Mapping the micro-proteome of the nuclear lamina and lamin associated domains

The nuclear lamina is a proteinaceous network of filaments that provide both structural and gene regulatory functions by tethering proteins and large domains of DNA, so-called lamin associated domains (LADs), to the periphery of the nucleus. LADs are a large fraction of the mammalian genome that are repressed, in part, by their association to the nuclear periphery. The genesis and maintenance of LADs is poorly understood as are the proteins that participate in these functions. In an effort to identify proteins that reside at the nuclear periphery and potentially interact with LADs, we have taken a two-pronged approach. First, we have undertaken an interactome analysis of the inner nuclear membrane bound LAP2β to further characterize the nuclear lamina proteome. To accomplish this, we have leveraged the BioID system, which previously has been successfully used to characterize the nuclear lamina proteome. Second, we have established a system to identify proteins that bind to LADs by developing a chromatin directed BioID system. We combined the BioID system with the m6A-tracer system which binds to LADs in live cells to identify both LAD proximal and nuclear lamina proteins. In combining these datasets, we have further characterized the protein network at the nuclear lamina, identified putative LAD proximal proteins and found several proteins that appear to interface with both micro-proteomes. Importantly, several proteins essential for LAD function, including heterochromatin regulating proteins related to H3K9 methylation, were identified in this study.

[1]  M. Brand,et al.  KMT1 family methyltransferases regulate heterochromatin–nuclear periphery tethering via histone and non‐histone protein methylation , 2019, EMBO reports.

[2]  N. Yamada,et al.  The repressive genome compartment is established early in the cell cycle before forming the lamina associated domains , 2018, bioRxiv.

[3]  O. Dreesen,et al.  2C-BioID: An Advanced Two Component BioID System for Precision Mapping of Protein Interactomes , 2018, iScience.

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

[5]  D. Trono,et al.  KAP1 facilitates reinstatement of heterochromatin after DNA replication , 2018, Nucleic acids research.

[6]  Matthew E. Ritchie,et al.  Long-range chromatin interactions on the inactive X and at Hox clusters are regulated by the non-canonical SMC protein Smchd1 , 2018, bioRxiv.

[7]  R. Huganir,et al.  BioSITe: A Method for Direct Detection and Quantitation of Site-Specific Biotinylation. , 2017, Journal of proteome research.

[8]  K. Reddy,et al.  The Nuclear Lamina and Genome Organization , 2018 .

[9]  R. Faustino,et al.  VRK2A is an A-type lamin–dependent nuclear envelope kinase that phosphorylates BAF , 2017, Molecular biology of the cell.

[10]  Bas van Steensel,et al.  Lamina-Associated Domains: Links with Chromosome Architecture, Heterochromatin, and Gene Repression , 2017, Cell.

[11]  N. Yamada,et al.  Chromosome Conformation Paints Reveal the Role of Lamina Association in Genome Organization and Regulation , 2017, bioRxiv.

[12]  M. Hetzer,et al.  Nucleoporin-mediated regulation of cell identity genes , 2016, Genes & development.

[13]  C. Stewart,et al.  A-type Lamins Form Distinct Filamentous Networks with Differential Nuclear Pore Complex Associations , 2016, Current Biology.

[14]  H. Leonhardt,et al.  Determination of local chromatin composition by CasID , 2016, Nucleus.

[15]  F. Collins,et al.  Biotinylation by antibody recognition - A novel method for proximity labeling , 2016, bioRxiv.

[16]  E. C. Schirmer,et al.  Anchoring a Leviathan: How the Nuclear Membrane Tethers the Genome , 2016, Front. Genet..

[17]  Wolfgang Huber,et al.  Nuclear Architecture Organized by Rif1 Underpins the Replication-Timing Program , 2016, Molecular cell.

[18]  S. Gasser,et al.  Histones and histone modifications in perinuclear chromatin anchoring: from yeast to man , 2016, EMBO reports.

[19]  K. Roux,et al.  Identifying Protein-Protein Associations at the Nuclear Envelope with BioID. , 2016, Methods in molecular biology.

[20]  K. Reddy,et al.  Tagged Chromosomal Insertion Site System: A Method to Study Lamina-Associated Chromatin. , 2016, Methods in enzymology.

[21]  Ruthellen H. Anderson,et al.  BioID Identification of Lamin-Associated Proteins. , 2016, Methods in enzymology.

[22]  E. C. Schirmer,et al.  The Application of DamID to Identify Peripheral Gene Sequences in Differentiated and Primary Cells. , 2016, Methods in molecular biology.

[23]  K. Reddy,et al.  Finding the Middlemen in Genome Organization. , 2015, Developmental cell.

[24]  N. Brockdorff,et al.  Independent Mechanisms Target SMCHD1 to Trimethylated Histone H3 Lysine 9-Modified Chromatin and the Inactive X Chromosome , 2015, Molecular and Cellular Biology.

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

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

[27]  P. Geyer,et al.  Networking in the nucleus: a spotlight on LEM-domain proteins. , 2015, Current opinion in cell biology.

[28]  B. Steensel,et al.  Nuclear lamins are not required for lamina‐associated domain organization in mouse embryonic stem cells , 2015, EMBO reports.

[29]  S. Clark,et al.  Methyl-CpG-binding domain proteins: readers of the epigenome. , 2015, Epigenomics.

[30]  Xiaochun Yu,et al.  Correction: The zinc finger proteins ZNF644 and WIZ regulate the G9a/GLP complex for gene repression , 2015, eLife.

[31]  B. Kc,et al.  Making the LINC: SUN and KASH protein interactions , 2015, Biological chemistry.

[32]  B. Edgar,et al.  FUCCI sensors: powerful new tools for analysis of cell proliferation , 2015, Wiley interdisciplinary reviews. Developmental biology.

[33]  S. Wheelan,et al.  Directed targeting of chromatin to the nuclear lamina is mediated by chromatin state and A-type lamins , 2015, The Journal of cell biology.

[34]  J. Déjardin,et al.  Constitutive heterochromatin formation and transcription in mammals , 2015, Epigenetics & Chromatin.

[35]  N. Crawford,et al.  Metastasis-Associated Protein Ribosomal RNA Processing 1 Homolog B (RRP1B) Modulates Metastasis through Regulation of Histone Methylation , 2014, Molecular Cancer Research.

[36]  J. Boros,et al.  Polycomb Repressive Complex 2 and H3K27me3 Cooperate with H3K9 Methylation To Maintain Heterochromatin Protein 1α at Chromatin , 2014, Molecular and Cellular Biology.

[37]  G. Gloor,et al.  Analysis of neonatal brain lacking ATRX or MeCP2 reveals changes in nucleosome density, CTCF binding and chromatin looping. , 2014, Nucleic acids research.

[38]  V. Doye,et al.  Probing nuclear pore complex architecture with proximity-dependent biotinylation , 2014, Proceedings of the National Academy of Sciences.

[39]  K. Reddy,et al.  NET gains and losses: the role of changing nuclear envelope proteomes in genome regulation. , 2014, Current opinion in cell biology.

[40]  K. Reddy,et al.  Genome regulation at the peripheral zone: lamina associated domains in development and disease. , 2014, Current opinion in genetics & development.

[41]  B. van Steensel,et al.  Stochastic genome-nuclear lamina interactions , 2014, Nucleus.

[42]  R. Katz,et al.  Specifying peripheral heterochromatin during nuclear lamina reassembly , 2014, Nucleus.

[43]  Q. Bian,et al.  Jcb: Article , 2022 .

[44]  N. Crawford,et al.  BRD4 Short Isoform Interacts with RRP1B, SIPA1 and Components of the LINC Complex at the Inner Face of the Nuclear Membrane , 2013, PloS one.

[45]  B. Burke,et al.  BioID: A Screen for Protein‐Protein Interactions , 2013, Current protocols in protein science.

[46]  K. Mansfield,et al.  The human protein PRR14 tethers heterochromatin to the nuclear lamina during interphase and mitotic exit. , 2013, Cell reports.

[47]  A. H. Smits,et al.  Cdyl, a New Partner of the Inactive X Chromosome and Potential Reader of H3K27me3 and H3K9me2 , 2013, Molecular and Cellular Biology.

[48]  Kairong Cui,et al.  Intragenic DNA methylation modulates alternative splicing by recruiting MeCP2 to promote exon recognition , 2013, Cell Research.

[49]  Edith Heard,et al.  Segmental folding of chromosomes: A basis for structural and regulatory chromosomal neighborhoods? , 2013, BioEssays : news and reviews in molecular, cellular and developmental biology.

[50]  H. Kimura,et al.  Human inactive X chromosome is compacted through a PRC2-independent SMCHD1-HBiX1 pathway , 2013, Nature Structural &Molecular Biology.

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

[52]  Edward Y. Chen,et al.  Enrichr: interactive and collaborative HTML5 gene list enrichment analysis tool , 2013, BMC Bioinformatics.

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

[54]  A. D’Andrea,et al.  Chromatin Remodeling at DNA Double-Strand Breaks , 2013, Cell.

[55]  H. Herrmann Nuclear architecture and dynamics , 2013 .

[56]  L. Peichl,et al.  LBR and Lamin A/C Sequentially Tether Peripheral Heterochromatin and Inversely Regulate Differentiation , 2013, Cell.

[57]  Hana Kim,et al.  Recruitment and biological consequences of histone modification of H3K27me3 and H3K9me3. , 2012, ILAR journal.

[58]  F. Dilworth,et al.  Maintenance of gene silencing by the coordinate action of the H3K9 methyltransferase G9a/KMT1C and the H3K4 demethylase Jarid1a/KDM5A , 2012, Proceedings of the National Academy of Sciences.

[59]  Vishnu Dileep,et al.  Mouse Rif1 is a key regulator of the replication‐timing programme in mammalian cells , 2012, The EMBO journal.

[60]  Dimos Gaidatzis,et al.  Step-Wise Methylation of Histone H3K9 Positions Heterochromatin at the Nuclear Periphery , 2012, Cell.

[61]  S. Abramchuk,et al.  The overexpression of nuclear envelope protein Lap2β induces endoplasmic reticulum reorganisation via membrane stacking , 2012, Biology Open.

[62]  Johannes E. Schindelin,et al.  Fiji: an open-source platform for biological-image analysis , 2012, Nature Methods.

[63]  Bradley E. Bernstein,et al.  DNA Sequence-Dependent Compartmentalization and Silencing of Chromatin at the Nuclear Lamina , 2012, Cell.

[64]  Brian Burke,et al.  A promiscuous biotin ligase fusion protein identifies proximal and interacting proteins in mammalian cells , 2012, The Journal of cell biology.

[65]  A. Feinberg,et al.  Genome-scale epigenetic reprogramming during epithelial to mesenchymal transition , 2011, Nature Structural &Molecular Biology.

[66]  K. Kaestner,et al.  The nuclear pore complex protein Elys is required for genome stability in mouse intestinal epithelial progenitor cells. , 2011, Gastroenterology.

[67]  Y. Shinkai,et al.  H3K9 methyltransferase G9a and the related molecule GLP. , 2011, Genes & development.

[68]  A. Chinnaiyan,et al.  The DEK oncoprotein is a Su(var) that is essential to heterochromatin integrity. , 2011, Genes & development.

[69]  Dustin E. Schones,et al.  Genomic Profiling of HMGN1 Reveals an Association with Chromatin at Regulatory Regions , 2010, Molecular and Cellular Biology.

[70]  T. Misteli,et al.  Identification of differential protein interactors of lamin A and progerin , 2010, Nucleus.

[71]  H. Kimura,et al.  Human POGZ modulates dissociation of HP1α from mitotic chromosome arms through Aurora B activation , 2010, Nature Cell Biology.

[72]  M. Fornerod,et al.  Nucleoporins Directly Stimulate Expression of Developmental and Cell-Cycle Genes Inside the Nucleoplasm , 2010, Cell.

[73]  M. Bustin,et al.  Regulation of chromatin structure and function by HMGN proteins. , 2010, Biochimica et biophysica acta.

[74]  Atsushi Miyawaki,et al.  Illuminating cell-cycle progression in the developing zebrafish embryo , 2009, Proceedings of the National Academy of Sciences.

[75]  G. Badaracco,et al.  Interaction between the inner nuclear membrane lamin B receptor and the heterochromatic methyl binding protein, MeCP2. , 2009, Experimental cell research.

[76]  A. Feinberg,et al.  Large histone H3 lysine 9 dimethylated chromatin blocks distinguish differentiated from embryonic stem cells , 2009, Nature Genetics.

[77]  S. Elledge,et al.  CDYL bridges REST and histone methyltransferases for gene repression and suppression of cellular transformation. , 2008, Molecular cell.

[78]  Archana Dhasarathy,et al.  The MBD protein family-reading an epigenetic mark? , 2008, Mutation research.

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

[80]  E. Bertolino,et al.  Transcriptional repression mediated by repositioning of genes to the nuclear lamina , 2008, Nature.

[81]  Atsushi Miyawaki,et al.  Visualizing Spatiotemporal Dynamics of Multicellular Cell-Cycle Progression , 2008, Cell.

[82]  T. Wandless,et al.  A Directed Approach for Engineering Conditional Protein Stability Using Biologically Silent Small Molecules* , 2007, Journal of Biological Chemistry.

[83]  H. Leonhardt,et al.  MeCP2 interacts with HP1 and modulates its heterochromatin association during myogenic differentiation , 2007, Nucleic acids research.

[84]  Bas van Steensel,et al.  Detection of in vivo protein–DNA interactions using DamID in mammalian cells , 2007, Nature Protocols.

[85]  Matthew J. Gamble,et al.  SET and PARP1 remove DEK from chromatin to permit access by the transcription machinery , 2007, Nature Structural &Molecular Biology.

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

[87]  D. Kavanagh,et al.  Organelle proteome variation among different cell types: lessons from nuclear membrane proteins. , 2007, Sub-cellular biochemistry.

[88]  S. Briggs,et al.  ELYS is a dual nucleoporin/kinetochore protein required for nuclear pore assembly and proper cell division , 2006, Proceedings of the National Academy of Sciences.

[89]  R. Ghosh,et al.  Multiple Modes of Interaction between the Methylated DNA Binding Protein MeCP2 and Chromatin , 2006, Molecular and Cellular Biology.

[90]  L. Banaszynski,et al.  A Rapid, Reversible, and Tunable Method to Regulate Protein Function in Living Cells Using Synthetic Small Molecules , 2006, Cell.

[91]  Y. Shinkai,et al.  Zinc Finger Protein Wiz Links G9a/GLP Histone Methyltransferases to the Co-repressor Molecule CtBP* , 2006, Journal of Biological Chemistry.

[92]  K. Nakayama,et al.  Two E3 ubiquitin ligases, SCF‐Skp2 and DDB1‐Cul4, target human Cdt1 for proteolysis , 2006, The EMBO journal.

[93]  S. L. Wong,et al.  Towards a proteome-scale map of the human protein–protein interaction network , 2005, Nature.

[94]  Y. Gruenbaum Faculty Opinions recommendation of The nuclear-envelope protein and transcriptional repressor LAP2beta interacts with HDAC3 at the nuclear periphery, and induces histone H4 deacetylation. , 2005 .

[95]  N. Amariglio,et al.  The nuclear-envelope protein and transcriptional repressor LAP2β interacts with HDAC3 at the nuclear periphery, and induces histone H4 deacetylation , 2005, Journal of Cell Science.

[96]  G. Maul,et al.  The mammalian heterochromatin protein 1 binds diverse nuclear proteins through a common motif that targets the chromoshadow domain. , 2005, Biochemical and biophysical research communications.

[97]  C. Peterson,et al.  Histones and histone modifications , 2004, Current Biology.

[98]  G. Almouzni,et al.  HP1 and the dynamics of heterochromatin maintenance , 2004, Nature Reviews Molecular Cell Biology.

[99]  G. Maul,et al.  Regulated recruitment of HP1 to a euchromatic gene induces mitotically heritable, epigenetic gene silencing: a mammalian cell culture model of gene variegation. , 2003, Genes & development.

[100]  Tony Kouzarides,et al.  The Methyl-CpG-binding Protein MeCP2 Links DNA Methylation to Histone Methylation* , 2003, The Journal of Biological Chemistry.

[101]  H. Worman,et al.  Inner nuclear membrane proteins: functions and targeting , 2001, Cellular and Molecular Life Sciences CMLS.

[102]  Prim B. Singh,et al.  Histones H3/H4 form a tight complex with the inner nuclear membrane protein LBR and heterochromatin protein 1 , 2001, EMBO reports.

[103]  A. Politou,et al.  Dynamic associations of heterochromatin protein 1 with the nuclear envelope , 2000, The EMBO journal.

[104]  C Cremer,et al.  Chromosome territories, interchromatin domain compartment, and nuclear matrix: an integrated view of the functional nuclear architecture. , 2000, Critical reviews in eukaryotic gene expression.

[105]  K. Furukawa LAP2 binding protein 1 (L2BP1/BAF) is a candidate mediator of LAP2-chromatin interaction. , 1999, Journal of cell science.

[106]  S. Gasser,et al.  Nuclear compartments and gene regulation. , 1999, Current opinion in genetics & development.

[107]  R. Foisner,et al.  Lamins and lamin-binding proteins in functional chromatin organization. , 1999, Critical reviews in eukaryotic gene expression.

[108]  M. Goldberg,et al.  The nuclear lamina: molecular organization and interaction with chromatin. , 1999, Critical reviews in eukaryotic gene expression.

[109]  J. Strouboulis,et al.  Methylated DNA and MeCP2 recruit histone deacetylase to repress transcription , 1998, Nature Genetics.

[110]  Colin A. Johnson,et al.  Transcriptional repression by the methyl-CpG-binding protein MeCP2 involves a histone deacetylase complex , 1998, Nature.

[111]  T. Jenuwein,et al.  SET domain proteins modulate chromatin domains in eu- and heterochromatin , 1998, Cellular and Molecular Life Sciences CMLS.

[112]  K. Wilson,et al.  Nuclear assembly. , 1997, Annual review of cell and developmental biology.