An Evolutionarily Conserved Long Noncoding RNA TUNA Controls Pluripotency and Neural Lineage Commitment

Lin, Nianwei; Chang, Kung-Yen; Li, Zhonghan; Gates, Keith P.; Rana, Zacharia A.; Dang, Jason; Zhang, Danhua; Han, Tianxu; Yang, Chyun-Yu; Cunningham, Thomas J.; Head, Steven R.; Duester, Gregg; Dong, Peng; Rana, Tariq M.

doi:10.1016/j.molcel.2014.01.021

Cited by 351 publications

(334 citation statements)

References 36 publications

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“…13 Although the vast majority of lncRNAs, operationally defined as being more than 200 nucleotides in length and lacking in putative coding regions, 13 have not yet been ascribed a function, they are increasingly implicated in the regulation of numerous cellular processes such as X-chromosome inactivation, 14 regulation of p53 pathway, 15 stem cell self-renewal and differentiation, 16,17 epidermal differentiation, 18 erythroid development, 19 DNA damage response, 20 chromosome architecture, 21 and maintenance of active chromatin state. 22 The low abundance and lack of sequence conservation of lncRNAs initially suggested they were of little biological significance.…”

Section: The Functions Of Lncrnasmentioning

confidence: 99%

“…Indeed, many lncRNAs discovered to date show preferences for specific loci. 15,17,28,30 It is likely that new methodology, such as RNase-protected RNA sequencing, will be needed to fully understand the structure-function relationship and molecular mechanisms underlying lncRNA-mediated regulation of gene expression.…”

Section: Concluding Remarks and Future Perspectivesmentioning

confidence: 99%

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Decoding the noncoding: Prospective of lncRNA-mediated innate immune regulation

Li¹,

Rana

2014

RNA Biology

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Section: The Functions Of Lncrnasmentioning

confidence: 99%

Section: Concluding Remarks and Future Perspectivesmentioning

confidence: 99%

Decoding the noncoding: Prospective of lncRNA-mediated innate immune regulation

Li¹,

Rana

2014

RNA Biology

Self Cite

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“…TUNA performs a regulatory function in pluripotency and neural differentiation of ESCs, acting as a scaffold for RNA‐binding proteins. TUNA also regulates the expression of several key neurogenic genes, including SOX2, and its depletion causes down‐regulation of SOX2 and subsequent loss of neurogenesis 43. Therefore, TUNA represents another example of an lncRNA involved in both neurogenesis and brain tumour progression.…”

Section: Dysregulated Lncrna Expression In Glioma Pathologymentioning

confidence: 99%

“…However, two dysregulated lncRNAs in glioma, linc‐RoR and TUNA, have been reported to promote reprogramming efficiency. Linc‐ROR acts as a sponge for miRNAs that target pluripotency regulators, and TUNA directly interacts with RNA‐binding proteins at the promoters of TFs, such as NANOG and SOX2, where transcription is activated by deposition of the active histone mark H3K4me3 43. Interestingly, the glioma tumour suppressor lincRNA‐p21 prevents somatic cell reprogramming by sustaining H3K9me3 and/or CpG methylation at pluripotency gene promoters or by direct association with SETDB1, a histone‐lysine N‐methyltransferase protein or DNMT1 80…”

Section: Epigenetic Alterations Induced By Lncrnasmentioning

confidence: 99%

Long non‐coding RNAs in brain tumours: Focus on recent epigenetic findings in glioma

Pop

Enciu

Necula

et al. 2018

J Cellular Molecular Medi

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Glioma biology is a major focus in tumour research, primarily due to the aggressiveness and high mortality rate of its most aggressive form, glioblastoma. Progress in understanding the molecular mechanisms behind poor prognosis of glioblastoma, regardless of treatment approaches, has changed the classification of brain tumours after nearly 100 years of relying on anatomopathological criteria. Expanding knowledge in genetic, epigenetic and translational medicine is also beginning to contribute to further elucidating molecular dysregulation in glioma. Long non‐coding RNAs (lncRNAs) and their main representatives, large intergenic non‐coding RNAs (lincRNAs), have recently been under scrutiny in glioma research, revealing novel mechanisms of pathogenesis and reinforcing others. Among those confirmed was the reactivation of events significant for foetal brain development and neuronal commitment. Novel mechanisms of tumour suppression and activation of stem‐like behaviour in tumour cells have also been examined. Interestingly, these processes involve lncRNAs that are present both during normal brain development and in brain malignancies and their reactivation might be explained by epigenetic mechanisms, which we discuss in detail in the present review. In addition, the review discusses the lncRNAs‐induced changes, as well as epigenetic changes that are consequential for tumour formation, affecting, in turn, the expression of various types of lncRNAs.

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“…These indicate that lncRNAs might be involved in the energy balance regulation. In the brain, several papers have detailed the importance of lncRNA in neuronal differentiation and brain development (Aprea et al 2013;Lin et al 2014), but adult expression patterns under stress-type conditions such as fasting have not been reported.…”

Section: Introductionmentioning

confidence: 99%

Characterization of the hypothalamic transcriptome in response to food deprivation reveals global changes in long noncoding RNA, and cell cycle response genes

et al. 2015

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The hypothalamus integrates energy balance information from the periphery using different neuronal subtypes within each of the hypothalamic areas. However, the effects of prandial state on global mRNA, microRNA and long noncoding (lnc) RNA expression within the whole hypothalamus are largely unknown. In this study, mice were given either a 24-h fast, or ad libitum access to food. RNA samples were analyzed by microarray, and then a subset was confirmed using quantitative real-time PCR (QPCR). A total of 540 mRNAs were either up-or downregulated with food deprivation. Since gene ontology enrichment analyses identified several categories of mRNAs related to cell cycle processes, ten cell-cycle-related genes were further analyzed using QPCR with six confirmed to be significantly up-regulated and one downregulated in response to 24-h fasting. While 22 independent microRNAs were differentially expressed by microarray, secondary analysis by QPCR failed to confirm significant changes with fasting. There were 622 lncRNAs identified as differentially expressed, and of three tested by QPCR, two were confirmed. Overall, this is the first time that expression of hypothalamic lncRNAs has been shown to be responsive to food deprivation. In addition, this study is the first to identify a list of lncRNAs with high expression in RNA extracted from hypothalamus. Individual contributions from specific miRNA, lncRNA and mRNAs to the food deprivation response can now be further studied at the physiological and biochemical levels.

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An Evolutionarily Conserved Long Noncoding RNA TUNA Controls Pluripotency and Neural Lineage Commitment

Cited by 351 publications

References 36 publications

Decoding the noncoding: Prospective of lncRNA-mediated innate immune regulation

Decoding the noncoding: Prospective of lncRNA-mediated innate immune regulation

Long non‐coding RNAs in brain tumours: Focus on recent epigenetic findings in glioma

Characterization of the hypothalamic transcriptome in response to food deprivation reveals global changes in long noncoding RNA, and cell cycle response genes

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