Abstract
Fine-tuning DNA replication and transcription is crucial to prevent collisions between their machineries(1). This is particularly important near promoters, where RNA polymerase II (RNAPII) initiates transcription and frequently arrests, forming R-loops(2-4). Arrested RNAPII can obstruct DNA replication, which often initiates near promoters(5,6). The mechanisms that rescue arrested RNAPII during elongation to avoid conflicts with co-directional replisomes remain unclear. Here, using genome-wide approaches and genetic screens, we identify CFAP20 as part of a protective pathway that salvages arrested RNAPII in promoter-proximal regions, diverting it from the path of co-directional replisomes. CFAP20-deficient cells accumulate R-loops near promoters, which leads to defects in replication timing and dynamics. These defects stem from accelerated replication-fork speeds that cause a secondary reduction in origin activity. Co-depletion of the Mediator complex or removal of R-loop-engaged RNAPII restores normal replication. Our findings suggest that transcription-dependent fork stalling in cis induces accelerated fork progression in trans, generating single-stranded DNA gaps. We propose that CFAP20 facilitates RNAPII elongation under high levels of Mediator-driven transcription, thereby preventing replisome collisions. This study provides a transcription-centred view of transcription-replication encounters, revealing how locally arrested transcription complexes propagate genome-wide replication phenotypes and defining CFAP20 as a key factor that safeguards genome stability.