Widespread occurrence of 5-methylcytosine in human coding and non-coding RNA

Squires, Jeffrey E.; Patel, Hardip R.; Nousch, Marco; Sibbritt, Tennille; Humphreys, David T.; Parker, Brian J.; Suter, Catherine M.; Preiß, Thomas

doi:10.1093/nar/gks144

Cited by 801 publications

(968 citation statements)

References 57 publications

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“…In coding mRNAs, we found that the identified modifications included previously characterized adenosine methylation (m 1 A) and Y sites (Squires et al, 2012;Carlile et al, 2014;Schwartz et al, 2014b), as well as novel cytosine (m 3 C) and guanosine methylation (m 1 G), dihydrouridylation (D), N 6 -isopentenyladenosylation (i 6 A), and threonylcarbamoyladenosylation (t 6 A) ( Figure 4B; Supplemental Figure 6). As in noncoding RNAs, the distribution of these modification types is distinct between stable RNA, smRNA, and uncapped, degrading transcripts.…”

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confidence: 87%

“…While modifications are best characterized in noncoding tRNAs and rRNAs, mRNAs have also been found to contain N 6 -methyladenosine (m 6 A) (Horowitz et al, 1984;Dominissini et al, 2012;Meyer et al, 2012), 5-methylcytosine (m 5 C) (Squires et al, 2012), inosine (I) (Li et al, 2009;Wulff et al, 2011), and pseudouridine (Y) (Carlile et al, 2014;Schwartz et al, 2014b). Additionally, there is a growing body of evidence to support the functional significance of RNA modifications within mRNAs.…”

Section: Introductionmentioning

confidence: 99%

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Chemical Modifications Mark Alternatively Spliced and Uncapped Messenger RNAs in Arabidopsis

et al. 2015

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Posttranscriptional chemical modification of RNA bases is a widespread and physiologically relevant regulator of RNA maturation, stability, and function. While modifications are best characterized in short, noncoding RNAs such as tRNAs, growing evidence indicates that mRNAs and long noncoding RNAs (lncRNAs) are likewise modified. Here, we apply our highthroughput annotation of modified ribonucleotides (HAMR) pipeline to identify and classify modifications that affect WatsonCrick base pairing at three different levels of the Arabidopsis thaliana transcriptome (polyadenylated, small, and degrading RNAs). We find this type of modifications primarily within uncapped, degrading mRNAs and lncRNAs, suggesting they are the cause or consequence of RNA turnover. Additionally, modifications within stable mRNAs tend to occur in alternatively spliced introns, suggesting they regulate splicing. Furthermore, these modifications target mRNAs with coherent functions, including stress responses. Thus, our comprehensive analysis across multiple RNA classes yields insights into the functions of covalent RNA modifications in plant transcriptomes.

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confidence: 87%

Section: Introductionmentioning

confidence: 99%

Chemical Modifications Mark Alternatively Spliced and Uncapped Messenger RNAs in Arabidopsis

et al. 2015

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“…3 Mapping of m 5 C in RNA was initially attempted by adapting the bisulfite sequencing technology used for m 5 C in DNA, leading to the identification of approximately 10,000 m 5 C sites in mRNA. 26,27 Subsequently, new methods were developed that leverage m 5 C methyltransferases to enrich m 5 C-containing RNA, either by incorporating 5-azacytidine into RNA, 28 or by mutating the methyltransferase 29 to enable modified RNA capture. These methods identified far fewer m 5 C sites in mRNA, on the order of a few hundred to one thousand, respectively.…”

Section: Mrnamentioning

confidence: 99%

“…While its biological function remains unclear, some of the machinery that regulates m 5 C in different RNA classes has been identified: Trm4p (in yeast), 31 and DNMT2 and NSUN2 (in human) have been identified as m 5 C methyltransferases. 27,32 While the roles and specificities of these enzymes is controversial, their functional characterization will likely aid in uncovering the roles of m 5 C in the future. [33][34][35] For instance, a recent study suggested functional roles for m 5 C oxidation to 5-hydroxymethylcytidine in D. melanogaster mRNA.…”

Section: Mrnamentioning

confidence: 99%

Publisher's Note

2017

RNA Biology

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RNA modifications have long been known to be central in the proper function of tRNA and rRNA. While chemical modifications in mRNA were discovered decades ago, their function has remained largely mysterious until recently. Using enrichment strategies coupled to next generation sequencing, multiple modifications have now been mapped on a transcriptome-wide scale in a variety of contexts. We now know that RNA modifications influence cell biology by many different mechanisms -by influencing RNA structure, by tuning interactions within the ribosome, and by recruiting specific binding proteins that intersect with other signaling pathways. They are also dynamic, changing in distribution or level in response to stresses such as heat shock and nutrient deprivation. Here, we provide an overview of recent themes that have emerged from the substantial progress that has been made in our understanding of chemical modifications across many major RNA classes in eukaryotes.

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“…Please do not adjust margins Please do not adjust margins 176 and RNA. 177 It is an important regulator of gene expression in eukaryotes and a guardian against methylation-sensitive endonucleases in prokaryotes.…”

Section: Bisulfite Sequencing For M 5 Cmentioning

confidence: 99%

Properties and reactivity of nucleic acids relevant to epigenomics, transcriptomics, and therapeutics

2016

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Developments in epigenomics, toxicology, and therapeutic nucleic acids all rely on a precise understanding of nucleic acid properties and chemical reactivity. In this review we discuss the properties and chemical reactivity of each nucleobase and attempt to provide some general principles for nucleic acid targeting or engineering. For adenine-thymine and guaninecytosine base pairs, we review recent quantum chemical estimates of their Watson-Crick interaction energy, - stacking energies, as well as the nuclear quantum effects on tautomerism. Reactions that target nucleobases have been crucial in the development of new sequencing technologies and we believe further developments in nucleic acid chemistry will be required to deconstruct the enormously complex transcriptome.

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Widespread occurrence of 5-methylcytosine in human coding and non-coding RNA

Cited by 801 publications

References 57 publications

Chemical Modifications Mark Alternatively Spliced and Uncapped Messenger RNAs in Arabidopsis

Chemical Modifications Mark Alternatively Spliced and Uncapped Messenger RNAs in Arabidopsis

Publisher's Note

Properties and reactivity of nucleic acids relevant to epigenomics, transcriptomics, and therapeutics

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