Functional interactions among microRNAs and long noncoding RNAs

•LncRNA stability and function can be potently regulated by miRNAs.•LncRNAs can function as miRNA decoys, derepressing miRNA target mRNAs.•LncRNAs can compete with miRNAs for degradation of target mRNAs.•LncRNAs can give rise to miRNA. In mammals, the vast majority of transcripts expressed are nonco...

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Vydané v:	Seminars in cell & developmental biology Ročník 34; s. 9 - 14
Hlavní autori:	Yoon, Je-Hyun, Abdelmohsen, Kotb, Gorospe, Myriam
Médium:	Journal Article
Jazyk:	English
Vydavateľské údaje:	England Elsevier Ltd 01.10.2014
Predmet:	Animals Humans MicroRNAs - physiology mRNA stability Post-transcriptional gene regulation Ribonucleoprotein complex RNA Interference RNA, Long Noncoding - physiology RNA-binding protein Translation ceRNA RBP UTR Ribonucleoprotein complex RNA-binding protein Translation lncRNA Post-transcriptional gene regulation lincRNA miRNA mRNA stability
ISSN:	1084-9521, 1096-3634, 1096-3634
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Abstract	•LncRNA stability and function can be potently regulated by miRNAs.•LncRNAs can function as miRNA decoys, derepressing miRNA target mRNAs.•LncRNAs can compete with miRNAs for degradation of target mRNAs.•LncRNAs can give rise to miRNA. In mammals, the vast majority of transcripts expressed are noncoding RNAs, ranging from short RNAs (including microRNAs) to long RNAs spanning up to hundreds of kb. While the actions of microRNAs as destabilizers and repressors of the translation of protein-coding transcripts (mRNAs) have been studied in detail, the influence of microRNAs on long noncoding RNA (lncRNA) function is only now coming into view. Conversely, the influence of lncRNAs upon microRNA function is also rapidly emerging. In some cases, lncRNA stability is reduced through the interaction of specific miRNAs. In other cases, lncRNAs can act as microRNA decoys, with the sequestration of microRNAs favoring expression of repressed target mRNAs. Other lncRNAs derepress gene expression by competing with miRNAs for interaction with shared target mRNAs. Finally, some lncRNAs can produce miRNAs, leading to repression of target mRNAs. These microRNA–lncRNA regulatory paradigms modulate gene expression patterns that drive major cellular processes (such as cell differentiation, proliferation, and cell death) which are central to mammalian physiologic and pathologic processes. We review and summarize the types of microRNA–lncRNA crosstalk identified to-date and discuss their influence on gene expression programs.
AbstractList	In mammals, the vast majority of transcripts expressed are noncoding RNAs, ranging from short RNAs (including microRNAs) to long RNAs spanning up to hundreds of kb. While the actions of microRNAs as destabilizers and repressors of the translation of protein-coding transcripts (mRNAs) have been studied in detail, the influence of microRNAs on long noncoding RNA (lncRNA) function is only now coming into view. Conversely, the influence of lncRNAs upon microRNA function is also rapidly emerging. In some cases, lncRNA stability is reduced through the interaction of specific miRNAs. In other cases, lncRNAs can act as microRNA decoys, with the sequestration of microRNAs favoring expression of repressed target mRNAs. Other lncRNAs derepress gene expression by competing with miRNAs for interaction with shared target mRNAs. Finally, some lncRNAs can produce miRNAs, leading to repression of target mRNAs. These microRNA-lncRNA regulatory paradigms modulate gene expression patterns that drive major cellular processes (such as cell differentiation, proliferation, and cell death) which are central to mammalian physiologic and pathologic processes. We review and summarize the types of microRNA-lncRNA crosstalk identified to-date and discuss their influence on gene expression programs.In mammals, the vast majority of transcripts expressed are noncoding RNAs, ranging from short RNAs (including microRNAs) to long RNAs spanning up to hundreds of kb. While the actions of microRNAs as destabilizers and repressors of the translation of protein-coding transcripts (mRNAs) have been studied in detail, the influence of microRNAs on long noncoding RNA (lncRNA) function is only now coming into view. Conversely, the influence of lncRNAs upon microRNA function is also rapidly emerging. In some cases, lncRNA stability is reduced through the interaction of specific miRNAs. In other cases, lncRNAs can act as microRNA decoys, with the sequestration of microRNAs favoring expression of repressed target mRNAs. Other lncRNAs derepress gene expression by competing with miRNAs for interaction with shared target mRNAs. Finally, some lncRNAs can produce miRNAs, leading to repression of target mRNAs. These microRNA-lncRNA regulatory paradigms modulate gene expression patterns that drive major cellular processes (such as cell differentiation, proliferation, and cell death) which are central to mammalian physiologic and pathologic processes. We review and summarize the types of microRNA-lncRNA crosstalk identified to-date and discuss their influence on gene expression programs. In mammals, the vast majority of transcripts expressed are noncoding RNAs, ranging from short RNAs (including microRNAs) to long RNAs spanning up to hundreds of kb. While the actions of microRNAs as destabilizers and repressors of the translation of protein-coding transcripts (mRNAs) have been studied in detail, the influence of microRNAs on long noncoding RNA (lncRNA) function is only now coming into view. Conversely, the influence of lncRNAs upon microRNA function is also rapidly emerging. In some cases, lncRNA stability is reduced through the interaction of specific miRNAs. In other cases, lncRNAs can act as microRNA decoys, with the sequestration of microRNAs favoring expression of repressed target mRNAs. Other lncRNAs derepress gene expression by competing with miRNAs for interaction with shared target mRNAs. Finally, some lncRNAs can produce miRNAs, leading to repression of target mRNAs. These microRNA-lncRNA regulatory paradigms modulate gene expression patterns that drive major cellular processes (such as cell differentiation, proliferation, and cell death) which are central to mammalian physiologic and pathologic processes. We review and summarize the types of microRNA-lncRNA crosstalk identified to-date and discuss their influence on gene expression programs. •LncRNA stability and function can be potently regulated by miRNAs.•LncRNAs can function as miRNA decoys, derepressing miRNA target mRNAs.•LncRNAs can compete with miRNAs for degradation of target mRNAs.•LncRNAs can give rise to miRNA. In mammals, the vast majority of transcripts expressed are noncoding RNAs, ranging from short RNAs (including microRNAs) to long RNAs spanning up to hundreds of kb. While the actions of microRNAs as destabilizers and repressors of the translation of protein-coding transcripts (mRNAs) have been studied in detail, the influence of microRNAs on long noncoding RNA (lncRNA) function is only now coming into view. Conversely, the influence of lncRNAs upon microRNA function is also rapidly emerging. In some cases, lncRNA stability is reduced through the interaction of specific miRNAs. In other cases, lncRNAs can act as microRNA decoys, with the sequestration of microRNAs favoring expression of repressed target mRNAs. Other lncRNAs derepress gene expression by competing with miRNAs for interaction with shared target mRNAs. Finally, some lncRNAs can produce miRNAs, leading to repression of target mRNAs. These microRNA–lncRNA regulatory paradigms modulate gene expression patterns that drive major cellular processes (such as cell differentiation, proliferation, and cell death) which are central to mammalian physiologic and pathologic processes. We review and summarize the types of microRNA–lncRNA crosstalk identified to-date and discuss their influence on gene expression programs.
Author	Gorospe, Myriam Abdelmohsen, Kotb Yoon, Je-Hyun
Author_xml	– sequence: 1 givenname: Je-Hyun surname: Yoon fullname: Yoon, Je-Hyun email: yoonjehyun@gmail.com – sequence: 2 givenname: Kotb surname: Abdelmohsen fullname: Abdelmohsen, Kotb – sequence: 3 givenname: Myriam surname: Gorospe fullname: Gorospe, Myriam email: myriamgorospe@nih.gov
BackLink	https://www.ncbi.nlm.nih.gov/pubmed/24965208$$D View this record in MEDLINE/PubMed
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Snippet	•LncRNA stability and function can be potently regulated by miRNAs.•LncRNAs can function as miRNA decoys, derepressing miRNA target mRNAs.•LncRNAs can compete... In mammals, the vast majority of transcripts expressed are noncoding RNAs, ranging from short RNAs (including microRNAs) to long RNAs spanning up to hundreds...
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SubjectTerms	Animals Humans MicroRNAs - physiology mRNA stability Post-transcriptional gene regulation Ribonucleoprotein complex RNA Interference RNA, Long Noncoding - physiology RNA-binding protein Translation
Title	Functional interactions among microRNAs and long noncoding RNAs
URI	https://dx.doi.org/10.1016/j.semcdb.2014.05.015 https://www.ncbi.nlm.nih.gov/pubmed/24965208 https://www.proquest.com/docview/1618141494 https://pubmed.ncbi.nlm.nih.gov/PMC4163095
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