetic and epigenetic determinants of human homolog-specific chromatin loops in GM12878 cells at 5kb-resolution. We nominated two new imprinting loci with unbalanced DNA folding in additional to the well-known H19/IGF2 locus. Interestingly, we also found that the sub-TAD loops at the DXZ4 “megadomain” boundary escapes X-inactivation, but the loops at the FIRRE “superloop” locus do not escape. Unexpectedly, DeepLoop detected four previously unknown Mb-sized heterozygous structure variants in the GM12878 genome, including two large inversions causing allele-specific gene expression via enhancer rewiring. Finally, DeepLoop also pinpointed dozens of loop regulatory SNPs that often have transcriptional consequences. Taken together, DeepLoop expands the use of Hi-C to provide genome-wide insights into the genetics of 3D genome at loop resolution.

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:We studied genome topology dynamics during reprogramming of different somatic cell types with highly distinct genome conformations. We find large-scale TAD repositioning and alterations of tissue-restricted genomic neighborhoods and chromatin loops, effectively erasing the somatic cell specific genome structures while establishing an embryonic stem cell-like 3D genome. Yet, early passage iPSCs carry topological hallmarks that enable discerning their cell-of-origin. These hallmarks are not remnants of somatic chromosome topologies. Instead, the distinguishing topological features are acquired during reprogramming, as we also find for cell-of-origin dependent gene expression patterns. Hi-C was performed in somatic cells (NSC, macrophages, MEFs and pre-B cells) and their corresponding early and late induced pluripotent stem cells. In addition Hi-C was performed in E14 embryonic stem cells

Project description:Genome-wide mapping of chromatin interactions at high resolution remains experimentally and computationally challenging. Here we used a low-input “easy Hi-C” protocol to map the 3D genome architecture in human neurogenesis and brain tissues and also demonstrated that a rigorous Hi-C bias-correction pipeline (HiCorr) can significantly improve the sensitivity and robustness of Hi-C loop identification at sub-TAD level, especially the enhancer-promoter (E-P) interactions. We used HiCorr to compare the high-resolution maps of chromatin interactions from 10 tissue or cell types with a focus on neurogenesis and brain tissues. We found that dynamic chromatin loops are better hallmarks for cellular differentiation than compartment switching. HiCorr allowed direct observation of cell-type- and differentiation-specific E-P aggregates spanning large neighborhoods, suggesting a mechanism that stabilizes enhancer contacts during development. Interestingly, we concluded that Hi-C loop outperforms eQTL in explaining neurological GWAS results, revealing a unique value of high-resolution 3D genome maps in elucidating the disease etiology.

Project description:Conformation capture-approaches like Hi-C can elucidate chromosome structure at a genome-wide scale. Hi-C datasets are large and require specialised software. Here, we present GENOVA: a user-friendly software package to analyse and visualise conformation capture data. GENOVA is an R-package that includes the most common Hi-C analyses, such as compartment and insulation score analysis. It can create annotated heatmaps to visualise the contact frequency at a specific locus and aggregate Hi-C signal over a user-specified genomic regions such as ChIP-seq data. Finally, our package supports output from the major mapping-pipelines. We demonstrate the capabilities of GENOVA by analysing Hi-C data from HAP1 cell lines in which the cohesin-subunits SA1 and SA2 were knocked out. We find that ΔSA1 cells gain intra-TAD interactions and increase compartmentalisation. ΔSA2 cells have longer loops and a less compartmentalised genome. These results suggest that cohesinSA1 forms longer loops, while cohesinSA2 plays a role in forming and maintaining intra-TAD interactions. The differences in loop-forming activity affect whole chromosome organisation consistent with a model where loops and compartments counterbalance each other. We show that GENOVA is an easy to use R-package, that allows researchers to explore Hi-C data in great detail.

Project description:Studying the conservation and differences of regulation between human and mouse helps understand gene regulation on mouse models. Chromatin loop is an important gene regulatory mechanism to drive the 3D regulation between genes and their regulatory elements. Here, we performed eHi-C to profile genome wide contacts in mouse strains B6 and CAST islet beta cells, together with the loops identified in human islet alpha and beta cells from previous studies (GSE195523). The results show that the conserved chromation loop and open chromatin regions highlight the function of T2D risk loci and improve our understanding in islet biology.

Project description:Liver cancer, particularly hepatocellular carcinoma (HCC), poses a significant global threat to human lives. To advance the development of innovative diagnostic and treatment approaches, it is essential to examine the hidden features of HCC, particularly its 3D genome architecture, which is not well understood. In this study, we investigated the 3D genome organization of four HCC cell lines—Hep3B, Huh1, Huh7, and SNU449—using in situ Hi-C and ATAC-seq. Our findings revealed that HCCs had elevated long-range interactions compared to HMECs, both intra- and interchromosomal. Unexpectedly, they displayed cell line-specific compartmental modifications at the Mb scale, which could aid in determining HCC subtypes. At the sub-Mb scale, we observed a decrease in intra-TAD interactions and chromatin loops in HCCs compared to HMECs. Lastly, we discovered a correlation between gene expression and 3D chromatin architecture in SLC8A1, which encodes the sodium-calcium antiporter known to induce apoptosis. Our findings suggest that HCCs have a distinct 3D genome organization that is different from normal and other cancer cells. Overall, we take this as evidence that genome organization plays a crucial role in cancer phenotype determination. Further exploration of epigenetics in HCC will lead us to a better understanding of specific gene regulation mechanisms and uncover novel targets for cancer treatments.

Project description:Liver cancer, particularly hepatocellular carcinoma (HCC), poses a significant global threat to human lives. To advance the development of innovative diagnostic and treatment approaches, it is essential to examine the hidden features of HCC, particularly its 3D genome architecture, which is not well understood. In this study, we investigated the 3D genome organization of four HCC cell lines—Hep3B, Huh1, Huh7, and SNU449—using in situ Hi-C and ATAC-seq. Our findings revealed that HCCs had elevated long-range interactions compared to HMECs, both intra- and interchromosomal. Unexpectedly, they displayed cell line-specific compartmental modifications at the Mb scale, which could aid in determining HCC subtypes. At the sub-Mb scale, we observed a decrease in intra-TAD interactions and chromatin loops in HCCs compared to HMECs. Lastly, we discovered a correlation between gene expression and 3D chromatin architecture in SLC8A1, which encodes the sodium-calcium antiporter known to induce apoptosis. Our findings suggest that HCCs have a distinct 3D genome organization that is different from normal and other cancer cells. Overall, we take this as evidence that genome organization plays a crucial role in cancer phenotype determination. Further exploration of epigenetics in HCC will lead us to a better understanding of specific gene regulation mechanisms and uncover novel targets for cancer treatments.

Project description:We describe Hi-C, a method that probes the three-dimensional architecture of whole genomes by coupling proximity-based ligation with massively parallel sequencing. We constructed spatial proximity maps of the human genome with Hi-C at a resolution of 1Mb. These maps confirm the presence of chromosome territories and the spatial proximity of small, gene-rich chromosomes. We identified an additional level of genome organization that is characterized by the spatial segregation of open and closed chromatin to form two genome-wide compartments. At the megabase scale, the chromatin conformation is consistent with a fractal globule, a knot-free conformation that enables maximally dense packing while preserving the ability to easily fold and unfold any genomic locus. The fractal globule is distinct from the more commonly used globular equilibrium model. Our results demonstrate the power of Hi-C to map the dynamic conformations of whole genomes. The processed heatmap data, showing the number of read pairs corresponding to particular locus pairs in the genome, are linked to the Series record below. The processed eigenvector data used to generate the heatmaps are linked to the Series record below. Additional DNAseI and ChIP-Seq data tracks were used in the paper, and are available at the UCSC browser (http://genome.ucsc.edu/) DNAseI: wgEncodeUwDnaseSeqRawSignalRep2K562 wgEncodeUwDnaseSeqRawSignalRep2Gm06990 ChIP-Seq: wgEncodeBroadChipSeqSignalGm12878H3k36me3 wgEncodeBroadChipSeqSignalGm12878H3k27me3 Interaction maps in 2 different cell types.