DDDR-13. MGMT FUNCTION DETERMINES THE DIFFERENTIAL RESPONSE OF ATR AND PARP INHIBITORS WITH DNA DAMAGING AGENTS FOR GBM THERAPY

Abstract

Abstract The most common cancer therapies including chemo- and radiation therapy are designed to induce cell death by DNA damage. However, DNA damage response (DDR) repair pathways initiated by tumor cells can resist the effect of anticancer drugs thus providing the rationale for combining DNA repair pathway inhibitors with radiation and DNA damaging anticancer drugs. The reliance of different cancer to different DDR mechanism can guide for targeted use of specific DDR inhibitor to maximize tumor cell killing. Here, we show the differential activities of two classes of DDR pathway inhibitors, Ataxia Telangiectasia- and Rad3-related kinase (ATRi) and poly(ADP-ribose) polymerases inhibitors (PARPi) across 20 glioma stem cell (GSC) lines. Using a panel of 3 ATRi, we identified a subgroup of GSCs, showing significant synergism with TMZ combination but resistant to ATRi single agent monotherapy. Interestingly, majority of the synergistic cell lines are associated with MGMT promoter methylation, suggesting that only tumor cells with no MGMT repair will benefit from ATR inhibition. Moreover, we also observe that PARPi + TMZ showed synergism only in MGMT unmethylated GSC cells suggesting that this synergism is a result of the dual function of PARPi in blocking BER repair and blocking MGMT PARylation thus abolishing MGMT mediated repair. Altogether, we believe MGMT methylation status in primary GBM could function as a strong biomarker for patient selection for ATRi or PARPi combination with TMZ in the clinic. We are currently exploring the activity of the triple combination of TMZ + PARPi + ATRi for the small subgroup of GSCs that do not show response to either TMZ + ATRi or PARPi + TMZ combinations.