Project description:The hostile tumor microenvironment (TME) is major challenge for cancer immunotherapies. Here, we design and perform TME-targeted in vivo CRISPR activation (CRISPRa) screens to uncover factors that promote anti-tumor immunity, culminating in rationally designed immune gene therapy combinations. Through adeno-associated virus (AAV) delivery, we find that multiplexed activation of pooled immunoregulatory genes encoding antigen presentation, cytokine, and co-stimulation molecules (APCM) leads to enhanced anti-tumor immunity. A CRISPRa screen targeting APCM genes in metastatic tumors identifies CD80, TNFSF14, CXCL10, TNFSF18, TNFSF9, and IFNG as the top immunostimulatory candidates. Further optimization pinpoints 4-1BBL(TNFSF9) + IFNG + IL12B (4II) as a potent streamlined therapeutic combination. AAV delivered 4II has potent in vivo anti-tumor efficacy in multiple tumor models, by enhancing tumor antigen presentation while simultaneously promoting the infiltration, activation, and expansion of anti-tumor T cells. We further demonstrate that APCM therapy synergizes with CAR-T therapy against human solid tumors in vivo. CRISPRa screens and gene activation systems targeting APCM factors thus represent a powerful approach for rapid development of off-the-shelf immune gene therapies against solid tumors.

Project description:The hostile tumor microenvironment (TME) is major challenge for cancer immunotherapies. Here, we design and perform TME-targeted in vivo CRISPR activation (CRISPRa) screens to uncover factors that promote anti-tumor immunity, culminating in rationally designed immune gene therapy combinations. Through adeno-associated virus (AAV) delivery, we find that multiplexed activation of pooled immunoregulatory genes encoding antigen presentation, cytokine, and co-stimulation molecules (APCM) leads to enhanced anti-tumor immunity. A CRISPRa screen targeting APCM genes in metastatic tumors identifies CD80, TNFSF14, CXCL10, TNFSF18, TNFSF9, and IFNG as the top immunostimulatory candidates. Further optimization pinpoints 4-1BBL(TNFSF9) + IFNG + IL12B (4II) as a potent streamlined therapeutic combination. AAV delivered 4II has potent in vivo anti-tumor efficacy in multiple tumor models, by enhancing tumor antigen presentation while simultaneously promoting the infiltration, activation, and expansion of anti-tumor T cells. We further demonstrate that APCM therapy synergizes with CAR-T therapy against human solid tumors in vivo. CRISPRa screens and gene activation systems targeting APCM factors thus represent a powerful approach for rapid development of off-the-shelf immune gene therapies against solid tumors.

Project description:TGFb signaling is a major pathway associated with poor clinical outcome in patients with advanced metastatic cancers and non-response to immune checkpoint blockade, particularly in the immune-excluded tumor phenotype. While previous pre-clinical studies demonstrated that converting tumors from an excluded to an inflamed phenotype and curative anti-tumor immunity require attenuation of both PD-L1 and TGFb signaling, the underlying cellular mechanisms remain unclear. Recent studies suggest that stem cell-like CD8 T cells (TSCL) can differentiate into non-exhausted CD8 T effector cells that drive durable anti-tumor immunity. Here, we show that TGFb and PD-L1 restrain TSCL expansion as well as replacement of progenitor exhausted and dysfunctional CD8 T cells with non-exhausted IFNghi CD8 T effector cells in the tumor microenvironment (TME). Blockade of TGFb and PD-L1 generated IFNghi CD8 T effector cells with enhanced motility, enabling both their accumulation in the TME and increased interaction with other cell types. Ensuing IFNg signaling markedly transformed myeloid, stromal, and tumor niches to yield a broadly immune-supportive ecosystem. Blocking IFNg completely abolished the effect of anti-PD-L1/ TGFb combination therapy. Our data suggest that TGFb works in concert with PD-L1 to prevent TSCL expansion and replacement of exhausted CD8 T cells with fresh CD8 T effector cells, thereby maintaining the CD8 T cell compartment in a dysfunctional state.

Project description:We devise Multiplex Universal Combinatorial Immunotherapy via Gene-silencing (MUCIG), as a versatile approach for combinatorial cancer immunotherapy. We harness CRISPR-Cas13d to efficiently target multiple endogenous immunosuppressive genes on demand, allowing us to silence various combinations of multiple immunosuppressive factors in the TME. Intra-tumoral AAV-mediated administration of MUCIG elicits significant anti-tumor activity with several Cas13d gRNA compositions (AAV-Cas13d-MUCIG). Optimization of TME targets by expression analysis led to a simplified off-the-shelf MUCIG targeting a four gene combination (PGGC: Pdl1/Cd274, Galectin9/Lgals9, Galectin3/Lgals3 and Cd47). AAV-Cas13d-PGGC showed significant in vivo anti-tumor efficacy in syngeneic tumor models. Single cell and flow profiling revealed that AAV-Cas13d-PGGC remodeled the TME by increasing CD8+ T cell infiltration and reducing neutrophils. MUCIG thus serves as a universal method to silence multiple immune genes in vivo, and can be delivered via AAV as a therapeutic approach. We devised an approach MUCIG (Multiplex Universal Combinatorial Immunotherapy via Gene-silencing) and designed MUCIG for targeting immunosuppressive genes at different scales of library pools. The first MUCIG pool included 313 genes selected based on these criteria. Subsequently, with a tiered approach, we designed three additional MUCIG pools (pool2: 152 genes; pool3: 55 genes; pool4: 19 genes). The distribution and coverage of gRNAs across all four pools were verified, confirming the robustness and specificity of this approach in the context of cancer immunosuppressive gene targeting therapy.

Project description:Recombinant cytokines have limited anti-cancer efficacy mostly due to narrow therapeutic window and systemic adverse effects. IL-18 is an inflammasome induced proinflammatory cytokine that enhances T and NK cell activity and stimulates IFNg production. The activity of IL-18 is naturally blocked by a high affinity endogenous binding protein (IL-18BP). IL-18BP is induced in the tumor microenvironment (TME) in response to IFNg upregulation in a negative feedback mechanism. In this study we found that IL-18 is upregulated in the TME compared to the periphery across multiple human tumors and most of it is bound to IL-18BP. Bound IL-18 levels were largely above the amount required for T cell activation in vitro, implying that releasing IL-18 in the TME could lead to potent T cell immune activation. To restore the activity of endogenous IL-18 we generated COM503, a high affinity anti-IL-18BP antibody (Ab), that blocks the IL-18BP:IL-18 interaction and displaces pre-complexed IL-18 to enhance T cell and NK cell activation. In vivo, administration of a surrogate anti-IL-18BP Ab, either alone or in combination with anti-PD-L1 Ab, resulted in significant tumor growth inhibition and increased survival across multiple mouse tumor models. Moreover, anti-IL-18BP Ab induced pronounced TME-localized immune modulation including an increase in polyfunctional non-exhausted T and NK cell numbers and activation. In contrast, no increase in inflammatory cytokines and lymphocyte numbers or activation state was observed in serum and spleen. Taken together, blocking IL-18BP using an Ab is a promising novel approach to harness cytokine biology for the treatment of cancer.

Project description:Tumor-infiltrating lymphocytes (TILs) are considered to be exhausted, lacking proliferative and effector functions, which impairs cancer immunity. We employed single-cell mass cytometry and tissue imaging technologies to dissect TILs in 25 resectable and 35 advanced non-small cell lung cancer (NSCLC) patients. We identified a phenotypically burn-out CD8 TIL subset (Ebo), specifically accumulated within the tumor microenvironment (TME). In contrast to exhausted T-cells, Ebo appears to be the most proliferative TIL subset. Furthermore, Ebo showed the highest expression of activation markers, but it was more apoptotic and produced less IFNg than other CD8 TIL subsets. Using a humanized patient-derived tumor xenograft model, we demonstrated that Ebo expansion occurred within the TME in a PD-pathway dependent manner. Importantly, Ebo abundance in baseline tumor tissues was associated with resistance to anti-PD therapy in NSCLC patients. Our study identified a dysfunctional TIL subset, distinct from exhausted T-cells, and implies strategies to overcome resistance in cancer immunotherapy.

Project description:Immune checkpoint inhibitors (ICIs) have transformed the treatment of melanoma. However, the majority of patients have primary or acquired resistance to ICIs, limiting durable responses and patient survival. Interferon-gamma (IFNg) signaling and the expression of IFNg-stimulated genes correlate with either response or resistance to ICIs, in a context-dependent manner. While IFNg-inducible immunostimulatory genes are required for response to ICIs, chronic IFNg signaling induces the expression of immunosuppressive genes, promoting resistance to these therapies. Here, we show that high levels of ULK1 correlate with poor survival in melanoma patients and overexpression of ULK1 in melanoma cells enhances IFNg-induced expression of immunosuppressive genes, with minimal effects on the expression of immunostimulatory genes. In contrast, genetic or pharmacological inhibition of ULK1 reduces expression of IFNg-induced immunosuppressive genes. ULK1 binds IRF1 in the nuclear compartment of melanoma cells, controlling its binding to the PD-L1 promoter region. Additionally, pharmacological inhibition of ULK1 in combination with anti-PD-1 therapy further reduces melanoma tumor growth and enhances anti-tumor immune responses in vivo. Our data suggest that targeting ULK1 represses IFNg-dependent immunosuppression. These findings support the combination of ULK1 drug-targeted inhibition with ICIs for the treatment of melanoma patients to improve response rates and patient outcomes.

Project description:We develop a system for bidirectional epigenetic editing (CRISPRai), in which orthogonal activating (CRISPRa) and repressive (CRISPRi) perturbations are applied simultaneously to multiple loci the same cell. We perform CRISPR gRNA enrichment screens to investigate pairwise CRISPRai perturbations of enhancers and the promoter of IL2 and IFNG genes in order to investigate enhancer-enhancer and enhancer-promoter interactions and regulatory element heirarchies.

Project description:Multiplexed activation of endogenous genes by CRISPRa elicits potent anti-tumor immunity

Project description:Multiplexed activation of endogenous genes by CRISPRa elicits potent anti-tumor immunity