Project description:Metabolic reprogramming an immune evasion are established hallmarks of the tumor microenvironment (TME). Growing evidence supports tumor metabolic dysregulation as an important mediator of tumor immune evasion. High TME levels of lactate potently suppress antitumor immunity. Pyruvate carboxylase (PC), responsible for the anaplerotic conversion of pyruvate to oxaloacetate, is essential for lung metastasis in breast cancer. Conversely, PC may be dispensable in some cells in the TME, with loss of PC associated with immunosuppression. Here we test whether PC suppression alters tumor metabolism and immunosuppression. Using multiple animal models of breast cancer, we identify a dimorphic role for PC expression in mammary cancer cells. PC supports metastatic colonization of the lungs; however, depletion of PC promotes primary tumor growth and suppresses histological and transcriptomic markers of antitumor immunity. We demonstrate that PC is potently suppressed by hypoxia, and that PC suppression is common in solid tumors, particularly those with higher levels of hypoxia. Using metabolomics, high resolution respirometry, and extracellular flux analysis, we show that PC-depleted cells produce more lactate and undergo less oxidative phosphorylation than scramble controls. Finally, we identify lactate metabolism as a targetable dependency of PC-depleted cells, which is sufficient to restore T cell populations to the TME of PC-depleted tumors. Taken together these data demonstrate that elevated lactate following PC suppression by hypoxia may be a key mechanism through which primary tumors limit antitumor immunity. Thus, these data highlight PC directed tumor metabolism is a nexus of tumor progression and antitumor immunity.

Project description:Metabolic reprogramming an immune evasion are established hallmarks of the tumor microenvironment (TME). Growing evidence supports tumor metabolic dysregulation as an important mediator of tumor immune evasion. High TME levels of lactate potently suppress antitumor immunity. Pyruvate carboxylase (PC), responsible for the anaplerotic conversion of pyruvate to oxaloacetate, is essential for lung metastasis in breast cancer. Conversely, PC may be dispensable in some cells in the TME, with loss of PC associated with immunosuppression. Here we test whether PC suppression alters tumor metabolism and immunosuppression. Using multiple animal models of breast cancer, we identify a dimorphic role for PC expression in mammary cancer cells. PC supports metastatic colonization of the lungs; however, depletion of PC promotes primary tumor growth and suppresses histological and transcriptomic markers of antitumor immunity. We demonstrate that PC is potently suppressed by hypoxia, and that PC suppression is common in solid tumors, particularly those with higher levels of hypoxia. Using metabolomics, high resolution respirometry, and extracellular flux analysis, we show that PC-depleted cells produce more lactate and undergo less oxidative phosphorylation than scramble controls. Finally, we identify lactate metabolism as a targetable dependency of PC-depleted cells, which is sufficient to restore T cell populations to the TME of PC-depleted tumors. Taken together these data demonstrate that elevated lactate following PC suppression by hypoxia may be a key mechanism through which primary tumors limit antitumor immunity. Thus, these data highlight PC directed tumor metabolism is a nexus of tumor progression and antitumor immunity.

Project description:<p>Plasmacytoid dendritic cells (pDC) are a subset of dendritic cells with unique immunophenotypic properties and functions. While their role in antiviral immunity through production of type I interferons is well-established, their contributions to anti-tumor immunity are less clear. While some evidence demonstrates that pDC in the tumor microenvironment (TME) may drive CD4+ T cell to become <a href="https://www.ncbi.nlm.nih.gov/gene/50943">Foxp3</a>+ T regulatory cells, little is understood about the relationship of pDC with cytotoxic CD8+ T cell, the key player in antitumor immune responses.</p> <p>In this study, we perform comprehensive immunophenotyping and functional analysis of pDC from the TME and draining lymph nodes of patients with head and neck squamous cell carcinoma (HNSCC) and identify a novel pDC subset characterized by expression of the TNF receptor superfamily member <a href="https://www.ncbi.nlm.nih.gov/gene/?term=7293">CD134 (OX40)</a>. We show that OX40 expression is expressed on intratumoral pDC in both humans and mice in a tumor-model specific fashion and that this subset of pDC enhances tumor associated-antigen (TAA)-specific CD8+ T cell responses. Through transcriptomic profiling of OX40-expressing pDC from the TME, we further characterize gene signatures unique to this pDC subset that support its role as an important immunostimulatory immune population in the TME.</p>

Project description:Tumor targeted therapies have been largely inefficient due to lack of concomitant effects on the tumor microenvironment (TME). We investigated the MAtrix REgulating MOtif (MAREMO) mimicking peptide MP5, that inhibits the pro-tumorigenic extracellular matrix (ECM) molecule tenascin-C, using immunocompetent autologous breast cancer bearing mice. MP5 treatment led to tumor regression and reduced tumor cell dissemination. Several cancer hallmarks were abolished such as tumor cell promoting growth suppression and inhibition of plasticity enhancing responsiveness to death inducers. MP5 acts on other TME players leading to blood vessel normalization and depletion of fibroblasts diminishing the ECM as an orchestrator of immune suppression, causing immune cell infiltration and reactivation of anti-tumor immunity involving IFNgamma. Thus, targeting the tumor matrix using MAREMO in tenascin-C represents a powerful novel anti-cancer strategy.

Project description:PD-1 blockade therapy exerts antitumor effects by restoring the infiltration of tumor antigen-specific CD8+ T cells. While neoantigens arising from gene alterations in cancer cells comprise critical tumor antigens in antitumor immunity, a subset of non-small-cell lung cancers (NSCLCs) harboring substantial tumor mutation burden (TMB) lack CD8+ T cells in the tumor microenvironment (TME), resulting in resistance to PD-1 blockade therapy. This resistance is an urgent issue, so the mechanism(s) mediating impaired antitumor immunity in highly mutated NSCLCs need to be explored. Here, we show that activation of the WNT/b-catenin signaling pathway contributes to the development of a noninflamed TME in tumors with high TMB. NSCLCs that lack immune cell infiltration into the TME despite high TMB preferentially upregulate the WNT/b-catenin pathway. Immunological assays revealed that those patients harbored neoantigen-specific CD8+ T cells in the peripheral blood but not in the TME, suggesting impaired T cell infiltration into the TME due to the activation of WNT/b-catenin signaling. In our animal model, the accumulation of gene mutations in cancer cells increased CD8+ T cell infiltration into the TME, slowing tumor growth. However, further accumulation of gene mutations blunted antitumor immunity by excluding CD8+ T cells from tumors in a WNT/b-catenin signaling-dependent manner. Combined treatment with PD-1 blockade and WNT/b-catenin signaling inhibitors induced far stronger antitumor immunity than either treatment alone. We propose a mechanism-oriented combination therapy concept in the cancer immunotherapy field, i.e., the combination of immune checkpoint inhibitors with drugs that target specific molecules in cancer cell-intrinsic oncogenic signaling pathways involved in immune escape.

Project description:The anatomic location and immunologic characteristics of brain tumors result in strong lymphocyte suppression. Consequently, conventional immunotherapies targeting CD8 T-cells are ineffective against brain tumors. Tumor cells escape immunosurveillance by various mechanisms, and tumor cell metabolism can affect the metabolic states and functions of tumor-infiltrating lymphocytes. Oxygen tension is one important factor influencing immune responses. Here, we discovered that brain tumor cells had a particularly high demand for oxygen, which affected γδ T-cell-mediated antitumor immune responses but not those of conventional T-cells. Specifically, tumor hypoxia activated the γδ T-cell protein kinase A (PKA) pathway at a transcriptional level, resulting in repression of NKG2D expression. Alleviating tumor hypoxia reinvigorated NKG2D expression and the antitumor function of γδ T-cells. These results reveal a hypoxia-mediated mechanism by which brain tumors and γδ T-cells interact and emphasize the importance of γδ T-cells for antitumor immunity against brain tumors.

Project description:Glioblastoma (GBM) is a malignancy with the complex tumor microenvironment (TME) dominated by glioblastoma stem cells (GSCs) and infiltrated with tumor-associated macrophages (TAMs), exhibiting aberrant metabolism progress. Lactate is a critical glycolytic metabolite that promotes tumor progression. However, the mechanism of lactate transporting and lactylation in the tumor microenvironment (TME) of GBM remains elusive. Examination of lactate metabolic signature highly expressed on TAMs and tumor cells. We uncovered that TAMs provide lactate to GSCs, promoting GSCs proliferation and inducing the non-homologous end joining (NHEJ) protein KU70 lactylated at K317. Furthermore, TAM-derived lactate-inducing KU70 lactylation inhibits cGAS- type I interferon signaling, remodeling the immunosuppressive microenvironment through reduced cytotoxic CD8+ T cell infiltration, promoting the malignant progress of GBM. This study unveils TAMs-derived lactate and lactylation as a critical regulator of NHEJ, providing fresh insights into how aberrant lactylation and TME reprogramming are linked to DNA damage repair, which contributes to exploring new therapeutic strategies for targeting lactate transporters in combination with anti-PD-1-antibody to enhance anti-tumor immunity, which provides the theoretical basis for improving the clinical prognosis of GBM.

Project description:Higher 13C-lactate labeling was seen in the more aggressive tumors, including all triple negative breast cancers. There was a significant correlation between lactate labeling and expression of the monocarboxylate transporter (MCT1), which mediates tumor cell pyruvate uptake, and a weaker correlation with expression of LDHA, which catalyzes label exchange between the injected pyruvate and the endogenous lactate pool.

Project description:Depleting the NURF chromatin remodeling complex results in enhanced antitumor immunity using mouse tumor models syngenic to two strain backgrounds. Selective depletion of immune cells from tumor-bearing mice discovers that both CD8+ and CD4+ cells are necessary for enhanced antitumor immunity to NURF-depleted cells. Our results suggest that NURF-depleted cells have significant differences in antigenicity compared to control cells.

Project description:Tumor-associated macrophages (TAMs) are key components of the tumor microenvironment (TME) which can either promote tumor progression (M2) or induce antitumor immunity (M1). The hypothesis of our study is that the expression of FOLR2 is associated with an M2-like macrophage profile. The main goal of this study is to compare the transcriptomic profile of FOLR2 positive and FOLR2 negative TAMs obtained from the ascites of C57BL/6 mice bearing ovarian ID8 intraperitoneal tumors. Abstract: The immunosuppressive tumor microenvironment (TME) represents a major barrier for effective immunotherapy. Tumor-associated macrophages (TAMs) are highly heterogeneous and plastic cell components of the TME which can either promote tumor progression (M2-like) or boost antitumor immunity (M1-like). Selective targeting of the pro-tumorigenic subset of TAMs represents an attractive therapeutic strategy. Here, we demonstrate that a subset of TAMs that expressing folate receptor β (FRβ) possess an immunosuppressive, tumor-promoting M2-like profile, while FRβ negative TAMs feature pro-inflammatory M1 macrophage properties. In syngeneic tumor mouse models, the administration of FRβ-targeted chimeric antigen receptor (CAR) T-cells mediated elimination of FRβ+ TAMs in the TME, which resulted in an enrichment of pro-inflammatory monocytes, an influx of endogenous tumor-specific CD8+ T-cells, delayed tumor progression, and prolonged survival. Preconditioning of the TME with FRβ-specific CAR T-cells also improved the effectiveness of tumor-directed anti-mesothelin CAR T-cells, while simultaneous co-administration of both CAR products did not. Thus, CAR T-cell-mediated depletion of immunosuppressive M2-like TAMs incites a pro-inflammatory TME that broadens endogenous antitumor immunity and limits tumor progression, highlighting the pro-tumor role of FRβ+ TAMs in the TME and the therapeutic implications of TAM-depleting agents as preparative adjuncts to conventional immunotherapies that directly target tumor antigens.