Your search keyword '"Imakaev, M."' showing total 4 results

1. Publisher Correction: Heterochromatin drives compartmentalization of inverted and conventional nuclei.

Author

Falk M, Feodorova Y, Naumova N, Imakaev M, Lajoie BR, Leonhardt H, Joffe B, Dekker J, Fudenberg G, Solovei I, and Mirny LA

Abstract

An Amendment to this paper has been published and can be accessed via a link at the top of the paper.

Published

2019

2. Heterochromatin drives compartmentalization of inverted and conventional nuclei.

Author

Falk M, Feodorova Y, Naumova N, Imakaev M, Lajoie BR, Leonhardt H, Joffe B, Dekker J, Fudenberg G, Solovei I, and Mirny LA

Subjects

Animals, Cell Nucleus genetics, Euchromatin genetics, Euchromatin metabolism, Heterochromatin genetics, Mice, Models, Biological, Nuclear Lamina genetics, Nuclear Lamina metabolism, Time Factors, Cell Compartmentation genetics, Cell Nucleus metabolism, Heterochromatin metabolism

Abstract

The nucleus of mammalian cells displays a distinct spatial segregation of active euchromatic and inactive heterochromatic regions of the genome 1,2 . In conventional nuclei, microscopy shows that euchromatin is localized in the nuclear interior and heterochromatin at the nuclear periphery 1,2 . Genome-wide chromosome conformation capture (Hi-C) analyses show this segregation as a plaid pattern of contact enrichment within euchromatin and heterochromatin compartments 3 , and depletion between them. Many mechanisms for the formation of compartments have been proposed, such as attraction of heterochromatin to the nuclear lamina 2,4 , preferential attraction of similar chromatin to each other 1,4-12 , higher levels of chromatin mobility in active chromatin 13-15 and transcription-related clustering of euchromatin 16,17 . However, these hypotheses have remained inconclusive, owing to the difficulty of disentangling intra-chromatin and chromatin-lamina interactions in conventional nuclei 18 . The marked reorganization of interphase chromosomes in the inverted nuclei of rods in nocturnal mammals 19,20 provides an opportunity to elucidate the mechanisms that underlie spatial compartmentalization. Here we combine Hi-C analysis of inverted rod nuclei with microscopy and polymer simulations. We find that attractions between heterochromatic regions are crucial for establishing both compartmentalization and the concentric shells of pericentromeric heterochromatin, facultative heterochromatin and euchromatin in the inverted nucleus. When interactions between heterochromatin and the lamina are added, the same model recreates the conventional nuclear organization. In addition, our models allow us to rule out mechanisms of compartmentalization that involve strong euchromatin interactions. Together, our experiments and modelling suggest that attractions between heterochromatic regions are essential for the phase separation of the active and inactive genome in inverted and conventional nuclei, whereas interactions of the chromatin with the lamina are necessary to build the conventional architecture from these segregated phases.

Published

2019

3. Single-nucleus Hi-C reveals unique chromatin reorganization at oocyte-to-zygote transition.

Author

Flyamer IM, Gassler J, Imakaev M, Brandão HB, Ulianov SV, Abdennur N, Razin SV, Mirny LA, and Tachibana-Konwalski K

Subjects

Animals, Cell Nucleus genetics, Cell Transdifferentiation, Cellular Reprogramming, Chromatin chemistry, Chromatin genetics, Female, Haploidy, Interphase, Maternal Inheritance genetics, Mice, Nucleic Acid Conformation, Oocytes metabolism, Paternal Inheritance genetics, Stochastic Processes, Totipotent Stem Cells cytology, Totipotent Stem Cells metabolism, Zygote metabolism, Cell Nucleus metabolism, Chromatin metabolism, Chromosome Positioning, Oocytes cytology, Single-Cell Analysis methods, Zygote cytology

Abstract

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.

Published

2017

4. Super-resolution imaging reveals distinct chromatin folding for different epigenetic states.

Author

Boettiger AN, Bintu B, Moffitt JR, Wang S, Beliveau BJ, Fudenberg G, Imakaev M, Mirny LA, Wu CT, and Zhuang X

Subjects

Animals, Cell Line, Chromosome Positioning, Drosophila melanogaster cytology, Epigenetic Repression, Fractals, Genome genetics, Polycomb-Group Proteins metabolism, Transcription, Genetic, Chromatin genetics, Chromatin metabolism, Chromatin Assembly and Disassembly, Drosophila melanogaster genetics, Epigenesis, Genetic

Abstract

Metazoan genomes are spatially organized at multiple scales, from packaging of DNA around individual nucleosomes to segregation of whole chromosomes into distinct territories. At the intermediate scale of kilobases to megabases, which encompasses the sizes of genes, gene clusters and regulatory domains, the three-dimensional (3D) organization of DNA is implicated in multiple gene regulatory mechanisms, but understanding this organization remains a challenge. At this scale, the genome is partitioned into domains of different epigenetic states that are essential for regulating gene expression. Here we investigate the 3D organization of chromatin in different epigenetic states using super-resolution imaging. We classified genomic domains in Drosophila cells into transcriptionally active, inactive or Polycomb-repressed states, and observed distinct chromatin organizations for each state. All three types of chromatin domains exhibit power-law scaling between their physical sizes in 3D and their domain lengths, but each type has a distinct scaling exponent. Polycomb-repressed domains show the densest packing and most intriguing chromatin folding behaviour, in which chromatin packing density increases with domain length. Distinct from the self-similar organization displayed by transcriptionally active and inactive chromatin, the Polycomb-repressed domains are characterized by a high degree of chromatin intermixing within the domain. Moreover, compared to inactive domains, Polycomb-repressed domains spatially exclude neighbouring active chromatin to a much stronger degree. Computational modelling and knockdown experiments suggest that reversible chromatin interactions mediated by Polycomb-group proteins play an important role in these unique packaging properties of the repressed chromatin. Taken together, our super-resolution images reveal distinct chromatin packaging for different epigenetic states at the kilobase-to-megabase scale, a length scale that is directly relevant to genome regulation.

Published

2016