RNA Structures as Mediators of Neurological Diseases and as Drug Targets

Bernat, Viachaslau; Disney, Matthew D.

doi:10.1016/j.neuron.2015.06.012

Cited by 114 publications

(113 citation statements)

References 312 publications

(421 reference statements)

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“…As these modifications are covalent changes, they are stable; thus, in vitro studies can accurately report on their location. m 6 A, which does not modify the WC face, was initially identified using antibody-based techniques (23) to pull down regions of RNA with modifications, whereas ψ was identified by a chemical reaction with CMC (N-cyclohexyl-N9-(2-morpholinoethyl)-carbodiimide metho-p-toluenesulfonate), which modifies the ψ and provides reverse-transcription stops (14,93). m 1 A has been identified in toto in mRNA by liquid chromatography-tandem mass spectrometry, whereas antibody-based pulldowns coupled with next-generation sequencing have been used to map m 1 A-containing sequences genome-wide (24,59).…”

Section: Methods To Identify Natural Rna Modifications Genome-widementioning

confidence: 99%

Section: Meta-properties Relating Rna Structure and Mrna Processingmentioning

confidence: 99%

“…Parallel transcriptome-wide analysis of m 6 A covalent modifications by m 6 A immunoprecipitation with anti-m 6 A antibody and of hnRNPC binding sites by PAR-CLIP revealed overrepresentation of m 6 A sites in RNA regions associated with hnRNPC-binding targets (63). On the basis of biochemical studies with specific hnRNPC targets, the authors (63) proposed that m 6 A in the complementary strands of U-rich hairpins promotes hnRNPC binding by weakening the hairpin secondary structure. Support for m 6 A regulation of RNA structure and hnRNPC binding as a genome-wide mechanism was provided by the observation that knockdown of two m 6 A methyltransferases reduced hnRNPC binding at more than 2,500 sites and also affected alternative splicing, promoting intron exclusion as deduced from the reduced presence of intron-exon junctions in RNA-Seq data (63).…”

Section: Meta-properties Relating Rna Structure and Mrna Processingmentioning

confidence: 99%

“…In recent years, modifications of mRNAs, resulting in the so-called epitranscriptome, have become increasingly recognized as important regulatory events. In particular, ψ and m 6 A modifications have apparent implications for RNA structural stability and half-life. With regard to structural stability, ψ can base pair noncanonically with all four nucleotides.…”

Section: Stability and Degradationmentioning

confidence: 99%

“…Whereas ψ is relatively rare in mRNAs, reported at only several hundred mRNA sites in studies on yeast and human cells (14,93), m 6 A is a common covalent modification of mRNAs, with many thousands of mRNA sites reported for mouse and human cell lines (23) as well as mouse (81) and human (23) brain tissue. m 6 A sites are conserved between mouse and human.…”

Section: Stability and Degradationmentioning

confidence: 99%

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Genome-Wide Analysis of RNA Secondary Structure

Bevilacqua¹,

Ritchey²,

et al. 2016

Annu. Rev. Genet.

203

157

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Single-stranded RNA molecules fold into extraordinarily complicated secondary and tertiary structures as a result of intramolecular base pairing. In vivo, these RNA structures are not static. Instead, they are remodeled in response to changes in the prevailing physicochemical environment of the cell and as a result of intermolecular base pairing and interactions with RNAbinding proteins. Remarkable technical advances now allow us to probe RNA secondary structure at single-nucleotide resolution and genome-wide, both in vitro and in vivo. These data sets provide new glimpses into the RNA universe. Analyses of RNA structuromes in HIV, yeast, Arabidopsis, and mammalian cells and tissues have revealed regulatory effects of RNA structure on messenger RNA (mRNA) polyadenylation, splicing, translation, and turnover. Application of new methods for genome-wide identification of mRNA modifications, particularly methylation and pseudouridylation, has shown that the RNA "epitranscriptome" both influences and is influenced by RNA structure. In this review, we describe newly developed genome-wide RNA structure-probing methods and synthesize the information emerging from their application.

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Section: Methods To Identify Natural Rna Modifications Genome-widementioning

confidence: 99%

Section: Meta-properties Relating Rna Structure and Mrna Processingmentioning

confidence: 99%

Section: Meta-properties Relating Rna Structure and Mrna Processingmentioning

confidence: 99%

Section: Stability and Degradationmentioning

confidence: 99%

Section: Stability and Degradationmentioning

confidence: 99%

See 3 more Smart Citations

Genome-Wide Analysis of RNA Secondary Structure

Bevilacqua¹,

Ritchey²,

et al. 2016

Annu. Rev. Genet.

203

157

View full text Add to dashboard Cite

show abstract

Discovery of Key Physicochemical, Structural, and Spatial Properties of RNA‐Targeted Bioactive Ligands

et al. 2017

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While amyriad non-coding RNAs are knowntobe essential in cellular processes and misregulated in diseases,the development of RNA-targeted small molecule probes has met with limited success.T oe lucidate the guiding principles for selective small molecule/RNArecognition, we analyzed cheminformatic and shape-based descriptors for 104 RNA-targeted ligands with demonstrated biological activity (RNA-targeted BIoactive ligaNd Database,R -BIND). We then compared R-BIND to both FDA-approved small molecule drugs and RNA ligands without reported bioactivity.S everal striking trends emerged for bioactive RNAligands,including:1)Compliance to medicinal chemistry rules,2 )distinctive structural features, and 3) enrichment in rod-like shapes over others.T his work provides unique insights that directly facilitate the selection and synthesis of RNA-targeted libraries with the goal of efficiently identifying selective small molecule ligands for therapeutically relevant RNAs.Supportinginformation and the ORCID identification number(s) for the author(s) of this article can be found under: https://doi.

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Discovery of Key Physicochemical, Structural, and Spatial Properties of RNA‐Targeted Bioactive Ligands

et al. 2017

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While myriad non-coding RNAs are known to be essential in cellular processes and misregulated in diseases, the development of RNA-targeted small molecule probes has met with limited success. To elucidate guiding principles for selective small molecule:RNA recognition, we analyzed cheminformatic and shape-based descriptors for 104 RNA-targeted ligands with demonstrated biological activity (RNA-targeted BIoactive ligaNd Database, R-BIND). We then compared R-BIND to both FDA-approved small molecule drugs and RNA ligands without reported bioactivity. Several striking trends emerged for bioactive RNA ligands, including: i) compliance to medicinal chemistry rules; ii) distinctive structural features; and iii) enrichment in “rod-like” over other shapes. This work provides unique insights that directly facilitate the selection and synthesis of RNA-targeted libraries with the goal of efficiently identifying selective small molecule ligands for therapeutically relevant RNAs.

show abstract

RNA Structures as Mediators of Neurological Diseases and as Drug Targets

Cited by 114 publications

References 312 publications

Genome-Wide Analysis of RNA Secondary Structure

Genome-Wide Analysis of RNA Secondary Structure

Discovery of Key Physicochemical, Structural, and Spatial Properties of RNA‐Targeted Bioactive Ligands

Discovery of Key Physicochemical, Structural, and Spatial Properties of RNA‐Targeted Bioactive Ligands

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