Initial high-resolution microscopic mapping of active and inactive regulatory sequences proves non-random 3D arrangements in chromatin domain clusters

Background The association of active transcription regulatory elements (TREs) with DNAse I hypersensitivity (DHS[+]) and an ‘open’ local chromatin configuration has long been known. However, the 3D topography of TREs within the nuclear landscape of individual cells in relation to their active or inactive status has remained elusive. Here, we explored the 3D nuclear topography of active and inactive TREs in the context of a recently proposed model for a functionally defined nuclear architecture, where an active and an inactive nuclear compartment (ANC–INC) form two spatially co-aligned and functionally interacting networks.ResultsUsing 3D structured illumination microscopy, we performed 3D FISH with differently labeled DNA probe sets targeting either sites with DHS[+], apparently active TREs, or DHS[−] sites harboring inactive TREs. Using an in-house image analysis tool, DNA targets were quantitatively mapped on chromatin compaction shaped 3D nuclear landscapes. Our analyses present evidence for a radial 3D organization of chromatin domain clusters (CDCs) with layers of increasing chromatin compaction from the periphery to the CDC core. Segments harboring active TREs are significantly enriched at the decondensed periphery of CDCs with loops penetrating into interchromatin compartment channels, constituting the ANC. In contrast, segments lacking active TREs (DHS[−]) are enriched toward the compacted interior of CDCs (INC).ConclusionsOur results add further evidence in support of the ANC–INC network model. The different 3D topographies of DHS[+] and DHS[−] sites suggest positional changes of TREs between the ANC and INC depending on their functional state, which might provide additional protection against an inappropriate activation. Our finding of a structural organization of CDCs based on radially arranged layers of different chromatin compaction levels indicates a complex higher-order chromatin organization beyond a dichotomic classification of chromatin into an ‘open,’ active and ‘closed,’ inactive state.

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

[2]  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.

[3]  Thomas Cremer,et al.  Three-dimensional super-resolution microscopy of the inactive X chromosome territory reveals a collapse of its active nuclear compartment harboring distinct Xist RNA foci , 2014, Epigenetics & Chromatin.

[4]  Leonid A. Mirny,et al.  Super-resolution imaging reveals distinct chromatin folding for different epigenetic states , 2015, Nature.

[5]  T. Cremer,et al.  Chromosome territories, nuclear architecture and gene regulation in mammalian cells , 2001, Nature Reviews Genetics.

[6]  Thomas Boudier,et al.  TANGO: a generic tool for high-throughput 3D image analysis for studying nuclear organization , 2013, Bioinform..

[7]  Peter Dalgaard,et al.  R Development Core Team (2010): R: A language and environment for statistical computing , 2010 .

[8]  William Stafford Noble,et al.  Statistical confidence estimation for Hi-C data reveals regulatory chromatin contacts , 2014, Genome research.

[9]  John W Sedat,et al.  OMX: a new platform for multimodal, multichannel wide-field imaging. , 2011, Cold Spring Harbor protocols.

[10]  S. Kosak,et al.  Topologically associated domains enriched for lineage-specific genes reveal expression-dependent nuclear topologies during myogenesis , 2016, Proceedings of the National Academy of Sciences.

[11]  U. Birk,et al.  A transient ischemic environment induces reversible compaction of chromatin , 2015, Genome Biology.

[12]  Shane J. Neph,et al.  DNase I–hypersensitive exons colocalize with promoters and distal regulatory elements , 2013, Nature Genetics.

[13]  S. Kosak,et al.  Differential contribution of cis-regulatory elements to higher order chromatin structure and expression of the CFTR locus , 2015, Nucleic acids research.

[14]  Nick Kepper,et al.  The detailed 3D multi-loop aggregate/rosette chromatin architecture and functional dynamic organization of the human and mouse genomes , 2015, bioRxiv.

[15]  D. Schübeler,et al.  Determinants and dynamics of genome accessibility , 2011, Nature Reviews Genetics.

[16]  T. Wolfsberg,et al.  DNase-chip: a high-resolution method to identify DNase I hypersensitive sites using tiled microarrays , 2006, Nature Methods.

[17]  M. Ramalho-Santos,et al.  Open chromatin in pluripotency and reprogramming , 2010, Nature Reviews Molecular Cell Biology.

[18]  J. Sklar,et al.  Genome-wide Detection of DNase I Hypersensitive Sites in Single Cells and FFPE Samples , 2015, Nature.

[19]  Wensheng Wei,et al.  Long-term dual-color tracking of genomic loci by modified sgRNAs of the CRISPR/Cas9 system , 2016, Nucleic acids research.

[20]  Justin Demmerle,et al.  Assessing resolution in super-resolution imaging. , 2015, Methods.

[21]  H. Leonhardt,et al.  Visualization of Genomic Loci in Living Cells with a Fluorescent CRISPR/Cas9 System. , 2016, Methods in molecular biology.

[22]  J. Keith Joung,et al.  Interactome Maps of Mouse Gene Regulatory Domains Reveal Basic Principles of Transcriptional Regulation , 2013, Cell.

[23]  Thomas J. Ha,et al.  Transcribed enhancers lead waves of coordinated transcription in transitioning mammalian cells , 2015, Science.

[24]  Robert Gentleman,et al.  Software for Computing and Annotating Genomic Ranges , 2013, PLoS Comput. Biol..

[25]  Michael R. Green,et al.  Transcriptional regulatory elements in the human genome. , 2006, Annual review of genomics and human genetics.

[26]  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.

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

[28]  T. Cremer,et al.  Correlative microscopy of individual cells: sequential application of microscopic systems with increasing resolution to study the nuclear landscape. , 2013, Methods in molecular biology.

[29]  Françoise Argoul,et al.  Structural organization of human replication timing domains , 2015, FEBS letters.

[30]  H. Leonhardt,et al.  A guide to super-resolution fluorescence microscopy , 2010, The Journal of cell biology.

[31]  Thomas Cremer,et al.  Quantitative analyses of the 3D nuclear landscape recorded with super-resolved fluorescence microscopy. , 2017, Methods.

[32]  S. Q. Xie,et al.  Hierarchical folding and reorganization of chromosomes are linked to transcriptional changes in cellular differentiation , 2015, Molecular systems biology.

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

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

[35]  William Stafford Noble,et al.  Mapping 3D genome architecture through in situ DNase Hi-C , 2016, Nature Protocols.

[36]  M. Nóbrega,et al.  Genome‐wide maps of transcription regulatory elements , 2010, Wiley interdisciplinary reviews. Systems biology and medicine.

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

[38]  S. Ferrari,et al.  Remodeling of nuclear landscapes during human myelopoietic cell differentiation maintains co-aligned active and inactive nuclear compartments , 2015, Epigenetics & Chromatin.

[39]  A. Belmont,et al.  Visualization of G1 chromosomes: a folded, twisted, supercoiled chromonema model of interphase chromatid structure , 1994, The Journal of cell biology.

[40]  3D structured illumination microscopy of mammalian embryos and spermatozoa , 2015, BMC Developmental Biology.

[41]  Takeharu Nagai,et al.  Local nucleosome dynamics facilitate chromatin accessibility in living mammalian cells. , 2012, Cell reports.

[42]  J. Stamatoyannopoulos,et al.  Genome-wide identification of DNaseI hypersensitive sites using active chromatin sequence libraries. , 2004, Proceedings of the National Academy of Sciences of the United States of America.

[43]  Masaki Sasai,et al.  Liquid-like behavior of chromatin. , 2016, Current opinion in genetics & development.

[44]  B. Porse,et al.  Peak-valley-peak pattern of histone modifications delineates active regulatory elements and their directionality , 2016, Nucleic acids research.

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

[46]  T. Cremer,et al.  Dynamic genome architecture in the nuclear space: regulation of gene expression in three dimensions , 2007, Nature Reviews Genetics.

[47]  Lothar Schermelleh,et al.  Fluorescence in situ hybridization applications for super-resolution 3D structured illumination microscopy. , 2013, Methods in molecular biology.

[48]  Peng Yin,et al.  Single-molecule super-resolution imaging of chromosomes and in situ haplotype visualization using Oligopaint FISH probes , 2015, Nature Communications.

[49]  T. Meehan,et al.  An atlas of active enhancers across human cell types and tissues , 2014, Nature.

[50]  Kazuhiro Maeshima,et al.  Chromatin structure: does the 30-nm fibre exist in vivo? , 2010, Current opinion in cell biology.

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

[52]  Kazunari Kaizu,et al.  The physical size of transcription factors is key to transcriptional regulation in chromatin domains , 2015, Journal of physics. Condensed matter : an Institute of Physics journal.

[53]  Nathan C. Sheffield,et al.  The accessible chromatin landscape of the human genome , 2012, Nature.

[54]  Shaojie Zhang,et al.  Multicolor CRISPR labeling of chromosomal loci in human cells , 2015, Proceedings of the National Academy of Sciences.

[55]  Andre J. Faure,et al.  3D structure of individual mammalian genomes studied by single cell Hi-C , 2017, Nature.

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

[57]  Yanli Wang,et al.  Topologically associating domains are stable units of replication-timing regulation , 2014, Nature.

[58]  I. Bronshtein,et al.  Exploring chromatin organization mechanisms through its dynamic properties , 2016, Nucleus.

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

[60]  P. Flicek,et al.  The Ensembl Regulatory Build , 2015, Genome Biology.

[61]  Wolfgang Huber,et al.  EBImage—an R package for image processing with applications to cellular phenotypes , 2010, Bioinform..

[62]  Justin Demmerle,et al.  Spatial separation of Xist RNA and polycomb proteins revealed by superresolution microscopy , 2014, Proceedings of the National Academy of Sciences.

[63]  Jérôme Déjardin,et al.  Constitutive heterochromatin formation and transcription in mammals , 2014, Epigenetics & Chromatin.

[64]  S. Michaels,et al.  Open and closed: the roles of linker histones in plants and animals. , 2014, Molecular plant.

[65]  M. Daly,et al.  Genome-wide mapping of DNase hypersensitive sites using massively parallel signature sequencing (MPSS). , 2005, Genome research.

[66]  Z. Weng,et al.  High-Resolution Mapping and Characterization of Open Chromatin across the Genome , 2008, Cell.

[67]  P. Cockerill Structure and function of active chromatin and DNase I hypersensitive sites , 2011, The FEBS journal.

[68]  Volker J Schmid,et al.  Reprogramming of fibroblast nuclei in cloned bovine embryos involves major structural remodeling with both striking similarities and differences to nuclear phenotypes of in vitro fertilized embryos , 2014, Nucleus.

[69]  Abena B. Redwood,et al.  Loss of lamin A function increases chromatin dynamics in the nuclear interior , 2015, Nature Communications.

[70]  Amos Tanay,et al.  Robust 4C-seq data analysis to screen for regulatory DNA interactions , 2012, Nature Methods.

[71]  Christopher R. Brown,et al.  From Structural Variation of Gene Molecules to Chromatin Dynamics and Transcriptional Bursting , 2015, Genes.

[72]  Ian M. Dobbie,et al.  SIMcheck: a Toolbox for Successful Super-resolution Structured Illumination Microscopy , 2015, Scientific Reports.