Tumor-intrinsic PD-L1 reduces actin cytoskeleton polymerization to promote mTORC1 signals driving tumor stemness

Abstract

Abstract Tumor-intrinsic PD-L1 signals contribute to tumor virulence and pathology, but mechanisms are poorly understood. We previously showed that tumor-intrinsic PD-L1 increases mTORC1 and tumor initiating cell (TIC) generation and function in ovarian cancer and melanoma. We used CRISPR/Cas9 (KO) and shRNA (lo) to reduce PD-L1 in mouse melanoma (B16) and ovarian cancer (ID8agg), and human ovarian cancer (ES2). PD-L1lo reduced mTORC1 and TIC as expected, but unexpectedly increased actin polymerization and filopodia, and altered cell morphology. The actin depolymerizing agents Latrunculin-A or Cytochalasin-D reversed actin polymerization in PD-L1lo ID8agg cells and increased mTORC1 (p-rpS6) without affecting mTORC2 (pAktS473). Latrunculin-A and Cytochalasin-D increased TIC numbers and stemness gene expression (Oct4) in PD-L1lo ID8agg cells with no effect on control ID8agg cells. Similar actin effects were seen in PD-L1KO B16 and PD-L1KO ES2. To confirm TIC function, Latrunculin-A increased tumorospheres (TIC self-renewal function) in PD-L1lo, but not control ID8agg cells. The mTORC1 inhibitor rapamycin reduced TIC numbers and functions with no effect on actin polymerization, suggesting mTORC1 is downstream of actin polymerization. Rptorlo ID8agg cells (with low mTORC1 signaling) did not exhibit the PD-L1lo actin polymerization, nor did Latrunculin-A increase Rptorlo ID8agg TIC numbers, tumorospheres, or stemness genes, confirming the flow of signals is PD-L1 to actin to mTORC1 to TIC (stemness). Our data define a highly novel tumor virulence control mechanism of cell-intrinsic PD-L1 through inhibiting actin polymerization suggesting new drug discovery targets. Preliminary data show some similar effects of tumor PD-1.