Literature DB >> 24153182

RNA polymerase I structure and transcription regulation.

Christoph Engel1, Sarah Sainsbury, Alan C Cheung, Dirk Kostrewa, Patrick Cramer.   

Abstract

Transcription of ribosomal RNA by RNA polymerase (Pol) I initiates ribosome biogenesis and regulates eukaryotic cell growth. The crystal structure of Pol I from the yeast Saccharomyces cerevisiae at 2.8 Å resolution reveals all 14 subunits of the 590-kilodalton enzyme, and shows differences to Pol II. An 'expander' element occupies the DNA template site and stabilizes an expanded active centre cleft with an unwound bridge helix. A 'connector' element invades the cleft of an adjacent polymerase and stabilizes an inactive polymerase dimer. The connector and expander must detach during Pol I activation to enable transcription initiation and cleft contraction by convergent movement of the polymerase 'core' and 'shelf' modules. Conversion between an inactive expanded and an active contracted polymerase state may generally underlie transcription. Regulatory factors can modulate the core-shelf interface that includes a 'composite' active site for RNA chain initiation, elongation, proofreading and termination.

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Year:  2013        PMID: 24153182     DOI: 10.1038/nature12712

Source DB:  PubMed          Journal:  Nature        ISSN: 0028-0836            Impact factor:   49.962


  63 in total

1.  RNA polymerase I contains a TFIIF-related DNA-binding subcomplex.

Authors:  Sebastian R Geiger; Kristina Lorenzen; Amelie Schreieck; Patrizia Hanecker; Dirk Kostrewa; Albert J R Heck; Patrick Cramer
Journal:  Mol Cell       Date:  2010-08-27       Impact factor: 17.970

2.  Structural biology of RNA polymerase III: subcomplex C17/25 X-ray structure and 11 subunit enzyme model.

Authors:  Anna J Jasiak; Karim-Jean Armache; Birgit Martens; Ralf-Peter Jansen; Patrick Cramer
Journal:  Mol Cell       Date:  2006-07-07       Impact factor: 17.970

3.  Evolution of two modes of intrinsic RNA polymerase transcript cleavage.

Authors:  Wenjie Ruan; Elisabeth Lehmann; Michael Thomm; Dirk Kostrewa; Patrick Cramer
Journal:  J Biol Chem       Date:  2011-03-23       Impact factor: 5.157

4.  Resolution of RNA polymerase I into dimers and monomers and their function in transcription.

Authors:  P Milkereit; P Schultz; H Tschochner
Journal:  Biol Chem       Date:  1997-12       Impact factor: 3.915

5.  Multiple forms of DNA-dependent RNA polymerase in eukaryotic organisms.

Authors:  R G Roeder; W J Rutter
Journal:  Nature       Date:  1969-10-18       Impact factor: 49.962

6.  TAF1B is a TFIIB-like component of the basal transcription machinery for RNA polymerase I.

Authors:  Srivatsava Naidu; J Karsten Friedrich; Jackie Russell; Joost C B M Zomerdijk
Journal:  Science       Date:  2011-09-16       Impact factor: 47.728

7.  hRRN3 is essential in the SL1-mediated recruitment of RNA Polymerase I to rRNA gene promoters.

Authors:  G Miller; K I Panov; J K Friedrich; L Trinkle-Mulcahy; A I Lamond; J C Zomerdijk
Journal:  EMBO J       Date:  2001-03-15       Impact factor: 11.598

8.  Features and development of Coot.

Authors:  P Emsley; B Lohkamp; W G Scott; K Cowtan
Journal:  Acta Crystallogr D Biol Crystallogr       Date:  2010-03-24

9.  Two RNA polymerase I subunits control the binding and release of Rrn3 during transcription.

Authors:  Frédéric Beckouet; Sylvie Labarre-Mariotte; Benjamin Albert; Yukiko Imazawa; Michel Werner; Olivier Gadal; Yasuhisa Nogi; Pierre Thuriaux
Journal:  Mol Cell Biol       Date:  2007-12-17       Impact factor: 4.272

10.  Architecture of the RNA polymerase II-TFIIF complex revealed by cross-linking and mass spectrometry.

Authors:  Zhuo Angel Chen; Anass Jawhari; Lutz Fischer; Claudia Buchen; Salman Tahir; Tomislav Kamenski; Morten Rasmussen; Laurent Lariviere; Jimi-Carlo Bukowski-Wills; Michael Nilges; Patrick Cramer; Juri Rappsilber
Journal:  EMBO J       Date:  2010-01-21       Impact factor: 11.598
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  97 in total

1.  Structure of Escherichia coli RNA polymerase holoenzyme at last.

Authors:  Lucia B Rothman-Denes
Journal:  Proc Natl Acad Sci U S A       Date:  2013-11-22       Impact factor: 11.205

Review 2.  Emerging Roles for Maf1 beyond the Regulation of RNA Polymerase III Activity.

Authors:  Akshat Khanna; Ajay Pradhan; Sean P Curran
Journal:  J Mol Biol       Date:  2015-07-11       Impact factor: 5.469

3.  Architecture of the RNA polymerase II-Mediator core initiation complex.

Authors:  C Plaschka; L Larivière; L Wenzeck; M Seizl; M Hemann; D Tegunov; E V Petrotchenko; C H Borchers; W Baumeister; F Herzog; E Villa; P Cramer
Journal:  Nature       Date:  2015-02-04       Impact factor: 49.962

4.  A new era of studying p53-mediated transcription activation.

Authors:  Wei-Li Liu; Robert A Coleman; Sameer K Singh
Journal:  Transcription       Date:  2017-10-04

5.  The dynamic assembly of distinct RNA polymerase I complexes modulates rDNA transcription.

Authors:  Eva Torreira; Jaime Alegrio Louro; Irene Pazos; Noelia González-Polo; David Gil-Carton; Ana Garcia Duran; Sébastien Tosi; Oriol Gallego; Olga Calvo; Carlos Fernández-Tornero
Journal:  Elife       Date:  2017-03-06       Impact factor: 8.140

6.  Crystal Structure of a Transcribing RNA Polymerase II Complex Reveals a Complete Transcription Bubble.

Authors:  Christopher O Barnes; Monica Calero; Indranil Malik; Brian W Graham; Henrik Spahr; Guowu Lin; Aina E Cohen; Ian S Brown; Qiangmin Zhang; Filippo Pullara; Michael A Trakselis; Craig D Kaplan; Guillermo Calero
Journal:  Mol Cell       Date:  2015-07-16       Impact factor: 17.970

Review 7.  Transcription factors that influence RNA polymerases I and II: To what extent is mechanism of action conserved?

Authors:  Yinfeng Zhang; Saman M Najmi; David A Schneider
Journal:  Biochim Biophys Acta Gene Regul Mech       Date:  2016-10-27       Impact factor: 4.490

8.  RNA polymerase I (Pol I) passage through nucleosomes depends on Pol I subunits binding its lobe structure.

Authors:  Philipp E Merkl; Michael Pilsl; Tobias Fremter; Katrin Schwank; Christoph Engel; Gernot Längst; Philipp Milkereit; Joachim Griesenbeck; Herbert Tschochner
Journal:  J Biol Chem       Date:  2020-02-14       Impact factor: 5.157

9.  tp53-dependent and independent signaling underlies the pathogenesis and possible prevention of Acrofacial Dysostosis-Cincinnati type.

Authors:  Kristin E N Watt; Cynthia L Neben; Shawn Hall; Amy E Merrill; Paul A Trainor
Journal:  Hum Mol Genet       Date:  2018-08-01       Impact factor: 6.150

10.  Acrofacial Dysostosis, Cincinnati Type, a Mandibulofacial Dysostosis Syndrome with Limb Anomalies, Is Caused by POLR1A Dysfunction.

Authors:  K Nicole Weaver; Kristin E Noack Watt; Robert B Hufnagel; Joaquin Navajas Acedo; Luke L Linscott; Kristen L Sund; Patricia L Bender; Rainer König; Charles M Lourenco; Ute Hehr; Robert J Hopkin; Dietmar R Lohmann; Paul A Trainor; Dagmar Wieczorek; Howard M Saal
Journal:  Am J Hum Genet       Date:  2015-04-23       Impact factor: 11.025
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