Ribose-seq: global mapping of ribonucleotides embedded in genomic DNA

Koh, Kyung Duk; Balachander, Sathya; Hesselberth, Jay R.; Storici, Francesca

doi:10.1038/nmeth.3259

Cited by 109 publications

(133 citation statements)

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“…It has been studied how the additional presence of a reactive 2′-hydroxyl group on the sugar ring may: i) alter the DNA physical properties, reducing its elasticity [102,103] and structure in a sequence dependent manner [104][105][106][107][108]; ii) induce DNA replication or transcription arrest making the DNA backbone prone to hydrolysis triggering a persistent genomic instability [103,108,109]. This incorporation occurs quite frequently into the cell [110,111], potentially during every DNA replication reaction [110]. It has been estimated that a few thousands of rNMPs are embedded in budding yeast genome [110] and over a million in mouse genome [112].…”

Section: New Insights About Ber Involvement Into Removal Of Modified mentioning

confidence: 99%

“…Moreover, oxidation can occur not only in DNA but also in the nucleotides pool and then rNMP may be incorporated into neo-replicated DNA. During last years, several approaches have been developed [119], including Ribose-seq, in order to map rNMPs sites into genomic DNA [111]. By using these methods, it has been discovered that the incorporation of rNMPs has a widespread but not random distribution in chromosomal DNA of budding and fission yeast [111] and their number, per nuclear chromosome, seems to be proportional to the chromosome size [111].…”

Section: New Insights About Ber Involvement Into Removal Of Modified mentioning

confidence: 99%

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Unveiling the non-repair face of the Base Excision Repair pathway in RNA processing: A missing link between DNA repair and gene expression?

2017

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Section: New Insights About Ber Involvement Into Removal Of Modified mentioning

confidence: 99%

Section: New Insights About Ber Involvement Into Removal Of Modified mentioning

confidence: 99%

Unveiling the non-repair face of the Base Excision Repair pathway in RNA processing: A missing link between DNA repair and gene expression?

2017

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“…Despite the efficiency with which replicative DNA polymerases discriminate between rNTP and dNTP precursors, there are 15,000 rNMPs inserted into yeast DNA during each round of replication, which translates into 1 rNMP per 1000 nucleotides (Nick McElhinny et al 2010b). rNMPs in budding yeast genomic DNA have recently been mapped to single-nucleotide resolution by several groups (Clausen et al 2015;Koh et al 2015;Reijns et al 2015). In contrast to R-loops, which are removed by RNase H1 (encoded by RNH1) or RNase H2 (catalytic subunit encoded by RNH201), only RNase H2 is capable of removing of single rNMPs embedded in DNA (Cerritelli and Crouch 2009).…”

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confidence: 99%

Elevated Genome-Wide Instability in Yeast Mutants Lacking RNase H Activity

O’Connell¹,

Jinks-Robertson

Petes

2015

Genetics

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Two types of RNA:DNA associations can lead to genome instability: the formation of R-loops during transcription and the incorporation of ribonucleotide monophosphates (rNMPs) into DNA during replication. Both ribonuclease (RNase) H1 and RNase H2 degrade the RNA component of R-loops, whereas only RNase H2 can remove one or a few rNMPs from DNA. We performed highresolution mapping of mitotic recombination events throughout the yeast genome in diploid strains of Saccharomyces cerevisiae lacking RNase H1 (rnh1D), RNase H2 (rnh201D), or both RNase H1 and RNase H2 (rnh1D rnh201D). We found little effect on recombination in the rnh1D strain, but elevated recombination in both the rnh201D and the double-mutant strains; levels of recombination in the double mutant were 50% higher than in the rnh201 single-mutant strain. An rnh201D mutant that additionally contained a mutation that reduces rNMP incorporation by DNA polymerase e (pol2-M644L) had a level of instability similar to that observed in the presence of wild-type Pol e. This result suggests that the elevated recombination observed in the absence of only RNase H2 is primarily a consequence of R-loops rather than misincorporated rNMPs.KEYWORDS RNase H1; RNase H2; loss of heterozygosity; mitotic recombination; microarrays R NA transcripts can stably associate with the DNA template during transcription, giving rise to R-loop structures containing an RNA:DNA hybrid and an unpaired DNA strand. Such R-loops can stall DNA replication forks and are a major source of recombination events that are stimulated by high levels of transcription (reviewed by Aguilera and Garcia-Muse 2012). Transcription-associated recombination (TAR) is generally strongest when the transcription machinery and a replication fork approach each other head on (Prado and Aguilera 2005), but there is also an orientation-independent component to such conflicts ). Importantly, TAR is highly elevated when RNA processing is perturbed and R-loops accumulate, or when R-loop removal mechanisms are disabled. The RNA component of R-loops can be removed by the Sen1 RNA-DNA helicase (Mischo et al. 2011) or degraded by ribonuclease (RNase) H1 or RNase H2 (reviewed in Cerritelli and Crouch 2009), which are generally considered to be functionally redundant.R-loops in yeast have been quantified genome-wide using immunoprecipitation with an antibody specific to DNA:RNA hybrids, followed by hybridization to a microarray or by DNA sequencing. This type of analysis has been done in wild type (Chan et al. 2014;El Hage et al. 2014), mRNA processing defective (Chan et al. 2014), RNase H-defective (Chan et al. 2014;El Hage et al. 2014), and RNA-DNA helicase (Sen1)-defective strains (Chan et al. 2014). In wild-type strains, Chan et al. (2014) observed RNA-DNA hybrid accumulation at Ty retrotransposons, near telomeres, within the ribosomal RNA (rRNA) gene cluster, and at highly transcribed GC-rich genes. El Hage et al. (2014) found hybrid accumulation in wild-type strains at highly transcribed genes, within the rRNA gen...

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“…Not only do polymerases incorporate rNMPs into the genome, but also there are other sources of rNMPs in DNA [13][14][15]. More recently, we developed an approach, ribose-seq, to profile these rNMPs in yeast genomic DNA [16]. These misincorporated rNMPs may have a significant effect on genome instability, resulting from DNA-protein and DNA-DNA interactions, which are crucial for many cellular processes.…”

Section: Introductionmentioning

confidence: 99%

Measuring the Elasticity of Ribonucleotide(s)-Containing DNA Molecules Using AFM

Koh

Chiu

Storici

2015

Methods in Molecular Biology

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Ribonucleotides, ribonucleoside monophosphates (rNMPs), have been revealed as possibly the most noncanonical nucleotides in genomic DNA. rNMPs, either not removed from Okazaki fragments during DNA replication or incorporated and scattered throughout the genome, pose a perturbation to the structure and a threat to the stability of DNA. The instability of DNA is mainly due to the extra 2′-hydroxyl (OH) group of rNMPs which give rise to local structural effects, which may disturb various molecular interactions in cells. As a result of these structural perturbations by rNMPs, the elastic properties of DNA are also affected. Here, we show the approach to test whether the presence of rNMPs in DNA duplexes could alter the elasticity of DNA by implementing atomic force microscopy (AFM)-based single molecule force-measurements of short rNMP(s)-containing oligonucleotides (oligos).

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Ribose-seq: global mapping of ribonucleotides embedded in genomic DNA

Cited by 109 publications

References 54 publications

Unveiling the non-repair face of the Base Excision Repair pathway in RNA processing: A missing link between DNA repair and gene expression?

Unveiling the non-repair face of the Base Excision Repair pathway in RNA processing: A missing link between DNA repair and gene expression?

Elevated Genome-Wide Instability in Yeast Mutants Lacking RNase H Activity

Measuring the Elasticity of Ribonucleotide(s)-Containing DNA Molecules Using AFM

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