Identification of a novel REV1-interacting motif necessary for DNA polymerase kappa function.

When a replicative DNA polymerase (Pol) is stalled by damaged DNA, a "polymerase switch" recruits specialized translesion synthesis (TLS) DNA polymerase(s) to sites of damage. Mammalian cells have several TLS DNA polymerases, including the four Y-family enzymes (Poleta, Poliota, Polkappa and REV1) that share multiple primary sequence motifs, but show preferential bypass of different DNA lesions. REV1 interacts with Poleta, Poliota, and Polkappa and therefore appears to play a central role during TLS in vivo. Here we have investigated the molecular basis for interactions between REV1 and Polkappa. We have identified novel REV1-interacting regions (RIRs) present in Polkappa, Poliota and Poleta. Within the RIRs, the presence of two consecutive phenylalanines (FF) is essential for REV1-binding. The consensus sequence for REV1-binding is denoted by x-x-x-F-F-y-y-y-y (x, no specific residue and y, no specific residue but not proline). Our results identify structural requirements that are necessary for FF-flanking residues to confer interactions with REV1. A Polkappa mutant lacking REV1-binding activity did not complement the genotoxin-sensitivity of Polk-null mouse embryonic fibroblast cells, thereby demonstrating that the REV1-interaction is essential for Polkappa function in vivo.

DNA damage-induced ubiquitylation of RFC2 subunit of replication factor C complex.

Many proteins involved in DNA replication and repair undergo post-translational modifications such as phosphorylation and ubiquitylation. Proliferating cell nuclear antigen (PCNA; a homotrimeric protein that encircles double-stranded DNA to function as a sliding clamp for DNA polymerases) is monoubiquitylated by the RAD6-RAD18 complex and further polyubiquitylated by the RAD5-MMS2-UBC13 complex in response to various DNA-damaging agents. PCNA mono- and polyubiquitylation activate an error-prone translesion synthesis pathway and an error-free pathway of damage avoidance, respectively. Here we show that replication factor C (RFC; a heteropentameric protein complex that loads PCNA onto DNA) was also ubiquitylated in a RAD18-dependent manner in cells treated with alkylating agents or H(2)O(2). A mutant form of RFC2 with a D228A substitution (corresponding to a yeast Rfc4 mutation that reduces an interaction with replication protein A (RPA), a single-stranded DNA-binding protein) was heavily ubiquitylated in cells even in the absence of DNA damage. Furthermore RFC2 was ubiquitylated by the RAD6-RAD18 complex in vitro, and its modification was inhibited in the presence of RPA. The inhibitory effect of RPA on RFC2 ubiquitylation was relatively specific because RAD6-RAD18-mediated ubiquitylation of PCNA was RPA-insensitive. Our findings suggest that RPA plays a regulatory role in DNA damage responses via repression of RFC2 ubiquitylation in human cells.