Protein oxidation increases SAMHD1 binding ssDNA via its regulatory site.

SAMHD1 dNTP hydrolase activity places it at the crossroad of several important biological pathways, such as viral restriction, cell cycle regulation, and innate immunity. Recently, a dNTPase independent function for SAMHD1 in homologous recombination (HR) of DNA double-strand breaks has been identified. SAMHD1 function and activity is regulated by several post-translational modifications, including protein oxidation. Here, we showed that oxidation of SAMHD1 increases ssDNA binding affinity and occurs in a cell cycle-dependent manner during S phase consistent with a role in HR. We determined the structure of oxidized SAMHD1 in complex with ssDNA. The enzyme binds ssDNA at the regulatory sites at the dimer interface. We propose a mechanism that oxidation of SAMHD1 acts as a functional switch to toggle between dNTPase activity and DNA binding.

SAMHD1 Phosphorylation at T592 Regulates Cellular Localization and S-phase Progression.

SAMHD1 activity is regulated by a network of mechanisms including phosphorylation, oxidation, oligomerization, and others. Significant questions remain about the effects of phosphorylation on SAMHD1 function and activity. We investigated the effects of a SAMHD1 T592E phosphorylation mimic on its cellular localization, catalytic activity, and cell cycle progression. We found that the SAMHD1 T592E is a catalytically active enzyme that is inhibited by protein oxidation. SAMHD1 T592E is retained in the nucleus at higher levels than the wild-type protein during growth factor-mediated signaling. This nuclear localization protects SAMHD1 from oxidation by cytoplasmic reactive oxygen species. The SAMHD1 T592E phosphomimetic further inhibits the cell cycle S/G2 transition. This has significant implications for SAMHD1 function in regulating innate immunity, antiviral response and DNA replication.