The cellular networks that maintain genome stability encompass numerous pathways involved in all aspects of nucleic acid metabolism. Through bioinformatic analysis, we identified the Zinc Finger CCCH- Show more
The cellular networks that maintain genome stability encompass numerous pathways involved in all aspects of nucleic acid metabolism. Through bioinformatic analysis, we identified the Zinc Finger CCCH-Type Containing 4 protein (ZC3H4), a suppressor of noncoding RNA (ncRNA) production, as a pivotal player in this system. Experimentally, ZC3H4 deficiency led to increased DNA damage, abnormal mitosis, and cellular senescence. Biochemical analysis and super-resolution microscopy revealed that the loss of ZC3H4 increased replication stress (RS)-a major driver of genome instability-by inducing a hypertranscription state that promoted R loop formation and transcription-replication conflicts (TRCs), both of which drive RS. Further bioinformatic analysis demonstrated that ZC3H4 preferentially binds to genomic regions prone to TRCs and R loops, where it suppresses ncRNA bursts, functioning as part of the Restrictor complex. Our findings identify ZC3H4 as a crucial factor in maintaining genome integrity, strategically positioned at the critical intersection of DNA and RNA synthesis. Show less