B-cells Drive Response to PD-1 Blockade in Glioblastoma Upon Neutralization of TGFβ-mediated Immunosuppression

Immunotherapy has revolutionized cancer treatment but has yet to be translated into brain tumors. Studies in other solid tumors suggest a central role of B-cell immunity in driving immune-checkpoint-blockade efficacy. Using single-cell and single-nuclei transcriptomics of human glioblastoma and melanoma brain metastasis, we found that tumor-associated B-cells have high expression of checkpoint molecules, known to block B-cell-receptor downstream effector function such as plasmablast differentiation and antigen-presentation. We also identified TGFβ-1/TGFβ receptor-2 interaction as a crucial modulator of B-cell suppression. Treatment of glioblastoma patients with pembrolizumab induced expression of B-cell checkpoint molecules and TGFβ-receptor-2. Abrogation of TGFβ using different conditional knockouts expanded germinal-center-like intratumoral B-cells, enhancing immune-checkpoint-blockade efficacy. Finally, blocking αVβ8 integrin (which controls the release of active TGFβ) and PD-1 significantly increased B-cell-dependent animal survival and immunological memory. Our study highlights the importance of intratumoral B-cell immunity and a remodeled approach to boost the effects of immunotherapy against brain tumors.

TMIC-42. LEVERAGING B CELL IMMUNITY TO PROMOTE IMMUNOTHERAPY IN GLIOBLASTOMA

Immunotherapy has revolutionized cancer treatment but has yet to be translated into brain tumors. Studies in melanoma and sarcoma, amongst other models, have revealed the accumulation of germinal-center-like B cells as a key survival predictor post-PD1 blockade. We seek to leverage B cell immunity to enhance immunotherapy effectiveness in glioblastoma (GBM). In human GBM and murine glioma models, we found that B cells in the tumor microenvironment (TME) are activated, but the expression of co-inhibitory molecules such as CD32 and CD72 blocks downstream effector function. Transcriptomic analysis showed high expression of inhibitory TGFβ receptors on B cells and high levels of TGFβ1 cytokine in the TME. We showed direct inhibition of B cell function through TGFβ signaling that could be prevented with TGFβ receptor blockade. Spatial multiplex immunofluorescence analysis of the TME revealed that tumor and myeloid cells express high levels of TGFβ and are also near B cells, allowing for TGFβ-mediated B cell inhibition. Blocking the TGFβ pathway via transgenic mice with TGFβ receptor knockout on B cells or TGFβ cytokine knockouts in myeloid cells, or generation of a CT2A tumor line with TGFβ cytokine knockdown, all demonstrated a survival benefit and more germinal-center-like B cells. There was also increased T cell proliferation and anti-tumor cytotoxicity. Finally, inhibiting αVβ8 integrin, a required factor that releases active TGFβ, is a translatable approach that also increased B cell proliferation and animal survival. Dual treatment with αVβ8+PD1 blockade showed the most potent survival as well as immunological memory against tumor re-challenge. Analysis of the B and T cell compartments after dual treatment showed synergy, with robust cellular proliferation and functional differentiation of plasmablasts and effector T cells. Collectively, our study highlights the importance of B cells in the TME and a remodeled approach to boost the effects of immunotherapy against GBM.

IMMU-29. B-CELL-BASED VACCINE PRODUCES GLIOBLASTOMA-REACTIVE ANTIBODIES THAT CONTRIBUTE TO TUMOR CLEARANCE

Glioblastomas (GBM) are characterized by a strong immunosuppressive environment, contributing to their poor prognosis and limited therapeutic response to immunotherapies. B-cells represent a unique opportunity to promote immunotherapy due to their potential to kill tumors by both cellular and humoral immunity. To generate our B-cell-based vaccine (BVax) platform, we activated 41BBL+ B cells from tumor bearing mice or GBM patient blood with BAFF, CD40, and IFNg. We have previously demonstrated that BVax potentiates radiation therapy, temozolomide and checkpoint blockade in murine models of GBM via enhancement of CD8+ T-cell based immunity. The aim of this current study is to evaluate the humoral effector functions of BVax. We examined the antibody (Ab) repertoire in vivo from serum of tumor-bearing B-cell knockout mice treated with BVax or by ex vivo stimulation of patient-derived BVax. Upon systemic administration, BVax infiltrates the tumor where it differentiates into plasmablasts. Murine BVax- and BNaive-derived serum immunoglobulin generated in vivo showed that the majority of murine BVax-derived Ab were IgG isotype, while BNaive mainly produced IgM isotype. Transfer of IgG from BVax treated mice directly into tumors of recipient animals significantly prolonged their survival, demonstrating anti-tumor cytotoxicity directly through humoral immunity. Patient-derived BVax activated ex vivo showed a plasmablast phenotype and the Ab repertoire supports the previous findings seen in our murine model. Our work suggests BVax-derived IgGs role in antibody-dependent cellular cytotoxicity and improved survival in murine models. This function, in addition to its role in cellular immunity against GBM, renders BVax a potentially effective alternative immunotherapeutic option for GBM patients.

EXTH-29. DUAL TGFB AND PD1 BLOCKADE PROMOTES GERMINAL-CENTER B-CELL IMMUNE RESPONSES AGAINST GLIOBLASTOMA

In contrast to other malignancies such as melanoma and sarcoma, Glioblastoma (GBM) remains difficult to treat with immunotherapies. Recent studies have shown that positive immunotherapeutic responses are mediated by the accumulation of germinal-center-like B cells which are predictive of survival in patients treated with neoadjuvant PD1 blockade. In contrast, GBM-associated B-cells are scarce and the establishment of germinal-center like cells have not been observed. This study seeks to identify how B-cells are driven towards their immunosuppressive phenotypes in GBM and how this prevents immunotherapeutic efficacy. Utilizing single-cell RNA sequencing (scRNA-seq) in a CT2A murine glioma model, TGFb receptors 1 and 3 were identified as the most highly expressed inhibitory receptors on GBM-associated B cells. Furthermore, using scRNA-seq, TGFb1 was identified as the most highly expressed immunosuppressive cytokine in the TME, which was produced principally by tumor-associated myeloid cells (TAMCs). Inhibiting the myeloid compartment using intracranial anti-Gr1 antibody in combination with PD1 blockade resulted in B-cells exhibiting greater proliferation and differentiation into memory B-cells in addition to germinal-center-like B-cells. Further demonstrating B-cell functional reprogramming, autologous T cells isolated from spleens exhibited greater proliferation and robust anti-tumor cytotoxicity when cocultured with tumor-associated B-cells from the dual treatment group. Finally, inhibiting a5b8 integrin, a key complex in releasing active TGFb, increased tumor-infiltrating proliferating B-cells and conferred a long-term survival benefit in the CT2A murine model. Our results demonstrate that the immunosuppressive TME of GBM is influenced by the vital interplay between B-cells and the TME through TGFb signaling. This study highlights the potential therapeutic benefits of targeting the TGFb signaling pathway in conjunction with the current standard of care for GBM.

TAMI-25. UPREGULATION OF CREATINE METABOLISM BY MYELOID CELLS RESULTS IN GLIOBLASTOMA PROGRESSION

Malignant brain tumors are uniquely immunosuppressive, with a predominant infiltration of immunosuppressive tumor-associated myeloid cells (TAMCs) and a deficit in T-cells unrivaled to any other tumor. This unique tumor microenvironment (TME) promotes resistance to both conventional and immune therapies for this disease. The underlying mechanisms by which TAMCs promote glioblastoma (GBM) progression are not fully understood. We found that TAMCs specifically upregulate de-novo creatine metabolism within GBM using unbiased genetic and metabolic screening. This metabolic phenotype was confirmed in human GBM patients by comparing peripheral versus tumor-infiltrating myeloid cells. Examination of de-novo creatine generation using Carbon13 arginine flux revealed that TAMCs, but not tumor-infiltrating CD8+ T-cells, can produce creatine. Furthermore, we demonstrate that TAMCs actively secrete de-novo generated creatine into cell cultures. Examination of the single-cell microenvironment of GBM revealed that malignant cells preferentially express the creatine transporter, indicating that TAMC-derived creatine is taken up by GBM. Notably, SLC6A8 is directly upregulated in the context of hypoxia and suggests that creatine uptake is a mechanism to promote survival under hypoxic stress. Indeed, exogenous creatine supplementation promoted both the migration and survival of multiple glioblastoma cell lines in-vitro. Utilizing an established inhibitor of creatine metabolism, β-Guanidinopropionic acid (β -GPA), we found that β -GPA blocks both the migration and survival of glioma cells under hypoxic stress. Lastly, β -GPA also inhibited creatine secretion by TAMCs, showing that creatine blockade can also influence TAMC metabolic phenotype. In the future, we will examine the importance of creatine metabolism on both immune suppression and tumor progression in-vivo. This work provides novel insights into the role of creatine metabolism in GBM and identifies a unique therapeutic avenue for this devastating disease.

IMMU-36. B CELL-VACCINE ELICITS LONG TERM IMMUNITY AGAINST GLIOBLASTOMA VIA ACTIVATION AND DIFFERENTIATION OF TUMOR-SPECIFIC CD8+ MEMORY T CELLS

While immunotherapy is used clinically to treat many cancers, its translation into brain tumors remains elusive. The importance of B cells in cancer immunity has become increasingly clear, and we previously developed a B cell-based cellular vaccine (BVax) against glioblastoma (GBM) by further activating 4-1BBL+ B cells with CD40 agonism and IFNγ. BVax were characterized as professional antigen-presenting cells (APCs) that promote CD8+ T cell migration and persistence in murine tumor-bearing brains. This study seeks to understand the mechanisms underlying BVax-induced CD8+ T cell fitness in the tumor microenvironment. Initial transcriptomic analysis highlighted that Bvax express high levels of IL15Rα, indicating their potential ability to trans-present IL15. Considering IL15 trans-presentation is fundamental in T-cell memory differentiation, we used BVax to induce T cell activation in the presence of exogenous IL15. BVax were better capable of activating antigen-specific CD8+ T cells and promoting a memory phenotype when compared to other professional APCs such as dendritic cells (DCs). T cell receptor (TCR) CDR3β sequencing showed that BVax expanded a number of TCR clones in-vitro that were found in brains of CT2A tumor-bearing mice in-vivo. These BVax-activated CD8+ T cells displayed a stronger antigen recall response and unique metabolic profile compared to DC-activated CD8+ T cells as shown by metabolomic analysis of tumor-infiltrating CD8+ T cells. When comparing the anti-tumor effects of CD8+ T cells activated by various APCs, BVax with exogenous IL15 promoted CD8+ T cells that displayed the most potent cytotoxicity against GBM cells in-vitro. Collectively, this study suggests that the IL15/IL15Rα axis and interactions with CD8+ T cell are key factors of BVax therapy in promoting a robust survival benefit and long-term immunologic memory against GBM in preclinical models. Additionally, the development of T cell therapies based on B cell licensing can be a promising future approach for glioblastoma therapy.

Current Immunotherapeutic Strategies for the Treatment of Glioblastoma

Glioblastoma (GBM) is a lethal primary brain tumor. Despite extensive effort in basic, translational, and clinical research, the treatment outcomes for patients with GBM are virtually unchanged over the past 15 years. GBM is one of the most immunologically "cold" tumors, in which cytotoxic T-cell infiltration is minimal, and myeloid infiltration predominates. This is due to the profound immunosuppressive nature of GBM, a tumor microenvironment that is metabolically challenging for immune cells, and the low mutational burden of GBMs. Together, these GBM characteristics contribute to the poor results obtained from immunotherapy. However, as indicated by an ongoing and expanding number of clinical trials, and despite the mostly disappointing results to date, immunotherapy remains a conceptually attractive approach for treating GBM. Checkpoint inhibitors, various vaccination strategies, and CAR T-cell therapy serve as some of the most investigated immunotherapeutic strategies. This review article aims to provide a general overview of the current state of glioblastoma immunotherapy. Information was compiled through a literature search conducted on PubMed and clinical trials between 1961 to 2021.