Literature DB >> 17038565

Human heterochromatin proteins form large domains containing KRAB-ZNF genes.

Maartje J Vogel1, Lars Guelen, Elzo de Wit, Daniel Peric-Hupkes, Martin Lodén, Wendy Talhout, Marike Feenstra, Ben Abbas, Anne-Kathrin Classen, Bas van Steensel.   

Abstract

Heterochromatin is important for gene regulation and chromosome structure, but the genes that are occupied by heterochromatin proteins in the mammalian genome are largely unknown. We have adapted the DamID method to systematically identify target genes of the heterochromatin proteins HP1 and SUV39H1 in human and mouse cells. Unexpectedly, we found that CBX1 (formerly HP1beta) and SUV39H1 bind to genes encoding KRAB domain containing zinc finger (KRAB-ZNF) transcriptional repressors. These genes constitute one of the largest gene families and are organized in clusters in the human genome. Preference of CBX1 for this gene family was observed in both human and mouse cells. High-resolution mapping on human chromosome 19 revealed that CBX1 coats large domains 0.1-4 Mb in size, which coincide with the position of KRAB-ZNF gene clusters. These domains show an intricate CBX1 binding pattern: While CBX1 is globally elevated throughout the domains, it is absent from the promoters and binds more strongly to the 3' ends of KRAB-ZNF genes. KRAB-ZNF domains contain large numbers of LINE elements, which may contribute to CBX1 recruitment. These results uncover a surprising link between heterochromatin and a large family of regulatory genes in mammals. We suggest a role for heterochromatin in the evolution of the KRAB-ZNF gene family.

Entities:  

Mesh:

Substances:

Year:  2006        PMID: 17038565      PMCID: PMC1665633          DOI: 10.1101/gr.5391806

Source DB:  PubMed          Journal:  Genome Res        ISSN: 1088-9051            Impact factor:   9.043


  76 in total

1.  Evolutionary analyses of the human genome.

Authors:  W H Li; Z Gu; H Wang; A Nekrutenko
Journal:  Nature       Date:  2001-02-15       Impact factor: 49.962

2.  Reversal of senescence in mouse fibroblasts through lentiviral suppression of p53.

Authors:  Annette M G Dirac; René Bernards
Journal:  J Biol Chem       Date:  2003-01-27       Impact factor: 5.157

3.  FoxM1 is required for execution of the mitotic programme and chromosome stability.

Authors:  Jamila Laoukili; Matthijs R H Kooistra; Alexandra Brás; Jos Kauw; Ron M Kerkhoven; Ashby Morrison; Hans Clevers; René H Medema
Journal:  Nat Cell Biol       Date:  2005-01-16       Impact factor: 28.824

4.  Ecdysone-inducible gene expression in mammalian cells and transgenic mice.

Authors:  D No; T P Yao; R M Evans
Journal:  Proc Natl Acad Sci U S A       Date:  1996-04-16       Impact factor: 11.205

5.  Interaction with members of the heterochromatin protein 1 (HP1) family and histone deacetylation are differentially involved in transcriptional silencing by members of the TIF1 family.

Authors:  A L Nielsen; J A Ortiz; J You; M Oulad-Abdelghani; R Khechumian; A Gansmuller; P Chambon; R Losson
Journal:  EMBO J       Date:  1999-11-15       Impact factor: 11.598

6.  Genome-wide HP1 binding in Drosophila: developmental plasticity and genomic targeting signals.

Authors:  Elzo de Wit; Frauke Greil; Bas van Steensel
Journal:  Genome Res       Date:  2005-08-18       Impact factor: 9.043

7.  Cell cycle behavior of human HP1 subtypes: distinct molecular domains of HP1 are required for their centromeric localization during interphase and metaphase.

Authors:  Tomohiro Hayakawa; Tokuko Haraguchi; Hiroshi Masumoto; Yasushi Hiraoka
Journal:  J Cell Sci       Date:  2003-07-02       Impact factor: 5.285

8.  Regulation of heterochromatic silencing and histone H3 lysine-9 methylation by RNAi.

Authors:  Thomas A Volpe; Catherine Kidner; Ira M Hall; Grace Teng; Shiv I S Grewal; Robert A Martienssen
Journal:  Science       Date:  2002-08-22       Impact factor: 47.728

9.  Chromosomal distribution of PcG proteins during Drosophila development.

Authors:  Nicolas Nègre; Jérôme Hennetin; Ling V Sun; Sergey Lavrov; Michel Bellis; Kevin P White; Giacomo Cavalli
Journal:  PLoS Biol       Date:  2006-04-20       Impact factor: 8.029

10.  Heterochromatin protein 1 (HP1) is associated with induced gene expression in Drosophila euchromatin.

Authors:  Lucia Piacentini; Laura Fanti; Maria Berloco; Barbara Perrini; Sergio Pimpinelli
Journal:  J Cell Biol       Date:  2003-05-19       Impact factor: 10.539
View more
  87 in total

1.  Late-replicating heterochromatin is characterized by decreased cytosine methylation in the human genome.

Authors:  Masako Suzuki; Mayumi Oda; María-Paz Ramos; Marién Pascual; Kevin Lau; Edyta Stasiek; Frederick Agyiri; Reid F Thompson; Jacob L Glass; Qiang Jing; Richard Sandstrom; Melissa J Fazzari; R Scott Hansen; John A Stamatoyannopoulos; Andrew S McLellan; John M Greally
Journal:  Genome Res       Date:  2011-09-28       Impact factor: 9.043

2.  Epigenetics of eu- and heterochromatin in inverted and conventional nuclei from mouse retina.

Authors:  Anja Eberhart; Yana Feodorova; Congdi Song; Gerhard Wanner; Elena Kiseleva; Takahisa Furukawa; Hiroshi Kimura; Gunnar Schotta; Heinrich Leonhardt; Boris Joffe; Irina Solovei
Journal:  Chromosome Res       Date:  2013-08-31       Impact factor: 5.239

Review 3.  A system biology approach to identify regulatory pathways underlying the neuroendocrine control of female puberty in rats and nonhuman primates.

Authors:  Alejandro Lomniczi; Hollis Wright; Juan Manuel Castellano; Kemal Sonmez; Sergio R Ojeda
Journal:  Horm Behav       Date:  2013-07       Impact factor: 3.587

Review 4.  Chromatin domains in higher eukaryotes: insights from genome-wide mapping studies.

Authors:  Elzo de Wit; Bas van Steensel
Journal:  Chromosoma       Date:  2008-10-14       Impact factor: 4.316

5.  Gene networks and the neuroendocrine regulation of puberty.

Authors:  Sergio R Ojeda; Christopher Dubay; Alejandro Lomniczi; Gabi Kaidar; Valerie Matagne; Ursula S Sandau; Gregory A Dissen
Journal:  Mol Cell Endocrinol       Date:  2009-12-22       Impact factor: 4.102

Review 6.  Lineage-specific transcription factors and the evolution of gene regulatory networks.

Authors:  Katja Nowick; Lisa Stubbs
Journal:  Brief Funct Genomics       Date:  2010-01-16       Impact factor: 4.241

Review 7.  The current state of chromatin immunoprecipitation.

Authors:  Philippe Collas
Journal:  Mol Biotechnol       Date:  2010-05       Impact factor: 2.695

8.  A 3D map of the human genome at kilobase resolution reveals principles of chromatin looping.

Authors:  Suhas S P Rao; Miriam H Huntley; Neva C Durand; Elena K Stamenova; Ivan D Bochkov; James T Robinson; Adrian L Sanborn; Ido Machol; Arina D Omer; Eric S Lander; Erez Lieberman Aiden
Journal:  Cell       Date:  2014-12-11       Impact factor: 41.582

9.  Genome wide transcriptional profiling in breast cancer cells reveals distinct changes in hormone receptor target genes and chromatin modifying enzymes after proteasome inhibition.

Authors:  H Karimi Kinyamu; Jennifer B Collins; Sherry F Grissom; Pratibha B Hebbar; Trevor K Archer
Journal:  Mol Carcinog       Date:  2008-11       Impact factor: 4.784

Review 10.  Analysis of epigenetic alterations to chromatin during development.

Authors:  Meghan E Minard; Abhinav K Jain; Michelle Craig Barton
Journal:  Genesis       Date:  2009-08       Impact factor: 2.487
View more

北京卡尤迪生物科技股份有限公司 © 2022-2023.