Intracellular PD-L1 regulates DNA damage checkpoints and suppresses Chk1 and PARP inhibitor synthetic lethality

Abstract

Abstract Tumor PD-L1 mediates non-canonical, intracellular signals including the DNA damage response (DDR), of unclear significance and mechanisms. We show that genetic PD-L1 depletion (PD-L1KO) destabilized the Chk2 protein, a DNA damage response (DDR) factor, resulting in ATM/Chk2 pathway defects but not ATR/Chk1 in melanoma, bladder, breast, and ovarian cancer. Consistent with ATM/Chk2 defects, PD-L1 KO led to DNA damage (γH2AX) and impaired homologous recombination (HR) (p-RPA32, BRCA1, Rad51 foci). Thus, PD-L1 KO vs control cells were significantly more sensitive to DDR inhibitors (DDRi) against ATR, Chk1, and PARP in vitro and in vivo in NSG mice. Chk2 regulation by PD-L1 was independent of PD-L1 cytoplasmic tail yet required intracellular (vs surface) PD-L1 suggesting physical PD-L1/Chk2 interaction supported by IP and imaging. PD-L1 stabilized Chk2 protein by preventing its lysosomal degradation without altering Chek2 mRNA. αPD-L1 is thought to work by protecting PD-L1 induced anti-tumor T cell suppression via PD-1, but PD-L1 DDR effects were PD-1-independent. Intracellular PD-L1 suppressed DDRi induced cGAS/STING activation by immunoblots and qRT-PCR of type 1 IFN genes. In vivo in WT mice, genetic PD-L1 depletion but not αPD-L1, sensitized highly immunotherapy resistant 4T1 breast cancer to PARPi. Strikingly, PARPi had reduced effect on PD-L1KO tumors in RAG2KO mice despite treating WT mice, indicating a strong immune component to DDRi efficacy. Our work implicates a novel role of intracellular PD-L1 in DDR and tumor immunogenicity and identifies related therapeutic vulnerabilities exposed by intracellular PD-L1 targeting. Surface vs intracellular PD-L1, and specific DDR signals could be treatment response biomarkers.