Landscape of transcription in human cells

Sarah Djebali; Carrie Davis; Angelika Merkel; Alexander Dobin; Timo Lassmann; A Mortazavi; Andrea Tanzer; Julien Lagarde; Wei Lin; Felix Schlesinger; Chenghai Xue; Georgi K. Marinov; Jainab Khatun; Brian A. Williams; Chris Zaleski; Joel Rozowsky; Maik Röder; Felix Kokocinski; Rehab Abdelhamid; Tyler Alioto; Igor Antoshechkin; Michael T. Baer; Nadav Bar; Philippe Batut; Kimberly Bell; Ian Bell; Sudipto K. Chakrabortty; Xian Chen; Jacqueline Chrast; João Curado; Thomas Derrien; Jörg Drenkow; Erica Dumais; Jacqueline Dumais; Radha Duttagupta; Emilie Falconnet; Meagan Fastuca; Kata Fejes-Toth; Pedro G. Ferreira; Sylvain Foissac; Melissa J. Fullwood; Hui Gao; David González; Assaf Gordon; Harsha P. Gunawardena; Cédric Howald; Sonali Jha; Rory Johnson; Philipp Kapranov; Brandon King; Colin Kingswood; Oscar Junhong Luo; Eddie Park; Kimberly Persaud; Jonathan Preall; Paolo Ribeca; Brian A. Risk; Daniel Robyr; Michael Sammeth; Lorian Schaffer; Lei-Hoon See; Atif Shahab; Jørgen Skancke; Ana Maria Suzuki; Hazuki Takahashi; Hagen Tilgner; Diane Trout; Nathalie Walters; Huaien Wang; John A. Wrobel; Yanbao Yu; Xiaoan Ruan; Yoshihide Hayashizaki; Jennifer Harrow; Mark Gerstein; Tim Hubbard; Alexandre Reymond; Stylianos E. Antonarakis; Gregory J. Hannon; Morgan C. Giddings; Yijun Ruan; B Wold; Piero Carninci; Roderic Guigó; T Gingeras

doi:10.1038/nature11233

Landscape of transcription in human cells

Sarah Djebali(Centre for Genomic Regulation), Carrie Davis(Cold Spring Harbor Laboratory), Angelika Merkel(Centre for Genomic Regulation), Alexander Dobin(Cold Spring Harbor Laboratory), Timo Lassmann(RIKEN Center for Integrative Medical Sciences), A Mortazavi(California Institute of Technology), Andrea Tanzer(Centre for Genomic Regulation), Julien Lagarde(Centre for Genomic Regulation), Wei Lin(Universitat Pompeu Fabra), Felix Schlesinger(Cold Spring Harbor Laboratory), Chenghai Xue(Cold Spring Harbor Laboratory), Georgi K. Marinov(RIKEN Center for Integrative Medical Sciences), Jainab Khatun(Boise State University), Brian A. Williams(California Institute of Technology), Chris Zaleski(Universitat Pompeu Fabra), Joel Rozowsky(Yale University), Maik Röder(Centre for Genomic Regulation), Felix Kokocinski(Yale University), Rehab Abdelhamid(Cold Spring Harbor Laboratory), Tyler Alioto(Centro Nacional de Análisis Genómico), Igor Antoshechkin(California Institute of Technology), Michael T. Baer(Universitat Pompeu Fabra), Nadav Bar(Norwegian University of Science and Technology), Philippe Batut(Universitat Pompeu Fabra), Kimberly Bell(Universitat Pompeu Fabra), Ian Bell(Norwegian University of Science and Technology), Sudipto K. Chakrabortty(Universitat Pompeu Fabra), Xian Chen(University of North Carolina at Chapel Hill), Jacqueline Chrast(University of North Carolina at Chapel Hill), João Curado(Centre for Genomic Regulation), Thomas Derrien(Centre for Genomic Regulation), Jörg Drenkow(Cold Spring Harbor Laboratory), Erica Dumais(Norwegian University of Science and Technology), Jacqueline Dumais(Norwegian University of Science and Technology), Radha Duttagupta(Norwegian University of Science and Technology), Emilie Falconnet(University of Geneva), Meagan Fastuca(Universitat Pompeu Fabra), Kata Fejes-Toth(Universitat Pompeu Fabra), Pedro G. Ferreira(Centre for Genomic Regulation), Sylvain Foissac(Laboratoire de Génétique Cellulaire), Melissa J. Fullwood(Genome Institute of Singapore), Hui Gao(Norwegian University of Science and Technology), David González(Centre for Genomic Regulation), Assaf Gordon(Cold Spring Harbor Laboratory), Harsha P. Gunawardena(University of North Carolina at Chapel Hill), Cédric Howald(University of North Carolina at Chapel Hill), Sonali Jha(Universitat Pompeu Fabra), Rory Johnson(Centre for Genomic Regulation), Philipp Kapranov(Norwegian University of Science and Technology), Brandon King(California Institute of Technology), Colin Kingswood(Centre for Genomic Regulation), Oscar Junhong Luo(Genome Institute of Singapore), Eddie Park(California Institute of Technology), Kimberly Persaud(Universitat Pompeu Fabra), Jonathan Preall(Cold Spring Harbor Laboratory), Paolo Ribeca(Centre for Genomic Regulation), Brian A. Risk(University of California, Irvine), Daniel Robyr(University of Lausanne), Michael Sammeth(Centre for Genomic Regulation), Lorian Schaffer(California Institute of Technology), Lei-Hoon See(Cold Spring Harbor Laboratory), Atif Shahab(Genome Institute of Singapore), Jørgen Skancke(Norwegian University of Science and Technology), Ana Maria Suzuki(Cold Spring Harbor Laboratory), Hazuki Takahashi(RIKEN Center for Integrative Medical Sciences), Hagen Tilgner(Centre for Genomic Regulation), Diane Trout(RIKEN Center for Integrative Medical Sciences), Nathalie Walters(University of Lausanne), Huaien Wang(Universitat Pompeu Fabra), John A. Wrobel(Boise State University), Yanbao Yu(NeuroMetrix (United States)), Xiaoan Ruan(Genome Institute of Singapore), Yoshihide Hayashizaki(Cold Spring Harbor Laboratory), Jennifer Harrow(Yale University), Mark Gerstein(Whitney Museum of American Art), Tim Hubbard(Wellcome Sanger Institute), Alexandre Reymond(University of North Carolina at Chapel Hill), Stylianos E. Antonarakis(University of Geneva), Gregory J. Hannon(Universitat Pompeu Fabra), Morgan C. Giddings(Boise State University), Yijun Ruan(Genome Institute of Singapore), B Wold(RIKEN Center for Integrative Medical Sciences), Piero Carninci(RIKEN Center for Integrative Medical Sciences), Roderic Guigó(Universitat Pompeu Fabra), T Gingeras(Norwegian University of Science and Technology)

Nature

September 1, 2012

10.1038/nature11233

Cited by 5,364Open Access

Full Text

Abstract

Eukaryotic cells make many types of primary and processed RNAs that are found either in specific subcellular compartments or throughout the cells. A complete catalogue of these RNAs is not yet available and their characteristic subcellular localizations are also poorly understood. Because RNA represents the direct output of the genetic information encoded by genomes and a significant proportion of a cell’s regulatory capabilities are focused on its synthesis, processing, transport, modification and translation, the generation of such a catalogue is crucial for understanding genome function. Here we report evidence that three-quarters of the human genome is capable of being transcribed, as well as observations about the range and levels of expression, localization, processing fates, regulatory regions and modifications of almost all currently annotated and thousands of previously unannotated RNAs. These observations, taken together, prompt a redefinition of the concept of a gene. A description is given of the ENCODE effort to provide a complete catalogue of primary and processed RNAs found either in specific subcellular compartments or throughout the cell, revealing that three-quarters of the human genome can be transcribed, and providing a wealth of information on the range and levels of expression, localization, processing fates and modifications of known and previously unannotated RNAs. These authors describe the ENCODE (Encyclopedia of DNA Elements) effort to provide a complete catalogue of primary and processed RNAs found either in specific sub-cellular compartments or throughout the cell. They show that three-quarters of the human genome can be transcribed, and provide a wealth of information about the range and levels of expression, localization, processing fates and modifications of both known and previously unannotated RNAs. Collectively, these observations suggest that the current concept of a gene should be revisited.

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