Project description: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 high-resolution mapping of mitotic recombination events throughout the yeast genome in diploid strains of Saccharomyces cerevisiae lacking RNase H1 (rnh1Δ), RNase H2 (rnh201Δ), or both RNase H1 and RNase H2 (rnh1Δ rnh201Δ). We found little effect on recombination in the rnh1Δ strain, but elevated recombination in both the rnh201Δ and the double-mutant strains; levels of recombination in the double mutant were about 50% higher than in the rnh201 single-mutant strain. An rnh201Δ mutant that additionally contained a mutation that reduces rNMP incorporation by DNA polymerase ε (pol2-M644L) had a level of instability similar to that observed in the presence of wild-type Polε. 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. The details of these experiments are in press in Genetics This diploid S.cerevisiae strain used here is a hybrid between W303-1A and YJM789. The backgrounds are diverged by about 50,000 polymorphisms that are surveyed by custom CGH microarrays containing SNP-specific probes (St. Charles et al., 2012; Genetics 190: 1267-1284; PMID 22267500). The whole genome array surveyed loss of heterozygosity (LOH) events throughout the genome of in wild type, pol2-M644L, rnh1Δ, rnh201Δ, rnh201Δ pol2-M644L, and rnh1Δ rnh201Δ mutant backgrounds in 10, 12, 10, 19, 17, and 22 samples, respectively. The names of these strains are KO_198,KO_234, KO_73, KO_75, KO_244, and KO_5, respectively. Another assay was performed mapping reciprocal crossover events on the right arm of chromosome IV in the rnh201Δ (strains KO_135 and KO188) and the rnh1Δrnh201Δ (strain KO_132) mutant backgrounds. A reporter system with a wild type ADE2 on the end of chromosome IV allowed us to detect crossovers by seeing a red-white sectored colony. Each reciprocal event was mapped by doing a microarray specific for the right arm of chromosome IV (St. Charles and Petes, 2013; PLoS Genet. 1267-1284 PMCID PMC3616911) on the red and white sides of sectors. 21 sectors were analyzed for the rnh201Δ mutant while 14 were analyzed for the rnh1Δ rnh201Δ mutant. We mapped crossovers on the right arm of chromosome IV in the rnh201Δ mutant in four different diploid isolates: KO135_5 (1R/1W, 2R/2W, 4R/4W, 5R/5W, 12R/12W, and 13R/13W), KO_135_6 (1R/1W, 4R/4W, 5R/5W, 7R/7W, 9R/9W, 11R/11W, 13R/13W, and 17R/17W), KO 188_1 (1R/1W, and 4R/4W), and KO188_2 (6R/6W, 7R/7W, 11R/11W, and 12R/12W). We mapped crossovers on the right arm of chromosome IV in the rnh1Δ rnh201Δ mutant in two different diploid isolates: KO_132_31 (2R/2W, 6R/6W, 8R/8W, 15R/15W, 17R/17W, 21R/21W, 22R/22W, and 24R/24W) and KO_132_29 (3R/3W, 7R/7W, 18R/18W, 24R/24W, and 34R/34W).

Project description:Class switch recombination generates antibody distinct isotypes critical to a robust adaptive immune system and defects are associated with auto-immune disorders and lymphomagenesis. Transcription is required during class switch to recruit the cytidine deaminase AID—an essential step for the formation of DNA doublestrand breaks—and strongly induces the formation of R loops within the immunoglobulin heavy chain locus. However, the impact of R loops on double-strand break formation and repair during class switch recombination remains unclear. Here we report that cells lacking two enzymes involved in R loop removal— Senataxin and RNase H2—exhibit increased R loop formation and genome instability at the immunoglobulin heavy chain locus without impacting class switch recombination efficiency, transcriptional activity, or AID recruitment. Senataxin and RNase H2-deficient cells also exhibit increased insertion mutations at switch junctions, a hallmark of alternative end joining. Importantly, these phenotypes were not observed in cells lacking Senataxin or RNase H2B alone. We propose that Senataxin acts redundantly with RNase H2 to mediate timely R loop removal, promoting efficient repair while suppressing AID-dependent genome instability and insertional mutagenesis.

Project description:Yeast Saccharomyces cerevisiae has been widely used as a model system for studying genome instability. Here, heterozygous S. cerevisiae zygotes were generated to determine the genomic alterations induced by sudden introduction of active RNase H2. In combination of a custom SNP microarray, the patterns of chromosomal instability could be explored at a whole genome level. Ribonucleotides can be incorporated into DNA during replication by the replicative DNA polymerases. These aberrant DNA subunits are efficiently recognized and removed by Ribonucleotide Excision Repair, which is initiated by the heterotrimeric enzyme RNase H2. While RNase H2 is essential in higher eukaryotes, the yeast Saccharomyces cerevisiae can survive without RNase H2 enzyme, although the genome undergoes mutation, recombination and other genome instability events at an increased rate. Although RNase H2 can be considered as a protector of the genome from the deleterious events that can ensue from recognition and removal of embedded ribonucleotides, under conditions of high ribonucleotide incorporation and retention in the genome in a RNase H2-negative strain, sudden introduction of active RNase H2 causes massive DNA breaks and genome instability in a condition which we term “ribodysgenesis”. The DNA breaks and genome instability arise solely from RNase H2 cleavage directed to the ribonucleotide-containing genome. Survivors of ribodysgenesis have massive loss of heterozygosity events stemming from recombinogenic lesions on the ribonucleotide-containing DNA, with increases of over 1000X from wild-type. DNA breaks are produced over one to two divisions and subsequently cells adapt to RNase H2 and ribonucleotides in the genome and grow with normal levels of genome instability.

Project description:R-loops represent a major source of replication stress but the mechanism by which these structures impede fork progression remains unclear. To address this question, we monitored fork progression, arrest and restart in S. cerevisiae cells lacking RNase H1 and H2, two enzymes responsible for degrading RNA:DNA hybrids. We found that while RNase H-deficient cells could replicate normally their chromosomes under unchallenged growth conditions, their replication was impaired when exposed to hydroxyurea (HU) or methyl methanesulfonate (MMS). Indeed, these cells exhibited increased levels of RNA:DNA hybrids at stalled forks and were unable to generate RPA-coated single-stranded (ssDNA), an important postreplicative step in resuming replication. Similar impairments in nascent DNA resection at HU-arrested forks were observed in human cells lacking RNase H2. However, the addition of triptolide, an inhibitor of transcription that induces RNA polymerase degradation, fully restored fork resection. Taken together, these data indicate that RNA:DNA hybrids not only act as barriers to replication forks, but also interfere with postreplicative fork repair mechanisms if not promptly degraded by RNase H.

Project description:RNase H2 is a specialized enzyme that degrades RNA in RNA/DNA hybrids and deficiency of this enzyme causes a severe neuroinflammatory disease, Aicardi Goutières syndrome (AGS). However, the molecular mechanism underlying AGS is still unclear. Here, we show that RNase H2 is associated with a subset of genes, in a transcription-dependent manner where it interacts with RNA Polymerase II. RNase H2 depletion impairs transcription leading to accumulation of R-loops, structures that comprise RNA/DNA hybrids and a displaced DNA strand, mainly associated with short and intronless genes. Importantly, accumulated R-loops are processed by XPG and XPF endonucleases which leads to DNA damage and activation of the immune response, features associated with AGS. Consequently, we uncover a key role for RNase H2 in the transcription of human genes by maintaining R-loop homeostasis. Our results provide insight into the mechanistic contribution of R-loops to AGS pathogenesis.

Project description:Strong cellular stress causes wide-spread perturbations in the transcriptome and in several types of DNA/RNA interactions, and through incompletely understood pathways to formation of cytoplasmic stress granules (SGs). We have investigated the relationships between strong transcriptional induction, RNA:DNA hybrid stretches (R-loops), and SG formation under severe hyperosmotic and glucose stress. Several mutations affecting DNA processing proteins, including the DNA polymerase subunit Pol32, confer SG formation defects. Severe stress increased R loop levels globally. We found that facilitating removal of R-loops by RNase H overexpression, with activity towards RNA:DNA hybrids, accelerated and enhanced transcriptional induction of stress-activated genes. Thus, overexpression of RNase H1, but not RNase H2, reduced R-loops globally around the 1 h mark. Remarkably, it also reduced SG formation. We performed a genome-wide analysis of the induction or repression kinetics of gene expression under severe stress conditions. RNase H1 overexpression reduced R-loops locally in highly transcribed stress-affected genes, as expected. Notably, it also increased expression of several stress-induced genes. Conversely, in cells where R-loops are not efficiently resolved, transcriptional induction of the same genes under stress was muted and occurred with a delay. Thus, in pol32∆ mutants, where SG accumulation is delayed, R-loop levels are elevated, and induction of stress genes suppressed. The pol32∆ mutants are also refractory to the effects of RNase H1 overexpression on stress gene induction, R-loop resolution, and SG formation, indicating that Pol32 may act downstream of Rnh1 in the regulation of these three processes. These findings demonstrate an unexpected link between R-loops and formation of SGs. Together, these observations indicate that under stress, strong transcriptional induction of specific genes or genomic regions causes R-loop accumulation, which then requires RNase H1 activity for resolution. If unresolved, the accumulated R-loops impede continued stress-induced transcription, and delay or prevent SG formation.

Project description:Human mitochondrial DNA (mtDNA) replication is first initiated at the origin of H-strand replication. The initiation depends on RNA primers generated by transcription from an upstream promoter (LSP). Here we reconstitute this process in vitro using purified transcription and replication factors. The majority of all transcription events from LSP are prematurely terminated after 120 nucleotides, forming stable R-loops. These nascent R-loops cannot directly prime mtDNA synthesis, but must first be processed by RNase H1 to generate 3-ends that can be used by DNA polymerase to initiate DNA synthesis. Our findings are consistent with recent studies of a knockout mouse model, which demonstrated that RNase H1 is required for R-loop processing and mtDNA maintenance in vivo. Both R-loop formation and DNA replication initiation are stimulated by the mitochondrial single-stranded DNA binding protein. In an RNase H1 deficient patient cell line, the precise initiation of mtDNA replication is lost and DNA synthesis is initiated from multiple sites throughout the mitochondrial control region. In combination with previously published in vivo data, the findings presented here suggests a model, in which R-loop processing by RNase H1 directs origin-specific initiation of DNA replication in human mitochondria.

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: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.

Project description:The exact in vivo role for RNase H1 in mammalian mitochondria (mtDNA) has been much debated and we show here that it is essential for processing of RNA primers to provide site-specific initiation of mtDNA replication. Without RNase H1, mtDNA replication is instead initiated at non-canonical sites and becomes impaired. Furthermore, RNase H1 is also needed for replication completion and in its absence linear deleted mtDNA molecules extending between the two origins of mtDNA replication are formed. Finally, we report the first patient with a homozygous pathogenic mutation in the hybrid-binding domain (HBD) of RNase H1 causing impaired mtDNA replication. In contrast to catalytically dead pathological variants of RNase H1, this mutant version has enhanced enzyme activity. This finding shows that the RNase H1 activity must be strictly controlled to allow proper regulation of mtDNA replication.