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: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:CFAP20 salvages arrested RNAPII from the path of co-directional replisomes

Project description:During the S-phase, conflicts of replication forks with RNA Polymerase II (RNAPII) threaten genomic stability. While the PAF complex can resolve such conflicts during elongation, the particularly deleterious conflicts with stalling RNAPII are resolved by an as of yet unknown mechanism. Here we show that the MYCN oncoprotein forms a ternary complex with RNAPII and the nuclear RNA exosome, a 3’‑5’ exoribonuclease complex. Together with TFIIS, this complex restarts promoter‑proximal RNAPII, allows escape from co-directional transcription-replication conflicts and prevents double‑strand break accumulation. In cells lacking RNA exosome function, MYCN globally terminates transcription. MYCN-mediated termination is triggered by ATM‑dependent recruitment of BRCA1, which then stabilizes nuclear mRNA decapping complexes. Disruption of mRNA decapping activates ATR, indicative of head-on transcription-replication conflicts, and inhibits DNA replication. We propose that MYCN resolves transcription-replication conflicts via this two-step mechanism to sustain the rapid proliferation of neuroendocrine tumor cells.

Project description:During the S-phase, conflicts of replication forks with RNA Polymerase II (RNAPII) threaten genomic stability. While the PAF complex can resolve such conflicts during elongation, the particularly deleterious conflicts with stalling RNAPII are resolved by an as of yet unknown mechanism. Here we show that the MYCN oncoprotein forms a ternary complex with RNAPII and the nuclear RNA exosome, a 3’‑5’ exoribonuclease complex. Together with TFIIS, this complex restarts promoter‑proximal RNAPII, allows escape from co-directional transcription-replication conflicts and prevents double‑strand break accumulation. In cells lacking RNA exosome function, MYCN globally terminates transcription. MYCN-mediated termination is triggered by ATM‑dependent recruitment of BRCA1, which then stabilizes nuclear mRNA decapping complexes. Disruption of mRNA decapping activates ATR, indicative of head-on transcription-replication conflicts, and inhibits DNA replication. We propose that MYCN resolves transcription-replication conflicts via this two-step mechanism to sustain the rapid proliferation of neuroendocrine tumor cells.

Project description:During the S-phase, conflicts of replication forks with RNA Polymerase II (RNAPII) threaten genomic stability. While the PAF complex can resolve such conflicts during elongation, the particularly deleterious conflicts with stalling RNAPII are resolved by an as of yet unknown mechanism. Here we show that the MYCN oncoprotein forms a ternary complex with RNAPII and the nuclear RNA exosome, a 3’‑5’ exoribonuclease complex. Together with TFIIS, this complex restarts promoter‑proximal RNAPII, allows escape from co-directional transcription-replication conflicts and prevents double‑strand break accumulation. In cells lacking RNA exosome function, MYCN globally terminates transcription. MYCN-mediated termination is triggered by ATM‑dependent recruitment of BRCA1, which then stabilizes nuclear mRNA decapping complexes. Disruption of mRNA decapping activates ATR, indicative of head-on transcription-replication conflicts, and inhibits DNA replication. We propose that MYCN resolves transcription-replication conflicts via this two-step mechanism to sustain the rapid proliferation of neuroendocrine tumor cells.