Abstract
TP53 deficiency in cancer is associated with poor patient outcomes and resistance to DNA damaging therapies. However, the mechanisms underlying treatment resistance in p53-deficient cells remain poorly characterized. Using live cell imaging of DNA double-strand breaks (DSBs) and cell cycle state transitions, we show that p53-deficient cells exhibit accelerated repair of radiomimetic-induced DSBs arising in S phase. Low-dose DNA-dependent protein kinase (DNA-PK) inhibition increases the S-phase DSB burden in p53-deficient cells, resulting in elevated rates of mitotic catastrophe. However, a subset of p53-deficient cells exhibits intrinsic resistance to radiomimetic-induced DSBs despite DNA-PK inhibition. We show that p53-deficient cells under DNA-PK inhibition utilize DNA polymerase theta (Pol θ)-mediated end joining repair to promote their viability in response to therapy-induced DSBs. Pol θ inhibition selectively increases S-phase DSB burden after radiomimetic therapy and promotes prolonged G2 arrest. Dual inhibition of DNA-PK and Pol θ restores radiation sensitivity in p53-deficient cells as well as in p53-mutant breast cancer cell lines. Thus, combination targeting of DNA-PK- and Pol θ-dependent end joining repair represents a promising strategy for overcoming resistance to DNA damaging therapies in p53-deficient cancers.
Highlights
TP53 is the most commonly mutated tumor suppressor gene [1]. p53 mediates pleiotropic tumorsuppressive effects through regulation of cell cycle arrest, apoptosis and cellular metabolism in response to cellular stress [2,3]
This study provides a detailed analysis of how p53 deficiency alters the kinetics of double-strand breaks (DSBs) repair after clastogenic therapy, as well as the relationship between therapeutic DSBs and cell cycle outcomes
Our study reveals independent roles for DNA-PK and Pol in repairing Sphase DSBs after radiomimetic treatment in p53-deficient cells, which collectively mediate radiation resistance (Figure 6F)
Summary
TP53 (gene product p53) is the most commonly mutated tumor suppressor gene [1]. p53 mediates pleiotropic tumorsuppressive effects through regulation of cell cycle arrest, apoptosis and cellular metabolism in response to cellular stress [2,3]. Several studies have demonstrated a role for p53 in suppressing homologous recombination (HR) repair, possibly through direct interactions with RPA and/or Rad51 [20,21] Consistent with these observations, p53-deficient HCT116 cells exhibit hyperactive HR activity and resistance to topoisomerase inhibitor therapy [22]. Expression of mutant p53 accelerates global DSB end joining rates and promotes error-prone microhomology-mediated end joining (MMEJ) [25,26,27] How these regulatory effects of p53 on DSB repair modulate radiation resistance remains poorly resolved. Our work recognizes a critical role for two targetable end joining repair pathways––NHEJ and TMEJ––in mediating resistance to DNA damaging therapy in p53-deficient cells
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