Abstract 2077: A novel assay for PARP-DNA trapping provides insights into the mechanism of action (MoA) of clinical PARP inhibitors (PARPi)

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Abstract Treatments with PARPi in cancers with impaired DNA repair mechanisms (i.e. with Homologous Recombination Repair Deficiency, HRD) causes unsupportable genomic instability resulting in tumor cell death. PARPi act via a dual mechanism: 1) they block PARylation activity that normally occurs in response to DNA damage; 2) they trap PARP onto DNA lesions creating potentially cytotoxic PARP-DNA complexes. The longer PARP is inhibited and trapped onto the DNA, the greater the cytotoxic effect of PARPi in preclinical models. However, differences in preclinical PARP trapping potency have not translated into increased clinical efficacy with standard clinical doses used. Therefore, the ability to assess PARP-chromatin trapping in cancer models is critical for understanding the MoA of existing clinical PARPi. To date, this has been achieved by low throughput assays in non-HRD models using high PARPi concentrations and the addition of exogenous DNA damage. Here, we describe the development of a novel assay, a high throughput in situ cell extraction platform, where PARP-chromatin trapping is monitored by immunofluorescence and can be multiplexed with the analysis of other relevant biomarkers. Our novel assay has several advantages compared to conventional methods: the overall experimental process is simpler and less time consuming with results being quantitative and less error prone. Most importantly, the higher throughput allows a thorough evaluation of PARP1-chromatin trapping kinetics and their effects with dose-response in a time-dependent manner for clinical PARPi following both continuous treatment or after a wash out of drug. Using this new assay, we tested the kinetics in isogenic cell line pairs (BRCA2-/- and WT) and followed in parallel the appearance of biomarkers of DNA damage (e.g. γ-H2AX). The data have revealed important elements of differentiation between the MoA of clinical PARPi including the important insight that the strongest PARP trapper (talazoparib) has clearly reduced cytotoxic specificity for HRD cells, which likely explains the significantly reduced dose used in the clinic compared to other PARPi. These along with other data presented highlight how this next generation PARP trapping assays can provide important insights into PARPi MoA. Citation Format: Giuditta Illuzzi, Mark J O'Connor, Elisabetta Leo. A novel assay for PARP-DNA trapping provides insights into the mechanism of action (MoA) of clinical PARP inhibitors (PARPi) [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2019; 2019 Mar 29-Apr 3; Atlanta, GA. Philadelphia (PA): AACR; Cancer Res 2019;79(13 Suppl):Abstract nr 2077.