Song, W.; Newman, J. A.; Zhao, Y.; Chalk, R.; Redfield, C.; Elliott, P. R.; Ramadan, K.

The DNA-dependent metalloprotease SPRTN has emerged as a key enzyme in the proteolysis of DNA-protein crosslinks (DPCs), thereby protecting us against genome instability, accelerated ageing, and cancer. DNA and ubiquitin chains serve as the primary activator and catalyst of SPRTN proteolysis, respectively, but how they promote SPRTN activation and activity remains incompletely understood. To address this question, we developed a highly sensitive multi-turnover fluorescence resonance energy transfer (FRET) assay to monitor SPRTN proteolysis in real time. We found that the auto-cleaved N-terminal SPRTN fragment, comprising the metalloprotease domain (MPD), zinc-binding domain (ZBD), and basic region (BR), is highly stable, enzymatically active, and retains ubiquitin-dependent activation. Interestingly, the MPD alone exhibits basal intrinsic activity that is independent of both DNA activation and ubiquitin avidity effect. We show that ZBD and MPD together exert steric regulation: ZBD maintains MPD in an autoinhibited state, while MPD largely prevents ZBD from binding to DNA. BR, together with DNA, is essential to relieve ZBD-mediated inhibition of MPD. Using a site-trapping approach, we demonstrate that the ZBD-BR- DNA trinity induces an open conformation of the SPRTN N-terminus in cis, thereby releasing autoinhibition. MPD and BR together restrict the DNA-binding stoichiometry of ZBD, enabling SPRTN to function efficiently in proximity to DNA despite its low abundance in vivo. Collectively, our work overturns the long-standing dogma that SPRTN autocleavage inactivates the enzyme and reveals how DNA-induced conformational changes in SPRTN fine-tune its protease activity, providing a prerequisite for subsequent ubiquitin activation and rapid proteolysis of DPCs.