Project description:Endonuclease RNaseH1 acts as a common R-loop resolvase to prevent R-loop accumulation genome-widely, whether there is any exonuclease complementing RNaseH1 to more efficiently resolve R-loops is worth investigation. Here we identify an exonuclease REXO4, which collaborates with RNaseH1 to efficiently degrade R-loops in an “endo- and exo-cleavage coupling” manner.DNA-RNA immunoprecipitation followed by sequencing (DRIP-seq) shows that R-loop regions regulated by REXO4 highly overlap with those regulated by RNaseH1.

Project description:Purpose: The exosome plays major roles in RNA processing and surveillance but the in vivo target range and substrate acquisition mechanisms remain unclear. We applied an in vivo cross-linking technique coupled with deep sequencing (CRAC) that captures transcriptome-wide interactions between individual yeast exosome subunits and their targets in a living cell. Methods: We apply CRAC to HTP-tagged proteins (HTP: His6 - TEV cleavage site - two copies of the z-domain of Protein A): Two nucleases (Rrp44, Rrp6) and two structural subunits (Rrp41, Csl4) of the yeast exosome. At least two independent experiments were performed in each case and analyzed separately. We performed CRAC on wild-type (WT) Rrp44 and two catalytic mutants, rrp44-endo (D91N, E120Q, D171N, D198N) and rrp44-exo (D551N). We further developed CRAC using cleavable proteins (split-CRAC) to compare endonuclease and exonuclease targets of Rrp44. Plasmids designed for split-CRAC contain a PreScission protease cleavage site (PP) inserted between aa 241 and 242 in the RRP44 ORF to allow in vitro cleavage of purified protein, and a His6 tag to select the respective cleaved fragment. Results: Analysis of wild-type Rrp44 and catalytic mutants showed that both the CUT and SUT classes of noncoding RNA, snoRNAs and, most prominently, pre-tRNAs and other Pol III transcripts are targeted for oligoadenylation and exosome degradation. Unspliced pre-mRNAs were also identified as targets for Rrp44 and Rrp6. CRAC performed using cleavable proteins (split-CRAC) revealed that Rrp44 endonuclease and exonuclease activities cooperate on most substrates. Mapping oligoadenylated reads suggests that the endonuclease activity may release stalled exosome substrates. Rrp6 was preferentially associated with structured targets, which frequently did not associate with the core exosome. This indicates that substrates can follow multiple pathways to the nucleases. Conclusion: Our study represents the first transcriptome-wide map of substrates for the yeast exosome nuclease complex. Identification of targets for individual exosome subunits in wild-type and mutant yeast cells.

Project description:Purpose: The exosome plays major roles in RNA processing and surveillance but the in vivo target range and substrate acquisition mechanisms remain unclear. We applied an in vivo cross-linking technique coupled with deep sequencing (CRAC) that captures transcriptome-wide interactions between individual yeast exosome subunits and their targets in a living cell. Methods: We apply CRAC to HTP-tagged proteins (HTP: His6 - TEV cleavage site - two copies of the z-domain of Protein A): Two nucleases (Rrp44, Rrp6) and two structural subunits (Rrp41, Csl4) of the yeast exosome. At least two independent experiments were performed in each case and analyzed separately. We performed CRAC on wild-type (WT) Rrp44 and two catalytic mutants, rrp44-endo (D91N, E120Q, D171N, D198N) and rrp44-exo (D551N). We further developed CRAC using cleavable proteins (split-CRAC) to compare endonuclease and exonuclease targets of Rrp44. Plasmids designed for split-CRAC contain a PreScission protease cleavage site (PP) inserted between aa 241 and 242 in the RRP44 ORF to allow in vitro cleavage of purified protein, and a His6 tag to select the respective cleaved fragment. Results: Analysis of wild-type Rrp44 and catalytic mutants showed that both the CUT and SUT classes of noncoding RNA, snoRNAs and, most prominently, pre-tRNAs and other Pol III transcripts are targeted for oligoadenylation and exosome degradation. Unspliced pre-mRNAs were also identified as targets for Rrp44 and Rrp6. CRAC performed using cleavable proteins (split-CRAC) revealed that Rrp44 endonuclease and exonuclease activities cooperate on most substrates. Mapping oligoadenylated reads suggests that the endonuclease activity may release stalled exosome substrates. Rrp6 was preferentially associated with structured targets, which frequently did not associate with the core exosome. This indicates that substrates can follow multiple pathways to the nucleases. Conclusion: Our study represents the first transcriptome-wide map of substrates for the yeast exosome nuclease complex.

Project description:R-loops are three-stranded nucleic acid structures composed of an RNA:DNA hybrid and displaced DNA strand. These structures can halt DNA replication when formed co- transcriptionally in the opposite orientation to replication fork progression. Recent studies have shown that replication forks stalled by co-transcription R-loops can be restarted by a mechanism involving fork cleavage by MUS81 endonuclease, followed by reactivation of transcription, and fork religation by the DNA ligase IV (LIG4)/XRCC4 complex. However, how R-loops are eliminated to allow the sequential restart of transcription and replication in this pathway remains elusive. Here, we identified the human DDX17 helicase as a factor that associates with R-loops and counteracts R-loop-mediated replication stress to preserve genome stability. We show that DDX17 unwinds RNA:DNA hybrids in vitro and promotes MUS81-dependent restart of R-loop-stalled forks in human cells in a manner dependent on its helicase activity. Loss of DDX17 helicase induces accumulation of R-loops and the formation of R-loop-dependent anaphase bridges and micronuclei. These findings establish DDX17 as a component of the MUS81-LIG4 pathway for resolution of R-loop-mediated transcription- replication conflicts, which may be involved in R-loop unwinding.

Project description:R-loop induces genome instability and regulates gene expression. However, regulatory mechanism of R-loop in stem cell biology remains unclear. Here, we mapped the profiling of R-loops during reprogramming process and revealed that R-loops change prior to gene expression and are mainly accumulated and enriched at terminator of genes. Disrupting homeostasis of R-loops via RNaseH1 loss-of-function blocks reprogramming in a medium independent manner. Interestingly, Sox2 but not other Yamanaka factors overcomes the inhibitory effects of RNaseH1 loss on reprogramming. Sox2 forms a complex with Ddx5 and R-loop in cells and common targets for Sox2 and Ddx5 at R-loops are mainly associated with pluripotent genes. Furthermore, Sox2 inhibits the resolving activity of RNA helicase Ddx5 at R-loops to facilitate reprogramming. Together, these results indicate that the importance of R-loops balance for reprogramming and shed light on the regulation Sox2/Ddx5 on R-loops during reprogramming.

Project description:G-quadruplexes (G4s) and R-loops are non-canonical DNA structures that can play regulatory functions of basic nuclear processes and can trigger DNA damage and genome instability. We here show that specific G4 ligands can stabilize G4s and simultaneously increase R-loop levels in human cancer cells likely by spreading DNA:RNA heteroduplexes to adjacent regions containing G4 structures. DNA cleavage and DNA damage response induced by G4 ligands were rescued by overexpression of exogenous RNaseH1 in cancer cells independently of BRCA2 status. The data thus show that R-loops are involved in the induction of DNA damage by chemical G4 stabilization. In addition, G4 ligands trigger the formation of micronuclei, particularly in BRCA2-silenced cancer cells, in an R-loop dependent manner. Our results uncover the mechanism of genome instability caused by G4 ligands and can open to the development of unexpected anticancer strategies using G4-targeted agents.

Project description:Efficient processing of widespread R-loops through an endo- and exo-cleavage coupling mode prevents genome instability

Project description:R-loop is a naturally formed three-strand nucleic acid structure that was reported to take part in multiple biological processes. In our study, we firstly mapped R-loop genomic distribution in mammalian meiotic cells by genome-wide S9.6 CUT & Tag seq. R-loop mainly distributed at promoter-related regions, and combined with systematically transcriptome analysis showed R-loop was closely related to transcription in the meiotic process. Moreover, we verified the conclusion by constructing conditional knockout mice of Rnaseh1, which delete the R-loop endonuclease before meiosis entry. Lack of RNase H1 caused mice completely sterile with R-loop accumulation and abnormal DSB repairing in spermatocytes. Further analysis showed R-loop accumulation in leptotene/zygotene influenced transcriptional regulation in the pachytene stage. Thus, mutual regulation of R-loop and transcription plays an essential role in spermatogenesis.

Project description:R-loops represent three-stranded nucleic acid structures comprising an RNA-DNA hybrid and a displaced single-stranded DNA. Deregulation of R-loop dynamics can obstruct DNA transcription and replication processes, compromising genome integrity and contributing to human diseases. Here, we identify EXD2(exonuclease 3′–5′ domain-containing 2) as a crucial R-Loop resolvase. We demonstrate that EXD2, through direct interaction with PARP1 via poly(ADP-ribose) (PAR) polymers, is recruited proximally to R-loops, where it undergoes acetylation by the acetyl-transferase CBP at Lys416. This modification increases EXD2’s binding affinity towards R-loop structures, enabling its transition to and retention on R-loops, despite the rapid turnover of PAR polymers. Once localized, EXD2 acts as an exonuclease, preferentially degrading RNA strands within R-loops to promote their resolution. Consequently, loss of EXD2 results in the intracellular accumulation of R-loops, exacerbating transcription-replication conflicts, and ultimately leading to genomic instability. These findings support a model in which R-loop-triggered PARP1 activation orchestrates EXD2-mediated resolution of R-loops, thereby preserving genome stability.

Project description:Transcription can pose a threat to genomic stability through the formation of R-loops that obstruct the progression of replication forks. R-loops are three-stranded nucleic acid structures formed by an RNA-DNA hybrid with a displaced non-template DNA strand. We developed RDProx to identify proteins that regulate R-loops in human cells. RDProx relies on the expression of the hybrid-binding domain (HBD) of Ribonuclease H1 (RNaseH1) fused to the ascorbate peroxidase (APEX2), which permits mapping of the R-loop proximal proteome using quantitative mass spectrometry. We associated R-loop regulation with different cellular proteins and identified a role of the tumor suppressor DEAD box protein 41 (DDX41) in opposing R-loop-dependent genomic instability. Depletion of DDX41 resulted in replication stress, double strand breaks and increased inflammatory signaling. Furthermore, DDX41 opposes accumulation of R-loops at gene promoters and its loss leads to upregulated expression of TGFβ and NOTCH signaling genes. Germline loss-of-function mutations in DDX41 lead to predisposition to acute myeloid leukemia (AML) in adulthood. We propose that accumulation of co-transcriptional R-loops, associated gene expression changes and inflammatory response contribute to the development of familial AML with mutated DDX41.