The SUMO-NIP45 pathway processes toxic DNA catenanes to prevent mitotic failure

Hertz et al. use CRISPR screening to identify genetic vulnerabilities to inhibition of SUMOylation in human cells. They show that SUMO exerts its essential role in cell proliferation via NIP45- and BTRR-PICH-mediated DNA catenane resolution pathways. SUMOylation regulates numerous cellular processes, but what represents the essential functions of this protein modification remains unclear. To address this, we performed genome-scale CRISPR-Cas9-based screens, revealing that the BLM-TOP3A-RMI1-RMI2 (BTRR)-PICH pathway, which resolves ultrafine anaphase DNA bridges (UFBs) arising from catenated DNA structures, and the poorly characterized protein NIP45/NFATC2IP become indispensable for cell proliferation when SUMOylation is inhibited. We demonstrate that NIP45 and SUMOylation orchestrate an interphase pathway for converting DNA catenanes into double-strand breaks (DSBs) that activate the G2 DNA-damage checkpoint, thereby preventing cytokinesis failure and binucleation when BTRR-PICH-dependent UFB resolution is defective. NIP45 mediates this new TOP2-independent DNA catenane resolution process via its SUMO-like domains, promoting SUMOylation of specific factors including the SLX4 multi-nuclease complex, which contributes to catenane conversion into DSBs. Our findings establish that SUMOylation exerts its essential role in cell proliferation by enabling resolution of toxic DNA catenanes via nonepistatic NIP45- and BTRR-PICH-dependent pathways to prevent mitotic failure.

Automated summary

Hertz et al. use CRISPR screening to identify genetic vulnerabilities to inhibition of SUMOylation in human cells. They show that SUMO exerts its essential role in cell proliferation via NIP45- and BTRR-PICH-mediated DNA catenane resolution pathways. NIP45 mediates a TOP2-independent DNA catenane resolution process through its SUMO-like domains, promoting SUMOylation of specific factors including the SLX4 multi-nuclease complex, which contributes to catenane conversion into DSBs. Their findings establish the importance of SUMOylation in enabling resolution of toxic DNA catenanes via non-epistatic NIP45- and BTRR-PICH-dependent pathways to prevent mitotic failure.