Fu, YuanLong, Marcus J. C.Wisitpitthaya, SomsineeInayat, HumaPierpont, Timothy M.Elsaid, Islam M.Bloom, Jordana C.Ortega, JoaquinWeiss, Robert S.Aye, Yimon2018-12-132018-12-132018-12-132018-10-0110.1038/s41589-018-0113-5https://infoscience.epfl.ch/handle/20.500.14299/152106WOS:000444714600012Since the origins of DNA-based life, the enzyme ribonucleotide reductase (RNR) has spurred proliferation because of its rate-limiting role in de novo deoxynucleoside-triphosphate (dNTP) biosynthesis. Paradoxically, the large subunit, RNR-alpha, of this obligatory two-component complex in mammals plays a context-specific antiproliferative role. There is little explanation for this dichotomy. Here, we show that RNR-alpha has a previously unrecognized DNA-replication inhibition function, leading to growth retardation. This underappreciated biological activity functions in the nucleus, where RNR-alpha interacts with ZRANB3. This process suppresses ZRANB3's function in unstressed cells, which we show to promote DNA synthesis. This nonreductase function of RNR-alpha is promoted by RNR-alpha hexamerization-induced by a natural and synthetic nucleotide of dA/ClF/CLA/FLU-which elicits rapid RNR-alpha nuclear import. The newly discovered nuclear signaling axis is a primary defense against elevated or imbalanced dNTP pools that can exert mutagenic effects irrespective of the cell cycle.Biochemistry & Molecular BiologyBiochemistry & Molecular Biologyhuman ribonucleotide reductaseimage-processing packagelung-cancerelectron-microscopyreplication stressmammalian-cellsdna-damageallosteric regulationlarge subunits-phasetext::journal::journal article::research article