Literature DB >> 23493425

A KRAB/KAP1-miRNA cascade regulates erythropoiesis through stage-specific control of mitophagy.

Isabelle Barde1, Benjamin Rauwel, Ray Marcel Marin-Florez, Andrea Corsinotti, Elisa Laurenti, Sonia Verp, Sandra Offner, Julien Marquis, Adamandia Kapopoulou, Jiri Vanicek, Didier Trono.   

Abstract

During hematopoiesis, lineage- and stage-specific transcription factors work in concert with chromatin modifiers to direct the differentiation of all blood cells. We explored the role of KRAB-containing zinc finger proteins (KRAB-ZFPs) and their cofactor KAP1 in this process. In mice, hematopoietic-restricted deletion of Kap1 resulted in severe hypoproliferative anemia. Kap1-deleted erythroblasts failed to induce mitophagy-associated genes and retained mitochondria. This was due to persistent expression of microRNAs (miRNAs) targeting mitophagy transcripts, itself secondary to a lack of repression by stage-specific KRAB-ZFPs. The KRAB/KAP1-miRNA regulatory cascade is evolutionarily conserved, as it also controls mitophagy during human erythropoiesis. Thus, a multilayered transcription regulatory system is present, in which protein- and RNA-based repressors are superimposed in combinatorial fashion to govern the timely triggering of an important differentiation event.

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Year:  2013        PMID: 23493425      PMCID: PMC3678075          DOI: 10.1126/science.1232398

Source DB:  PubMed          Journal:  Science        ISSN: 0036-8075            Impact factor:   47.728


  27 in total

1.  Targeting histone deacetylase complexes via KRAB-zinc finger proteins: the PHD and bromodomains of KAP-1 form a cooperative unit that recruits a novel isoform of the Mi-2alpha subunit of NuRD.

Authors:  D C Schultz; J R Friedman; F J Rauscher
Journal:  Genes Dev       Date:  2001-02-15       Impact factor: 11.361

2.  Sequence-specific transcriptional corepressor function for BRCA1 through a novel zinc finger protein, ZBRK1.

Authors:  L Zheng; H Pan; S Li; A Flesken-Nikitin; P L Chen; T G Boyer; W H Lee
Journal:  Mol Cell       Date:  2000-10       Impact factor: 17.970

3.  KAP1 regulates gene networks controlling T-cell development and responsiveness.

Authors:  Francesca R Santoni de Sio; Isabelle Barde; Sandra Offner; Adamandia Kapopoulou; Andrea Corsinotti; Karolina Bojkowska; Raphaël Genolet; James H Thomas; Immanuel F Luescher; Daniel Pinschewer; Nicola Harris; Didier Trono
Journal:  FASEB J       Date:  2012-08-07       Impact factor: 5.191

4.  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

5.  TRIM28 prevents autoinflammatory T cell development in vivo.

Authors:  Shunsuke Chikuma; Naomasa Suita; Il-Mi Okazaki; Shiro Shibayama; Tasuku Honjo
Journal:  Nat Immunol       Date:  2012-04-29       Impact factor: 25.606

6.  The KRAB-ZFP/KAP1 system contributes to the early embryonic establishment of site-specific DNA methylation patterns maintained during development.

Authors:  Simon Quenneville; Priscilla Turelli; Karolina Bojkowska; Charlène Raclot; Sandra Offner; Adamandia Kapopoulou; Didier Trono
Journal:  Cell Rep       Date:  2012-10-04       Impact factor: 9.423

7.  Combinatorial assembly of developmental stage-specific enhancers controls gene expression programs during human erythropoiesis.

Authors:  Jian Xu; Zhen Shao; Kimberly Glass; Daniel E Bauer; Luca Pinello; Ben Van Handel; Serena Hou; John A Stamatoyannopoulos; Hanna K A Mikkola; Guo-Cheng Yuan; Stuart H Orkin
Journal:  Dev Cell       Date:  2012-10-04       Impact factor: 12.270

8.  KAP1 regulates gene networks controlling mouse B-lymphoid cell differentiation and function.

Authors:  Francesca R Santoni de Sio; Joanna Massacand; Isabelle Barde; Sandra Offner; Andrea Corsinotti; Adamandia Kapopoulou; Karolina Bojkowska; Antonis Dagklis; Marylise Fernandez; Paolo Ghia; James H Thomas; Daniel Pinschewer; Nicola Harris; Didier Trono
Journal:  Blood       Date:  2012-03-27       Impact factor: 22.113

9.  The sequence of the human genome.

Authors:  J C Venter; M D Adams; E W Myers; P W Li; R J Mural; G G Sutton; H O Smith; M Yandell; C A Evans; R A Holt; J D Gocayne; P Amanatides; R M Ballew; D H Huson; J R Wortman; Q Zhang; C D Kodira; X H Zheng; L Chen; M Skupski; G Subramanian; P D Thomas; J Zhang; G L Gabor Miklos; C Nelson; S Broder; A G Clark; J Nadeau; V A McKusick; N Zinder; A J Levine; R J Roberts; M Simon; C Slayman; M Hunkapiller; R Bolanos; A Delcher; I Dew; D Fasulo; M Flanigan; L Florea; A Halpern; S Hannenhalli; S Kravitz; S Levy; C Mobarry; K Reinert; K Remington; J Abu-Threideh; E Beasley; K Biddick; V Bonazzi; R Brandon; M Cargill; I Chandramouliswaran; R Charlab; K Chaturvedi; Z Deng; V Di Francesco; P Dunn; K Eilbeck; C Evangelista; A E Gabrielian; W Gan; W Ge; F Gong; Z Gu; P Guan; T J Heiman; M E Higgins; R R Ji; Z Ke; K A Ketchum; Z Lai; Y Lei; Z Li; J Li; Y Liang; X Lin; F Lu; G V Merkulov; N Milshina; H M Moore; A K Naik; V A Narayan; B Neelam; D Nusskern; D B Rusch; S Salzberg; W Shao; B Shue; J Sun; Z Wang; A Wang; X Wang; J Wang; M Wei; R Wides; C Xiao; C Yan; A Yao; J Ye; M Zhan; W Zhang; H Zhang; Q Zhao; L Zheng; F Zhong; W Zhong; S Zhu; S Zhao; D Gilbert; S Baumhueter; G Spier; C Carter; A Cravchik; T Woodage; F Ali; H An; A Awe; D Baldwin; H Baden; M Barnstead; I Barrow; K Beeson; D Busam; A Carver; A Center; M L Cheng; L Curry; S Danaher; L Davenport; R Desilets; S Dietz; K Dodson; L Doup; S Ferriera; N Garg; A Gluecksmann; B Hart; J Haynes; C Haynes; C Heiner; S Hladun; D Hostin; J Houck; T Howland; C Ibegwam; J Johnson; F Kalush; L Kline; S Koduru; A Love; F Mann; D May; S McCawley; T McIntosh; I McMullen; M Moy; L Moy; B Murphy; K Nelson; C Pfannkoch; E Pratts; V Puri; H Qureshi; M Reardon; R Rodriguez; Y H Rogers; D Romblad; B Ruhfel; R Scott; C Sitter; M Smallwood; E Stewart; R Strong; E Suh; R Thomas; N N Tint; S Tse; C Vech; G Wang; J Wetter; S Williams; M Williams; S Windsor; E Winn-Deen; K Wolfe; J Zaveri; K Zaveri; J F Abril; R Guigó; M J Campbell; K V Sjolander; B Karlak; A Kejariwal; H Mi; B Lazareva; T Hatton; A Narechania; K Diemer; A Muruganujan; N Guo; S Sato; V Bafna; S Istrail; R Lippert; R Schwartz; B Walenz; S Yooseph; D Allen; A Basu; J Baxendale; L Blick; M Caminha; J Carnes-Stine; P Caulk; Y H Chiang; M Coyne; C Dahlke; A Deslattes Mays; M Dombroski; M Donnelly; D Ely; S Esparham; C Fosler; H Gire; S Glanowski; K Glasser; A Glodek; M Gorokhov; K Graham; B Gropman; M Harris; J Heil; S Henderson; J Hoover; D Jennings; C Jordan; J Jordan; J Kasha; L Kagan; C Kraft; A Levitsky; M Lewis; X Liu; J Lopez; D Ma; W Majoros; J McDaniel; S Murphy; M Newman; T Nguyen; N Nguyen; M Nodell; S Pan; J Peck; M Peterson; W Rowe; R Sanders; J Scott; M Simpson; T Smith; A Sprague; T Stockwell; R Turner; E Venter; M Wang; M Wen; D Wu; M Wu; A Xia; A Zandieh; X Zhu
Journal:  Science       Date:  2001-02-16       Impact factor: 47.728

10.  TRIM28 repression of retrotransposon-based enhancers is necessary to preserve transcriptional dynamics in embryonic stem cells.

Authors:  Helen M Rowe; Adamandia Kapopoulou; Andrea Corsinotti; Liana Fasching; Todd S Macfarlan; Yara Tarabay; Stéphane Viville; Johan Jakobsson; Samuel L Pfaff; Didier Trono
Journal:  Genome Res       Date:  2012-12-10       Impact factor: 9.043
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  50 in total

1.  TAF10 Interacts with the GATA1 Transcription Factor and Controls Mouse Erythropoiesis.

Authors:  Petros Papadopoulos; Laura Gutiérrez; Jeroen Demmers; Elisabeth Scheer; Farzin Pourfarzad; Dimitris N Papageorgiou; Elena Karkoulia; John Strouboulis; Harmen J G van de Werken; Reinier van der Linden; Peter Vandenberghe; Dick H W Dekkers; Sjaak Philipsen; Frank Grosveld; Làszlò Tora
Journal:  Mol Cell Biol       Date:  2015-04-13       Impact factor: 4.272

2.  The TRIMming on an erythroid repressor complex.

Authors:  Margaret H Baron
Journal:  Blood       Date:  2013-11-28       Impact factor: 22.113

Review 3.  Precision autophagy directed by receptor regulators - emerging examples within the TRIM family.

Authors:  Tomonori Kimura; Michael Mandell; Vojo Deretic
Journal:  J Cell Sci       Date:  2016-02-15       Impact factor: 5.285

4.  The WTX Tumor Suppressor Interacts with the Transcriptional Corepressor TRIM28.

Authors:  Woo Jae Kim; Ben S Wittner; Arnaud Amzallag; Brian W Brannigan; David T Ting; Sridhar Ramaswamy; Shyamala Maheswaran; Daniel A Haber
Journal:  J Biol Chem       Date:  2015-04-16       Impact factor: 5.157

5.  TRIM proteins regulate autophagy and can target autophagic substrates by direct recognition.

Authors:  Michael A Mandell; Ashish Jain; John Arko-Mensah; Santosh Chauhan; Tomonori Kimura; Christina Dinkins; Guido Silvestri; Jan Münch; Frank Kirchhoff; Anne Simonsen; Yongjie Wei; Beth Levine; Terje Johansen; Vojo Deretic
Journal:  Dev Cell       Date:  2014-08-07       Impact factor: 12.270

6.  KAP1 represses differentiation-inducible genes in embryonic stem cells through cooperative binding with PRC1 and derepresses pluripotency-associated genes.

Authors:  Bo Cheng; Xiaojun Ren; Tom K Kerppola
Journal:  Mol Cell Biol       Date:  2014-03-31       Impact factor: 4.272

7.  Mitochondrial NIX Promotes Tumor Survival in the Hypoxic Niche of Glioblastoma.

Authors:  Jinkyu Jung; Ying Zhang; Orieta Celiku; Wei Zhang; Hua Song; Brian J Williams; Amber J Giles; Jeremy N Rich; Roger Abounader; Mark R Gilbert; Deric M Park
Journal:  Cancer Res       Date:  2019-09-05       Impact factor: 12.701

8.  TRIM28 is essential for erythroblast differentiation in the mouse.

Authors:  Tomonori Hosoya; Mary Clifford; Régine Losson; Osamu Tanabe; James Douglas Engel
Journal:  Blood       Date:  2013-10-03       Impact factor: 22.113

9.  TRIM17 contributes to autophagy of midbodies while actively sparing other targets from degradation.

Authors:  Michael A Mandell; Ashish Jain; Suresh Kumar; Moriah J Castleman; Tahira Anwar; Eeva-Liisa Eskelinen; Terje Johansen; Rytis Prekeris; Vojo Deretic
Journal:  J Cell Sci       Date:  2016-08-25       Impact factor: 5.285

10.  MicroRNA-137 is a novel hypoxia-responsive microRNA that inhibits mitophagy via regulation of two mitophagy receptors FUNDC1 and NIX.

Authors:  Wen Li; Xingli Zhang; Haixia Zhuang; He-ge Chen; Yinqin Chen; Weili Tian; Wenxian Wu; Ying Li; Sijie Wang; Liangqing Zhang; Yusen Chen; Longxuan Li; Bin Zhao; Senfang Sui; Zhe Hu; Du Feng
Journal:  J Biol Chem       Date:  2014-02-26       Impact factor: 5.157
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