Wwox Binding to the Murine Brca1-BRCT Domain Regulates Timing of Brip1 and CtIP Phospho-Protein Interactions with This Domain at DNA Double-Strand Breaks, and Repair Pathway Choice.

Wwox-deficient human cells show elevated homologous recombination, leading to resistance to killing by double-strand break-inducing agents. Human Wwox binds to the Brca1 981-PPLF-984 Wwox-binding motif, likely blocking the pChk2 phosphorylation site at Brca1-S988. This phosphorylation site is conserved across mammalian species; the PPLF motif is conserved in primates but not in rodents. We now show that murine Wwox does not bind Brca1 near the conserved mouse Brca1 phospho-S971 site, leaving it open for Chk2 phosphorylation and Brca1 activation. Instead, murine Wwox binds to Brca1 through its BRCT domain, where pAbraxas, pBrip1, and pCtIP, of the A, B, and C binding complexes, interact to regulate double-strand break repair pathway response. In Wwox-deficient mouse cells, the Brca1-BRCT domain is thus accessible for immediate binding of these phospho-proteins. We confirm elevated homologous recombination in Wwox-silenced murine cells, as in human cells. Wwox-deficient murine cells showed increased ionizing radiation-induced Abraxas, Brca1, and CtIP foci and long resected single-strand DNA, early after ionizing radiation. Wwox deletion increased the basal level of Brca1-CtIP interaction and the expression level of the MRN-CtIP protein complex, key players in end-resection, and facilitated Brca1 release from foci. Inhibition of phospho-Chk2 phosphorylation of Brca1-S971 delays the end-resection; the delay of premature end-resection by combining Chk2 inhibition with ionizing radiation or carboplatin treatment restored ionizing radiation and platinum sensitivity in Wwox-deficient murine cells, as in human cells, supporting the use of murine in vitro and in vivo models in preclinical cancer treatment research.

Interaction of Wwox with Brca1 and associated complex proteins prevents premature resection at double-strand breaks and aberrant homologous recombination.

Down regulation of Wwox protein expression occurs in many cancers, contributing to insensitivity to ionizing radiation (IR) and platinum drug treatments. Patients with reduced Wwox expression in their cancer tissue show decreased overall survival following these treatments, in accord with our earlier finding that reduced Wwox protein expression in cancers is associated with changes in choice of DNA double-strand break (DSB) repair pathway. Our current investigation of mechanisms underlying the initial choice of repair by homologous recombination/single-strand annealing (HR/SSA) in Wwox-deficient cells, showed immediate DNA end-resection at DSBs following IR, abrogating initial repair by the expected non-homologous end-joining (NHEJ) pathway. Mechanisms supporting the expected choice of DSB repair by NHEJ in Wwox-sufficient cells are: 1) direct recruitment of Wwox protein binding to Brca1 through the Brca1 981PPLF984 Wwox-binding motif; 2) possible Wwox blocking of Brca1-Rad50 interaction and of Brca1 activation by Chk2 phosphorylation of Brca1 S988; 3) Wwox suppression of Brca1 interaction with the B and C complex proteins, Brip1 and CtIP, thereby delaying the process of DSB end-resection post-IR. Wwox deficiency, instead, leads to early formation of the Brca1-CtIP/MRN complex at induced DSBs, stimulating immediate post-IR end-resection. This premature resection at DNA DSBs leads to inappropriate HR/SSA repair not restricted to late S/G2 cell cycle phases, and increases mutations in genomes of radiation or platinum-resistant colonies. Prevention of premature initiation of end-resection, by combining Chk2 inhibition with IR or carboplatin treatment, successfully sensitized IR and platinum-resistant Wwox-deficient cells by synthetic lethality, but did not alter response of Wwox-sufficient cells. Our results establish Wwox as a biomarker for treatment response and provide potential targets, such as Chk2, for reversal of treatment resistance.