Graphical AbstractHighlights d Ubp10 and Ubp12 DUBs remove ubiquitin from PCNA K164 with distinct chain preferences d Fork association of Ubp10, but not Ubp12, depends on PCNA binding to lagging strands d PCNA-DUBs counteract template switch and Rev1 TLS factor binding to replication forks d Ubp10-and Ubp12-mediated PCNA K164 deubiquitylation promotes processive DNA replication SUMMARY DNA damage tolerance plays a key role in protecting cell viability through translesion synthesis and template switching-mediated bypass of genotoxic polymerase-blocking base lesions. Both tolerance pathways critically rely on ubiquitylation of the proliferating-cell nuclear antigen (PCNA) on lysine 164 and have been proposed to operate uncoupled from replication. We report that Ubp10 and Ubp12 ubiquitin proteases differentially cooperate in PCNA deubiquitylation, owing to distinct activities on PCNAlinked ubiquitin chains. Ubp10 and Ubp12 associate with replication forks in a fashion determined by Ubp10 dependency on lagging-strand PCNA residence, and they downregulate translesion polymerase recruitment and template switch events engaging nascent strands. These findings reveal PCNA K164 deubiquitylation as a key mechanism for the modulation of lesion bypass during replication, which might set a framework for establishing strand-differential pathway choices. We propose that damage tolerance is tempered at replication forks to limit the extension of bypass events and sustain chromosome replication rates.
Proliferating-cell nuclear antigen (PCNA) is a DNA sliding clamp with an essential function in DNA replication and a key role in tolerance to DNA damage by ensuring the bypass of lesions. In eukaryotes, DNA damage tolerance is regulated by ubiquitylation of lysine 164 of PCNA through a well-known control mechanism; however, the regulation of PCNA deubiquitylation remains poorly understood. Our work is a systematic and functional study on PCNA deubiquitylating enzymes (DUBs) in Schizosaccharomyces pombe. Our study reveals that the deubiquitylation of PCNA in fission yeast cells is a complex process that requires several ubiquitin proteases dedicated to the deubiquitylation of a specific subnuclear fraction of mono- and di-ubiquitylated PCNA or a particular type of poly-ubiquitylated PCNA and that there is little redundancy among these enzymes. To understand how DUB activity regulates the oscillatory pattern of ubiquitylated PCNA in fission yeast, we assembled multiple DUB mutants and found that a quadruple mutation of ubp2+, ubp12+, ubp15+, and ubp16+ leads to the stable accumulation of mono-, di-, and poly-ubiquitylated forms of PCNA, increases S-phase duration, and sensitizes cells to DNA damage. Our data suggest that the dynamic ubiquitylation and deubiquitylation of PCNA occurs during S-phase to ensure processive DNA replication.
FAM111A is a replisome associated protein and dominant mutations within its trypsinlike peptidase domain are linked to severe human developmental syndromes. However, FAM111A functions and its putative substrates remain largely unknown. Here, we showed that FAM111A promotes origin activation and interacts with the putative peptidase FAM111B, and we identified the first potential FAM111A substrate, the suicide enzyme HMCES. Moreover, unrestrained expression of FAM111A wild-type and patient mutants impaired DNA replication and caused cell death only when the peptidase domain remained intact. Altogether our data reveal how FAM111A promotes DNA replication in normal conditions and becomes harmful in a disease context.
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