Project description:Chemicals or drugs were demonstrated to accumulate within biomolecule condensates formed through phase separation in cells. Here, we employed super-resolution imaging to search for chemicals that induce phase transition of chromatin at the microscale. We found that adriamycin (doxorubicin), a widely-used chemotherapeutic drug against malignancies, is able to induce local condensation and global conformational change of chromatin in cancer and primary cells. Hi-C and ATAC-seq experiments demonstrated that adriamycin-induced chromatin condensation is accompanied by weakened chromatin interaction within topologically-associated domains, compartment A/B switching, lower chromatin accessibility, and corresponding transcriptomic changes. Mechanistically, adriamycin complexes with histone H1 and induces the phase transition of H1, forming fibrous aggregates in vitro. Our results reveal a new action mechanism of an anti-cancer drug discovered for decades, demonstrate the link between the physical properties of chromatin and gene expression, and suggest that interactions between drugs and biomolecules could exert profound effects on cells.

Project description:Chemicals or drugs were demonstrated to accumulate within biomolecule condensates formed through phase separation in cells. Here, we employed super-resolution imaging to search for chemicals that induce phase transition of chromatin at the microscale. We found that adriamycin (doxorubicin), a widely-used chemotherapeutic drug against malignancies, is able to induce local condensation and global conformational change of chromatin in cancer and primary cells. Hi-C and ATAC-seq experiments demonstrated that adriamycin-induced chromatin condensation is accompanied by weakened chromatin interaction within topologically-associated domains, compartment A/B switching, lower chromatin accessibility, and corresponding transcriptomic changes. Mechanistically, adriamycin complexes with histone H1 and induces the phase transition of H1, forming fibrous aggregates in vitro. Our results reveal a new action mechanism of an anti-cancer drug discovered for decades, demonstrate the link between the physical properties of chromatin and gene expression, and suggest that interactions between drugs and biomolecules could exert profound effects on cells.

Project description:Chemicals or drugs were demonstrated to accumulate within biomolecule condensates formed through phase separation in cells. Here, we employed super-resolution imaging to search for chemicals that induce phase transition of chromatin at the microscale. We found that adriamycin (doxorubicin), a widely-used chemotherapeutic drug against malignancies, is able to induce local condensation and global conformational change of chromatin in cancer and primary cells. Hi-C and ATAC-seq experiments demonstrated that adriamycin-induced chromatin condensation is accompanied by weakened chromatin interaction within topologically-associated domains, compartment A/B switching, lower chromatin accessibility, and corresponding transcriptomic changes. Mechanistically, adriamycin complexes with histone H1 and induces the phase transition of H1, forming fibrous aggregates in vitro. Our results reveal a new action mechanism of an anti-cancer drug discovered for decades, demonstrate the link between the physical properties of chromatin and gene expression, and suggest that interactions between drugs and biomolecules could exert profound effects on cells.

Project description:Chemical-Induced Phase Transition and Global Conformational Reorganization of Chromatin [Hi-C]

Project description:Chemical-Induced Phase Transition and Global Conformational Reorganization of Chromatin [ATAC-seq]

Project description:Chemical-Induced Phase Transition and Global Conformational Reorganization of Chromatin [RNA-seq]

Project description:The chemical pressure approach offers a new paradigm for property control in functional materials. In this work, we disclose a correlation between the β → α pressure-induced phase transition in SnMoO4 and the substitution process of Mo6+ by W6+ in SnMo1-xWxO4 solid solutions (x = 0-1). Special attention is paid to discriminating the role of the lone pair Sn2+ cation from the structural distortive effect along the Mo/W substitution process, which is crucial to disentangle the driven force of the transition phase. Furthermore, the reverse α → β transition observed at high temperature in SnWO4 is rationalized on the same basis as a negative pressure effect associated with a decreasing of W6+ percentage in the solid solution. This work opens a versatile chemical approach in which the types of interactions along the formation of solid solutions are clearly differentiated and can also be used to tune their properties, providing opportunities for the development of new materials.

Project description:In the cell nucleus, each chromosome is confined to a chromosome territory. This spatial organization of chromosomes plays a crucial role in gene regulation and genome stability. An additional level of organization has been discovered at the chromosome scale: the spatial segregation into open and closed chromatins to form two genome-wide compartments. Although considerable progress has been made in our knowledge of chromatin organization, a fundamental issue remains the understanding of its dynamics, especially in cancer. To address this issue, we performed genome-wide mapping of chromatin interactions (Hi-C) over the time after estrogen stimulation of breast cancer cells. To biologically interpret these interactions, we integrated with estrogen receptor α (ERα) binding events, gene expression and epigenetic marks. We show that gene-rich chromosomes as well as areas of open and highly transcribed chromatins are rearranged to greater spatial proximity, thus enabling genes to share transcriptional machinery and regulatory elements. At a smaller scale, differentially interacting loci are enriched for cancer proliferation and estrogen-related genes. Moreover, these loci are correlated with higher ERα binding events and gene expression. Taken together these results reveal the role of a hormone--estrogen--on genome organization, and its effect on gene regulation in cancer.

Project description:Chromatin is reprogrammed after fertilization to produce a totipotent zygote with the potential to generate a new organism. The maternal genome inherited from the oocyte and the paternal genome provided by sperm coexist as separate haploid nuclei in the zygote. How these two epigenetically distinct genomes are spatially organized is poorly understood. Existing chromosome conformation capture-based methods are not applicable to oocytes and zygotes owing to a paucity of material. To study three-dimensional chromatin organization in rare cell types, we developed a single-nucleus Hi-C (high-resolution chromosome conformation capture) protocol that provides greater than tenfold more contacts per cell than the previous method. Here we show that chromatin architecture is uniquely reorganized during the oocyte-to-zygote transition in mice and is distinct in paternal and maternal nuclei within single-cell zygotes. Features of genomic organization including compartments, topologically associating domains (TADs) and loops are present in individual oocytes when averaged over the genome, but the presence of each feature at a locus varies between cells. At the sub-megabase level, we observed stochastic clusters of contacts that can occur across TAD boundaries but average into TADs. Notably, we found that TADs and loops, but not compartments, are present in zygotic maternal chromatin, suggesting that these are generated by different mechanisms. Our results demonstrate that the global chromatin organization of zygote nuclei is fundamentally different from that of other interphase cells. An understanding of this zygotic chromatin 'ground state' could potentially provide insights into reprogramming cells to a state of totipotency.

Project description: Not available