Project description:Glioblastoma multiforme (GBM) is an aggressive brain tumour. Current immunotherapy approaches have been unsuccessful, highlighting the need to determine underlying mechanisms of immune evasion. Here, we developed syngeneic immunocompetent mouse models of GBM to explore this. GBM stem cells (GSCs) were serially transplanted through immunocompetent hosts, which uncovered an acquired capability to escape immune clearance through an enhanced immunosuppressive tumour microenvironment. Mechanistically, this was not elicited via genetic selection of tumour subclones, but through an epigenetic immunoediting process wherein stable transcriptional and epigenetic changes in GSCs are enforced following immune attack. These include activation of interferon signalling modules, myeloid-affiliated transcription factors and chemokines, which leads to increased recruitment of tumour-associated macrophages. Furthermore, we identify similar epigenetic and transcriptional signatures in human mesenchymal subtype GSCs. We conclude that epigenetic immunoediting may drive an acquired immune evasion program in the most aggressive mesenchymal GBM subtype by reshaping the tumour immune microenvironment.

Project description:Glioblastoma multiforme (GBM) is an aggressive brain tumour. Current immunotherapy approaches have been unsuccessful, highlighting the need to determine underlying mechanisms of immune evasion. Here, we developed syngeneic immunocompetent mouse models of GBM to explore this. GBM stem cells (GSCs) were serially transplanted through immunocompetent hosts, which uncovered an acquired capability to escape immune clearance through an enhanced immunosuppressive tumour microenvironment. Mechanistically, this was not elicited via genetic selection of tumour subclones, but through an epigenetic immunoediting process wherein stable transcriptional and epigenetic changes in GSCs are enforced following immune attack. These include activation of interferon signalling modules, myeloid-affiliated transcription factors and chemokines, which leads to increased recruitment of tumour-associated macrophages. Furthermore, we identify similar epigenetic and transcriptional signatures in human mesenchymal subtype GSCs. We conclude that epigenetic immunoediting may drive an acquired immune evasion program in the most aggressive mesenchymal GBM subtype by reshaping the tumour immune microenvironment.

Project description:Cancers evade the immune system in order to grow or metastasise through the process of cancer immunoediting. While checkpoint inhibitor therapy has been effective for reactivating tumour immunity in some cancers, many solid cancers, including breast cancer, remain largely non-responsive. Understanding the way non-responsive cancers evolve to evade immunity, what resistance pathways are activated and whether this occurs at the clonal level will improve immunotherapeutic design. We tracked cancer cell clones during the immunoediting process and determined clonal transcriptional profiles that allow immune evasion in murine mammary tumour growth in response to immunotherapy with anti-PD1 and anti-CTLA4. Clonal diversity was significantly restricted by immunotherapy treatment at both the primary and metastatic sites. These findings demonstrate that immunoediting selects for pre-existing breast cancer cell populations, that immunoediting is not a static process and is ongoing during metastasis and immunotherapy treatment. Isolation of immunotherapy resistant clones revealed unique and overlapping transcriptional signatures. The overlapping gene signature was predictive of poor survival in basal-like breast cancer patient cohorts. Some of these overlapping genes have existing small molecules which can be used to potentially improve immunotherapy response.

Project description:Glioblastoma (GBM) is a lethal brain cancer composed of heterogeneous cellular populations including glioma stem cells (GSCs) and their progeny differentiated non-stem glioma cells (NSGCs). Although accumulating evidence points out the significance of GSCs for tumour initiation and propagation, the roles of NSGCs remain elusive. Here we demonstrate that, when patient-derived GSCs in GBM tumours undergo differentiation with diminished telomerase activity and shortened telomeres, they subsequently become senescent phenotype, thereby secreting angiogenesis-related proteins, including vascular endothelial growth factors. Interestingly, these secreted factors from senescent NSGCs promote proliferation of human umbilical vein endothelial cells and tumorigenic potentials of GSCs in immunocompromised mice. These experimental data are likely clinically-relevant, since immunohistochemistry of both patient tumours of GBM and the patient GSC-derived mouse xenografted tumours detected tumour cells that express a set of markers for the senescence phenotype. Collectively, our data suggest that the inter-cellular signals from senescent NSGCs promote GBM tumour angiogenesis thereby increasing malignant progression of GBM. We monitored gene expression profiling in GSC, differentiated NSGC (GSC at day7 after serum exposure), and senescent NSGC (GSC at day30 after serum exposure) of GBM146 and GBM157.

Project description:To investigate immunoediting at the primary tumour, we used DNA barcoding combined with NGS. By stably integrating 4T1 murine cancer cell line with 5000 unique DNA barcodes (1 barcode per cell), we can trace how barcode (and therefore subclonal) diversity changes over time and in reponse to the endogenous immune system in immunocompetent mice compared to immunocompromised mice.

Project description:Glioblastoma (GBM), an aggressive brain malignancy with a cellular hierarchy dominated by GBM stem cells (GSCs), evades anti-tumor immunity through mechanisms that remain incompletely understood. Like most cancers, GBMs undergo metabolic reprogramming towards glycolysis to generate lactate. Here, we show that lactate production by patient-derived GSCs and microglia induces tumor cell epigenetic reprogramming through histone lactylation, an activating modification that leads to immunosuppressive transcriptional programs and suppression of microglial phagocytosis via transcriptional upregulation of CD47, a “don’t eat me” signal, in GBM cells. Leveraging these findings, pharmacologic targeting of lactate production augments efficacy of anti-CD47 therapy. Mechanistically, lactylated histone interacts with the heterochromatin component chromobox protein homolog 3 (CBX3). Although CBX3 does not possess direct lactyltransferase activity, CBX3 binds histone acetyltransferase (HAT) P300 to induce increased P300 substrate specificity toward lactyl-coA and a transcriptional shift toward an immunosuppressive cytokine profile. Targeting CBX3 inhibits tumor growth by both tumor cell-intrinsic mechanisms and increased tumor cell phagocytosis. Collectively, these results suggest that lactate mediates a metabolism-induced epigenetic reprogramming in GBM that contributes to CD47-dependent immune evasion, which can be leveraged to augment efficacy of immune-oncology therapies.

Project description:Glioblastoma (GBM), an aggressive brain malignancy with a cellular hierarchy dominated by GBM stem cells (GSCs), evades anti-tumor immunity through mechanisms that remain incompletely understood. Like most cancers, GBMs undergo metabolic reprogramming towards glycolysis to generate lactate. Here, we show that lactate production by patient-derived GSCs and microglia induces tumor cell epigenetic reprogramming through histone lactylation, an activating modification that leads to immunosuppressive transcriptional programs and suppression of microglial phagocytosis via transcriptional upregulation of CD47, a “don’t eat me” signal, in GBM cells. Leveraging these findings, pharmacologic targeting of lactate production augments efficacy of anti-CD47 therapy. Mechanistically, lactylated histone interacts with the heterochromatin component chromobox protein homolog 3 (CBX3). Although CBX3 does not possess direct lactyltransferase activity, CBX3 binds histone acetyltransferase (HAT) P300 to induce increased P300 substrate specificity toward lactyl-coA and a transcriptional shift toward an immunosuppressive cytokine profile. Targeting CBX3 inhibits tumor growth by both tumor cell-intrinsic mechanisms and increased tumor cell phagocytosis. Collectively, these results suggest that lactate mediates a metabolism-induced epigenetic reprogramming in GBM that contributes to CD47-dependent immune evasion, which can be leveraged to augment efficacy of immune-oncology therapies.

Project description:Glioblastoma (GBM) is a lethal brain cancer composed of heterogeneous cellular populations including glioma stem cells (GSCs) and their progeny differentiated non-stem glioma cells (NSGCs). Although accumulating evidence points out the significance of GSCs for tumour initiation and propagation, the roles of NSGCs remain elusive. Here we demonstrate that, when patient-derived GSCs in GBM tumours undergo differentiation with diminished telomerase activity and shortened telomeres, they subsequently become senescent phenotype, thereby secreting angiogenesis-related proteins, including vascular endothelial growth factors. Interestingly, these secreted factors from senescent NSGCs promote proliferation of human umbilical vein endothelial cells and tumorigenic potentials of GSCs in immunocompromised mice. These experimental data are likely clinically-relevant, since immunohistochemistry of both patient tumours of GBM and the patient GSC-derived mouse xenografted tumours detected tumour cells that express a set of markers for the senescence phenotype. Collectively, our data suggest that the inter-cellular signals from senescent NSGCs promote GBM tumour angiogenesis thereby increasing malignant progression of GBM.

Project description:In addition to accumulation of step-wise genetic mutations, epigenetic alterations play critical roles in the evolution of colon cancers. However, distinct mutational patterns and patient backgrounds render it challenging to distinguish driver epigenetic alterations from passenger epigenetic alterations. To address this, we combined the colon cancer organoid orthotopic transplantation approach with comprehensive epigenomic and transcriptomic analyses. We found that an in vivo environment induces epigenetic alterations with fetal intestinal features that converge on SOX17, a transcription factor that is required for endoderm development. Surprisingly, SOX17 knockout leads to tumour rejection in immunocompetent mice, but not in immunodeficient mice, by turning immune cold tumours into hot with robust infiltration of activated CD8+ T cells. Mechanistically, SOX17 suppresses Ifngr1-mediated MHC-I expression to evade CD8+ T cell-mediated tumour cell killing. At the tumour initiation, SOX17 expression is induced by APC loss, and SOX17 facilitates the production of LGR5- cells with low MHC-I expression to evade immune surveillance. Together, our result reveals that SOX17 is a master transcriptional factor that induces in vivo epigenetic reprograming of tumours, which provides fundamental understanding of how an immune evasion program is initiated at the early stages of colon cancer development.

Project description:In addition to accumulation of step-wise genetic mutations, epigenetic alterations play critical roles in the evolution of colon cancers. However, distinct mutational patterns and patient backgrounds render it challenging to distinguish driver epigenetic alterations from passenger epigenetic alterations. To address this, we combined the colon cancer organoid orthotopic transplantation approach with comprehensive epigenomic and transcriptomic analyses. We found that an in vivo environment induces epigenetic alterations with fetal intestinal features that converge on SOX17, a transcription factor that is required for endoderm development. Surprisingly, SOX17 knockout leads to tumour rejection in immunocompetent mice, but not in immunodeficient mice, by turning immune cold tumours into hot with robust infiltration of activated CD8+ T cells. Mechanistically, SOX17 suppresses Ifngr1-mediated MHC-I expression to evade CD8+ T cell-mediated tumour cell killing. At the tumour initiation, SOX17 expression is induced by APC loss, and SOX17 facilitates the production of LGR5- cells with low MHC-I expression to evade immune surveillance. Together, our result reveals that SOX17 is a master transcriptional factor that induces in vivo epigenetic reprograming of tumours, which provides fundamental understanding of how an immune evasion program is initiated at the early stages of colon cancer development.