Regulated post-transcriptional RNA cleavage diversifies the eukaryotic transcriptome

The complexity of the eukaryotic transcriptome is generated by the interplay of transcription initiation, termination, alternative splicing, and other forms of post-transcriptional modification. It was recently shown that RNA transcripts may also undergo cleavage and secondary 5' capping. Here,...

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Veröffentlicht in:	Genome research 2010-12, Vol.20 (12), p.1639-1650
Hauptverfasser:	Mercer, Tim R, Dinger, Marcel E, Bracken, Cameron P, Kolle, Gabriel, Szubert, Jan M, Korbie, Darren J, Askarian-Amiri, Marjan E, Gardiner, Brooke B, Goodall, Gregory J, Grimmond, Sean M, Mattick, John S
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Sprache:	eng
Schlagworte:	Epigenesis, Genetic - genetics Eukaryota - genetics Gene Expression Profiling Genetic Variation Peptide Hydrolases - metabolism RNA Processing, Post-Transcriptional - genetics RNA, Messenger - genetics RNA, Messenger - metabolism Sequence Analysis, RNA
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container_title	Genome research
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creator	Mercer, Tim R Dinger, Marcel E Bracken, Cameron P Kolle, Gabriel Szubert, Jan M Korbie, Darren J Askarian-Amiri, Marjan E Gardiner, Brooke B Goodall, Gregory J Grimmond, Sean M Mattick, John S
description	The complexity of the eukaryotic transcriptome is generated by the interplay of transcription initiation, termination, alternative splicing, and other forms of post-transcriptional modification. It was recently shown that RNA transcripts may also undergo cleavage and secondary 5' capping. Here, we show that post-transcriptional cleavage of RNA contributes to the diversification of the transcriptome by generating a range of small RNAs and long coding and noncoding RNAs. Using genome-wide histone modification and RNA polymerase II occupancy data, we confirm that the vast majority of intraexonic CAGE tags are derived from post-transcriptional processing. By comparing exonic CAGE tags to tissue-matched PARE data, we show that the cleavage and subsequent secondary capping is regulated in a developmental-stage- and tissue-specific manner. Furthermore, we find evidence of prevalent RNA cleavage in numerous transcriptomic data sets, including SAGE, cDNA, small RNA libraries, and deep-sequenced size-fractionated pools of RNA. These cleavage products include mRNA variants that retain the potential to be translated into shortened functional protein isoforms. We conclude that post-transcriptional RNA cleavage is a key mechanism that expands the functional repertoire and scope for regulatory control of the eukaryotic transcriptome.
doi_str_mv	10.1101/gr.112128.110
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It was recently shown that RNA transcripts may also undergo cleavage and secondary 5' capping. Here, we show that post-transcriptional cleavage of RNA contributes to the diversification of the transcriptome by generating a range of small RNAs and long coding and noncoding RNAs. Using genome-wide histone modification and RNA polymerase II occupancy data, we confirm that the vast majority of intraexonic CAGE tags are derived from post-transcriptional processing. By comparing exonic CAGE tags to tissue-matched PARE data, we show that the cleavage and subsequent secondary capping is regulated in a developmental-stage- and tissue-specific manner. Furthermore, we find evidence of prevalent RNA cleavage in numerous transcriptomic data sets, including SAGE, cDNA, small RNA libraries, and deep-sequenced size-fractionated pools of RNA. These cleavage products include mRNA variants that retain the potential to be translated into shortened functional protein isoforms. 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subjects	Epigenesis, Genetic - genetics Eukaryota - genetics Gene Expression Profiling Genetic Variation Peptide Hydrolases - metabolism RNA Processing, Post-Transcriptional - genetics RNA, Messenger - genetics RNA, Messenger - metabolism Sequence Analysis, RNA
title	Regulated post-transcriptional RNA cleavage diversifies the eukaryotic transcriptome
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