Tumor-associated Microglia Research Articles

TMIC-62. INVESTIGATING THE ROLE OF OSTEOPONTIN IN RADIORESISTANCE OF H3.3-G34R PEDIATRIC HIGH-GRADE GLIOMA

Abstract Pediatric high-grade gliomas (pHGGs) are currently the leading cause of cancer-related deaths in children. Around 15% of pHGGs harbor a glycine to arginine (G34R) mutation in histone H3.3. Gliomas in general, including H3.3-G34R gliomas, contain cell populations that are resistant to chemotherapy and radiation therapy. These resistant cell populations are responsible for tumor recurrence seen in over 90% of patients within two years after treatment. Uncovering molecular mechanisms responsible for radiation resistance is essential for the development of new targeted therapies against glioma. In our lab’s H3.3-G34R mouse model, we have observed mice that are both radioresistant and radiosensitive. In order to investigate potential mechanisms of resistance leading to this phenotype, we performed single-cell RNA sequencing (scRNA-seq) on 3 non-treated (NT) glioma-bearing mice, 3 mice resistant to treatment (R), and 3 mice susceptible to treatment (S). The scRNA-seq data was processed and filtered using FastQC, Cellranger, CellBender, and DoubletFinder before downstream analysis. Ligand-receptor interaction analysis using CellChat in conjunction with differential expression analysis demonstrated differential expression and secretion of a cytokine known as Secreted Phosphoprotein 1 (SPP1)/Osteopontin (OPN) from tumor-associated microglia and macrophages. Current literature on SPP1 has suggested that its expression may play a role in tumor aggressiveness. However, there is conflicting evidence regarding its mechanism of action when secreted from tumor-associated microglia and macrophages. Additionally, its role in radioresistance has yet to be fully explored. We will present data utilizing in vitro and in vivo experimentation to elucidate the role that differential expression of SPP1 may play in the radioresistance of our H3.3-G34R mouse model. Supported by grants from NIH-NINDS, the Pediatric Brain Tumor Foundation, and Ian’s Friends Foundation

IMMU-27. INHIBITION OF THE EXTRACELLULAR MATRIX PROTEIN EFEMP1/FIBULIN-3 REDUCES IMMUNOSUPPRESIVE SIGNALING IN TUMOR STEM CELLS AND INCREASES MACROPHAGE ACTIVATION AGAINST GLIOBLASTOMA

Abstract Glioblastoma tumors remain a formidable challenge for immune-based treatments because of their molecular heterogeneity, poor immunogenicity, and growth in the largely isolated and immunosuppresive neural environment. As the tumor grows, GBM cells change the composition and architecture of the neural extracellular matrix (ECM), affecting the mobility, survival, and function of immune cells such as tumor-associated microglia and infiltrated macrophages (TAMs). We have previously described the unique expression of the ECM protein EFEMP1/fibulin-3 in GBM compared to normal brain and demonstrated that this secreted protein promotes growth and resistance of the GBM stem cell (GSC) population. Here, we describe a novel immunomodulatory role of fibulin-3 and the immuno-boosting effects of targeting this ECM protein. Mice carrying fibulin-3-deficient intracranial tumors showed increased myeloid infiltration and reduced expression of TAM pro-tumoral markers (Arginase, CD206) compared to controls. The opposite was observed in orthotopic tumors overexpressing fibulin-3. In silico dataset analysis revealed positive correlation of fibulin-3 with an immunosuppresive signature in GBM, which was validated in GBM stem cells (GSCs). Accordingly, expression of fibulin-3 by GSCs promoted anti-inflammatory polarization of co-cultured macrophages. We further demonstrated that fibulin-3 regulated the expression of immunosuppresive signals (CSF-1, TGFbeta) and the innate immune checkpoint CD47 in GSCs via autocrine activation of NF-kB signaling. Immunosuppresive signals in GSCs were downregulated by knockdown of fibulin-3 or inhibition of this protein with an anti-fibulin-3 antibody (mAb428.2). Genetic or antibody-mediated targeting of fibulin-3 in GSCs co-cultured with macrophages (U937 and THP1 lines) increased macrophage phagocytosis and reduced the viability of the tumor cells. Furthermore, local delivery of mAb428.2 in mice carrying intracranial GBM resulted in increased infiltration of TAMs expressing pro-inflammatory markers and reducing tumor viability. Our findings show that anti-fibulin-3 approaches, which impact the tumor ECM, can diminish immunosuppression in GBM and boost innate immune responses against the tumor.

Lipid-Laden Macrophages Recycle Myelin to Feed Glioblastoma.

Tumor-associated microglia and macrophages (TAM) make up the largest immune cell population in the glioblastoma (GBM) tumor microenvironment. Given the heterogeneity and plasticity of TAMs in the GBM tumor microenvironment, understanding the context-dependent cancer cell-TAM symbiotic interaction is crucial for understanding GBM biology and developing effective therapies. In a recent issue of Cell, Kloosterman and colleagues identified a subpopulation of glycoprotein nonmetastatic melanoma protein Bhigh lipid-laden microglia and macrophages (LLM) in GBM. Mesenchymal-like GBM cells help generate the LLM phenotype. Reciprocally, LLMs are epigenetically rewired to recycle myelin and transfer the lipid from myelin to cancer cells, fueling mesenchymal-like GBM progression in a liver X receptor/ABCA1-dependent manner. Together, leveraging LLMs opens new therapeutic possibilities for rewiring the metabolism-mediated tumor-TAM interaction during GBM progression.

Enhancing Glioblastoma Immunotherapy with Integrated Chimeric Antigen Receptor T Cells through the Re-Education of Tumor-Associated Microglia and Macrophages.

Glioblastoma (GBM) is an aggressive brain cancer that is highly resistant to treatment including chimeric antigen receptor (CAR)-T cells. Tumor-associated microglia and macrophages (TAMs) are major contributors to the immunosuppressive GBM microenvironment, which promotes tumor progression and treatment resistance. Hence, the modulation of TAMs is a promising strategy for improving the immunotherapeutic efficacy of CAR-T cells against GBM. Molecularly targeting drug pexidartinib (PLX) has been reported to re-educate TAMs toward the antitumorigenic M1-like phenotype. Here, we developed a cell-drug integrated technology to reversibly conjugate PLX-containing liposomes (PLX-Lip) to CAR-T cells and establish tumor-responsive integrated CAR-T cells (PLX-Lip/AZO-T cells) as a combination therapy for GBM. We used a mouse model of GBM to show that PLX-Lip was stably maintained on the surface of PLX-Lip/AZO-T cells in circulation and these cells could transmigrate across the blood-brain barrier and deposit PLX-Lip at the tumor site. The uptake of PLX-Lip by TAMs effectively re-educated them into the M1-like phenotype, which in turn boosted the antitumor function of CAR-T cells. GBM tumor growth was completely eradicated in 60% of the mice after receiving PLX-Lip/AZO-T cells and extended their overall survival time beyond 50 days; in comparison, the median survival time of mice in other treatment groups did not exceed 35 days. Overall, we demonstrated the successful fusion of CAR-T cells and small-molecule drugs with the cell-drug integrated technology. These integrated CAR-T cells provided a superior combination strategy for GBM treatment and presented a reference for the construction of integrated cell-based drugs.

Tumor associated microglia/macrophages utilize GPNMB to promote tumor growth and alter immune cell infiltration in glioma

Tumor-associated microglia and blood-derived macrophages (TAMs) play a central role in modulating the immune suppressive microenvironment in glioma. Here, we show that GPNMB is predominantly expressed by TAMs in human glioblastoma multiforme and the murine RCAS-PDGFb high grade glioma model. Loss of GPNMB in the in vivo tumor microenvironment results in significantly smaller tumor volumes and generates a pro-inflammatory innate and adaptive immune cell microenvironment. The impact of host-derived GPNMB on tumor growth was confirmed in two distinct murine glioma cell lines in organotypic brain slices from GPNMB-KO and control mice. Using published data bases of human glioma, the elevated levels in TAMs could be confirmed and the GPNMB expression correlated with a poorer survival.

Super-enhancer-driven LIF promotes the mesenchymal transition in glioblastoma by activating ITGB2 signaling feedback in microglia.

The mesenchymal (MES) subtype of glioblastoma (GBM) is believed to be influenced by both cancer cell-intrinsic alterations and extrinsic cellular interactions, yet the underlying mechanisms remain unexplored. Identification of microglial heterogeneity by bioinformatics analysis. Transwell migration, invasion assays, and tumor models were used to determine gene function and the role of small molecule inhibitors. RNA sequencing, chromatin immunoprecipitation, and dual-luciferase reporter assays were performed to explore the underlying regulatory mechanisms. We identified the inflammatory microglial subtype of tumor-associated microglia (TAM) and found that its specific gene integrin beta 2 (ITGB2) was highly expressed in TAM of MES GBM tissues. Mechanistically, the activation of ITGB2 in microglia promoted the interaction between the SH2 domain of STAT3 and the cytoplasmic domain of ITGB2, thereby stimulating the JAK1/STAT3/IL-6 signaling feedback to promote the MES transition of GBM cells. Additionally, microglia communicated with GBM cells through the interaction between the receptor ITGB2 on microglia and the ligand ICAM-1 on GBM cells, while an increased secretion of ICAM-1 was induced by the proinflammatory cytokine leukemia inhibitory factor (LIF). Further studies demonstrated that inhibition of cyclin-dependent kinase 7 substantially reduced the recruitment of SNW1 to the super-enhancer of LIF, resulting in transcriptional inhibition of LIF. We identified notoginsenoside R1 as a novel LIF inhibitor that exhibited synergistic effects in combination with temozolomide. Our research reveals that the epigenetic-mediated interaction of GBM cells with TAM drives the MES transition of GBM and provides a novel therapeutic avenue for patients with MES GBM.

Abstract 5551: Targeted nanoparticles co-delivering PARP inhibitor and other immune modulators overcome the immunosuppressive tumor microenvironment

Abstract Several mutations have been identified that are associated with an increased risk of triple-negative breast cancer (TNBC), including those that are deleterious in the BRCA gene. TNBC is associated with the worst prognosis and the highest incidence of brain metastasis (30%) among all subtypes of BC. Despite objective responses to poly (ADP-ribose) polymerase (PARP) inhibition and improvements in progression-free survival (PFS) compared to standard chemotherapy in patients with BRCA-mutated TNBC, benefits are transitory. Furthermore, our understanding of the effect of PARP inhibitors (PARPi) in treating breast cancer brain metastasis (BCBM) and modulating its tumor microenvironment (TME) is still lacking. To this end, we analyzed the brain TME of BRCA-mutated BCBM in the absence or presence of treatment with PARPi. Interestingly, we found that the immune TME of the brain hinder the antitumor activity of PARPi by upregulating multiple immunosuppressive molecules, including PD-L1. Furthermore, we found that BCBM overexpress P-selectin through its interaction with the tumor-associated microglia, bone marrow-derived macrophages and endothelial cells in the TME. Thus, we designed a novel nanoparticle (NP) targeting P-selectin to serve as a brain-penetrant delivery system for the treatment of BCBM. In order to target BRCA-mutated BCBM, we harnessed our novel P-selectin-targeted NPs to entrap PARPi and other immune modulators that we found to exert synergistic activity when combined. To evaluate the antitumor activity of our P-selectin-targeted NPs, we established 3-dimensional (3D) ex vivo and in vivo BRCA-mutated BCBM models. Importantly, we saw favorable effects of the P-selectin-targeted NPs in comparison to the combination of the free drugs, suggesting that out targeted-NPs overcome the TME-mediated resistance to PARPi through the modulation of the immunosuppressive microenvironment of the brain. Citation Format: Rami Khoury, Ron Kleiner, Eilam Yeini, Daniel Rodriguez Ajamil, Sahar Israeli Dangoor, Tamer Sanalla, Iris Barshack, Roni Satchi-Fainaro. Targeted nanoparticles co-delivering PARP inhibitor and other immune modulators overcome the immunosuppressive tumor microenvironment [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2024; Part 1 (Regular Abstracts); 2024 Apr 5-10; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2024;84(6_Suppl):Abstract nr 5551.

Morphological differentiation of peritumoral brain zone microglia.

The Peritumoral Brain Zone (PBZ) contributes to Glioblastoma (GBM) relapse months after the resection of the original tumor, which is influenced by a variety of pathological factors. Among those, microglia are recognized as one of the main regulators of GBM progression and probably relapse. Although microglial morphology has been analyzed inside GBM and its immediate surroundings, it has not been objectively characterized throughout the PBZ. Thus, we aimed to perform a thorough characterization of microglial morphology in the PBZ and its likely differentiation not just from the tumor-associated microglia but from control tissue microglia. For this purpose, Sprague Dawley rats were intrastriatally implanted with C6 cells to induce a GBM formation. Gadolinium-based magnetic resonance imaging (MRI) was performed to locate the tumor and to define the PBZ (2 mm beyond the tumor border), thus delimitating the different regions of interest (ROIs: core tumoral zone and immediate interface; contralateral striatum as control). Brain slices were obtained and immunolabeled with the microglia marker Iba-1. Sixteen morphological parameters were measured for each cell, significative differences were found in all parameters when comparing the four ROIs. To determine if PBZ microglia could be morphologically differentiated from microglia in other ROIs, hierarchical clustering analysis was performed, revealing that microglia can be separated into four morphologically differentiated clusters, each of them mostly integrated by cells sampled in each ROI. Furthermore, a classifier based on linear discriminant analysis, including only three morphological parameters, categorized microglial cells across the studied ROIs and showed a gradual transition between them. The robustness of this classification was assessed through principal component analysis with the remaining 13 morphological parameters, corroborating the obtained results. Thus, in this study we provided objective and quantitative evidence that PBZ microglia represent a differentiable microglial morphotype that could contribute to the recurrence of GBM in this area.

Glioma: bridging the tumor microenvironment, patient immune profiles and novel personalized immunotherapy.

Glioma is the most common primary brain tumor, characterized by a consistently high patient mortality rate and a dismal prognosis affecting both survival and quality of life. Substantial evidence underscores the vital role of the immune system in eradicating tumors effectively and preventing metastasis, underscoring the importance of cancer immunotherapy which could potentially address the challenges in glioma therapy. Although glioma immunotherapies have shown promise in preclinical and early-phase clinical trials, they face specific limitations and challenges that have hindered their success in further phase III trials. Resistance to therapy has been a major challenge across many experimental approaches, and as of now, no immunotherapies have been approved. In addition, there are several other limitations facing glioma immunotherapy in clinical trials, such as high intra- and inter-tumoral heterogeneity, an inherently immunosuppressive microenvironment, the unique tissue-specific interactions between the central nervous system and the peripheral immune system, the existence of the blood-brain barrier, which is a physical barrier to drug delivery, and the immunosuppressive effects of standard therapy. Therefore, in this review, we delve into several challenges that need to be addressed to achieve boosted immunotherapy against gliomas. First, we discuss the hurdles posed by the glioma microenvironment, particularly its primary cellular inhabitants, in particular tumor-associated microglia and macrophages (TAMs), and myeloid cells, which represent a significant barrier to effective immunotherapy. Here we emphasize the impact of inducing immunogenic cell death (ICD) on the migration of Th17 cells into the tumor microenvironment, converting it into an immunologically "hot" environment and enhancing the effectiveness of ongoing immunotherapy. Next, we address the challenge associated with the accurate identification and characterization of the primary immune profiles of gliomas, and their implications for patient prognosis, which can facilitate the selection of personalized treatment regimens and predict the patient's response to immunotherapy. Finally, we explore a prospective approach to developing highly personalized vaccination strategies against gliomas, based on the search for patient-specific neoantigens. All the pertinent challenges discussed in this review will serve as a compass for future developments in immunotherapeutic strategies against gliomas, paving the way for upcoming preclinical and clinical research endeavors.

TMIC-52. HISTONE H3K27ME3 LEVEL GOVERN TUMOR-ASSOCIATED MICROGLIA REPROGRAMMING IN RESPONSE TO GBM

Abstract Glioblastoma (GBM) is the most common malignant primary brain tumor and its invasive nature makes complete dissection difficult. However, how GBM invade in the brain is poorly understood. Although, microglia are the resident immune cells in the brain that can support GBM invasion, their roles are yet elusive. Here, we retraced early steps of GBM invasion and their interaction with tumor-associated microglia (TAM) in a highly infiltrative murine GBM model in immunocompetent background. We show that microglia are activated in a wide tumor field ahead of GBM invasion, followed by glial net formation, encircling invading tumors. Next, physical contacts with GBM cells initiate an astounding morphological, and functional transformation of microglia and marrow-derived macrophages to form collectively organized migration streams with intertwined GBM cells. Here we show that Kdm6b, a H3K27me3 demethylase, is induced in TAMs during this process. Intriguingly, GBM disseminated more widely in juvenile host brains, which was associated with highly induced Kdm6b expression. Moreover, we show that Kdm6b inhibition with small chemical inhibitor GSKJ-4, perturbs TAM reprogramming, and GBM invasion. Together, our data reveal that microglia reprogramming provide directional cues for GBM invasion through epigenetic mechanisms and this may give insights to halt GBM invasion.

TMIC-78. ENDOTHELIAL REGULATION OF THE IMMUNOSUPPRESSIVE PHENOTYPE OF TUMOR-ASSOCIATED MICROGLIA IN GLIOBLASTOMA

Abstract Glioblastoma (GBM) is considered a non-immunogenic “cold tumor” with an immunosuppressive microenvironment that blocks T-cell infiltration and function, limiting the efficacy of targeted immunotherapy. Tumor-associated microglia and macrophages (TAM) constitute approximately 30-50% of the non-neoplastic immune cells, and they are closely associated with blood vessels in GBM. However, the precise mechanism by which TAM acquire the immunosuppressive phenotype remains poorly understood. In this study, we show that tumor endothelial cells (TEC) from primary and recurrent GBM express inflammatory cytokines and chemokines that influence the function and polarization of microglia. We demonstrate that conditioned media (CM) of TEC promotes the immunosuppressive phenotype of normal microglia and patient-derived TAM. RNA-sequencing of TAM treated with TEC-CM shows upregulation of immunosuppressive cytokines, as well as T-cell co-inhibitory molecules such as PD-L1. Culturing CD8 T-cells in CM of TAM-polarized by TEC inhibits their cytotoxic function and cytokine production, and induces expression of PD-1 and CTLA-4. Furthermore, gene set enrichment analysis uncovers alterations in calcium signaling-related pathways in TAM polarized by TEC-CM. Blocking calcium signaling with small molecule inhibitors in microglia reverses the immunosuppressive phenotype induced by TEC. To determine whether the interactions between GBM, endothelial cells and TAM promotes immunosuppression in vivo, we utilize the humanized immune system mouse model (huNOG-EXL) that harbor human lymphocytes and monocyte populations. In preliminary studies, we found that co-transplantation of GBM tumor cells with TAM and TEC significantly promotes tumor growth compared with GBM cells alone. Single-cell mass cytometry analysis of peripheral blood mononuclear cells (PBMC) pre- and post-transplant, and scRNA-sequencing and spatial-transcriptomic studies of these co-transplanted mice will potentially reveal key insights into local- and peripheral immune responses regulated by tumor endothelial-microglia interactions. Together, our findings highlight a key role for endothelial-mediated calcium signaling in regulation of the immunosuppressive phenotype of microglia in GBM.

TMIC-38. MITOCHONDRIAL ATP BIOGENESIS REGULATED BY VDAC1 IN TMEM119+ TUMOR-ASSOCIATED MICROGLIA AND MACROPHAGES MEDIATES HIGH-GRADE GLIOMA GROWTH

Abstract Patients with high-grade glioma have a poor prognosis and an average survival of less than 15 months, which is associated with an increase in tumor-associated microglia and macrophages (TAMs). TAMs in the glioma microenvironment are traditionally thought to suppress antitumor immune responses and are metabolically reprogrammed by glioma. However, it is unknown whether metabolic processes, like ATP synthesis, in TAMs can directly affect glioma growth. Through RNAseq, we identified a novel subpopulation that had elevated metabolic expression patterns. These TAMs (TMEM119+) had increased protein expression of ATP synthases and VDAC1, and surprisingly only TAMs located within the tumor center had increased mitochondrial energy potential. In vitro and ex vivo co-culture assays determined that activated TAMs increased the expression of metabolic, growth, and survival genes in high-grade glioma cells. These activated TAMs produced higher levels of extracellular ATP, which in turn increased glioma cell viability. Inhibition studies identified P2X purinoceptor 7 (P2X7R) as a key player in the TAMs ATP-induced glioma survival. Our findings demonstrate for the first time that a subpopulation of TAMs induced a more tumorigenic microenvironment through the secretion of ATP.

The Neuroimmune Regulation and Potential Therapeutic Strategies of Optic Pathway Glioma.

Optic pathway glioma (OPG) is one of the causes of pediatric visual impairment. Unfortunately, there is as yet no cure for such a disease. Understanding the underlying mechanisms and the potential therapeutic strategies may help to delay the progression of OPG and rescue the visual morbidities. Here, we provide an overview of preclinical OPG studies and the regulatory pathways controlling OPG pathophysiology. We next discuss the role of microenvironmental cells (neurons, T cells, and tumor-associated microglia and macrophages) in OPG development. Last, we provide insight into potential therapeutic strategies for treating OPG and promoting axon regeneration.

P06.16.A FRACTIONATED IRRADIATION ACTIVATES GLIOMA IMMUNE MICROENVIRONMENT AND BOOSTS ANTIGEN-SPECIFIC T CELL RESPONSE IN MALIGNANT GLIOMAS

Abstract Several ongoing clinical trials employ vaccine, immune checkpoint inhibitors and/or adoptive T cell therapy to treat glioblastoma. However, the impact of irradiation as part of the standard of care on the immune microenvironment and response to immunotherapy is ill-defined. In the present study, we analyzed the post-irradiation changes in the GBM immune microenvironment, and further elucidated the impact of fractionated tumor irradiation (FIR) on the efficacy of T cell-mediated immunotherapies in experimental gliomas. FIR boosted the response of orthotopically-implanted GL261 tumors expressing the tumor-associated antigen glycoprotein (gp)100 to a gp100 vaccine. Furthermore, FIR enhanced the infiltration of GL261-gp100 gliomas by adoptively-transferred gp100 T cell receptor-transgenic T cells, which also displayed a more activated and less exhausted phenotype post-irradiation. Single cell transcriptomic studies of tumor-infiltrating CD45+ leukocytes revealed that FIR promotes the expression of leukocyte-endothelial adhesion molecules in T cells, and transcripts encoding proinflammatory M1-like genes in tumor-associated microglia and macrophages. Collectively, our preclinical findings support the use of FIR with to increase response to T cell-based immunotherapies.

MTOR Inhibition Is Effective against Growth, Survival and Migration, but Not against Microglia Activation in Preclinical Glioma Models.

Initially introduced in therapy as immunosuppressants, the selective inhibitors of mTORC1 have been approved for the treatment of solid tumors. Novel non-selective inhibitors of mTOR are currently under preclinical and clinical developments in oncology, attempting to overcome some limitations associated with selective inhibitors, such as the development of tumor resistance. Looking at the possible clinical exploitation in the treatment of glioblastoma multiforme, in this study we used the human glioblastoma cell lines U87MG, T98G and microglia (CHME-5) to compare the effects of a non-selective mTOR inhibitor, sapanisertib, with those of rapamycin in a large array of experimental paradigms, including (i) the expression of factors involved in the mTOR signaling cascade, (ii) cell viability and mortality, (iii) cell migration and autophagy, and (iv) the profile of activation in tumor-associated microglia. We could distinguish between effects of the two compounds that were overlapping or similar, although with differences in potency and or/time-course, and effects that were diverging or even opposite. Among the latter, especially relevant is the difference in the profile of microglia activation, with rapamycin being an overall inhibitor of microglia activation, whereas sapanisertib was found to induce an M2-profile, which is usually associated with poor clinical outcomes.

Molecular Identity Changes of Tumor-Associated Macrophages and Microglia After Magnetic Resonance Imaging-Guided Focused Ultrasound-Induced Blood-Brain Barrier Opening in a Mouse Glioblastoma Model.

An orthotopically allografted mouse GL26 glioma model (Ccr2RFP/wt-Cx3cr1GFP/wt) was used to evaluate the effect of transient, focal opening of the blood-brain barrier (BBB) on the composition of tumor-associated macrophages and microglia (TAMs). BBB opening was induced by magnetic resonance imaging (MRI)-guided focused ultrasound (MRgFUS) combined with microbubbles. CX3CR1-GFP cells and CCR2-RFP cells in brain tumors were quantified in microscopic images. Tumors in animals treated with a single session of MRgFUS did not exhibit significant changes in cell numbers when compared with tumors in animals not receiving FUS. However, tumors that received two or three sessions of MRgFUS had significantly increased amounts of both CX3CR1-GFP and CCR2-RFP cells. The effect of MRgFUS on immune cell composition was also characterized and quantified using flow cytometry. Glioma implantation resulted in increased amounts of lymphocytes, monocytes and neutrophils in the brain parenchyma. Tumors administered MRgFUS exhibited increased numbers of monocytes and monocyte-derived TAMs. In addition, MRgFUS-treated tumors exhibited more CD80+ cells in monocytes and microglia. In summary, transient, focal opening of the BBB using MRgFUS combined with microbubbles can activate the homing and differentiation of monocytes and induce a shift toward a more pro-inflammatory status of the immune environment in glioblastoma.

Proinflammatory macrophage activation by the polysialic acid-Siglec-16 axis is linked to increased survival of glioblastoma patients.

Interactions with tumor-associated microglia and macrophages (TAM) are critical for glioblastoma progression. Polysialic acid (polySia) is a tumor-associated glycan, but its frequency of occurrence and its prognostic value in glioblastoma are disputed. Through interactions with the opposing immune receptors Siglec-11 and Siglec-16, polySia is implicated in the regulation of microglia and macrophage activity. However, due to a nonfunctional SIGLEC16P allele, SIGLEC16 penetrance is less than 40%. Here, we explored possible consequences of SIGLEC16 status and tumor cell-associated polySia on glioblastoma outcome. FFPE specimens of two independent cohorts with 70 and 100 newly diagnosed glioblastoma patients were retrospectively analyzed for SIGLEC16 and polySia status in relation to overall survival. Inflammatory TAM activation was assessed in tumors, in heterotypic tumor spheroids consisting of polySia-positive glioblastoma cells and Siglec-16-positive or -negative macrophages, and by exposing Siglec-16-positive or -negative macrophages to glioblastoma cell-derived membrane fractions. Overall survival of SIGLEC16 carriers with polySia-positive tumors was increased. Consistent with proinflammatory Siglec-16 signaling, levels of TAM positive for the M2 marker CD163 were reduced, whereas the M1 marker CD74 and TNF expression were increased, and CD8+ T cells enhanced in SIGLEC16 polySia double-positive tumors. Correspondingly, TNF production was elevated in heterotypic spheroid cultures with Siglec-16-expressing macrophages. Furthermore, a higher, mainly M1-like cytokine release and activating immune signaling was observed in SIGLEC16-positive as compared to SIGLEC16-negative macrophages confronted with glioblastoma cell-derived membranes. Collectively, these results strongly suggest that proinflammatory TAM activation causes the better outcome in glioblastoma patients with a functional polySia-Siglec-16 axis.

466 Robust Model of Microglia Replacement With Circulation-Derived Microglia-Like Cells (CDMCs) in CNS Malignancies

INTRODUCTION: Tumor-associated microglia and macrophages (TAMs) represent a main cell type of brain malignancies and demonstrate complex interactions with cancerous cells and the tumor microenvironment. These interactions have important implications for the progression and treatment of malignant central nervous system (CNS) tumors. TAMs have therefore emerged as therapeutic targets, though their potential to date has been unfulfilled. METHODS: C57BL/6 mice were preconditioned for BMT with retroorbital busulfan injections (25 mg/kg), and native microglia were depleted via PLX5622 (1200 mg/kg, chow). Following transplantation, animals underwent intracranial stereotactic injection of syngeneic cell lines of either high-grade glioma (GL261) or breast cancer metastasis (E0771). Following animal sacrifice, we used single cell RNA sequencing of CD45-positive cells to profile the transcriptomic identity of glioma tumor-associated CDMCs (TA-CDMCs). RESULTS: Lineage tracing proved high intra- and peri-tumoral chimerism of BMT-graft derived cells among CNS myeloid cells in both models two weeks after tumor cell injection, demonstrating a robust ability to modify the tumor-immune microenvironment in animal models. TA-CDMCs showed a similarly activated morphology as naÏve TAMs under immunohistochemistry. Pathway enrichment analysis revealed an upregulation of immune response pathways in TA-CDMCs compared to regular TAMs, including the overexpression of genes relevant for the regulation of T cell activation, suggesting possible modification of the glioma immune-environment following CDMC repopulation. CONCLUSIONS: The present study offered a robust proof-of-concept that highly efficient TAM replacement could be achieved in orthotopic murine brain tumor models. Additionally, it appears that replaced CDMCs retain unique transcriptional patterns in the tumor-immune microenvironment, with the upregulation of several key immune response pathways. These efforts may represent a novel route of tumor-directed immunotherapy and offer exciting opportunities for ex-vivo CDMC manipulation to specifically target neoplastic cells.

Distinct spatiotemporal features of microglia and monocyte-derived macrophages in glioma.

Gliomas are the most frequent primary tumors of the brain. Glioma progression is regulated by the tumor microenvironment, which is mainly composed of tumor-associated microglia (TA-MG) and monocyte-derived macrophages (MDM). Recent studies have highlighted the distinct properties of these cells in glioma progression. However, their spatiotemporal alteration during tumor progression has not been fully explored. Using a genetic lineage tracing approach, we show that TA-MG and MDMs differ in their spatiotemporal distribution and interaction with other components of the glioma microenvironment. MDM were present only inside the tumor, whereas TA-MG accumulated both outside and inside the tumor. However, TA-MG was eliminated from the tumor mass as the tumor progressed. Depletion of MDM led to enhanced occupancy of TA-MG in the tumor core, indicating that TA-MG elimination was regulated by MDM. TA-MG and MDM are heterogeneous cell populations whose compositions and properties can change during tumor progression. Finally, MG, TA-MG and MDM were enriched in the perivascular area (PVA) compared to more distal blood vessel-associated areas. However, inside the tumor, the MDM enrichment in PVA was higher than that in TA-MG. Collectively, we established that TA-MG and MDM exhibit different spatiotemporal features in glioma, suggesting distinctive roles during tumor progression.

The dual role of the CD95 and CD95L signaling pathway in glioblastoma.

Binding of CD95, a cell surface death receptor, to its homologous ligand CD95L, transduces a cascade of downstream signals leading to apoptosis crucial for immune homeostasis and immune surveillance. Although CD95 and CD95L binding classically induces programmed cell death, most tumor cells show resistance to CD95L-induced apoptosis. In some cancers, such as glioblastoma, CD95-CD95L binding can exhibit paradoxical functions that promote tumor growth by inducing inflammation, regulating immune cell homeostasis, and/or promoting cell survival, proliferation, migration, and maintenance of the stemness of cancer cells. In this review, potential mechanisms such as the expression of apoptotic inhibitor proteins, decreased activity of downstream elements, production of nonapoptotic soluble CD95L, and non-apoptotic signals that replace apoptotic signals in cancer cells are summarized. CD95L is also expressed by other types of cells, such as endothelial cells, polymorphonuclear myeloid-derived suppressor cells, cancer-associated fibroblasts, and tumor-associated microglia, and macrophages, which are educated by the tumor microenvironment and can induce apoptosis of tumor-infiltrating lymphocytes, which recognize and kill cancer cells. The dual role of the CD95-CD95L system makes targeted therapy strategies against CD95 or CD95L in glioblastoma difficult and controversial. In this review, we also discuss the current status and perspective of clinical trials on glioblastoma based on the CD95-CD95L signaling pathway.