Long non-coding RNA identification over mouse brain development by integrative modeling of chromatin and genomic features

Lv, Jie; Liu, Hongbo; Huang, Zhijun; Su, Jianzhong; He, Hongbin; Xiu, Youcheng; Zhang, Yan; Wu, Qiong

doi:10.1093/nar/gkt818

Cited by 65 publications

(48 citation statements)

References 84 publications

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“…The results together with others (Lv et al, 2013a;Lv et al, 2013b;Ng et al, 2012b;Qureshi and Mehler, 2012) have highlighted the importance of lncRNAs in regulation of cellular fate in neural cells and brain. Increasing evidences suggested that lncRNAs can control epigenetic targeting via their ability to bind RNA, DNA and protein (Guttman and Rinn, 2012;Mercer and Mattick, 2013;Tsai et al, 2010).…”

Section: High-throughput Approaches To Study the Lncrnas In Cns Develsupporting

confidence: 65%

“…Actually, many transcriptomic studies have revealed the dynamic lncRNA expression profiles and their functions among developing, fetal and adult tissues, in additional to embryonic stem (ES) cells Sheik Mohamed et al, 2010), neural cell subtypes Aprea et al, 2013;Lin et al, 2011), and brain Ponjavic et al, 2009;Lv et al, 2013a;Lv et al, 2013b).…”

Section: Lncrnas In the Central Nervous Systemmentioning

confidence: 99%

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Long Non-coding RNAs: key players in brain and central nervous system development

Lv¹,

Liu²,

Liu³

et al. 2014

cmb

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CanadaComputational Molecular Biology (Online, ISSN 1927-5587) ), indexed by international database ProQuest, is an open access, peer reviewed journal publishing original research papers of general interest involving in the computational biology at the molecular level.The Journal is publishing all the latest and outstanding research articles, letters, methods, and reviews in all areas of Computational Molecular Biology, covering new discoveries in molecular biology, from genes to genomes, using statistical, mathematical, and computational methods as well as new development of computational methods and databases in molecular and genome biology.The papers published in the journal are expected to be of interests to computational scientists, biologists, and teachers/students/researchers engaged in biology, as well as are appropriate for R & D personnel and general readers interested in computational technology and biology.Computational Molecular Biology is published independently by BioPublisher. It is committed to publishing and disseminating significant original achievements in the related research fields of molecular biology. Vol.4, No.5, 1-13 (doi: 10.5376/cmb.2014.04.0005) Abstract Regulatory long non-coding RNAs have been emerged as a major contribution of cognitive evolution in mammalian central nervous system and brain tissues. Though proteins have relatively conserved during evolution, the lncRNAs have evolved rapidly to cope with essential and widespread cellular regulation, partly by directing generic protein function. Long non-coding RNAs, highly yet specifically expressed in mammalian brain, provide tissue-and neuronal activity-specific epigenetic and transcriptional regulation. lncRNAs have been documented to be essential for brain development and be involved in brain related diseases. We suggest that lncRNAs are important to modulate diverse central nervous system processes and are the major factor that is important to the brain development, which may be employed to develop novel diagnostic and therapeutic strategies to treat brain related diseases. Moreover, animal models with altered lncRNA expressions and high-throughput approaches would help to understand the mechanisms of lncRNAs in brain development and the etiology of lncRNA-driven human neurological diseases.

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Section: High-throughput Approaches To Study the Lncrnas In Cns Develsupporting

confidence: 65%

Section: Lncrnas In the Central Nervous Systemmentioning

confidence: 99%

Long Non-coding RNAs: key players in brain and central nervous system development

Lv¹,

Liu²,

Liu³

et al. 2014

cmb

Self Cite

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“…Indeed, a nuclear isoform of PTEN antisense transcript and its cytosolic counterparts have opposite effects on PTEN expression, due to differential sequestration of small ncRNAs within the two cellular compartments (Poliseno et al 2010;Jalali et al 2012). Owing to these diverse molecular mechanisms, lncRNAs are now known as important regulators of fundamental processes such as development, imprinting, and cell differentiation (Kretz 2013;Lee and Bartolomei 2013;Lv et al 2013). They are also involved in stress responses to heat, hypoxia, or DNA damage (Jolly et al 2004;Bertozzi et al 2011;Wu et al 2012;Place and Noonan 2013;Wan et al 2013;Yang et al 2013a;Zhang et al 2013).…”

Section: Introductionmentioning

confidence: 99%

Databases for lncRNAs: a comparative evaluation of emerging tools

Fritah

Niclou

Azuaje

2014

RNA

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The vast majority of the human transcriptome does not code for proteins. Advances in transcriptome arrays and deep sequencing are giving rise to a fast accumulation of large data sets, particularly of long noncoding RNAs (lncRNAs). Although it is clear that individual lncRNAs may play important and diverse biological roles, there is a large gap between the number of existing lncRNAs and their known relation to molecular/cellular function. This and related information have recently been gathered in several databases dedicated to lncRNA research. Here, we review the content of general and more specialized databases on lncRNAs. We evaluate these resources in terms of the quality of annotations, the reporting of validated or predicted molecular associations, and their integration with other resources and computational analysis tools. We illustrate our findings using known and novel cancer-related lncRNAs. Finally, we discuss limitations and highlight potential future directions for these databases to help delineating functions associated with lncRNAs.

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“…Previous studies indicated that both protein-coding genes and non-coding genes were associated with diverse chromatin signals Lv et al, 2013). H3K4me3 and H3K27me3 are known to mark promoters for activating and repressing gene expression respectively (Li et al, 2012), while H3K36me3 generally marks the elongation sites of transcribed regions (Lv et al, 2013).…”

Section: Characterization Of Transcriptional Activity and Conservatiomentioning

confidence: 99%

“…H3K4me3 and H3K27me3 are known to mark promoters for activating and repressing gene expression respectively (Li et al, 2012), while H3K36me3 generally marks the elongation sites of transcribed regions (Lv et al, 2013). So we examined these related transcriptional element of all non-coding RNAs.…”

Section: Characterization Of Transcriptional Activity and Conservatiomentioning

confidence: 99%

Identification and analysis of mouse non-coding RNA using transcriptome data

Zhao

Liu

Zeng

et al. 2016

Sci. China Life Sci.

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Transcripts are expressed spatially and temporally and they are very complicated, precise and specific; however, most studies are focused on protein-coding related genes. Recently, massively parallel cDNA sequencing (RNA-seq) has emerged to be a new and promising tool for transcriptome research, and numbers of non-coding RNAs, especially lincRNAs, have been widely identified and well characterized as important regulators of diverse biological processes. In this study, we used ultra-deep RNA-seq data from 15 mouse tissues to study the diversity and dynamic of non-coding RNAs in mouse. Using our own criteria, we identified totally 16,249 non-coding genes (21,569 non-coding RNAs) in mouse. We annotated these non-coding RNAs by diverse properties and found non-coding RNAs are generally shorter, have fewer exons, express in lower level and are more strikingly tissue-specific compared with protein-coding genes. Moreover, these non-coding RNAs show significant enrichment with transcriptional initiation and elongation signals including histone modifications (H3K4me3, H3K27me3 and H3K36me3), RNAPII binding sites and CAGE tags. The gene set enrichment analysis (GSEA) result revealed several sets of lincRNAs associated with diverse biological processes such as immune effector process, muscle development and sexual reproduction. Taken together, this study provides a more comprehensive annotation of mouse non-coding RNAs and gives an opportunity for future functional and evolutionary study of mouse non-coding RNAs.non-coding RNA, RNA-seq, transcriptome, lincRNA, mouse Citation:

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Long non-coding RNA identification over mouse brain development by integrative modeling of chromatin and genomic features

Cited by 65 publications

References 84 publications

Long Non-coding RNAs: key players in brain and central nervous system development

Long Non-coding RNAs: key players in brain and central nervous system development

Databases for lncRNAs: a comparative evaluation of emerging tools

Identification and analysis of mouse non-coding RNA using transcriptome data

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