Parg Inhibitors Exhibit Synthetic Lethality With Xrcc1 Deficiency And A Cellular Mechanism Of Action That Is Distinct From Parp Inhibition

Poly(ADP-ribose) glycohydrolase (PARG) hydrolyzes poly(ADP-ribose) (PAR) chains that are polymerized by PARP enzymes, completing the PAR cycle. Small molecule inhibitors of PARG result in a dose dependent increase in cellular PAR after DNA damage. Here we demonstrate that depletion of XRCC1, a scaffolding protein with an essential role in base-excision repair (BER), sensitizes cancer cells to PARG inhibition. XRCC1 deficient cells exhibit increased nuclear PAR foci in response to PARG inhibition even in the absence of DNA damaging agents. Inhibition of PARP1 with RNAi or small molecule inhibitors rescues cell growth inhibition and reduces the amount of cellular PAR accumulation in PARG inhibitor treated cells. This indicates that the cellular growth inhibition is dependent upon cellular PAR levels, demonstrating selectivity of the small molecule inhibitors for PARG. We hypothesized that inhibition of PAR hydrolysis could result in depletion of cellular NAD as this could prevent recycling of PAR to NAD. Consistent with this hypothesis, PARG inhibition enhanced NAD depletion after treatment of cells with the DNA damaging agent methyl methanesulfonate (MMS). Live cell imaging of XRCC1 depleted cells treated with a PARG inhibitor revealed that cells have large membrane protrusions, similar to the morphology of cells that have been treated with a NAMPT inhibitor, which results in depletion of cellular NAD. Furthermore, addition of the NAD precursor, nicotinamide mononucleotide (NMN) rescued proliferation of PARG inhibited cells. Taken together, these data support a hypothesis in which PARG inhibitors are cytotoxic to sensitive cancer cells via depletion of NAD, ultimately starving the cell of ATP. Thus, PARG inhibition is a novel strategy for exploiting synthetic lethality in cancer cells. The defects that sensitize cancer cells to PARG inhibition are distinct from those that sensitize to PARP inhibitors, namely defects in homology directed repair. Approximately 15% of breast cancer samples exhibit low or no XRCC1 by IHC. A subset (approximately 35%) of the XRCC1 low patient samples also have defects in BRCA1, suggesting that the majority of XRCC1 low tumors may not be responsive to PARP inhibitors. Small molecule PARG inhibitors are currently being evaluated for efficacy in XRCC1 low xenograft models. Citation Format: Leenus Martin, Tzuling Cheng, Dominic I. James, Habiba Begum, Kate M. Smith, Allan Jordan, Ian Waddell, Kedar Vaidya, Marcus Fischer, Bing Yao, Jason Drummond, Leah Cleary, Ruben Martinez, James Sutton, Nandini Ravindran, James Joseph, Eleni Venetsanakos, Michael Dillon, Jeffrey H. Hager, Lisa D. Belmont. PARG inhibitors exhibit synthetic lethality with XRCC1 deficiency and a cellular mechanism of action that is distinct from PARP inhibition [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2018; 2018 Apr 14-18; Chicago, IL. Philadelphia (PA): AACR; Cancer Res 2018;78(13 Suppl):Abstract nr 1943.