Xist-seeded nucleation sites form local concentration gradients of silencing proteins to inactivate the X-chromosome

The long non-coding RNA Xist exploits numerous effector proteins to progressively induce gene silencing across the X chromosome and form the inactive X (Xi)-compartment. The mechanism underlying formation of the chromosome-wide Xi-compartment is poorly understood. Here, we find that formation of the Xi-compartment is induced by ∼50 locally confined granules, where two Xist RNA molecules nucleate supra-molecular complexes (SMCs) of interacting proteins. Xist-SMCs are transient structures that concentrate rapidly recycling proteins in the X by increasing protein binding affinity. We find that gene silencing originates at Xist-SMCs and propagates across the entire chromosome over time, achieved by Polycomb-mediated coalescence of chromatin regions and aggregation, via its intrinsically disordered domains, of the critical silencing factor SPEN. Our results suggest a new model for X chromosome inactivation, in which Xist RNA induces macromolecular crowding of heterochromatinizing proteins near distinct sites which ultimately increases their density throughout the chromosome. This mechanism enables deterministic gene silencing without the need for Xist ribonucleoprotein complex-chromatin interactions at each target gene.

[1]  C. K. Valsecchi,et al.  RNA nucleation by MSL2 induces selective X chromosome compartmentalization , 2020, Nature.

[2]  D. Black,et al.  A protein assembly mediates Xist localization and gene silencing , 2020, Nature.

[3]  N. Brockdorff,et al.  Progress toward understanding chromosome silencing by Xist RNA , 2020, Genes & development.

[4]  Amy Pandya-Jones An Xist-dependent protein assembly mediates Xistlocalization and gene silencing , 2020 .

[5]  K. Rippe,et al.  Subcompartment Formation by Phase Separation. , 2020, Journal of molecular biology.

[6]  R. Mitra,et al.  Quantitative analysis of transcription factor binding and expression using calling cards reporter arrays , 2020, Nucleic acids research.

[7]  K. Rippe,et al.  Mouse Heterochromatin Adopts Digital Compaction States without Showing Hallmarks of HP1-Driven Liquid-Liquid Phase Separation , 2020, Molecular cell.

[8]  D. Marenduzzo,et al.  Bridging-induced microphase separation: photobleaching experiments, chromatin domains and the need for active reactions. , 2020, Briefings in functional genomics.

[9]  J. Dekker,et al.  SPEN integrates transcriptional and epigenetic control of X-inactivation , 2020, Nature.

[10]  Silvio C. E. Tosatto,et al.  Disentangling the complexity of low complexity proteins , 2019, Briefings Bioinform..

[11]  Ilya M. Flyamer,et al.  A central role for canonical PRC1 in shaping the 3D nuclear landscape , 2019, bioRxiv.

[12]  B. Chadwick Characterization of chromatin at structurally abnormal inactive X chromosomes reveals potential evidence of a rare hybrid active and inactive isodicentric X chromosome , 2019, Chromosome Research.

[13]  E. Heard,et al.  Xist RNA in action: Past, present, and future , 2019, PLoS genetics.

[14]  Xiang-Dong Fu,et al.  Chromatin-associated RNAs as facilitators of functional genomic interactions , 2019, Nature Reviews Genetics.

[15]  Howard Y. Chang,et al.  The role of Xist‐mediated Polycomb recruitment in the initiation of X‐chromosome inactivation , 2019, EMBO reports.

[16]  J. Starmer,et al.  lncRNA-Induced Spread of Polycomb Controlled by Genome Architecture, RNA Abundance, and CpG Island DNA. , 2019, Molecular cell.

[17]  Vladimir N Uversky,et al.  Stochasticity of Biological Soft Matter: Emerging Concepts in Intrinsically Disordered Proteins and Biological Phase Separation. , 2019, Trends in biochemical sciences.

[18]  N. Brockdorff,et al.  Systematic allelic analysis defines the interplay of key pathways in X chromosome inactivation , 2018, Nature Communications.

[19]  Jeannie T. Lee,et al.  PRC1 collaborates with SMCHD1 to fold the X-chromosome and spread Xist RNA between chromosome compartments , 2019, Nature Communications.

[20]  P. Avner,et al.  Phase separation drives X-chromosome inactivation: a hypothesis , 2019, Nature Structural & Molecular Biology.

[21]  Yang Wang,et al.  Cellular functions of long noncoding RNAs , 2019, Nature Cell Biology.

[22]  Robert S. Illingworth Chromatin folding and nuclear architecture: PRC1 function in 3D , 2019, Current opinion in genetics & development.

[23]  Andrea J. Kriz,et al.  Xist Deletional Analysis Reveals an Interdependency between Xist RNA and Polycomb Complexes for Spreading along the Inactive X. , 2019, Molecular cell.

[24]  P. Cramer,et al.  The Implication of Early Chromatin Changes in X Chromosome Inactivation , 2019, Cell.

[25]  Chong-Jian Chen,et al.  Kinetics of Xist-induced gene silencing can be predicted from combinations of epigenetic and genomic features , 2019, bioRxiv.

[26]  E. Heard,et al.  X-Chromosome Inactivation: A Crossroads Between Chromosome Architecture and Gene Regulation. , 2018, Annual review of genetics.

[27]  G. Kay,et al.  Smchd1 Targeting to the Inactive X Is Dependent on the Xist-HnrnpK-PRC1 Pathway. , 2018, Cell reports.

[28]  Jeannie T. Lee,et al.  SMCHD1 Merges Chromosome Compartments and Assists Formation of Super-Structures on the Inactive X , 2018, Cell.

[29]  C. Bond,et al.  Functional Domains of NEAT1 Architectural lncRNA Induce Paraspeckle Assembly through Phase Separation. , 2018, Molecular cell.

[30]  Dianne Cook,et al.  plyranges: a grammar of genomic data transformation , 2018, Genome Biology.

[31]  R. Tjian,et al.  Visualizing transcription factor dynamics in living cells , 2018, The Journal of cell biology.

[32]  N. Brockdorff,et al.  hnRNPK Recruits PCGF3/5-PRC1 to the Xist RNA B-Repeat to Establish Polycomb-Mediated Chromosomal Silencing , 2017, Molecular cell.

[33]  Jean-Baptiste Morlot,et al.  P-Body Purification Reveals the Condensation of Repressed mRNA Regulons. , 2017, Molecular cell.

[34]  J. Ellenberg,et al.  Real-Time Imaging of a Single Gene Reveals Transcription-Initiated Local Confinement , 2017, Biophysical journal.

[35]  N. Brockdorff Polycomb complexes in X chromosome inactivation , 2017, Philosophical Transactions of the Royal Society B: Biological Sciences.

[36]  Jeannie T. Lee,et al.  Repeat E anchors Xist RNA to the inactive X chromosomal compartment through CDKN1A-interacting protein (CIZ1) , 2017, Proceedings of the National Academy of Sciences.

[37]  Achim P. Popp,et al.  DNA residence time is a regulatory factor of transcription repression , 2017, Nucleic acids research.

[38]  M. Tomita,et al.  Dynamic organization of chromatin domains revealed by super-resolution live-cell imaging , 2017 .

[39]  A. Barski,et al.  Xist RNA repeat E is essential for ASH2L recruitment to the inactive X and regulates histone modifications and escape gene expression , 2017, PLoS genetics.

[40]  T. Misteli,et al.  Comparative analysis of 2D and 3D distance measurements to study spatial genome organization , 2016, bioRxiv.

[41]  N. Brockdorff,et al.  PCGF3/5–PRC1 initiates Polycomb recruitment in X chromosome inactivation , 2017, Science.

[42]  Jeannie T. Lee,et al.  The X chromosome in space , 2017, Nature Reviews Genetics.

[43]  Anthony A. Hyman,et al.  Biomolecular condensates: organizers of cellular biochemistry , 2017, Nature Reviews Molecular Cell Biology.

[44]  Atsushi Matsuda,et al.  Quantitative 3D structured illumination microscopy of nuclear structures , 2017, Nature Protocols.

[45]  N. Brockdorff,et al.  The nuclear matrix protein CIZ1 facilitates localization of Xist RNA to the inactive X-chromosome territory , 2017, Genes & development.

[46]  Atsushi Matsuda,et al.  Strategic and practical guidelines for successful structured illumination microscopy , 2017, Nature Protocols.

[47]  S. Hohmann,et al.  Transcription factor clusters regulate genes in eukaryotic cells , 2017, bioRxiv.

[48]  K. Hall Faculty Opinions recommendation of Chromosomes. A comprehensive Xist interactome reveals cohesin repulsion and an RNA-directed chromosome conformation. , 2017 .

[49]  Johannes Schindelin,et al.  TrackMate: An open and extensible platform for single-particle tracking. , 2017, Methods.

[50]  Beryl B. Cummings,et al.  Landscape of X chromosome inactivation across human tissues , 2016, Nature.

[51]  Jesse M. Engreitz,et al.  Long non-coding RNAs: spatial amplifiers that control nuclear structure and gene expression , 2016, Nature Reviews Molecular Cell Biology.

[52]  Howard Y. Chang,et al.  Structural organization of the inactive X chromosome in the mouse , 2016, Nature.

[53]  D. J. McKay,et al.  Concentrating pre-mRNA processing factors in the histone locus body facilitates efficient histone mRNA biogenesis , 2016, The Journal of cell biology.

[54]  David Baker,et al.  Design of a hyperstable 60-subunit protein icosahedron , 2016, Nature.

[55]  Anthony Barsic,et al.  ATPase-Modulated Stress Granules Contain a Diverse Proteome and Substructure , 2016, Cell.

[56]  Vladimir N Uversky,et al.  The multifaceted roles of intrinsic disorder in protein complexes , 2015, FEBS letters.

[57]  P. Avner,et al.  Xist localization and function: new insights from multiple levels , 2015, Genome Biology.

[58]  Jeannie T. Lee,et al.  The Xist RNA-PRC2 complex at 20-nm resolution reveals a low Xist stoichiometry and suggests a hit-and-run mechanism in mouse cells , 2015, Proceedings of the National Academy of Sciences.

[59]  Jeannie T. Lee,et al.  Chromosomes. A comprehensive Xist interactome reveals cohesin repulsion and an RNA-directed chromosome conformation. , 2015, Science.

[60]  N. Brockdorff,et al.  A Pooled shRNA Screen Identifies Rbm15, Spen, and Wtap as Factors Required for Xist RNA-Mediated Silencing , 2015, Cell reports.

[61]  S. Thore,et al.  Identification of Spen as a Crucial Factor for Xist Function through Forward Genetic Screening in Haploid Embryonic Stem Cells , 2015, Cell reports.

[62]  Qiangfeng Cliff Zhang,et al.  Systematic Discovery of Xist RNA Binding Proteins , 2015, Cell.

[63]  Michael J. Sweredoski,et al.  The Xist lncRNA directly interacts with SHARP to silence transcription through HDAC3 , 2015, Nature.

[64]  Joshua C. Chang,et al.  Bayesian field theoretic reconstruction of bond potential and bond mobility in single molecule force spectroscopy , 2015, 1502.06415.

[65]  W. Huber,et al.  Moderated estimation of fold change and dispersion for RNA-seq data with DESeq2 , 2014, Genome Biology.

[66]  E. Heard,et al.  Noncoding RNAs and epigenetic mechanisms during X-chromosome inactivation. , 2014, Annual review of cell and developmental biology.

[67]  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.

[68]  N. Blüthgen,et al.  The two active X chromosomes in female ESCs block exit from the pluripotent state by modulating the ESC signaling network. , 2014, Cell stem cell.

[69]  D. Reinberg,et al.  Jarid2 Is Implicated in the Initial Xist-Induced Targeting of PRC2 to the Inactive X Chromosome. , 2014, Molecular cell.

[70]  Takahide Yokoi,et al.  NEAT1 long noncoding RNA regulates transcription via protein sequestration within subnuclear bodies , 2014, Molecular biology of the cell.

[71]  Luke A. Gilbert,et al.  Dynamic Imaging of Genomic Loci in Living Human Cells by an Optimized CRISPR/Cas System , 2013, Cell.

[72]  Tom Chou,et al.  A Path-Integral Approach to Bayesian Inference for Inverse Problems Using the Semiclassical Approximation , 2013, 1312.2974.

[73]  Cheemeng Tan,et al.  Molecular crowding shapes gene expression in synthetic cellular nanosystems , 2013, Nature nanotechnology.

[74]  M. Saitou,et al.  Generation of eggs from mouse embryonic stem cells and induced pluripotent stem cells , 2013, Nature Protocols.

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

[76]  Robert H Singer,et al.  mRNA on the Move: The Road to Its Biological Destiny* , 2013, The Journal of Biological Chemistry.

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

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

[79]  G. Montana,et al.  Smchd1-Dependent and -Independent Pathways Determine Developmental Dynamics of CpG Island Methylation on the Inactive X Chromosome , 2012, Developmental cell.

[80]  J. McNally,et al.  A benchmark for chromatin binding measurements in live cells , 2012, Nucleic acids research.

[81]  Bin Wu,et al.  Fluorescence fluctuation spectroscopy enables quantitative imaging of single mRNAs in living cells. , 2012, Biophysical journal.

[82]  Jimin Pei,et al.  Cell-free Formation of RNA Granules: Low Complexity Sequence Domains Form Dynamic Fibers within Hydrogels , 2012, Cell.

[83]  N. Brockdorff,et al.  RYBP-PRC1 Complexes Mediate H2A Ubiquitylation at Polycomb Target Sites Independently of PRC2 and H3K27me3 , 2012, Cell.

[84]  R. Kingston,et al.  Compaction of chromatin by diverse Polycomb group proteins requires localized regions of high charge. , 2011, Genes & development.

[85]  T. Cremer,et al.  A top-down analysis of Xa- and Xi-territories reveals differences of higher order structure at ≥ 20 Mb genomic length scales , 2011, Nucleus.

[86]  A. Wutz Gene silencing in X-chromosome inactivation: advances in understanding facultative heterochromatin formation , 2011, Nature Reviews Genetics.

[87]  N. Daigle,et al.  A system for imaging the regulatory noncoding Xist RNA in living mouse embryonic stem cells , 2011, Molecular biology of the cell.

[88]  E. Heard,et al.  Evolutionary diversity and developmental regulation of X-chromosome inactivation , 2011, Human Genetics.

[89]  C. Kanduri Kcnq1ot1: a chromatin regulatory RNA. , 2011, Seminars in cell & developmental biology.

[90]  M. Dundr,et al.  Nucleation of nuclear bodies by RNA , 2011, Nature Cell Biology.

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

[92]  A. Kenworthy,et al.  A quantitative approach to analyze binding diffusion kinetics by confocal FRAP. , 2010, Biophysical journal.

[93]  Jeremy Schofield,et al.  Constructing smooth potentials of mean force, radial distribution functions, and probability densities from sampled data. , 2009, The Journal of chemical physics.

[94]  Jan Ellenberg,et al.  Molecular crowding affects diffusion and binding of nuclear proteins in heterochromatin and reveals the fractal organization of chromatin , 2009, The EMBO journal.

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

[96]  Andrew Wright,et al.  High efficiency of HIV-1 genomic RNA packaging and heterozygote formation revealed by single virion analysis , 2009, Proceedings of the National Academy of Sciences.

[97]  David Eisenberg,et al.  In Brief , 2009, Nature Reviews Neuroscience.

[98]  Jeannie T. Lee,et al.  Polycomb Proteins Targeted by a Short Repeat RNA to the Mouse X Chromosome , 2008, Science.

[99]  F. Grosveld,et al.  Xist RNA Is Confined to the Nuclear Territory of the Silenced X Chromosome throughout the Cell Cycle , 2008, Molecular and Cellular Biology.

[100]  Bernd A. Berg,et al.  From data to probability densities without histograms , 2007, Comput. Phys. Commun..

[101]  James G McNally,et al.  Quantitative FRAP in analysis of molecular binding dynamics in vivo. , 2008, Methods in cell biology.

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

[103]  P. Lichter,et al.  Experimental evidence for the influence of molecular crowding on nuclear architecture , 2007, Journal of Cell Science.

[104]  Maria Carmo-Fonseca,et al.  A reaction-diffusion model to study RNA motion by quantitative fluorescence recovery after photobleaching. , 2007, Biophysical journal.

[105]  J. Forman-Kay,et al.  Atomic-level characterization of disordered protein ensembles. , 2007, Current opinion in structural biology.

[106]  E. Heard,et al.  A novel role for Xist RNA in the formation of a repressive nuclear compartment into which genes are recruited when silenced. , 2006, Genes & development.

[107]  Rudolf Jaenisch,et al.  Efficient method to generate single‐copy transgenic mice by site‐specific integration in embryonic stem cells , 2006, Genesis.

[108]  Enrico Gratton,et al.  Chromatin dynamics in interphase cells revealed by tracking in a two-photon excitation microscope. , 2005, Biophysical journal.

[109]  R. Kingston,et al.  Chromatin Compaction by a Polycomb Group Protein Complex , 2004, Science.

[110]  N. Brockdorff,et al.  Establishment of histone h3 methylation on the inactive X chromosome requires transient recruitment of Eed-Enx1 polycomb group complexes. , 2003, Developmental cell.

[111]  Hengbin Wang,et al.  Role of Histone H3 Lysine 27 Methylation in X Inactivation , 2003, Science.

[112]  T. Misteli,et al.  Measuring Dynamics of Nuclear Proteins by Photobleaching , 2003, Current protocols in cell biology.

[113]  Austin G Smith,et al.  Defined conditions for neural commitment and differentiation. , 2003, Methods in enzymology.

[114]  Wendy A Bickmore,et al.  Chromatin Motion Is Constrained by Association with Nuclear Compartments in Human Cells , 2002, Current Biology.

[115]  Rudolf Jaenisch,et al.  Chromosomal silencing and localization are mediated by different domains of Xist RNA , 2002, Nature Genetics.

[116]  Dmitri A. Nusinow,et al.  Xist RNA and the mechanism of X chromosome inactivation. , 2002, Annual review of genetics.

[117]  R. Jaenisch,et al.  A shift from reversible to irreversible X inactivation is triggered during ES cell differentiation. , 2000, Molecular cell.

[118]  A. Minton Implications of macromolecular crowding for protein assembly. , 2000, Current opinion in structural biology.

[119]  R. Hansen,et al.  The timing of XIST replication: dominance of the domain. , 1999, Human molecular genetics.

[120]  R. Singer,et al.  Localization of ASH1 mRNA particles in living yeast. , 1998, Molecular cell.

[121]  C. Costanzi,et al.  Histone macroH2A1 is concentrated in the inactive X chromosome of female mammals , 1998, Nature.

[122]  R. Jaenisch,et al.  Role of the Xist Gene in X Chromosome Choosing , 1998, Cell.

[123]  R. Jaenisch,et al.  X Chromosome Inactivation Is Mediated by Xist RNA Stabilization , 1997, Cell.

[124]  Brian D. Hendrich,et al.  Identification and characterization of the human XIST gene promoter: implications for models of X chromosome inactivation , 1997, Nucleic Acids Res..

[125]  S. Rastan,et al.  Requirement for Xist in X chromosome inactivation , 1996, Nature.

[126]  Dominic P. Norris,et al.  The product of the mouse Xist gene is a 15 kb inactive X-specific transcript containing no conserved ORF and located in the nucleus , 1992, Cell.

[127]  Carolyn J. Brown,et al.  The human XIST gene: Analysis of a 17 kb inactive X-specific RNA that contains conserved repeats and is highly localized within the nucleus , 1992, Cell.