Glioblastoma Multiforme Cells Research Articles

TMET-08. RADIATION-INDUCED SLC25A22 CONTRIBUTES TO GLIOBLASTOMA RADIORESISTANCE ACQUISITION THROUGH REMODELING GLUTAMATE METABOLISM

Abstract Glioblastoma Multiforme (GBM), a malignant primary brain tumor, is treated by surgical resection followed by chemo- and radiotherapy. Nevertheless, most GBM patients show dismal prognosis due to the radioresistance acquisition of GBM cells via metabolic rewiring. Therefore, it is urgently required to discover how metabolic rewiring attributes to GBM radioresistance, and its targeting strategies. To identify GBM radioresistance driver genes, we previously established radioresistance GBM cells (RGCs) via repetitive in vivo selection, followed by mRNA sequencing, and selected candidate genes that are altered in RGCs (fold change>2 or <0.5, p-value<0.05) and also related with GBM patients’ prognosis. Here, we focused on amino acid transmembrane transporter (Gene Ontology: 0003333) and found that SLC25A22 was the most increased in RGCs. SLC25A22 exhibits uni-directional properties, exporting glutamate to cytosol, resulting in cytosolic glutamate accumulation in RGCs. Using 13C glutamine isotope tracing analysis following mitochondrial fractionation, we quantified the mitochondrial metabolic flux of glutamine. Despite decreased 13C glutamate efflux from RGCs mitochondria after genetic inhibition of SLC25A22, glutamine metabolites (a-ketoglutarate, succinate, malate, fumarate) remained constant. Cytosolic glutamate, as a substrate, is incorporated into various biosynthetic pathways, especially glutathione (GSH) and proline synthesis pathways in radioresistant GBM cells. GSH protects GBM cells by scavenging radiation-induced reactive oxygen species. Whereas, proline, a rate-limiting substrate for collagen biosynthesis, leads GBM cells to show an invasiveness phenotype via extracellular matrix remodeling. Genetic inhibition of SLC25A22 using short hairpin RNA (shRNA) or microRNA-184 mimic suppresses RGCs radioresistance and aggressiveness. Additionally, intranasal administration of microRNA-184 mimic prolonged the survival (median survival: 26 days after irradiation) of GBM-bearing mice, compared with non-target control (median survival: 16 days after irradiation). Together, our study demonstrates that SLC25A22 upregulation confers GBM radioresistance by inducing cytosolic glutamate-driven biosynthesis and suggests SLC25A22 as a therapeutic target to overcome GBM radioresistance.

DDDR-21. MPT0G521 AS A DUAL INHIBITOR OF LSD1 AND HDAC: A POTENTIAL THERAPEUTIC AGENT AGAINST PARENTAL AND TEMOZOLOMIDE-RESISTANT GLIOBLASTOMA MULTIFORME

Abstract INTRODUCTION Glioblastoma multiforme (GBM) is an aggressive brain tumor with limited treatment options and poor prognosis. Resistance to temozolomide (TMZ), the standard chemotherapy for GBM, further complicates treatment. This study investigates the effects of MPT0G521, a dual inhibitor of LSD1 and HDAC, on both parental and TMZ-resistant GBM cells to determine its potential as a therapeutic agent. MATERIALS AND METHODS TMZ and MPT0G521 were introduced in our study. Human GBM cell lines A172 and patient-derived primary GBM cells Pt#3, along with their TMZ-resistant counterparts, were cultured under specified conditions. Assays conducted include cell proliferation (MTT), colony formation, cell cycle analysis via flow cytometry, and western blot analysis for protein expression. Statistical significance was evaluated using ANOVA. RESULTS MPT0G521 exhibited significant anti-proliferative activity and toxicity against both parental and TMZ-resistant GBM cells in a dose- and time-dependent manner. Treatment with MPT0G521 led to reduced cell viability and colony formation. Cell cycle analysis revealed G2M phase arrest and increased subG1 phase, indicating cell cycle disruption and apoptosis. Western blot analysis showed upregulation of histone H3 methylation and acetylation, confirming the dual inhibitory action of MPT0G521 on LSD1 and HDAC. Additionally, MPT0G521 modulated markers of cell cycle and apoptosis, including increased levels of cleaved caspase-3 and PARP. CONCLUSION MPT0G521 demonstrates potential as an effective therapeutic agent against GBM by inhibiting cell proliferation, inducing cell cycle arrest, and promoting apoptosis in both parental and TMZ-resistant cells. These findings support further investigation of MPT0G521 as a promising treatment for GBM, particularly in cases resistant to standard chemotherapy.

TMIC-47. HUMAN BLOOD-BRAIN TUMOR BARRIER ON A CHIP TO INVESTIGATE PERSONALIZED TREATMENT FOR GLIOBLASTOMA PATIENTS

Abstract The inherent characteristics of glioblastoma multiforme (GBM), including tumoral heterogeneity and invasive capacity, combined with the presence of the blood-brain tumor barrier (BBTB), present challenges in developing effective treatment for GBM. Especially, the margins of GBM, where GBM cells infiltrate normal brain tissue, exhibit high resistance to therapies. Despite the difficulties in controlling tumor progression from this region, the GBM margin remains a critical area to be studied. Here we report a microengineered model that mimics the BBTB within the GBM margin, incorporating a 3D network of normal astrocytes and GBM cells isolated from patients newly diagnosed with GBM. The interaction between GBM cells and stromal cells results in increased vascular permeability, reactive gliosis, and alterations in astrocyte behavior to foster tumor invasiveness and progression. We compare patient-specific tumor responses to conventional chemotherapy in our BBTB on a chip model with clinical outcomes, demonstrating the capability of the model to predict personalized drug responses. Our BBTB model may serve as a personalized tool to examine the interactions between tumors and normal brain tissue, ultimately facilitating the screening of personalized medicine for GBM treatment.

TMET-33. INVESTIGATING THE ROLE OF CHEMERIN SIGNALING IN GLIOBLASTOMA

Abstract Glioblastoma multiforme (GBM) is one of the most common and lethal primary brain tumors in adults. Despite clinical efforts, patient prognosis remains poor with a median survival of approximately 14 months. Thus, identification of novel treatment avenues is needed. Metabolic rewiring is a hallmark of cancer and lipid homeostasis has an increasingly appreciated role in cancer cell survival. It has been shown that the disruption of lipid metabolic balance can lead to lipotoxicity, creating a new avenue in GBM treatment. Therefore, identifying methods to disrupt said lipid metabolic balance in GBM could provide a needed foothold. Previous studies from the lab have identified chemerin, a multifunctional adipokine encoded by the retinoic acid receptor responder 2 (RARRES2) gene, as an important and targetable lipid metabolism modulator in Clear cell renal cell carcinoma (ccRCC). Chemerin has also been implicated in the mesenchymal-phenotype promoting network between GBM cells and tumor-associated macrophages. Given similarities in GBM and ccRCC lipid metabolism and the existing role of chemerin in the tumor immune microenvironment in GBM, we hypothesize that chemerin drives GBM development by regulating lipid metabolism in addition to immune cell trafficking. This study aims to investigate the role and therapeutic opportunities of altered lipid metabolism in GBM by examining chemerin and its receptors (CMKLR1 and GPR1). Immunocompetent GBM mouse models generated through CRISPR-in utero electroporation (IUE) show that mice bearing RARRES2, CMKLR1, and GPR1 knockout tumors have prolonged survival. In addition, in vitro molecular inhibition of CMKLR1 in both human and murine GBM cell lines results in cell death. Ongoing studies involving in vitro CRISPR knockouts of RARRES2, CMKLR1, and GPR1 aim to elucidate the mechanisms by which in vivo inhibition of chemerin signaling results in slower tumor progression.

TMET-06. CLIP3 DOWNREGULATION LEADS TO RADIORESISTANCE IN GLIOBLASTOMA BY PROMOTING GLYCOLYTIC FLUX

Abstract Glioblastoma Multiforme (GBM), a highly aggressive primary brain tumor, often develops resistance to standard treatments such as ionizing radiation (IR), which leads to a median survival of about 15 months. GBM contains glioblastoma stem cells (GSCs), which are crucial in driving therapeutic resistance and recurrence. In our study, we conducted comprehensive analyses to evaluate the molecular changes associated with radioresistance and explored the role of the Spy1-CLIP3 axis as a key regulator of GSC maintenance. Our methods included quantitative PCR and immunoblotting to measure CLIP3 mRNA and protein levels, revealing a significant reduction in expression among radioresistant GBM cells. We found that exposure to IR leads to the upregulation of Spy1 and downregulation of CLIP3, contributing to the development of radioresistance in surviving GBM cells. We used metabolic flux analysis techniques to observe changes in glycolytic activity, which increased in correlation with CLIP3 downregulation. IR induces CLIP3 downregulation, increasing glycolytic activity by facilitating the trafficking of GLUT3, the primary glucose transporter in GSCs. Additionally, colony-forming ability was evaluated using colony-forming assay after treatment of glimepiride with or without IR. Glimepiride didn’t reduce colony-forming ability in non-irradiated cells, but when combined with IR, it significantly reduced colony-forming ability, possibly by disrupting maintenance of GSCs. Importantly, our data reveal that glimepiride, a CLIP3 activator targets GSCs metabolism and enhances radiosensitization while maintaining low toxicity. The radioresistant GBM cells that survive radiotherapy exhibit increased stemness and glycolytic activity mediated by the Spy1-CLIP3 axis. Overall, our findings suggest that clinical trials using glimepiride for GBM patients may potentially improve survival rates, particularly for those experiencing recurrence after radiotherapy. This research highlights the importance of targeting cellular metabolism and stem cell properties in the context of GBM radioresistance and suggests potential avenues for improving the effectiveness of existing treatments.

CCRG-02. MICRORNA TARGETING LOGIC IN DIRECT NEURONAL REPROGRAMMING OF GLIOBLASTOMA

Abstract microRNA (miR)-124 is one of the main drivers of mitotic exit during neurogenesis, which is recapitulated in miR-9/9* and -124 (miR-9/9*-124)-mediated direct neuronal reprogramming. In the reprogramming of various cell types, miR-9/9*-124 induce non-neuronal cell fate erasure before activating the neuronal program. Regardless of the different starting transcriptome landscapes, a core gene regulatory network (GRN) is always targeted by miR-9/9*-124, with cell cycle progression as the most significant pathway. We reason that miR-9/9*-124 can induce cell fate erasure in cancerous cells by repressing similar GRNs, using glioblastoma multiforme (GBM) as a paradigm. Mechanistic insights into GBM fate erasure by miR-9/9*-124 while inducing the postmitotic state would facilitate the understanding of GRNs that govern the tumorigenic identity of GBMs and potentially offer novel therapeutic implications. Indeed, miR-9/9*-124 readily induces mitotic exit in patient-derived GBM cell lines, represses GBM cell fates, and promotes neuronal identity over time as assessed by RNA-seq. Mice receiving GBM intracerebral xenografts with miR-9/9*-124 survived significantly longer than those receiving non-specific control miRNA. Global profiling of miRNA targeting activity by AGO2-eCLIP reveals that miR-124 binds to transcripts enriched in G1/S transition and mitogen response. Conversely, miR-506—a miR-124 homolog—despite of sharing identical seed sequences, has significantly less targeting activity and fails to stop cell cycle progression. We are currently dissecting how the difference in the miRNA 3’ sequence renders contrasting biological outcomes. Preliminary data suggests that the length of miRNA alone alters targeting specificity to cell cycle transcripts. However, different permutations of miRNA 3’ sequence, though sufficient to induce mitotic exit, are not all competent to achieve neuronal reprogramming, indicating that mitotic exit and neurogenic activities of miR-124 could be decoupled. We hope that understanding the grammar logic of miRNA targeting would provide deeper insights into how miRNAs can be leveraged to manipulate GBM identity.

IMMU-29. B7-H3-TARGETED CAR-T AND CAR-NK CELLS AGAINST HUMAN GLIOBLASTOMA

Abstract Glioblastoma multiforme (GBM) is the most lethal primary brain tumor, necessitating novel therapies. Chimeric antigen receptor (CAR) T-cell therapy has recently shown efficacy against GBM. However, this approach is costly and time-consuming due to its personalized nature. Alternatively, CAR-transduced natural killer (NK) cells offer a potential “off-the-shelf” immunotherapy option, as they do not cause graft-versus-host disease. This study aimed to assess the anti-GBM efficacy of CAR T and NK cells targeting B7-H3, a protein highly expressed in GBM. To achieve this, CAR T cells targeting B7-H3 were developed using known anti-B7-H3 scFv sequences. Additionally, cord blood-derived NK cells were transduced with the B7-H3 CAR. Both types of CAR-modified cells were tested for their anti-GBM activity in vitro. Moreover, their anti-tumor effects were evaluated in an in vivo xenograft model using patient-derived GBM cells. The results demonstrated that both B7-H3 CAR T cells and CAR NK cells exhibited significant cytotoxicity against patient-derived GBM cells in vitro. Furthermore, intracranial injection of these CAR-modified cells into the xenograft model significantly reduced tumor growth. In conclusion, B7-H3 targeted CAR T cells and cord blood-derived CAR NK cells both show potential in eliminating GBM cells, suggesting promising avenues for future GBM treatment strategies.

BIOM-40. BLOOD AND NASAL BIOMARKERS OF BRAIN MICROENVIRONMENT BLOOD–BRAIN BARRIER PERMEABILITY: CLINICAL AND APPLIED CONCEPTS

Abstract The limiting step to treating glioblastoma (GBM) patients is the close blood-brain barrier (BBB) which protects the brain making it an inaccessible compartment. Although multiple studies have highlighted the presence of circulating tumour cells (CTCs) in glioblastoma multiforme (GBM) patients their relationship with brain microenvironment and BBB permeability was not explored in depth. We studied the development of GBM by transferring tumour cells into the mouse brain and also in a subcutaneous location to verify how the different microenvironment affected the release of circulating tumour and endothelial cells. Glioblastoma U3T3MG IDHwt secondary cell line was transfected to track circulating tumour cells released. Moreover, both U3T3 cells and short-time-expanded CTCs1 from GBM patients were used for intracranial xenografts and patient-derived xenografts (PDX). The in vivo models demonstrated the correspondence between BBB permeability with the release of CTCs and the increment of endothelial progenitor cells in GBM HIFpos >20% compared to subcutaneous xenografts releasing CTCs in GBM HIFpos< 20%. These data were confirmed in HIFpos tissue biopsy of GBM-IDHwt patients with CTCs >30 cells/ml. Both in PDXs and in the GBM patient demonstrated that the release of CTCs was intermittent, related to BBB opening induced by HIF-dependent cytokines release (IL8, TNFa)2. In parallel, the analysis of structural Glial fibrillary acidic protein (GFAP)3, on nasal secretion and interstitial fluid, collected in surgical treated GBM patients, demonstrated that the recognition of the two GFAP isoforms (p150 and p50 kDa) were the result of inflammatory microenvironment enriched for proteases induced by IL8, TNFa. Overall data indicate at least two different ways of monitoring the BBB and the brain microenvironment, one distal (blood) and one proximal (nasal secretion) useful to perform precision treatments in patients with GBM. REFERENCES 1) Malara, N. et al. Mol Cancer 23, 32 (2024). doi.org/10.1186/s12943-024-01951-x2) Coluccio ML. et al Cancers (2020) doi: 10.3390/cancers12061362.3) Malara, N. et al Front. Oncol.(2021) doi.org/10.3389/fonc.2021.737730

DDDR-18. TARGETTING GLIOBLASTOMA MULTIFORME USING A MULTIACTION ANTICANCER ANTI-INFLAMMATORY THERAPEUTIC STRATEGY

Abstract Glioblastoma multiforme (GBM) represents a significant challenge in adult brain tumor management, characterized by its aggressive nature and poor prognosis despite multimodal therapies. Current standard chemotherapy, Temozolomide (TMZ), offers limited survival benefits. In a recent breakthrough, the cyclic peptide cyclo-((2-Nal)-Leu-Ser-(2-Nal)-Arg) acetate (c2), initially developed for prostate cancer, demonstrates remarkable promise against GBM. By selectively inhibiting the inflammatory phospholipase enzyme sPLA2IIA, c2 significantly impedes GBM cell proliferation, surpassing TMZ efficacy in multiple resistant cell lines. Moreover, c2 exhibits potential to inhibit tumor growth and metastasis, confirmed in 3D tumoroid and wound healing assays. Mechanistic insights reveal modulation of crucial cellular pathways, including viral entry, cytoskeletal structure, and signaling cascades. Preclinical investigations demonstrate c2’s ability to penetrate the blood-brain barrier and attenuate tumor progression markers. At multiple levels, c2 is shown to target inhibition of ERBB2 and EGFR signalling and also have impacts on HIF1-NF-kB axis. This study proposes c2 as a potent anti-GBM candidate, warranting evaluations for its pharmacological profile, safety, and efficacy. With its potential to address the urgent need for effective GBM therapies, c2 holds promise as a significant advancement in GBM treatment, offering hope for improved patient outcomes.

CARD16 restores tumorigenesis and restraints apoptosis in glioma cells Via FOXO1/TRAIL axis

A hallmark of glioma cells, particularly glioblastoma multiforme (GBM) cells, is their resistance to apoptosis. Accumulating evidences has demonstrated that CARD16, a caspase recruitment domain (CARD) only protein, enhances both anti-apoptotic and tumorigenic properties. Nevertheless, there is a limited understanding of the expression and functional role of CARD16 in glioma. This study seeks to investigate, through in silico analysis and clinical specimens, the role of CARD16 as a potential tumor promoter in glioma. Functional assays and molecular studies revealed that CARD16 promotes tumorigenesis and suppresses apoptosis in glioma cells. Moreover, knockdown of CARD16 enhances the expression of the FOXO1/TRAIL axis in GBM cells. Additionally, FOXO1 downregulation in CARD16 knockdown GBM cells restores proliferation and reduces apoptosis. Further investigation demonstrated that elevated P21 expression inhibits CDK2-mediated FOXO1 phosphorylation and ubiquitination in CARD16-knockdown GBM cells. Collectively, these findings suggest that CARD16 is a tumor-promoting molecular in glioma via downregulating FOXO1/TRAIL axis, and suppressing TRAIL-induced apoptosis. The CARD16 gene presents significant potential for prognostic prediction and advances in innovative apoptotic therapeutics.

Chitosan-coated nanoemulsion for intranasal administration increases temozolomide mucosal permeation, cellular uptake, and In vitro cytotoxicity in glioblastoma multiforme cells

Glioblastoma multiforme (GBM) is the most prevalent and aggressive type of brain cancer in adults. Temozolomide (TMZ) is the chemotherapeutic agent used to treat primary central nervous system tumors. However, TMZ's clinical effectiveness faces several challenges due to its physical-chemical properties and biological features of GBM, such as the blood-brain barrier (BBB). Mucoadhesive nanosystems such as those coated with chitosan represent a promising alternative for optimizing the delivery of therapeutic agents to the central nervous system, as they possess ideal characteristics that enhance their interaction with the intranasal mucosa. We aimed to develop a chitosan-coated nanoemulsion containing temozolomide (CS-NE-TMZ) for nose-to-brain delivery and characterize its physical-chemical and in vitro biological properties. CS-NE-TMZ were obtained by emulsification followed by sonication. The optimized CS-NE-TMZ presented droplet size of 123,4 ± 2,3 nm, polydispersity index of 0.273 ± 0.028, zeta potential of +21,5 ± 0,81 mV, entrapment efficiency of 100 ± 1,91 % and drug loading of 2 ± 0,007 %. An in vitro release study of CS-NE-TMZ showed sustained release for up to 24 h following the Korsmeyer-Peppas model with Fickian diffusion. CS-NE-TMZ demonstrated significantly enhanced ex vivo mucosal permeation, compared to free TMZ, and showed enhanced in vitro cellular uptake, selectively increasing cytotoxicity in U-87MG glioma cells but not in healthy L929 fibroblasts, reinforcing the potential of mucoadhesive nanoemulsions as effective intranasal drug delivery systems for future brain cancer therapies.

Therapeutic Contribution of Tau-Binding Thiazoloflavonoid Hybrid Derivatives Against Glioblastoma Using Pharmacological Approach in 3D Spheroids.

Growing evidence has unveiled the pathological significance of Tau in many cancers, including the most aggressive and lethal brain tumor glioblastoma multiform (GBM). In this regard, we have recently examined the structure-activity relationship of a new series of seventeen 2-aminothiazole-fused to flavonoid hybrid compounds (TZF) on Tau-overexpressing GBM cells. Here, we evaluated the anticancer activities of the two lead compounds 2 and 9 using multi-cellular spheroids (MCSs) which represent an easy 3D human cell model to mimic GBM organization, physical constraints and drug penetration. The two compounds reduced cell evasion from spheroids up to three times, especially for Tau-expressing cells. As a first step towards a therapeutic approach, we quantified the effects of these compounds on MCS growth using two complementary protocols: single and repeated treatments. A single injection with compound 9 slowed down the growth of MCSs formed with U87 shCTRL cells by 40% at 10 µM. More interestingly, multiple treatment with compound 9 slowed the growth of U87 shCTRL spheroids by 40% at a concentration of 5 µM, supporting the increased bioavailability of compound 9 within MCSs. In conclusion, compound 9 deserves particular attention as promising candidate for specifically targeting Tau-expressing cancers such as GBM.

Bioengineering human heavy-chain nanoferritin for glioblastoma multiforme-specific delivery and efficient immunotherapy

The blood–brain barrier (BBB) caused limited drug accumulation and programmed death-ligand 1 (PD-L1) compromised immunosuppressive microenvironment are bottlenecks in glioblastoma multiforme (GBM) treatment. Herein, we bioengineered a human heavy chain nanoferritin (HTE NPs) for GBM-specific delivery and efficient immunotherapy. To achieve targeted mitochondrial metabolic regulation, we connected triphenylphosphonium (TPP) with the photosensitive agent IR780 to form T780, which self-assembles with esomeprazole magnesium (EM) and human H-ferritin (HFn) to obtain HTE NPs. HFn endows HTE NPs with BBB penetration and specific site-targeting capabilities, thereby enhancing tumor accumulation and pH-responsive release within GBM cells. T780 subsequently induces mitochondrial damage, activating the AMP-dependent protein kinase (AMPK) pathway and blocking the transmission of T-cell inhibitory signals through the phosphorylation of PD-L1, thereby promoting T-cell activation. Moreover, EM inhibits the release of extracellular vesicles (EVs), reducing the inhibitory effect of PD-L1 on circulating T cells. Furthermore, mitochondrial impairment-induced mitochondrial DNA (mtDNA) leakage activates the cGAS-STING signaling pathway, inducing the maturation of dendritic cells (DCs), recruiting supportive immune cells to clear GBM cells, and improving the immunosuppressive microenvironment. Therefore, HTE NPs not only achieve efficient tumor accumulation but also facilitate the activation immune response, providing a promising strategy for the clinical treatment of GBM.

Comprehensive Pan-cancer analysis of CD73: explore its association with prognosis and tumor immune microenvironment

BackgroundCD73 is adenosine generation molecule, which is involved in the immune regulation. However, the roles of CD73 in the tumor microenvironment remain unknown. MethodsCD73 expression levels in pan-cancers were analyzed, based on The Cancer Genome Atlas (TCGA), Genotype-Tissue Expression (GTEx) and Human Protein ALTAS (HPA) databases. Kaplan-Meier (KM) plotter was used to analyze the prognostic values of CD73. Immune scores in pan-cancers was evaluated by ESTIMATE. TIMER2.0 and UCSCXena were used to explore the correlation between CD73 and immune infiltration/immune checkpoints/tumor mutation burden (TMB)/microsatellite instability (MSI). CD73 expression correlated genes in tumor tissues were screened by using LinkedOmics tool. ResultsFirstly, CD73 was significant increased in following cancer types: esophageal carcinoma (ESCA), glioblastoma multiforme (GBM), head and neck squamous cell carcinoma (HNSC), brain lower grade glioma (LGG), lung adenocarcinoma (LUAD), pancreatic adenocarcinoma (PAAD) and stomach adenocarcinoma (STAD). Secondly, high CD73 expression was associated with poor overall survival in patients with breast invasive carcinoma (BRCA), CESC, HNSC, liver hepatocellular carcinoma (LIHC), LUAD, lung squamous cell carcinoma (LUSC), PAAD and STAD. However, in KIRC and UCEC, patients high CD73 expression showed a favorable prognosis. Thirdly, the immune scores of the high CD73 expression in bladder urothelial carcinoma (BLCA), BRCA, kidney chromophobe (KICH), LUAD, LUSC, ovarian serous cystadenocarcinoma (OV), pheochromocytoma and paraganglioma (PCPG), prostate adenocarcinoma (PRAD), and skin cutaneous melanoma (SKCM) were significant higher than that of patients with low CD73 expression. Furthermore, we observed a positive correlation between CD73 and the multiple immune cells infiltration, including CD4+ memory T cells, CD8+ T cells, Treg cells, myeloid DC and macrophage, particularly in BRCA and LUAD. There was no strong correlation between CD73 and TMB/MSI. In LUAD, CD73 expression correlated genes were mainly enrichment in positive regulation of cell proliferation, cell adhesion, positive regulation of kinase activity, cellular response to LPS. However, in UCEC, CD73 correlated genes were mainly associated with fatty acid omega-oxidation, protein localization to endoplasmic reticulum exit site, endoplasmic reticulum to Golgi vesicle-mediated transport. ConclusionCD73 could be used to predict the prognosis of patients with several cancers. The potential functional mechanism of CD73 involved in cancer progress may not only dependent on its immunomodulatory effects.

Deciphering CD59: Unveiling Its Role in Immune Microenvironment and Prognostic Significance.

CD59, a GPI-anchored membrane protein, protects cancer cells from complement-dependent cytotoxicity (CDC) by inhibiting the formation of the membrane attack complex (MAC). It has been demonstrated to be overexpressed in most solid tumors, where it facilitates tumor cell escape from complement surveillance. The role of CD59 in cancer growth and interactions between CD59 and immune cells that modulate immune evasion has not been well explored. Using cancer patient database from The Cancer Genome Atlas (TCGA) and other public databases, we analyzed CD59 expression, its prognostic significance, and its association with immune cell infiltration in the tumor microenvironment, identifying associated genomic and functional networks and validating findings with invitro cell-line experimental data. This article describes the abundant expression of CD59 in multiple tumors such as cervical squamous cell carcinoma (CESC), kidney renal cell carcinoma (KIRC), glioblastoma multiforme (GBM), head and neck squamous cell carcinoma (HNSC), and stomach adenocarcinoma (STAD), as well as in pan-cancer, using The Cancer Genome Atlas (TCGA) database and confirmed using multiple cancer cell lines. The expression of CD59 significantly alters the overall survival (OS) of patients with multiple malignancies such as CESC, GBM, HNSC, and STAD. Further, the correlation between CD59 and Treg and/or MDSC in the tumor microenvironment (TME) has shown to be strongly associated with poor outcomes in CESC, GBM, HNSC, and STAD as these tumors express high FOXP3 compared to KIRC. Moreover, unfavorable outcomes were strongly associated with the expression of CD59 and M2 tumor-associated macrophage infiltration in the TME via the IL10/pSTAT3 pathway in CESC and GBM but not in KIRC. In addition, TGFβ1-dominant cancers such as CESC, GBM, and HNSC showed a high correlation between CD59 and TGFβ1, leading to suppression of cytotoxic T cell activity. Overall, the correlation between CD59 and immune cells predicts its prognosis as unfavorable in CESC, GBM, HNSC, and STAD while being favorable in KIRC.

Novel 1,8-Naphthalimide Derivatives Inhibit Growth and Induce Apoptosis in Human Glioblastoma.

Given the rapid advancement of functional 1,8-Naphthalimide derivatives in anticancer research, we synthesized these two novel naphthalimide derivatives with diverse substituents and investigated the effect on glioblastoma multiforme (GBM) cells. Cytotoxicity, apoptosis, cell cycle, topoisomerase II and Western blotting assays were evaluated for these compounds against GBM in vitro. A human GBM xenograft mouse model established by subcutaneously injecting U87-MG cells and the treatment responses were assessed. Both compounds 3 and 4 exhibited significant antiproliferative activities, inducing apoptosis and cell death. Only compound 3 notably induced G2/M phase cell cycle arrest in the U87-MG GBM cells. Both compounds inhibited DNA topoisomerase II activity, resulting in DNA damage. The in vivo antiproliferative potential of compound 3 was further validated in a U87-MG GBM xenograft mouse model, without any discernible loss of body weight or kidney toxicity noted. This study presents novel findings demonstrating that 1,8-Naphthalimide derivatives exhibited significant GBM cell suppression in vitro and in vivo without causing adverse effects on body weight or kidney function. Further experiments, including investigations into mechanisms and pathways, as well as preclinical studies on the pharmacokinetics and pharmacodynamics, may be instrumental to the development of a new anti-GBM compound.

Nanoplatforms for Magnetic-Photo-Heating of Thermo-Resistant Tumor Cells: Singular Synergic Therapeutic Effects at Mild Temperature.

A self-assemble amphiphilic diblock copolymer that can incorporate iron oxide nanocubes (IONCs) in chain-like assemblies as heat mediators for magnetic hyperthermia (MHT) and tuneable amounts of IR780 dye as agent for photothermal therapy (PTT) is developed. MHT-heating performance of photobeads in viscous media have the same heat performances in water at magnetic field conditions of clinical use. Thanks to IR780, the photobeads are activated by infrared laser light within the first biological window (808nm) with a significant enhancement of photo-stability of IR780 enabling the raise of the temperature at therapeutic values during multiple PTT cycles and showing unchanged optical features up to 8 days. Moreover, the photobeads fluorescent signal is preserved once internalized by glioblastoma multiforme (GBM) cells. Peculiarly, the photobeads are used as toxic agents to eradicate thermo-resistant GBM cells at mild heat, as low as 41°C, with MHT and PTT both of clinical use. Indeed, a high U87 GBM cell mortality percentage is obtained only with dual MHT/PTT while each single treatment dose not provide the same cytotoxic effects. Only for the combined treatment, the cell death mechanism is assigned to clear sign of apoptosis as observed by structural/morphological cell studies and enhanced lysosome permeability.

In Vitro Experiment Present ROCK2 Inhibition Promotes the Therapeutic Effect of Bevacizumab in the Treatment of Glioblastoma Multiforme

Objective Gliomas are a general designation for neuroepithelial tumors derived from the glial cells of the central nervous system. According to the histopathological and immunohistochemical features, the World Health Organization classifies gliomas into four grades. Bevacizumab is a monoclonal antibody targeting vascular endothelial growth factor that has been approved for the treatment of glioblastoma multiforme (GBM) as a second-line therapy. However, its efficacy remains limited. Rho/Rho-associated kinase (ROCK) is a downstream molecule of small guanosine triphosphatases (GTPases) that regulates multiple cellular processes, including motility, migration, and proliferation. Thus, ROCK has been regarded as a therapeutic target for cardiovascular diseases, neurological diseases, immune diseases, and cancer, and ROCK inhibitors have high potential clinical value. Methods Viability rate of cells was detected using MTT assay, and apoptosis of cells was detected using FACS. Expression of target genes and proteins was detected using qPCR and western blotting analysis. Concentration of cytokines was detected using ELISA methods. Results Viability and migration of GBM cells were reduced after bevacizumab treatment and that these effects were enhanced by ROCK2 inhibition. We further found that ROCK2 inhibition promoting the effect of bevacizumab was mainly mediated by the RhoA/ROCK2 pathway, further inducing apoptosis in GBM cells. In addition, we found that angiogenesis and degradation of cellular matrix-related cytokines were reduced by ROCK2 inhibition. Conclusions ROCK2 inhibition contributes to the therapeutic effects of bevacizumab.

A Versatile Microfluidic Device System that Lacks a Synthetic Extracellular Matrix Recapitulates the Blood-Brain Barrier and Dynamic Tumor Cell Interaction.

Microfluidic systems offer controlled microenvironments for cell-to-cell and cell-to-stroma interactions, which have precise physiological, biochemical, and mechanical features. The optimization of their conditions to best resemble tumor microenvironments constitutes an experimental modeling challenge, particularly regarding carcinogenesis in the central nervous system (CNS), given the specific features of the blood-brain barrier (BBB). Gel-free 3D microfluidic cell culture systems (gel-free 3D-mFCCSs), including features such as self-production of extracellular matrices, provide significant benefits, including promoting cell-cell communication, interaction, and cell polarity. The proposed microfluidic system consisted of a gel-free culture device inoculated with human brain microvascular endothelial cells (HBEC5i), glioblastoma multiforme cells (U87MG), and astrocytes (ScienCell 1800). The gel-free 3D-mFCCS showed a diffusion coefficient of 4.06 × 10-9 m2·s-1, and it reconstructed several features and functional properties that occur at the BBB, such as the vasculogenic ability of HBEC5i and the high duplication rate of U87MG. The optimized conditions of the gel-free 3D-mFCCS allowed for the determination of cellular proliferation, invasion, and migration, with evidence of both physical and biochemical cellular interactions, as well as the production of pro-inflammatory cytokines. In conclusion, the proposed gel-free 3D-mFCCSs represent a versatile and suitable alternative to microfluidic systems, replicating several features that occur within tumor microenvironments in the CNS. This research contributes to the characterization of microfluidic approaches and could lead to a better understanding of tumor biology and the eventual development of personalized therapies.

Co-delivery of temozolomide and quercetin with folic acid-conjugated exosomes in glioblastoma treatment.

Aim: The study aims to improve glioblastoma multiforme (GBM) treatment by combining temozolomide (TMZ) and quercetin (Qct), using folic acid (FA)-conjugated exosomes to overcome TMZ resistance and enhance blood-brain barrier (BBB) penetration.Methods: Exosomes were isolated and after characterizing and modifying their surfaces with FA, drug loading of TMZ and Qct into exosomes was done. In vitro assays, including cell viability tests, RT-PCR, Western-blotting and flow-cytometry, were performed using U87MG and U251MG GBM cell lines. In vivo analysis included administering exosome-drug formulations to glioblastoma-bearing Wistar rats, monitored through optical imaging and PET scans, followed by post-mortem immunohistochemistry and histological examination.Results: The results showed successful exosome isolation and FA conjugation, with drug release studies indicating accelerated release of TMZ and Qct in acidic conditions, enhancing cytotoxicity. Immunofluorescence indicated greater exosome uptake in GBM cells due to FA conjugation. Cell viability assays demonstrated increased toxicity of the combination therapy, correlating with elevated apoptosis. In vivo studies revealed significant tumor size reduction, alongside increased apoptosis and reduced angiogenesis, particularly in the TMZ-Qct-Exo-FA group.Conclusion: FA-conjugated exosomes loaded with TMZ and Qct represent a promising strategy to enhance GBM treatment efficacy by improving drug delivery, apoptosis induction and inhibiting the PI3K/Akt/mTOR pathway.