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. Author manuscript; available in PMC: 2022 Nov 1.
Published in final edited form as: Biochim Biophys Acta Gene Regul Mech. 2021 Aug 28;1864(11-12):194750. doi: 10.1016/j.bbagrm.2021.194750

Table 1.

Techniques for profiling genome-wide R-loop distribution.

Technique Innovation Experimental workflow Strengths Weaknesses Ref.
DRIP-seq and its derivatives DRIP-seq Using the intrinsic specificity of the S9.6 antibody for RNA-DNA hybrid 1. DNA extraction
2. Restriction enzyme
digestion
3. Immunoprecipitation with S9.6 antibody
4. ds DNA sequencing
Convenient, robust signal Low resolution, higher background, not strand specific, S9.6 antibody’s bias in sequence recognition [100] [50, 89]
RDIP-seq Pre-treatment with RNase I, use of sonication, directional sequencing 1. Whole cell nucleic acid sonication
2. RNase I pre-treatment
3. Immunoprecipitation with S9.6 antibody
4. RNA sequencing
Reduced background, Strand-specific A sonication step for nucleic acid fragmentation, which has been shown to reduce the number of genomic R-loops, off target affinity of the S9.6 antibody for dsRNA [90]
S1-DRIP-seq Using optimized levels of S1 nuclease to
preserve RNA-DNA hybrid during sonication
1. DNA extraction
2. S1 nuclease digestion
3. Sonication
4. Immunoprecipitation with S9.6 antibody
5. dsDNA sequencing
Quantitative recovery of R loops, High-resolution Not strand specific, S9.6 antibody’s bias in sequence recognition [91]
DRIPc-seq Further digestion by DNase I, cDNA conversion 1. DNA extraction
2. Restriction enzyme digestion
3. Immunoprecipitation with S9.6 antibody
4. DNase I treatment
5. RNA recovery and reverse transcription to cDNA
6. RNA sequencing
High resolution, strand specific Off target affinity of the S9.6 antibody for dsRNA [18, 89]
ssDRIP-seq Distinguish specific DNA strands with fewer steps for library construction than DRIPc-seq 1. DNA extraction
2. Sonication
3. Immunoprecipitation with S9.6 antibody
4. ssDNA sequencing
Strand specific S9.6 antibody’s bias in sequence recognition [92]
bisDRIP-seq In vivo R-loop profiling, combining the use of the S9.6 antibody with sodium bisulfite treatment 1. Cell lysis in the presence of bisulfite
2. DNA extraction
3. Restriction enzyme digestion
4. Immunoprecipitation with S9.6 antibody
5. Bisulfite-modified dsDNA sequencing
Discriminate between the R-loop sequence and the surrounding non-R-loop sequence, high resolution, Strand specific High sequencing depth is needed, background conversions in ds DNA by bisulfite, S9.6 antibody’s bias in sequence recognition [93]
qDRIP-seq Combining synthetic RNA-DNA hybrid internal standards (spike-in) 1. Adding spike-in to cell lysate
2. Sonication
3. Immunoprecipitation with S9.6 antibody
4. ssDNA sequencing
Accurate cross-condition normalization, absolute quantitation, sensitive, high resolution, strand-specific S9.6 antibody’s bias in sequence recognition [56]
Other S9.6 based approaches DRIP-chip DRIP followed by hybridization on tiling microarray 1. Crosslinking with formaldehyde
2. Sonication
3. Immunoprecipitation with S9.6 antibody
4. T7 RNA polymerase amplification
5. Biotin labeling
6. Microarray
S9.6 antibody’s bias in sequence recognition [94]
S9.6 ChIP-seq (chromatin immunoprecipitation with antibody S9.6, followed by deep sequencing of immunopurified DNA fragments) Application of ChIP-seq to mapping R loops 1. Crosslinking with formaldehyde
2. Sonication
3. Immunoprecipitation with S9.6 antibody
4. Reverse crosslinking
5. dsDNA sequencing
High-resolution Formaldehyde crosslinking could affect results, not strand specific [95]
RNase H based approaches DRIVE-seq (DNA:RNA in vitro Enrichment) Using specificity of catalytically dead RNase H1
for RNA-DNA hybrid
1. Genomic DNA extraction
2. Restriction enzyme digestion
3. Catalytically dead RNase H1 incubation
4. Pull-down
5. dsDNA sequencing
Enable the specific and near quantitative recovery of R loop molecules in complexnucleic acid mixture exquisite specificity of RNase H Low capture efficiency, not strand specific, substantial RNase H-resistant regions on the genome [50]
R-ChIP In vivo R-loop profiling using catalytically dead RNase H1 1. Introduce V5-tagged catalytically dead mutant RNase H1 into cells
2. Sonication
3. Immunoprecipitation with anti-V5 antibody
4. ssDNA sequencing
exquisite specificity of RNase H, strand-specific substantial RNase H- resistant regions on the genome, require the generation of stable cell lines (time-consuming) [34, 96]
MapR Combining the specificity of RNase H for RNA-DNA hybrid with CUT&RUN approach 1. Immobilize cells on beads
2. Incubate with GST-RNaseHΔcat-MNase
3. R-loop recognition by RNaseHΔcat
4. MNase mediated R-loop cleavage
5. DNA sequencing
Antibody-independent, does not require the generation of stable cell lines (fast and convenient), high sensitivity with low input material substantial RNase H-resistant regions on the genome [97, 98]
R-loop imaging Imaging and quantifying R-loops using GFP-catalytically dead RNase H1 (dRNH1) 1. Expression and purification of GFP-dRNH
2. Transfection in fixed cells
3. Imaging
Using purified GFP-dRNH1 protein, bypassing the need for cell line engineering GFP-dRNH1 has its own limitations (non-specific binding, binding preference to G-rich) [99]