p15(PAF) binding to PCNA modulates the DNA sliding surface

p15(PAF) is an oncogenic intrinsically disordered protein that regulates DNA replication and lesion bypass by interacting with the human sliding clamp PCNA. In the absence of DNA, p15(PAF) traverses the PCNA ring via an extended PIP-box that contacts the sliding surface. Here, we probed the atomic-scale structure of p15(PAF)–PCNA–DNA ternary complexes. Crystallography and MD simulations show that, when p15(PAF) occupies two subunits of the PCNA homotrimer, DNA within the ring channel binds the unoccupied subunit. The structure of PCNA-bound p15(PAF) in the absence and presence of DNA is invariant, and solution NMR confirms that DNA does not displace p15(PAF) from the ring wall. Thus, p15(PAF) reduces the available sliding surfaces of PCNA, and may function as a belt that fastens the DNA to the clamp during synthesis by the replicative polymerase (pol δ). This constraint, however, may need to be released for efficient DNA lesion bypass by the translesion synthesis polymerase (pol η). Accordingly, our biochemical data show that p15(PAF) impairs primer synthesis by pol η–PCNA holoenzyme against both damaged and normal DNA templates. In light of our findings, we discuss the possible mechanistic roles of p15(PAF) in DNA replication and suppression of DNA lesion bypass.