Project description:Fine-tuning DNA replication and transcription co-occurrence is vital to avoid collisions between their machineries. This is especially relevant near promoters, where RNAPII initiates transcription and often arrests, forming R-loops. Arrested RNAPII poses a roadblock for DNA replication, which evolutionarily initiates near promoters. The mechanisms that salvage arrested RNAPII during elongation to avoid conflicts with incoming replisomes remain unaddressed. In this study, employing genome-wide and proteomic approaches, we identify and characterize CFAP20 as part of a protective pathway that rescues arrested RNAPII in promoter-proximal regions, diverting it from the path of co-directional replisomes. CFAP20-deficient cells accumulate R-loops specifically near promoters, displaying defects in replication origin firing and fork progression. Co-depletion of the Mediator coactivator complex or removal of RNAPII engaged with R-loops rescues these replication phenotypes. Therefore, we propose that CFAP20 salvages arrested RNAPII under conditions of high Mediator-driven transcription to promote RNAPII elongation, thereby preventing collisions with co-directional replisomes.

Project description:Fine-tuning DNA replication and transcription co-occurrence is vital to avoid collisions between their machineries. This is especially relevant near promoters, where RNAPII initiates transcription and often arrests, forming R-loops. Arrested RNAPII poses a roadblock for DNA replication, which evolutionarily initiates near promoters. The mechanisms that salvage arrested RNAPII during elongation to avoid conflicts with incoming replisomes remain unaddressed. In this study, employing genome-wide and proteomic approaches, we identify and characterize CFAP20 as part of a protective pathway that rescues arrested RNAPII in promoter-proximal regions, diverting it from the path of co-directional replisomes. CFAP20-deficient cells accumulate R-loops specifically near promoters, displaying defects in replication origin firing and fork progression. Co-depletion of the Mediator coactivator complex or removal of RNAPII engaged with R-loops rescues these replication phenotypes. Therefore, we propose that CFAP20 salvages arrested RNAPII under conditions of high Mediator-driven transcription to promote RNAPII elongation, thereby preventing collisions with co-directional replisomes.

Project description:Fine-tuning DNA replication and transcription co-occurrence is vital to avoid collisions between their machineries. This is especially relevant near promoters, where RNAPII initiates transcription and often arrests, forming R-loops. Arrested RNAPII poses a roadblock for DNA replication, which evolutionarily initiates near promoters. The mechanisms that salvage arrested RNAPII during elongation to avoid conflicts with incoming replisomes remain unaddressed. In this study, employing genome-wide and proteomic approaches, we identify and characterize CFAP20 as part of a protective pathway that rescues arrested RNAPII in promoter-proximal regions, diverting it from the path of co-directional replisomes. CFAP20-deficient cells accumulate R-loops specifically near promoters, displaying defects in replication origin firing and fork progression. Co-depletion of the Mediator coactivator complex or removal of RNAPII engaged with R-loops rescues these replication phenotypes. Therefore, we propose that CFAP20 salvages arrested RNAPII under conditions of high Mediator-driven transcription to promote RNAPII elongation, thereby preventing collisions with co-directional replisomes.

Project description:Fine-tuning DNA replication and transcription co-occurrence is vital to avoid collisions between their machineries. This is especially relevant near promoters, where RNAPII initiates transcription and often arrests, forming R-loops. Arrested RNAPII poses a roadblock for DNA replication, which evolutionarily initiates near promoters. The mechanisms that salvage arrested RNAPII during elongation to avoid conflicts with incoming replisomes remain unaddressed. In this study, employing genome-wide and proteomic approaches, we identify and characterize CFAP20 as part of a protective pathway that rescues arrested RNAPII in promoter-proximal regions, diverting it from the path of co-directional replisomes. CFAP20-deficient cells accumulate R-loops specifically near promoters, displaying defects in replication origin firing and fork progression. Co-depletion of the Mediator coactivator complex or removal of RNAPII engaged with R-loops rescues these replication phenotypes. Therefore, we propose that CFAP20 salvages arrested RNAPII under conditions of high Mediator-driven transcription to promote RNAPII elongation, thereby preventing collisions with co-directional replisomes.

Project description:Fine-tuning DNA replication and transcription co-occurrence is vital to avoid collisions between their machineries. This is especially relevant near promoters, where RNAPII initiates transcription and often arrests, forming R-loops. Arrested RNAPII poses a roadblock for DNA replication, which evolutionarily initiates near promoters. The mechanisms that salvage arrested RNAPII during elongation to avoid conflicts with incoming replisomes remain unaddressed. In this study, employing genome-wide and proteomic approaches, we identify and characterize CFAP20 as part of a protective pathway that rescues arrested RNAPII in promoter-proximal regions, diverting it from the path of co-directional replisomes. CFAP20-deficient cells accumulate R-loops specifically near promoters, displaying defects in replication origin firing and fork progression. Co-depletion of the Mediator coactivator complex or removal of RNAPII engaged with R-loops rescues these replication phenotypes. Therefore, we propose that CFAP20 salvages arrested RNAPII under conditions of high Mediator-driven transcription to promote RNAPII elongation, thereby preventing collisions with co-directional replisomes.

Project description:R loops are an important source of genome instability largely due to its negative impact on replication progression. Yra1/ALY is an abundant RNA-binding factor conserved from yeast to humans and required for mRNA export, but its excess cause lethality and genome instability. Here, we show that Yra1 binds RNA-DNA hybrids in vitro and when artificially overexpressed is recruited to chromatin in an RNA-DNA hybrid-dependent manner stabilizing R loops and converting them into replication obstacles in vivo. Importantly, excess of Yra1 increases R loop-mediated genome instability caused by transcription-replication collisions regardless of whether they are co-directional or head-on. It also induces telomere shortening and senescence, consistent with a defect in telomere replication. Our results indicate that R loops form transiently in cells regardless of replication and, after stabilization by excess Yra1, they compromise genome integrity, in agreement with a two-step model of R loop-mediated genome instability. This work opens new perspectives to understand transcription-associated genome instability in repair-deficient cells, including tumoral cells.

Project description:RNAPII-dependent ATM signaling at collisions with replication forks

Project description:Meiotic recombination is initiated by the Spo11-dependent programmed DNA double-strand breaks (DSBs) that are preferentially concentrated within genomic regions known as hotspots, but the factor(s) which specify the positions for meiotic DSB hotspots remain unclear. Here, we show that the frequency and distribution of R-loops, a type of functional chromatin structure comprising single-stranded DNA and a DNA:RNA hybrid, change dramatically throughout meiosis. We detected the formation of multiple de novo R-loops in the pachytene stage, and found they co-localize with meiotic DSB hotspots. We further show that transcription-replication head-on collisions could promote R-loop formation during meiosis, and apparently direct the initiation of meiotic DSB formation. Furthermore, the hotspots can be eliminated by reverse the direction of either transcription or replication, and reconstituted by reverse both of their direction. Our study reveals that R-loops may play dual roles in meiotic recombination. In addition to participation in meiotic DSB processing, some meiotic DSB hotspots may be originated from the transcription-replication head-on collisions during meiotic DNA replication.

Project description:RNAPII-dependent ATM signaling at collisions with replication forks [DSBCapture]

Project description:RNAPII-dependent ATM signaling at collisions with replication forks [DSB]