| scholarly article | Q13442814 |
| P356 | DOI | 10.7554/ELIFE.14864 |
| P8608 | Fatcat ID | release_qgdihb4leza25o6f6fwkqzirqa |
| P932 | PMC publication ID | 4914367 |
| P698 | PubMed publication ID | 27192037 |
| P50 | author | Anton Goloborodko | Q56506820 |
| Leonid Mirny | Q57963609 | ||
| P2093 | author name string | John F Marko | |
| Maxim V Imakaev | |||
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| Organization of the mitotic chromosome | Q33693950 | ||
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| Loops determine the mechanical properties of mitotic chromosomes | Q34117373 | ||
| Integration of the cytogenetic map with the draft human genome sequence | Q34191136 | ||
| Architecture of metaphase chromosomes and chromosome scaffolds | Q34270990 | ||
| Condensin II initiates sister chromatid resolution during S phase. | Q34327315 | ||
| Metaphase chromosome structure: Evidence for a radial loop model | Q66940311 | ||
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| Mitotic chromosomes are chromatin networks without a mechanically contiguous protein scaffold | Q34386361 | ||
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| Visualization of early chromosome condensation: a hierarchical folding, axial glue model of chromosome structure | Q34550665 | ||
| A heterodimeric coiled-coil protein required for mitotic chromosome condensation in vitro | Q34725116 | ||
| The structure of histone-depleted metaphase chromosomes | Q34741905 | ||
| Polymer models of meiotic and mitotic chromosomes | Q34743523 | ||
| SMC condensin entraps chromosomal DNA by an ATP hydrolysis dependent loading mechanism in Bacillus subtilis | Q35640052 | ||
| Chromosomes Progress to Metaphase in Multiple Discrete Steps via Global Compaction/Expansion Cycles. | Q35664788 | ||
| Condensin promotes the juxtaposition of DNA flanking its loading site in Bacillus subtilis. | Q35952752 | ||
| DNA loops generate intracentromere tension in mitosis. | Q35965448 | ||
| An electron microscopic study of mitosis in mouse duodenal crypt cells confirms that the prophasic condensation of chromatin begins during the DNA-synthesizing (S) stage of the cycle | Q36185256 | ||
| Mitotic chromatin condensation in vitro using somatic cell extracts and nuclei with variable levels of endogenous topoisomerase II. | Q36224150 | ||
| Topoisomerase II does not play a scaffolding role in the organization of mitotic chromosomes assembled in Xenopus egg extracts | Q36232430 | ||
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| ChromoShake: a chromosome dynamics simulator reveals that chromatin loops stiffen centromeric chromatin. | Q36412957 | ||
| Chiasma formation: chromatin/axis interplay and the role(s) of the synaptonemal complex | Q36429060 | ||
| Self-organization of domain structures by DNA-loop-extruding enzymes | Q36478028 | ||
| Cell cycle control of higher-order chromatin assembly around naked DNA in vitro | Q36530510 | ||
| Sister chromatid separation in frog egg extracts requires DNA topoisomerase II activity during anaphase | Q36531445 | ||
| Formation of Chromosomal Domains by Loop Extrusion. | Q36957773 | ||
| Mitotic chromosome structure: reproducibility of folding and symmetry between sister chromatids | Q37279188 | ||
| The G-banded prophase chromosomes of man | Q39337232 | ||
| Dynamics of chromosome compaction during mitosis | Q39605350 | ||
| C. elegans condensin promotes mitotic chromosome architecture, centromere organization, and sister chromatid segregation during mitosis and meiosis | Q39753833 | ||
| Maximal chromosome compaction occurs by axial shortening in anaphase and depends on Aurora kinase | Q40122169 | ||
| Biochemical and genetic dissection of mitotic chromosome condensation | Q40372146 | ||
| Drosophila CAP-D2 is required for condensin complex stability and resolution of sister chromatids | Q40415592 | ||
| The size of chromatin loops in HeLa cells | Q41203135 | ||
| OpenMM: A Hardware Independent Framework for Molecular Simulations | Q41566522 | ||
| Scanning electron microscopy of mammalian chromosomes from prophase to telophase | Q41676648 | ||
| Scaling of Linking and Writhing Numbers for Spherically Confined and Topologically Equilibrated Flexible Polymers | Q42757723 | ||
| A Two-Step Scaffolding Model for Mitotic Chromosome Assembly | Q44399616 | ||
| Linking topology of tethered polymer rings with applications to chromosome segregation and estimation of the knotting length | Q45045135 | ||
| Condensin I binds chromatin early in prophase and displays a highly dynamic association with Drosophila mitotic chromosomes | Q47071861 | ||
| A role for Drosophila SMC4 in the resolution of sister chromatids in mitosis. | Q47071869 | ||
| Chromosome protein framework from proteome analysis of isolated human metaphase chromosomes. | Q50948251 | ||
| Condensin I stabilizes chromosomes mechanically through a dynamic interaction in live cells. | Q53635877 | ||
| P407 | language of work or name | English | Q1860 |
| P577 | publication date | 2016-05-18 | |
| P1433 | published in | eLife | Q2000008 |
| P1476 | title | Compaction and segregation of sister chromatids via active loop extrusion | |
| P478 | volume | 5 |
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| Q89720891 | A Well-Mixed E. coli Genome: Widespread Contacts Revealed by Tracking Mu Transposition |
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| Q52597946 | A quantitative map of human Condensins provides new insights into mitotic chromosome architecture. |
| Q33833458 | Bacillus subtilis SMC complexes juxtapose chromosome arms as they travel from origin to terminus. |
| Q60312679 | Bottom-up modeling of chromatin segregation due to epigenetic modifications |
| Q39108692 | Boundaries of loop domains (insulators): Determinants of chromosome form and function in multicellular eukaryotes |
| Q58083865 | CRISPR-Sirius: RNA scaffolds for signal amplification in genome imaging |
| Q47645730 | Caenorhabditis elegans Dosage Compensation: Insights into Condensin-Mediated Gene Regulation |
| Q47320129 | Catching DNA with hoops-biophysical approaches to clarify the mechanism of SMC proteins |
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| Q89451441 | Chromosome Conformation Capture and Beyond: Toward an Integrative View of Chromosome Structure and Function |
| Q91586980 | Chromosome organization by one-sided and two-sided loop extrusion |
| Q92851887 | Cohesin Disrupts Polycomb-Dependent Chromosome Interactions in Embryonic Stem Cells |
| Q57175562 | Computational methods for analyzing and modeling genome structure and organization |
| Q89408874 | Condensin Depletion Causes Genome Decompaction Without Altering the Level of Global Gene Expression in Saccharomyces cerevisiae |
| Q89997946 | Condensin II drives large-scale folding and spatial partitioning of interphase chromosomes in Drosophila nuclei |
| Q58554665 | Condensin action and compaction |
| Q38759535 | Condensin, master organizer of the genome. |
| Q47296411 | Condensins promote chromosome individualization and segregation during mitosis, meiosis, and amitosis in Tetrahymena thermophila |
| Q97531449 | Cryo-EM structures of holo condensin reveal a subunit flip-flop mechanism |
| Q58132113 | DNA Mechanics and Topology |
| Q64980888 | DNA entry, exit and second DNA capture by cohesin: insights from biochemical experiments. |
| Q59074200 | DNA's secret weapon against knots and tangles |
| Q90053773 | DNA-loop extruding condensin complexes can traverse one another |
| Q92599712 | DNA-segment-capture model for loop extrusion by structural maintenance of chromosome (SMC) protein complexes |
| Q92862114 | Differential contribution of steady-state RNA and active transcription in chromatin organization |
| Q36168968 | Dynamic Nucleosome Movement Provides Structural Information of Topological Chromatin Domains in Living Human Cells |
| Q90167031 | Emergent properties of mitotic chromosomes |
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| Q42570932 | Extruding Loops to Make Loopy Globules? |
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| Q36957773 | Formation of Chromosomal Domains by Loop Extrusion. |
| Q38696563 | Genome Organization Drives Chromosome Fragility |
| Q39311049 | Genome organization during the cell cycle: unity in division. |
| Q55341628 | How epigenome drives chromatin folding and dynamics, insights from efficient coarse-grained models of chromosomes. |
| Q64107981 | Live imaging of marked chromosome regions reveals their dynamic resolution and compaction in mitosis |
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| Q89877044 | Organization of the Escherichia coli Chromosome by a MukBEF Axial Core |
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| Q42255573 | SMC complexes differentially compact mitotic chromosomes according to genomic context |
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| Q48266900 | Single-cell Hi-C bridges microscopy and genome-wide sequencing approaches to study 3D chromatin organization. |
| Q42657177 | Structural Basis for a Safety-Belt Mechanism That Anchors Condensin to Chromosomes. |
| Q92937727 | Structural Basis of an Asymmetric Condensin ATPase Cycle |
| Q64068290 | Synergy of topoisomerase and structural-maintenance-of-chromosomes proteins creates a universal pathway to simplify genome topology |
| Q36678954 | The 3D Genome as Moderator of Chromosomal Communication |
| Q46383154 | The Three-Dimensional Organization of Mammalian Genomes |
| Q50144994 | The biology and polymer physics underlying large-scale chromosome organization |
| Q47838187 | The condensin complex is a mechanochemical motor that translocates along DNA. |
| Q90408550 | The regulation of chromosome segregation via centromere loops |
| Q91712155 | Topological Constraints in Eukaryotic Genomes and How They Can Be Exploited to Improve Spatial Models of Chromosomes |
| Q99579421 | Toward understanding the dynamic state of 3D genome |
| Q58609851 | Towards a Unified Model of SMC Complex Function |
| Q42163298 | Transcription-induced supercoiling explains formation of self-interacting chromatin domains in S. pombe |
| Q42183879 | Tuned SMC Arms Drive Chromosomal Loading of Prokaryotic Condensin. |
| Q47035974 | Two independent modes of chromatin organization revealed by cohesin removal |
| Q94656800 | Zooming in on chromosome dynamics |
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