Project description:During transcription the nascent RNA can invade the DNA template, forming extended RNA-DNA duplexes (R-loops). Here we employ ChIP-seq in strains expressing or lacking RNase H to map targets of RNase H activity throughout budding yeast genome. In wild-type strains, R-loops were readily detected over the 35S rDNA region transcribed by Pol I and over the 5S rDNA transcribed by Pol III. In strains lacking RNase H activity, R-loops were elevated over other Pol III genes notably tRNAs, SCR1 and U6 snRNA, and were also associated with the cDNAs of endogenous TY1 retrotransposons, which showed increased rates of mobility to the 5?-flanking regions of tRNA genes. Unexpectedly, R-loops were also associated with mitochondrial genes in the absence of RNase H1, but not of RNase H2. Finally, R-loops were detected on highly expressed protein-coding genes in the wild-type, notably over the second exon of spliced ribosomal protein genes. ChIP-seq of RNA-DNA hybrids using antibody S9.6

Project description:We showed that the majority of the signal observed in S9.6 immunofluorescence microscopy images of fixed human cells arises from RNA, not RNA:DNA hybrids. S9.6 staining is quantitatively unchanged by pre-treatment with the human RNA:DNA hybrid-specific nuclease, RNase H1, despite experimental verification that the enzyme was active in situ. S9.6 staining was, however, significantly sensitive to pre-treatments with RNase T1, and in some cases RNase III, two ribonucleases that specifically degrade single-stranded and double-stranded RNA, respectively. In contrast, genome-wide maps obtained by high-throughput DNA sequencing after S9.6-mediated DNA:RNA Immunoprecipitation (DRIP) are RNase H1-sensitive and RNase T1- and RNase III-insensitive. Altogether, these data demonstrate that the S9.6 antibody, though capable of recognizing RNA:DNA hybrids in situ and in vitro, suffers from a lack of specificity that precludes reliable imaging of RNA:DNA hybrids and renders associated imaging data inconclusive in the absence of controls for its promiscuous recognition of cellular RNAs.

Project description:R-loops both threaten genome integrity and act as physiological regulators of gene expression and chromatin patterning. To characterize R-loop forming loci in the fission yeast, we used the S9.6-based DRIPc-seq approach to obtain improved strand-specific maps of R-loop forming loci at near nucleotide resolution. We show that the weak affinity of the S9.6 antibody for double-stranded RNA (dsRNA) is sufficient to confound the mapping of genuine R-loops by this approach. dsRNA elimination allowed the identification of two distinct classes of R-loops that differ by their sensitivity to endogenous RNase H activity. Both classes associate with common chromatin features, which are similar to those associated with R-loop formation in human. We used RNA-seq to identify transcripts whose steady-state levels were affected by genome-wide manipulation of R-loop levels. gdh2 is such a transcript and we show that extra RNase H1 stimulates the cis-acting transcription interference between an upstream non-coding RNA and gdh2. Surprisingly, we found that most transcripts whose levels were altered by in vivo manipulation of R-loop levels did not form R-loops. Conversely, the abundance of only few R-loop forming transcripts was impacted by genome-wide variation of R-loop levels. We conclude that prolonged manipulation of R-loop levels imparts indirect effects on the transcriptome that could complicate the use of this strategy to understand R-loop functions.

Project description:Gene regulation in most eukaryotes involves two fundamental physical processes -- alterations in the packaging of the genome by nucleosomes, with active cis-regulatory elements (CREs) generally characterized by an open-chromatin configuration, and the activation of transcription. Mapping these physical properties and biochemical activities genome-wide -- through profiling chromatin accessibility and active transcription -- have now long been key tools used to understand the logic and mechanisms of transcription and its regulation. However, the direct relationship between the two has not been accessible to measurements, leaving the exact chromatin state of actively transcribed DNA molecules unresolved. To address this question, we developed KAS-ATAC, a combination of the KAS-seq (Kethoxal-Assisted SsDNA sequencing and ATAC-seq (Assay for Transposase-Accessible Chromatin using sequencing) methods for mapping single-stranded DNA (and thus active transcription) and chromatin accessibility, respectively, which maps DNA fragments that are simultaneously accessible and containing ssDNA genome-wide. We use KAS-ATAC to evaluate levels of active transcription over different classes of regulatory elements in the human genome, to estimate the absolute levels of transcribed accessible DNA over CREs, to map the nucleosomal configurations associated with RNA polymerase activities, and to assess transcription factor association with transcribed DNA through transcription factor binding site (TFBS) footprinting.

Project description:DNA sequencing of libraries from CUT&Tag with R-loops antibody (S9.6) in Ube2t knockdown and control P19 cells

Project description:We report the correlation we found between R-loops and antisense trasncription initiation. Our in vitro data suggests that RNA pol II can initiate transcription off the displaced single stranded DNA from within the R-loop. Therefore we generated Chromatin associated RNA-seq with and without over-expressing RNaseH1 and RDIP-seq (the directional RNA-seq of the RNA moeity from within the S9.6 pull down R-loop) as well as RR-ChIP-seq (the directional RNA-seq of the RNA moeity from within the catalytically dead RNaseH1-GFP GFP pull down R-loop) and confirm the correlation in vivo. We also aligned our findings with ChrCAP-seq (which is is a library enriched for RNA polymerase II capped RNA using chromatin associated RNA as the initial source) and found that capped antisense RNA were sensitive to RNase H1 overexpression.

Project description:R-Loops are unique RNA-containing chromatin structures, which participate in various key biological processes and associate with multiple human diseases. Accurately and comprehensively profiling R-Loops in the genome is crucial to study their functions under the physiological and pathological conditions. However, the existing methodologies have produced broad discrepancies in R-Loop profiling and an independent strategy is urgently needed. Here, we constructed an artificial DNA-RNA hybrid recognition sensor protein GST-His6-2XHBD with the hybrid-binding domain of RNase H1, and found GST-His6-2XHBD could specifically interact with DNA-RNA hybrids and behaves similarly to the anti-DNA-RNA hybrid S9.6 antibody in DRIPc-seq. Furthermore, we established a convenient method, R-loop CUT&Tag, by combination of GST-His6-2XHBD with a Tn5-based cleavage under targets and tagmentation approach. R-Loop CUT&Tag generates highly specific signals for native R-Loops, and can sensitively detect the R-Loop signals at the promoter, genebody and enhancer. R-Loop CUT&Tag also provides possibilities to genome-widely map the native R-Loops with limited materials, and may benefit the resolving of the broad discrepancies between multiple R-Loop mapping methods.

Project description:Distribution of R-loops on genomic sites was studied for exponentially growing Escherichia coli in different conditions using strand-specific DRIP-Seq with S9.6 antibodies.

Project description:Kethoxal-assisted ssDNA sequencing (KAS-seq) is gaining popularity as a robust and effective approach to study the dynamics of transcriptionally engaged RNA polymerases through profiling of genome-wide single-stranded DNA (ssDNA). Its latest variant, spKAS-seq, a strand-specific version of KAS-seq, has been developed to map genome-wide R-loop structures by detecting imbalances of ssDNA on two strands. However, user-friendly, open-source, and specific bioinformatic analyzer for KAS-seq data are still lacking. Here we present KAS-Analyzer as a flexible and integrated toolkit to facilitate the analysis and interpretation of KAS-seq data. KAS-Analyzer can perform standard analyses such as quality control, read alignment, and differential RNA polymerase activity analysis. In addition, KAS-Analyzer introduces many novel features, including, but not limited to: calculation of transcriptional indexes, identification of single-stranded transcribing enhancers, and high-resolution mapping of R-loops. We use benchmark datasets to demonstrate that KAS-Analyzer provides a powerful framework to study transient transcriptional regulatory programs. KAS-Analyzer is available at https://github.com/Ruitulyu/KAS-Analyzer.

Project description:To reveal the role of MCM8 in suppressing R-loop accumulation, we performed the CUT&TAG assay using the S9.6 antibody to map genome-wide R-loops in Mcm8 wildtype MEFs and Mcm8 knockout MEFs. We also conducted the CUT&TAG assay to detect genome-wide R-loops in Ddx5 downregulated MEFs by adenovirus infection and in control MEFs. To investigate the underlying molecular mechanism of MCM8 suppressing R-loops, we conducted the DNA sequencing of libraries from CUT&TAG assay using the antibody against FLAG in HEK293 cells transfected with FLAG-MCM8 plasmid and using the S9.6 antibody in HEK293 cells. Besides, an IgG control and control of RNH1 overexpression were included.