Project description:We demonstrates that pre-translational mammalian mRNPs fold as linear rod-like structures with no strong propensity for 5' and 3' end interaction.

Project description: Not available

Project description:TADs are 3D structural units of higher-order chromosome organization in Drosophila

Project description:Abnormal chromatin structure is one of the hallmarks in cancer and has long been used for cancer diagnosis, but the observed aberrant chromatin structures characteristic of cancer cells is limited to microscale features, largely due to due to the diffraction-limited resolution of conventional light microscopy. Recent advances in super-resolution microscopy overcome the technical limitations of conventional light microscopy and enable the in-situ visualization of the higher-order chromatin structure down to ~30 nm. Here we present PathSTORM, a variant of stochastic optical reconstruction microscopy (STORM) optimized for super-resolution imaging of densely packed higher-order chromatin organization at different epigenomic states on pathological tissue. We then apply this tool to characterize the structural alteration of higher-order heterochromatin, enriched with H3K9me3 and satellite repeats, at various stages of carcinogenesis in mouse models and human tissue specimens. PathSTORM reveals that a significant disruption of higher-order heterochromatin structure occurs in early carcinogenesis when tissue still appears histologically normal and becomes progressively severe during neoplastic progression. The disrupted higher-order heterochromatin structure also appears to be a common feature that reflects the evolution of carcinogenesis independent of molecular pathways in multiple tumor types. Taken together, PathSTORM can serve as a powerful tool to visualize higher-order chromatin structure in the spatial context of tissue architecture on pathological tissue. Our findings provide new insights on the role of higher-order heterochromatin structure in carcinogenesis, especially at the early stage, and have the potential for improving cancer diagnosis, risk stratification and facilitating the development and evaluation of new preventive strategies.

Project description:DNA methylation maintains integrity of higher order genome architecture

Project description:Eukaryotic genomes are folded into three-dimensional (3D) hierarchical architectures consisting of multi-way chromatin contacts that are involved in complex gene regulation. High-throughput chromosome conformation capture (Hi-C), chromatin interaction analysis by paired-end tag sequencing (ChIA-PET) , and methods similar to these two rely on pairwise ligation of fragments in proximity in a population of cells, thus fail to reveal multi-way chromatin interactions in single allele at single fragment resolution. To explore higher-order chromatin interaction genome-widely, a straightforward strategy is integrating multi-fragment ligates preparation with third-generation sequencing technology. To achieve this purpose, we developed a protocol of in situ high throughput multi-way contact long read Pore-C sequencing (in situ HiPore-C) We performed genome-wide multi-way contact profiling analysis using data obtained from in situ HiPore-C sequencing of GM12878 and K562 cell lines.

Project description:TOPORS, a tumor suppressor protein, maintains higher-order chromatin organization in mouse hepatocytes

Project description:Higher-order inter-chromosomal hubs shape 3-dimensional genome organization in the nucleus

Project description:Co-opted transposons help perpetuate conserved higher-order chromosomal structures

Project description:Gamma entrainment binds higher order brain regions and alleviates neurodegeneration