Abstract PR001: Oncogene-induced matrix reorganization controls CD8+ T cell immunity in the UPS microenvironment

CD8+ T cell dysfunction, characterized by reduced effector function, impaired proliferation, and inhibitory receptor upregulation, is a fundamental barrier to anti-tumor immunity. However, molecular mechanisms underlying the regulation of CD8+ T cell dysfunction in the tumor microenvironment (TME) are incompletely understood. In solid cancers, the extracellular matrix (ECM) facilitates tumor progression in part by inhibiting T cell migration/infiltration, but the impact of individual tumor-associated ECM molecules on T cell function remains unclear. Therefore, we investigated the regulation and impact of ECM composition on CD8+ T cell function in muscle-derived undifferentiated pleomorphic sarcoma (UPS). UPS exhibits durable responses to checkpoint therapy in a subset of human patients, potentially offering valuable insights into strategies for ameliorating T cell function and improving patient responses to immunotherapy. Using the autochthonous Kras G12D/+; Trp53 fl/fl (KP) murine model of UPS, we previously showed that deletion of the central Hippo pathway effector Yap1 (Kras G12D/+; Trp53 fl/fl; Yap1 fl/fl; KPY) suppressed UPS cell proliferation and tumor progression. Given the well-established role of Yap1 in mechanotransduction, we leveraged this system to investigate the effects of Yap1 on the ECM and CD8+ T cell function in UPS. We discovered that loss of UPS-cell intrinsic Yap1 reduced the proportion of dysfunctional CD8+ T cells in the TME and enhanced T cell cytolytic capacity. Yap1 loss also downregulated expression of multiple collagen genes in UPS cells and bulk tumors, including those that encode collagen type VI (ColVI). ColVI is a beaded microfilament collagen that binds to fibril-forming collagens in the ECM, such as collagen type I (ColI), and has been implicated in the pathogenesis of skeletal muscle myopathies. These data suggest that proper ColVI structure and function are critical for normal skeletal muscle physiology, with important implications for muscle-derived tumors such as UPS. Accordingly, COL6A1 was upregulated in human UPS relative to normal skeletal muscle, and inversely associated with UPS patient survival. Moreover, loss of UPS cell-intrinsic Col6a1 suppressed tumor progression, enhanced T cell cytolytic function, and attenuated CD8+ T cell exhaustion, phenocopying the effects of Yap1 deletion. Mechanistically, Yap1-mediated ColVI deposition promoted CD8+ T cell dysfunction by remodeling ColI networks in the UPS TME, and