Understanding Spatial Genome Organization: Methods and Insights

The manner by which eukaryotic genomes are packaged into nuclei while maintaining crucial nuclear functions remains one of the fundamental mysteries in biology. Over the last ten years, we have witnessed rapid advances in both microscopic and nucleic acid-based approaches to map genome architecture, and the application of these approaches to the dissection of higher-order chromosomal structures has yielded much new information. It is becoming increasingly clear, for example, that interphase chromosomes form stable, multilevel hierarchical structures. Among them, self-associating domains like so-called topologically associating domains (TADs) appear to be building blocks for large-scale genomic organization. This review describes features of these broadly-defined hierarchical structures, insights into the mechanisms underlying their formation, our current understanding of how interactions in the nuclear space are linked to gene regulation, and important future directions for the field.

[1]  Wolfgang Huber,et al.  Enhancer loops appear stable during development and are associated with paused polymerase , 2014, Nature.

[2]  A. Tanay,et al.  Single cell Hi-C reveals cell-to-cell variability in chromosome structure , 2013, Nature.

[3]  William Stafford Noble,et al.  The lncRNA Firre anchors the inactive X chromosome to the nucleolus by binding CTCF and maintains H3K27me3 methylation , 2015, Genome Biology.

[4]  Peter R Cook,et al.  A model for all genomes: the role of transcription factories. , 2010, Journal of molecular biology.

[5]  Timothy E. Reddy,et al.  Highly Specific Epigenome Editing by CRISPR/Cas9 Repressors for Silencing of Distal Regulatory Elements , 2015, Nature Methods.

[6]  Jill M Dowen,et al.  Control of Cell Identity Genes Occurs in Insulated Neighborhoods in Mammalian Chromosomes , 2014, Cell.

[7]  David R. Kelley,et al.  Topological organization of multichromosomal regions by the long intergenic noncoding RNA Firre , 2014, Nature Structural &Molecular Biology.

[8]  Jennifer A. Mitchell,et al.  Preferential associations between co-regulated genes reveal a transcriptional interactome in erythroid cells , 2010, Nature Genetics.

[9]  Nir Friedman,et al.  Mapping Nucleosome Resolution Chromosome Folding in Yeast by Micro-C , 2015, Cell.

[10]  Thomas Cremer,et al.  The 4D nucleome: Evidence for a dynamic nuclear landscape based on co‐aligned active and inactive nuclear compartments , 2015, FEBS letters.

[11]  A. Tanay,et al.  Single-cell epigenomics: techniques and emerging applications , 2015, Nature Reviews Genetics.

[12]  E. Lander,et al.  The Xist lncRNA Exploits Three-Dimensional Genome Architecture to Spread Across the X Chromosome , 2013, Science.

[13]  B. Ren,et al.  The 3D genome in transcriptional regulation and pluripotency. , 2014, Cell stem cell.

[14]  J. Dekker,et al.  Predictive Polymer Modeling Reveals Coupled Fluctuations in Chromosome Conformation and Transcription , 2014, Cell.

[15]  Peter H. L. Krijger,et al.  CTCF Binding Polarity Determines Chromatin Looping. , 2015, Molecular cell.

[16]  Yusuke Miyanari,et al.  Live visualization of chromatin dynamics with fluorescent TALEs , 2013, Nature Structural &Molecular Biology.

[17]  Matthew C. Canver,et al.  BCL11A enhancer dissection by Cas9-mediated in situ saturating mutagenesis , 2015, Nature.

[18]  J. Dekker,et al.  Genomics tools for the unraveling of chromosome architecture , 2010, Nature Biotechnology.

[19]  P. Kaufman,et al.  Grabbing the genome by the NADs , 2015, Chromosoma.

[20]  Zhijun Duan,et al.  The genome in space and time: Does form always follow function? , 2012, BioEssays : news and reviews in molecular, cellular and developmental biology.

[21]  P. Gregory,et al.  Controlling Long-Range Genomic Interactions at a Native Locus by Targeted Tethering of a Looping Factor , 2012, Cell.

[22]  Wendy A. Bickmore,et al.  The Radial Positioning of Chromatin Is Not Inherited through Mitosis but Is Established De Novo in Early G1 , 2004, Current Biology.

[23]  Zhaohui S. Qin,et al.  Gene density, transcription, and insulators contribute to the partition of the Drosophila genome into physical domains. , 2012, Molecular cell.

[24]  A. Pombo,et al.  Three-dimensional genome architecture: players and mechanisms , 2015, Nature Reviews Molecular Cell Biology.

[25]  V. Corces,et al.  CTCF: Master Weaver of the Genome , 2009, Cell.

[26]  Roland Eils,et al.  Global Chromosome Positions Are Transmitted through Mitosis in Mammalian Cells , 2003, Cell.

[27]  T. Misteli Beyond the Sequence: Cellular Organization of Genome Function , 2011 .

[28]  D. Weitz,et al.  Single-cell ChIP-seq reveals cell subpopulations defined by chromatin state , 2015, Nature Biotechnology.

[29]  S. Henikoff,et al.  Identification of in vivo DNA targets of chromatin proteins using tethered Dam methyltransferase , 2000, Nature Biotechnology.

[30]  K. Sandhu,et al.  Circular chromosome conformation capture (4C) uncovers extensive networks of epigenetically regulated intra- and interchromosomal interactions , 2006, Nature Genetics.

[31]  Mingzhu Wang,et al.  Cryo-EM Study of the Chromatin Fiber Reveals a Double Helix Twisted by Tetranucleosomal Units , 2014, Science.

[32]  Thomas Cremer,et al.  Multicolor 3D fluorescence in situ hybridization for imaging interphase chromosomes. , 2008, Methods in molecular biology.

[33]  Gail Mandel,et al.  A High-Resolution Imaging Approach to Investigate Chromatin Architecture in Complex Tissues , 2015, Cell.

[34]  Joan-Ramon Daban,et al.  Electron microscopy and atomic force microscopy studies of chromatin and metaphase chromosome structure. , 2011, Micron.

[35]  C. Barbas,et al.  ZFN, TALEN, and CRISPR/Cas-based methods for genome engineering. , 2013, Trends in biotechnology.

[36]  Jeannie T. Lee Epigenetic Regulation by Long Noncoding RNAs , 2012, Science.

[37]  Cole Trapnell,et al.  Defining cell types and states with single-cell genomics , 2015, Genome research.

[38]  E. Callaway The revolution will not be crystallized: a new method sweeps through structural biology , 2015, Nature.

[39]  Yaniv Lubling,et al.  Single-cell Hi-C for genome-wide detection of chromatin interactions that occur simultaneously in a single cell , 2015, Nature Protocols.

[40]  Romain Koszul,et al.  Condensin- and Replication-Mediated Bacterial Chromosome Folding and Origin Condensation Revealed by Hi-C and Super-resolution Imaging. , 2015, Molecular cell.

[41]  Tiago Branco,et al.  Changes in chromosome organization during PHA-activation of resting human lymphocytes measured by cryo-FISH , 2008, Chromosome Research.

[42]  Maitreya J. Dunham,et al.  Species-Level Deconvolution of Metagenome Assemblies with Hi-C–Based Contact Probability Maps , 2014, G3: Genes, Genomes, Genetics.

[43]  Viviana I. Risca,et al.  Unraveling the 3D genome: genomics tools for multiscale exploration. , 2015, Trends in genetics : TIG.

[44]  J. Dekker,et al.  Capturing Chromosome Conformation , 2002, Science.

[45]  W. D. Laat,et al.  A Decade of 3c Technologies: Insights into Nuclear Organization References , 2022 .

[46]  Philip A. Ewels,et al.  Mapping long-range promoter contacts in human cells with high-resolution capture Hi-C , 2015, Nature Genetics.

[47]  Jay Shendure,et al.  Saturation Editing of Genomic Regions by Multiplex Homology-Directed Repair , 2014, Nature.

[48]  Christopher M. Vockley,et al.  Epigenome editing by a CRISPR/Cas9-based acetyltransferase activates genes from promoters and enhancers , 2015, Nature Biotechnology.

[49]  Steven Henikoff,et al.  Histone variants — ancient wrap artists of the epigenome , 2010, Nature Reviews Molecular Cell Biology.

[50]  M. Gustafsson,et al.  Subdiffraction Multicolor Imaging of the Nuclear Periphery with 3D Structured Illumination Microscopy , 2008, Science.

[51]  J. Joung,et al.  Locus-specific editing of histone modifications at endogenous enhancers using programmable TALE-LSD1 fusions , 2013, Nature Biotechnology.

[52]  Philip D. Gregory,et al.  Reactivation of Developmentally Silenced Globin Genes by Forced Chromatin Looping , 2014, Cell.

[53]  Yuri R. Bendaña,et al.  Functional footprinting of regulatory DNA , 2015, Nature Methods.

[54]  R. Schneider,et al.  Dynamics and interplay of nuclear architecture, genome organization, and gene expression. , 2007, Genes & development.

[55]  Juliet A. Ellis,et al.  The spatial organization of human chromosomes within the nuclei of normal and emerin-mutant cells. , 2001, Human molecular genetics.

[56]  E. Liu,et al.  An Oestrogen Receptor α-bound Human Chromatin Interactome , 2009, Nature.

[57]  A. Conesa,et al.  Initial Genomics of the Human Nucleolus , 2010, PLoS genetics.

[58]  J. Dekker,et al.  The hierarchy of the 3D genome. , 2013, Molecular cell.

[59]  Ilya M. Flyamer,et al.  Active chromatin and transcription play a key role in chromosome partitioning into topologically associating domains , 2016, Genome research.

[60]  Jan-Fang Cheng,et al.  Loss of silent-chromatin looping and impaired imprinting of DLX5 in Rett syndrome , 2005, Nature Genetics.

[61]  Li Wang,et al.  Perinuclear Anchoring of H3K9-Methylated Chromatin Stabilizes Induced Cell Fate in C. elegans Embryos , 2015, Cell.

[62]  P. Cook,et al.  Supercoils in human DNA. , 1975, Journal of cell science.

[63]  J. Dekker,et al.  Structural and functional diversity of Topologically Associating Domains , 2015, FEBS letters.

[64]  Erik Splinter,et al.  Looping and interaction between hypersensitive sites in the active beta-globin locus. , 2002, Molecular cell.

[65]  P. Park ChIP–seq: advantages and challenges of a maturing technology , 2009, Nature Reviews Genetics.

[66]  X. Zhuang,et al.  Spatially resolved, highly multiplexed RNA profiling in single cells , 2015, Science.

[67]  Melike Lakadamyali,et al.  Advanced microscopy methods for visualizing chromatin structure , 2015, FEBS letters.

[68]  J. Dekker,et al.  Condensin-Driven Remodeling of X-Chromosome Topology during Dosage Compensation , 2015, Nature.

[69]  Raymond K. Auerbach,et al.  Extensive Promoter-Centered Chromatin Interactions Provide a Topological Basis for Transcription Regulation , 2012, Cell.

[70]  J. Sedat,et al.  Spatial partitioning of the regulatory landscape of the X-inactivation centre , 2012, Nature.

[71]  A. Tanay,et al.  Three-Dimensional Folding and Functional Organization Principles of the Drosophila Genome , 2012, Cell.

[72]  L. Wessels,et al.  Domain organization of human chromosomes revealed by mapping of nuclear lamina interactions , 2008, Nature.

[73]  George M. Church,et al.  Highly Multiplexed Subcellular RNA Sequencing in Situ , 2014, Science.

[74]  John F. Marko,et al.  Self-organization of domain structures by DNA-loop-extruding enzymes , 2012, Nucleic acids research.

[75]  Victor V Lobanenkov,et al.  A novel sequence-specific DNA binding protein which interacts with three regularly spaced direct repeats of the CCCTC-motif in the 5'-flanking sequence of the chicken c-myc gene. , 1990, Oncogene.

[76]  X. Zhuang,et al.  Breaking the Diffraction Barrier: Super-Resolution Imaging of Cells , 2010, Cell.

[77]  A. Visel,et al.  Disruptions of Topological Chromatin Domains Cause Pathogenic Rewiring of Gene-Enhancer Interactions , 2015, Cell.

[78]  Jesse R. Dixon,et al.  Topological Domains in Mammalian Genomes Identified by Analysis of Chromatin Interactions , 2012, Nature.

[79]  Thomas Cremer,et al.  Replication-timing-correlated spatial chromatin arrangements in cancer and in primate interphase nuclei , 2008, Journal of Cell Science.

[80]  R. Tjian,et al.  Dynamics of CRISPR-Cas9 genome interrogation in living cells , 2015, Science.

[81]  Long Cai,et al.  Single cell systems biology by super-resolution imaging and combinatorial labeling , 2012, Nature Methods.

[82]  Elizabeth Kerr,et al.  Recruitment to the Nuclear Periphery Can Alter Expression of Genes in Human Cells , 2008, PLoS genetics.

[83]  Wouter de Laat,et al.  Getting the genome in shape: the formation of loops, domains and compartments , 2015, Genome Biology.

[84]  Giacomo Cavalli,et al.  Chromatin-driven behavior of topologically associating domains. , 2015, Journal of molecular biology.

[85]  P. Chambon,et al.  Electron microscopic and biochemical evidence that chromatin structure is a repeating unit , 1975, Cell.

[86]  C. Nusbaum,et al.  Chromosome Conformation Capture Carbon Copy (5C): a massively parallel solution for mapping interactions between genomic elements. , 2006, Genome research.

[87]  Giacomo Cavalli,et al.  The Role of Chromosome Domains in Shaping the Functional Genome , 2015, Cell.

[88]  Howard Y. Chang,et al.  Genomic maps of long noncoding RNA occupancy reveal principles of RNA-chromatin interactions. , 2011, Molecular cell.

[89]  L. Mirny,et al.  High-Resolution Mapping of the Spatial Organization of a Bacterial Chromosome , 2013, Science.

[90]  David A. Orlando,et al.  Mediator and Cohesin Connect Gene Expression and Chromatin Architecture , 2010, Nature.

[91]  L. Mirny,et al.  Exploring the three-dimensional organization of genomes: interpreting chromatin interaction data , 2013, Nature Reviews Genetics.

[92]  Peter Teague,et al.  Differences in the Localization and Morphology of Chromosomes in the Human Nucleus , 1999, The Journal of cell biology.

[93]  Robert S. Illingworth,et al.  Chromatin decondensation is sufficient to alter nuclear organization in embryonic stem cells , 2014, Science.

[94]  B. Steensel,et al.  Nuclear organization of active and inactive chromatin domains uncovered by chromosome conformation capture–on-chip (4C) , 2006, Nature Genetics.

[95]  I. Clay,et al.  Transcription factories and nuclear organization of the genome. , 2010, Cold Spring Harbor symposia on quantitative biology.

[96]  A. Wood,et al.  Condensin and cohesin complexity: the expanding repertoire of functions , 2010, Nature Reviews Genetics.

[97]  Roger D. Kornberg,et al.  Stable Chromosome Condensation Revealed by Chromosome Conformation Capture , 2015, Cell.

[98]  E. Lander,et al.  Identification and characterization of essential genes in the human genome , 2015, Science.

[99]  Yan Li,et al.  A high-resolution map of three-dimensional chromatin interactome in human cells , 2013, Nature.

[100]  Howard Y. Chang,et al.  A long noncoding RNA maintains active chromatin to coordinate homeotic gene expression , 2011, Nature.

[101]  E. Betzig,et al.  Imaging live-cell dynamics and structure at the single-molecule level. , 2015, Molecular cell.

[102]  T. Cremer,et al.  Evolutionary conservation of chromosome territory arrangements in cell nuclei from higher primates , 2002, Proceedings of the National Academy of Sciences of the United States of America.

[103]  D. Ward,et al.  Immunological method for mapping genes on Drosophila polytene chromosomes. , 1982, Proceedings of the National Academy of Sciences of the United States of America.

[104]  Neville E. Sanjana,et al.  Genome-Scale CRISPR-Cas9 Knockout Screening in Human Cells , 2014, Science.

[105]  S. Dalton,et al.  Evolutionarily conserved replication timing profiles predict long-range chromatin interactions and distinguish closely related cell types. , 2010, Genome research.

[106]  J. Lis,et al.  Imaging RNA Polymerase II transcription sites in living cells. , 2014, Current opinion in genetics & development.

[107]  Matteo Pellegrini,et al.  Genome-wide Hi-C analyses in wild-type and mutants reveal high-resolution chromatin interactions in Arabidopsis. , 2014, Molecular cell.

[108]  I. Amit,et al.  Comprehensive mapping of long range interactions reveals folding principles of the human genome , 2011 .

[109]  M. Gobbi,et al.  Analysis of hundreds of cis-regulatory landscapes at high resolution in a single, high-throughput experiment , 2014, Nature Genetics.

[110]  J. Dekker,et al.  The long-range interaction landscape of gene promoters , 2012, Nature.

[111]  Sigal Shachar,et al.  3D Chromosome Regulatory Landscape of Human Pluripotent Cells. , 2016, Cell stem cell.

[112]  Marc W. Schmid,et al.  Hi-C analysis in Arabidopsis identifies the KNOT, a structure with similarities to the flamenco locus of Drosophila. , 2014, Molecular cell.

[113]  Chee Seng Chan,et al.  CTCF-Mediated Functional Chromatin Interactome in Pluripotent Cells , 2011, Nature Genetics.

[114]  A. West,et al.  The Protein CTCF Is Required for the Enhancer Blocking Activity of Vertebrate Insulators , 1999, Cell.

[115]  Dariusz M Plewczynski,et al.  CTCF-Mediated Human 3D Genome Architecture Reveals Chromatin Topology for Transcription , 2015, Cell.

[116]  Siddharth S. Dey,et al.  Genome-wide Maps of Nuclear Lamina Interactions in Single Human Cells , 2015, Cell.

[117]  E. Rebar,et al.  Genome editing with engineered zinc finger nucleases , 2010, Nature Reviews Genetics.

[118]  Ian M. Carr,et al.  The proteomes of transcription factories containing RNA polymerases I, II or III , 2011, Nature Methods.

[119]  G. Blobel,et al.  Manipulating nuclear architecture. , 2014, Current opinion in genetics & development.

[120]  William Stafford Noble,et al.  Bipartite structure of the inactive mouse X chromosome , 2015, Genome Biology.

[121]  Howard Y. Chang,et al.  Revealing long noncoding RNA architecture and functions using domain-specific chromatin isolation by RNA purification , 2014, Nature Biotechnology.

[122]  Jean-Marie Rouillard,et al.  Versatile design and synthesis platform for visualizing genomes with Oligopaint FISH probes , 2012, Proceedings of the National Academy of Sciences.

[123]  B. Bernstein,et al.  Charting histone modifications and the functional organization of mammalian genomes , 2011, Nature Reviews Genetics.

[124]  Thomas Cremer,et al.  The potential of 3D‐FISH and super‐resolution structured illumination microscopy for studies of 3D nuclear architecture , 2012, BioEssays : news and reviews in molecular, cellular and developmental biology.

[125]  K. Hansen,et al.  Reconstructing A/B compartments as revealed by Hi-C using long-range correlations in epigenetic data , 2015, Genome Biology.

[126]  Erez Lieberman Aiden,et al.  The expanding scope of DNA sequencing , 2012, Nature Biotechnology.

[127]  Reza Kalhor,et al.  Genome architectures revealed by tethered chromosome conformation capture and population-based modeling , 2011, Nature Biotechnology.

[128]  William Stafford Noble,et al.  Three-dimensional modeling of the P. falciparum genome during the erythrocytic cycle reveals a strong connection between genome architecture and gene expression , 2014, Genome research.

[129]  Tom Misteli,et al.  Tissue-specific spatial organization of genomes , 2004, Genome Biology.

[130]  Andrew C. Adey,et al.  Multiplex single-cell profiling of chromatin accessibility by combinatorial cellular indexing , 2015, Science.

[131]  Neva C. Durand,et al.  Chromatin extrusion explains key features of loop and domain formation in wild-type and engineered genomes , 2015, Proceedings of the National Academy of Sciences.

[132]  Jeffry D Sander,et al.  Targeted DNA demethylation and activation of endogenous genes using programmable TALE-TET1 fusion proteins , 2013, Nature Biotechnology.

[133]  Shawn M. Gillespie,et al.  Insulator dysfunction and oncogene activation in IDH mutant gliomas , 2015, Nature.

[134]  M. Groudine,et al.  Controlling the double helix , 2003, Nature.

[135]  William Stafford Noble,et al.  A Three-Dimensional Model of the Yeast Genome , 2010, Nature.

[136]  Job Dekker,et al.  Cohesin-dependent globules and heterochromatin shape 3D genome architecture in S. pombe , 2014, Nature.

[137]  E. Lander,et al.  Genetic Screens in Human Cells Using the CRISPR-Cas9 System , 2013, Science.

[138]  Cherisse R. Loucks,et al.  Chromosome Organization by a Nucleoid-Associated Protein in Live Bacteria , 2011, Science.

[139]  Timur Zhiyentayev,et al.  Single-cell in situ RNA profiling by sequential hybridization , 2014, Nature Methods.

[140]  W. Bickmore,et al.  Single-Cell Dynamics of Genome-Nuclear Lamina Interactions , 2013, Cell.

[141]  Michael Q. Zhang,et al.  CRISPR Inversion of CTCF Sites Alters Genome Topology and Enhancer/Promoter Function , 2015, Cell.

[142]  D. Spector,et al.  Visualization of gene activity in living cells , 2000, Nature Cell Biology.

[143]  P. Flicek,et al.  Molecular maps of the reorganization of genome-nuclear lamina interactions during differentiation. , 2010, Molecular cell.

[144]  Ugljesa Djuric,et al.  Open and closed domains in the mouse genome are configured as 10‐nm chromatin fibres , 2012, EMBO reports.

[145]  Jesse R. Dixon,et al.  Cohesin and CTCF differentially affect chromatin architecture and gene expression in human cells , 2013, Proceedings of the National Academy of Sciences.

[146]  D. Bazett-Jones,et al.  A view of the chromatin landscape. , 2012, Micron.

[147]  Tom Misteli,et al.  Biogenesis of nuclear bodies. , 2010, Cold Spring Harbor perspectives in biology.

[148]  William Stafford Noble,et al.  Analysis methods for studying the 3D architecture of the genome , 2015, Genome Biology.

[149]  A. Lamond,et al.  High-Resolution Whole-Genome Sequencing Reveals That Specific Chromatin Domains from Most Human Chromosomes Associate with Nucleoli , 2010, Molecular biology of the cell.

[150]  Tom Misteli,et al.  The Meaning of Gene Positioning , 2008, Cell.

[151]  Jing Liang,et al.  Chromatin architecture reorganization during stem cell differentiation , 2015, Nature.

[152]  Chris Anderson,et al.  Beyond the Sequence , 2015 .

[153]  T. Cremer,et al.  Chromosome territories. , 2010, Cold Spring Harbor perspectives in biology.

[154]  W. Sung,et al.  Chromatin connectivity maps reveal dynamic promoter–enhancer long-range associations , 2013, Nature.

[155]  M. Garcia-Parajo,et al.  Chromatin Fibers Are Formed by Heterogeneous Groups of Nucleosomes In Vivo , 2015, Cell.

[156]  Sigal Shachar,et al.  Identification of Gene Positioning Factors Using High-Throughput Imaging Mapping , 2015, Cell.

[157]  D. Toomre,et al.  A new wave of cellular imaging. , 2010, Annual review of cell and developmental biology.

[158]  T. Misteli,et al.  Long-Range Chromatin Interactions. , 2015, Cold Spring Harbor perspectives in biology.

[159]  Josée Dostie,et al.  An Overview of Genome Organization and How We Got There: from FISH to Hi-C , 2015, Microbiology and Molecular Reviews.

[160]  Thomas Cremer,et al.  Chromosome order in HeLa cells changes during mitosis and early G1, but is stably maintained during subsequent interphase stages , 2003, The Journal of cell biology.

[161]  V. Guillemot,et al.  Distance between homologous chromosomes results from chromosome positioning constraints , 2010, Journal of Cell Science.

[162]  Neva C. Durand,et al.  A 3D Map of the Human Genome at Kilobase Resolution Reveals Principles of Chromatin Looping , 2014, Cell.

[163]  William Stafford Noble,et al.  Fine-scale chromatin interaction maps reveal the cis-regulatory landscape of human lincRNA genes , 2014, Nature Methods.

[164]  Yoshinori Nishino,et al.  Chromosomes without a 30-nm chromatin fiber , 2012, Nucleus.

[165]  Mark Ptashne,et al.  DNA loops induced by cooperative binding of λ repressor , 1986, Nature.

[166]  Mark Groudine,et al.  Form follows function: The genomic organization of cellular differentiation. , 2004, Genes & development.