Literature DB >> 12819130

Antisense transcripts with FANTOM2 clone set and their implications for gene regulation.

Hidenori Kiyosawa1, Itaru Yamanaka, Naoki Osato, Shinji Kondo, Yoshihide Hayashizaki.   

Abstract

We have used the FANTOM2 mouse cDNA set (60,770 clones), public mRNA data, and mouse genome sequence data to identify 2481 pairs of sense-antisense transcripts and 899 further pairs of nonantisense bidirectional transcription based upon genomic mapping. The analysis greatly expands the number of known examples of sense-antisense transcript and nonantisense bidirectional transcription pairs in mammals. The FANTOM2 cDNA set appears to contain substantially large numbers of noncoding transcripts suitable for antisense transcript analysis. The average proportion of loci encoding sense-antisense transcript and nonantisense bidirectional transcription pairs on autosomes was 15.1 and 5.4%, respectively. Those on the X chromosome were 6.3 and 4.2%, respectively. Sense-antisense transcript pairs, rather than nonantisense bidirectional transcription pairs, may be less prevalent on the X chromosome, possibly due to X chromosome inactivation. Sense and antisense transcripts tended to be isolated from the same libraries, where nonantisense bidirectional transcription pairs were not apparently coregulated. The existence of large numbers of natural antisense transcripts implies that the regulation of gene expression by antisense transcripts is more common that previously recognized. The viewer showing mapping patterns of sense-antisense transcript pairs and nonantisense bidirectional transcription pairs on the genome and other related statistical data is available on our Web site.

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Year:  2003        PMID: 12819130      PMCID: PMC403655          DOI: 10.1101/gr.982903

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


  113 in total

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Authors:  P R Cooper; N J Smilinich; C D Day; N J Nowak; L H Reid; R S Pearsall; M Reece; D Prawitt; J Landers; D E Housman; A Winterpacht; B U Zabel; J Pelletier; B E Weissman; T B Shows; M J Higgins
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4.  Multiple imprinted sense and antisense transcripts, differential methylation and tandem repeats in a putative imprinting control region upstream of mouse Igf2.

Authors:  T Moore; M Constancia; M Zubair; B Bailleul; R Feil; H Sasaki; W Reik
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5.  Zac1 (Lot1), a potential tumor suppressor gene, and the gene for epsilon-sarcoglycan are maternally imprinted genes: identification by a subtractive screen of novel uniparental fibroblast lines.

Authors:  G Piras; A El Kharroubi; S Kozlov; D Escalante-Alcalde; L Hernandez; N G Copeland; D J Gilbert; N A Jenkins; C L Stewart
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Authors:  M Paulsen; K R Davies; L M Bowden; A J Villar; O Franck; M Fuermann; W L Dean; T F Moore; N Rodrigues; K E Davies; R J Hu; A P Feinberg; E R Maher; W Reik; J Walter
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Authors:  S Rainier; L A Johnson; C J Dobry; A J Ping; P E Grundy; A P Feinberg
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  96 in total

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10.  The effect of temperature on Natural Antisense Transcript (NAT) expression in Aspergillus flavus.

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