Inhibits Glioma Progression Research Articles

TMOD-05. GLIOMA-ASSOCIATED OLIGODENDROCYTE PROGENITOR CELLS’ DYNAMIC PATTERNS SUGGEST FUNCTIONAL ADAPTATIONS DURING GLIOMA PROGRESSION IN A UNIQUE MOUSE MODEL

Abstract Gliomas account for more than one-third of brain tumors in children, with high fatality rate despite aggressive adjuvant treatment. Two-thirds of survivors suffer from health conditions due to the toxicity of conventional therapies. Notably, gliomas with the BRAFV600E mutation, occurring in ~20% of all glioma cases, are difficult to treat and have a high risk for progression, especially when combined with CDKN2A deletion. The mechanisms for glioma progression remain unclear and unraveling them could lead to therapies that inhibit glioma progression, preventing high-grade gliomas. Objectives: To gain mechanistic insights into glioma progression and exploit therapeutically for preventing progression. We developed two novel mouse models for BRAFV600E mutant progressive gliomas – one at high genetic risk for progression and one at intermediate genetic risk for progression. Expression of genetic alterations were induced by injecting compound transgenic mice with adenovirus-Cre. Our new mouse models therefore more faithfully recapitulated the genetic changes accompanying glioma formation and progression from low- to high-grade than earlier mouse models which used the RCAS system to overexpress the oncogene (PMCID: PMC11112369 ). Glioma formation was followed non-invasively by magnetic resonance imaging. Single cell RNA sequencing and spatial transcriptomics were performed and immunofluorescence was used for validation (PMCID: PMC10619673 ). We present new data showing that animal subject survival is significantly shorter in the high risk model than in the low risk model. Our two models with distinct latency can be used for preclinical studies and studies of the changes associated with progression, including in the glioma microenvironment. Analyses revealed temporal, functional, and spatial changes in glioma-associated oligodendrocyte progenitor cells (GA-OPCs) at distinct stages (initiation, expansion, progression) and grades. Our findings that GA-OPCs closely interact with glioma cells and their morphological transformation as gliomas progress, suggest changing functions, including potential roles in phagocytosis and immunomodulation. Understanding the unclear role of glioma microenvironment OPCs in promoting glioma progression could reveal an Achilles heel for targeted therapies.

WZ-3146 acts as a novel small molecule inhibitor of KIF4A to inhibit glioma progression by inducing apoptosis

BackgroundGlioma is considered the most common primary malignant tumor of the central nervous system. Although traditional treatments have not achieved satisfactory outcomes, recently, targeted therapies for glioma have shown promising efficacy. However, due to the single-target nature of targeted therapy, traditional targeted therapies are ineffective; thus, novel therapeutic targets are urgently needed.MethodsThe gene expression data for glioma patients were derived from the GEO (GSE4290, GSE50161), TCGA and CGGA databases. Next, the upregulated genes obtained from the above databases were cross-analyzed, finally, 10 overlapping genes (BIRC5, FOXM1, EZH2, CDK1, KIF11, KIF4A, NDC80, PBK, RRM2, and TOP2A) were ultimately screened and only KIF4A expression has the strongest correlation with clinical characteristics in glioma patients. Futher, the TCGA and CGGA database were utilized to explore the correlation of KIF4A expression with glioma prognosis. Then, qRT-PCR and Western blot was used to detect the KIF4A mRNA and protein expression level in glioma cells, respectively. And WZ-3146, the small molecule inhibitor targeting KIF4A, were screened by Cmap analysis. Subsequently, the effect of KIF4A knockdown or WZ-3146 treatment on glioma was measured by the MTT, EdU, Colony formation assay and Transwell assay. Ultimately, GSEA enrichment analysis was performed to find that the apoptotic pathway could be regulated by KIF4A in glioma, in addition, the effect of WZ-3146 on glioma apoptosis was detected by flow cytometry and Western blot.ResultsIn the present study, we confirmed that KIF4A is abnormally overexpressed in glioma. In addition, KIF4A overexpression is a key indicator of glioma prognosis; moreover, suppressing KIF4A expression can inhibit glioma progression. We also discovered that WZ-3146, a small molecule inhibitor of KIF4A, can induce apoptosis in glioma cells and exhibit antiglioma effects.ConclusionIn conclusion, these observations demonstrated that targeting KIF4A can inhibit glioma progression. With further research, WZ-3146, a small molecule inhibitor of KIF4A, could be combined with other molecular targeted drugs to cooperatively inhibit glioma progression.

Unveiling the therapeutic potential of IHMT-337 in glioma treatment: targeting the EZH2-SLC12A5 axis

Glioma is the most common malignant tumor of the central nervous system, with EZH2 playing a crucial regulatory role. This study further explores the abnormal expression of EZH2 and its mechanisms in regulating glioma progression. Additionally, it was found that IHMT-337 can potentially be a therapeutic agent for glioma. The prognosis, expression, and localization of EZH2 were determined using bioinformatics, IHC staining, Western blot (WB) analysis, and immunofluorescence (IF) localization. The effects of EZH2 on cell function were assessed using CCK-8 assays, Transwell assays, and wound healing assays. Public databases and RT-qPCR were utilized to identify downstream targets. The mechanisms regulating these downstream targets were elucidated using MS-PCR and WB analysis. The efficacy of IHMT-337 was demonstrated through IC50 measurements, WB analysis, and RT-qPCR. The effects of IHMT-337 on glioma cells in vitro were evaluated using Transwell assays, EdU incorporation assays, and flow cytometry. The potential of IHMT-337 as a treatment for glioma was assessed using a blood–brain barrier (BBB) model and an orthotopic glioma model. Our research confirms significantly elevated EZH2 expression in gliomas, correlating with patient prognosis. EZH2 facilitates glioma proliferation, migration, and invasion alongside promoting SLC12A5 DNA methylation. By regulating SLC12A5 expression, EZH2 activates the WNK1-OSR1-NKCC1 pathway, enhancing its interaction with ERM to promote glioma migration. IHMT-337 targets EZH2 in vitro to inhibit WNK1 activation, thereby suppressing glioma cell migration. Additionally, it inhibits cell proliferation and arrests the cell cycle. IHMT-337 has the potential to cross the BBB and has successfully inhibited glioma progression in vivo. This study expands our understanding of the EZH2-SLC12A5 axis in gliomas, laying a new foundation for the clinical translation of IHMT-337 and offering new insights for precision glioma therapy.

Knockdown of trem2 promotes proinflammatory microglia and inhibits glioma progression via the JAK2/STAT3 and NF-κB pathways

BackgroundIn the tumor immune microenvironment (TIME), triggering receptor expressed on myeloid cells 2 (trem2) is widely considered to be a crucial molecule on tumor-associated macrophages(TAMs). Multiple studies have shown that trem2 may function as an immune checkpoint in various malignant tumors, mediating tumor immune evasion. However, its specific molecular mechanisms, especially in glioma, remain elusive.MethodsLentivirus was transfected to establish cells with stable knockdown of trem2. A Transwell system was used for segregated coculture of glioma cells and microglia. Western blotting, quantitative real-time polymerase chain reaction (qRT‒PCR), and immunofluorescence (IF) were used to measure the expression levels of target proteins. The proliferation, invasion, and migration of cells were detected by colony formation, cell counting kit-8 (CCK8), 5-ethynyl-2’-deoxyuridine (EdU) and transwell assays. The cell cycle, apoptosis rate and reactive oxygen species (ROS) level of cells were assessed using flow cytometry assays. The comet assay and tube formation assay were used to detect DNA damage in glioma cells and angiogenesis activity, respectively. Gl261 cell lines and C57BL/6 mice were used to construct the glioma orthotopic transplantation tumor model.ResultsTrem2 was highly overexpressed in glioma TAMs. Knocking down trem2 in microglia suppressed the growth and angiogenesis activity of glioma cells in vivo and in vitro. Mechanistically, knockdown of trem2 in microglia promoted proinflammatory microglia and inhibited anti-inflammatory microglia by activating jak2/stat1 and inhibiting the NF-κB p50 signaling pathway. The proinflammatory microglia produced high concentrations of nitric oxide (NO) and high levels of the proinflammatory cytokines TNF-α, IL-6, and IL-1β, and caused further DNA damage and promoted the apoptosis rate of tumor cells.ConclusionsOur findings revealed that trem2 in microglia plays a significant role in the TIME of gliomas. Knockdown of trem2 in microglia might help to improve the efficiency of inhibiting glioma growth and delaying tumor progression and provide new ideas for further treatment of glioma.

Abstract 6812: Durable control of brain tumors by glioma inhibitory macrophages and IL33

Abstract Glioblastoma is the most common and deadly form of brain cancer. Even with aggressive treatment including surgery, chemotherapy, and radiotherapy, survival outcomes for newly diagnosed glioblastoma patients remains less than two years. Novel high throughput omics technologies have expanded our understanding of the role of innate immune system in brain tumors, that are generally believed to drive glioma progression and enable evasion of the adaptive immune system. However, targeting of this axis in the clinic remains an unmet opportunity. Previously, we discovered that the dual-function (secreted and nuclear) cytokine IL-33 is a crucial regulator of the inflammatory microenvironment that promotes glioma tumorigenesis through phenotypic and functional changes in the innate immune cell repertoire. Strikingly, when IL-33 is prevented from entering the nucleus, by deletion of its nuclear localization sequence (ΔNLS IL-33), but is still secreted, in vivo tumor growth is dramatically inhibited resulting in prolonged long-term survival. Using multiplex immunohistochemistry and spatial transcriptomics with temporal resolution across different stages of tumor progression, we identified a population of glioma-inhibitory macrophages (GIMs) unique to this suppressive environment. Assessment of GIMs in xenografts generated from patient brain tumor initiating cells found an enriched presence of these cells in xenografts with long-term survival (greater than 300 days) versus short-term survival (less than 100 days). The ability of GIMs to inhibit glioma progression was demonstrated when tumors established using a combination of ΔNLS IL-33 expressing cancer cells together with highly tumorigenic cells resulted in a growth inhibitory environment that significantly extended survival. A deeper molecular characterization of this phenotype and development of clinical strategies are currently underway. Citation Format: Shyam V. Menon, Xueqing Lun, Peipei Zeng, Jianbo Zhang, Bo Young Ahn, Henry Yu, Alisha Poole, Ngoc Ha Dang, Katalin Osz, Jennifer A. Chan, Daniela F. Quail, Stephen M. Robbins, Donna L. Senger. Durable control of brain tumors by glioma inhibitory macrophages and IL33 [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 6812.

NPS-2143 inhibit glioma progression by suppressing autophagy through mediating AKT-mTOR pathway.

Gliomas are the most common tumours in the central nervous system. In the present study, we aimed to find a promising anti-glioma compound and investigate the underlying molecular mechanism. Glioma cells were subjected to the 50 candidate compounds at a final concentration of 10 μM for 72 h, and CCK-8 was used to evaluate their cytotoxicity. NPS-2143, an antagonist of calcium-sensing receptor (CASR), was selected for further study due to its potent cytotoxicity to glioma cells. Our results showed that NPS-2143 could inhibit the proliferation of glioma cells and induce G1 phase cell cycle arrest. Meanwhile, NPS-2143 could induce glioma cell apoptosis by increasing the caspase-3/6/9 activity. NPS-2143 impaired the immigration and invasion ability of glioma cells by regulating the epithelial-mesenchymal transition process. Mechanically, NPS-2143 could inhibit autophagy by mediating the AKT-mTOR pathway. Bioinformatic analysis showed that the prognosis of glioma patients with low expression of CASR mRNA was better than those with high expression of CASR mRNA. Gene set enrichment analysis showed that CASR was associated with cell adhesion molecules and lysosomes in glioma. The nude mice xenograft model showed NPS-2143 could suppress glioma growth invivo. In conclusion, NPS-2143 can suppress the glioma progression by inhibiting autophagy.

Study on Inhibition of Glioma Tumorigenesis by Circular RNA Mitogen-Activated Protein Kinase 1 via miR-587/Dipeptidyl Peptidase 9 Regulatory Pathway

Accumulating evidence verified that, circular RNA MAPK1 (Hsa_circ_0004872) is involved in tumorigenesis, and whether circMAPK1 is involved in glioma remains unclear. circMAPK1 was markedly downregulated in glioma tissues. Upregulation of circMAPK1 attenuated activities of glioma cells. Moreover, circMAPK1 could bind miR-587, which was upregulated in glioma cells. DPP9 was a downstream gene for miR-587, indicating that, DPP9 upregulation inhibits glioma progression, while downregulation of DPP9 abolished circMAPK1 overexpression effect on glioma cell growth. Our discoveries demonstrated that, the circMAPK1 is a tumor suppressor by regulating the circMAPK1/miR-587/DPP9 signaling pathway in glioma, and circMAPK1 might be a potential biomarker or target for glioma diagnosis and therapy.

Dishevelled-associated antagonist of β-catenin homolog 3 (DACT3) suppresses glioma progression though Notch1 signaling pathway in β-catenin-dependent manner

The disheveled-associated antagonist of β-catenin homolog 3 (DACT3) has been recognized as a tumor suppressor in various cancers. However, the function of DACT3 on glioma malignant progression along with potential molecular mechanisms is poorly clarified. This research aimed to investigate how DACT3 contributes to suppressing the progression of glioma. In our investigation, a pronounced decrease in DACT3 expression was observed in glioma tissues. Through the overexpression of DACT3, we noted a significant suppression in the proliferation, invasion, and migration of glioma cells, while concurrently observing an increase in cell adhesion. Our exploration into the molecular mechanisms revealed that DACT3 executes its tumor-suppressive role by impeding the expression of notch 1 intracellular domain (NICD) and translocating into the nucleus by downregulating the expression of β-catenin. Consequently, this process leads to the suppression of Notch1 signaling. To summarize, our findings reveal the function of DACT3 to inhibit glioma progression via the Notch1 signaling pathway in β-catenin dependent manner. This study stands as the pioneer in examining the role of DACT3 in glioma progression and comprehensively elucidating its molecular mechanisms in glioma development. Therefore, our results suggest that DACT3 holds promise as both a prognostic factor and a potential biomarker for guiding treatment strategies in glioma patients (Graphical Abstract).

Oncolytic virus Ad-TD-nsIL-12 inhibits glioma growth and reprograms the tumor immune microenvironment

AimsGliomas are the most common central nervous system malignancies, with limited therapeutic options and poor prognosis, which are primarily attributed to the “immune desert” microenvironment. Previously, we constructed a three-gene-deleted oncolytic adenovirus (Ad-TD) loaded with non-secreting interleukin-12 (nsIL-12), which could be amplified in tumor cells and induce immunity to suppress tumors. However, the effects of this oncolytic virus on gliomas and their immune microenvironment remain unclear. There is an urgent need for further research. Materials and methodsWe constructed a Syrian hamster brain tumor model and demonstrated the efficacy and mechanism of the novel oncolytic virus in treating brain tumors through a series of in vitro and in vivo experiments. We investigated the efficacy and safety (the number of hamsters in each group is either 5 or 10) of the oncolytic virus treatment in Syrian hamsters using a virus-treated group, a control virus-treated group, and a blank control group. Key findingsIn vitro assays showed that Ad-TD-nsIL-12 could specifically proliferate in brain tumor cells which induce tumor cell apoptosis and intracellular expression of interleukin (IL)-12. Moreover, in vivo experiments demonstrated that Ad-TD-nsIL-12 could effectively inhibit the progression of brain tumors and prolong survival. Ad-TD-nsIL-12 significantly enhanced T-cell infiltration in the brain tumor microenvironment. SignificanceAd-TD-nsIL-12 can inhibit glioma progression and increase T-cell infiltration in the tumor tissue, particularly infiltration by cytotoxic T cells (CD8+). Ad-TD-nsIL-12 can amplify and produce IL-12, inducing anti-glioma immune responses to inhibit tumor progression.

Knockdown of SLC39A14 inhibits glioma progression by promoting erastin-induced ferroptosis SLC39A14 knockdown inhibits glioma progression

BackgroundFerroptosis is a newly classified form of regulated cell death with implications in various tumor progression pathways. However, the roles and mechanisms of ferroptosis-related genes in glioma remain unclear.MethodsBioinformatics analysis was employed to identify differentially expressed ferroptosis-related genes in glioma. The expression levels of hub genes were assessed using real-time reverse transcriptase-polymerase chain reaction (RT-qPCR). To explore the role of SLC39A14 in glioma, a series of in vitro assays were conducted, including cell counting kit-8 (CCK-8), 5-ethynyl-2’-deoxyuridine (EdU), flow cytometry, wound healing, and Transwell assays. Enzyme-linked immunosorbent assay (ELISA) was utilized to measure the levels of indicators associated with ferroptosis. Hematoxylin-eosin (HE) and immunohistochemistry (IHC) staining were performed to illustrate the clinicopathological features of the mouse transplantation tumor model. Additionally, Western blot analysis was used to assess the expression of the cGMP-PKG pathway-related proteins.ResultsSeven ferroptosis-related hub genes, namely SLC39A14, WWTR1, STEAP3, NOTCH2, IREB2, HIF1A, and FANCD2, were identified, all of which were highly expressed in glioma. Knockdown of SLC39A14 inhibited glioma cell proliferation, migration, and invasion, while promoting apoptosis. Moreover, SLC39A14 knockdown also facilitated erastin-induced ferroptosis, leading to the suppression of mouse transplantation tumor growth. Mechanistically, SLC39A14 knockdown inhibited the cGMP-PKG signaling pathway activation.ConclusionSilencing SLC39A14 inhibits ferroptosis and tumor progression, potentially involving the regulation of the cGMP-PKG signaling pathway.

Oncolytic Viral Therapy for Glioma by Recombinant Sindbis Virus.

The characteristics of glioblastoma, such as drug resistance during treatment, short patient survival, and high recurrence rates, have made patients with glioblastoma more likely to benefit from oncolytic therapy. In this study, we investigated the safety of the sindbis virus by injecting virus intravenously and intracranially in mice and evaluated the therapeutic effect of the virus carrying different combinations of IL-12, IL-7, and GM-CSF on glioma in a glioma-bearing mouse model. SINV was autologously eliminated from the serum and organs as well as from neural networks after entering mice. Furthermore, SINV was restricted to the injection site in the tree shrew brain and did not spread throughout the whole brain. In addition, we found that SINV-induced apoptosis in conjunction with the stimulation of the immune system by tumor-killing cytokines substantially suppressed tumor development. It is worth mentioning that SINV carrying IL-7 and IL-12 had the most notable glioma-killing effect. Furthermore, in an intracranial glioma model, SINV containing IL-7 and IL-12 effectively prolonged the survival time of mice and inhibited glioma progression. These results suggest that SINV has a significant safety profile as an oncolytic virus and that combining SINV with cytokines is an efficient treatment option for malignant gliomas.

Inhibition of hyaluronic acid degradation pathway suppresses glioma progression by inducing apoptosis and cell cycle arrest

BackgroundAbnormal hyaluronic acid (HA) metabolism is a major factor in tumor progression, and the metabolic regulation of HA mainly includes HA biosynthesis and catabolism. In glioma, abnormal HA biosynthesis is intimately involved in glioma malignant biological properties and the formation of immunosuppressive microenvironment; however, the role of abnormal HA catabolism in glioma remains unclear.MethodsHA catabolism is dependent on hyaluronidase. In TCGA and GEPIA databases, we found that among the 6 human hyaluronidases (HYAL1, HYAL2, HYAL3, HYAL4, HYALP1, SPAM1), only HYAL2 expression was highest in glioma. Next, TCGA and CGGA database were further used to explore the correlation of HYAL2 expression with glioma prognosis. Then, the mRNA expression and protein level of HYAL2 was determined by qRT-PCR, Western blot and Immunohistochemical staining in glioma cells and glioma tissues, respectively. The MTT, EdU and Colony formation assay were used to measure the effect of HYAL2 knockdown on glioma. The GSEA enrichment analysis was performed to explore the potential pathway regulated by HYAL2 in glioma, in addition, the HYAL2-regulated signaling pathways were detected by flow cytometry and Western blot. Finally, small molecule compounds targeting HYAL2 in glioma were screened by Cmap analysis.ResultsIn the present study, we confirmed that Hyaluronidase 2 (HYAL2) is abnormally overexpressed in glioma. Moreover, we found that HYAL2 overexpression is associated with multiple glioma clinical traits and acts as a key indicator for glioma prognosis. Targeting HYAL2 could inhibit glioma progression by inducing glioma cell apoptosis and cell cycle arrest.ConclusionCollectively, these observations suggest that HYAL2 overexpression could promote glioma progression. Thus, treatments that disrupt HA catabolism by altering HYAL2 expression may serve as effective strategies for glioma treatment.

Retracted: Peptide ARHGEF9 Inhibits Glioma Progression via PI3K/AKT/mTOR Pathway.

[This retracts the article DOI: 10.1155/2023/7146589.].

Hsa_circ_0010889 downregulation inhibits malignant glioma progression by modulating the miR-590-5p/SATB1 axis.

Glioma is a general neurological tumor and circular RNAs (circRNAs) have been implicated in glioma development. However, the underlying mechanisms and circRNA biological functions responsible for the regulation of glioma progression remain unknown. In this study, we employ next-generation sequencing (NGS) to investigate altered circRNA expression in glioma tissues. Regulatory mechanisms were studied using luciferase reporter analyses, transwell migration, CCK8, and EdU analysis. Tumorigenesis and metastasis assays were utilized to determine the function of hsa_circ_0010889 in glioma. Our results showed that hsa_circ_0010889 expression increased in glioma cell lines and tissues, indicating that hsa_circ_0010889 may be involved in glioma progression. Downregulation of hsa_circ_0010889 inhibited glioma invasion and proliferation in both in vitro and in vivo experiments and luciferase report assays found that miR-590-5p and SATB1 were downstream targets for hsa_circ_0010889. SATB1 overexpression or miR-590-5p inhibition reversed glioma cells proliferation and migration post-silencing of hsa_circ_0010889. Taken together, our study demonstrates that hsa_circ_0010889 downregulation inhibits glioma progression through the miR-590-5p/SATB1 axis.

NUCLEAR DEFECTIVE IL-33 DRIVES AN ANTI-TUMORIGENIC MICROENVIRONMENT IN GLIOBLASTOMA

Abstract Despite a sophisticated treatment regimen, including surgery, chemotherapy, and radiotherapy, survival outcomes for glioblastoma remain at a dismal 14.6 months. Multi-omics profiling have established that myeloid phagocytes drive glioma progression and contribute to therapeutic resistance. However, effective targeting of this axis remains an unmet clinical opportunity. Previously, we found that the dual-function (secreted and nuclear) cytokine IL-33 is a key regulator of the inflammatory microenvironment that aids glioma tumorigenesis through phenotypic and functional changes in the innate immune cell repertoire. Strikingly, when IL-33 is prevented from entering the nucleus, by deletion of its nuclear localization signal (ΔNLS IL-33), but is still secreted, in vivo tumor growth is dramatically suppressed resulting in extended long-term survival. Using spatial transcriptomics and multiplex immunohistochemistry with temporal resolution at different stages of tumor progression, we identified a population of glioma-inhibitory macrophages (GIMs) unique to this suppressive environment. Assessment of xenografts generated from patient brain tumor initiating cells found an enrichment of GIMs in xenografts with long-term survival (>300 days) compared to short-term survivors (<100 days). The ability of GIMs to inhibit glioma progression was further highlighted when tumors established using a combination of ΔNLS IL-33 expressing cancer cells together with highly tumorigenic cells resulted in a growth inhibitory environment that significantly prolonged survival through the polarization and activation of GIMs. Additional characterization of this phenotype and development of clinical strategies to deliver ΔNLS IL-33 to brain tumors is warranted to determine if recruitment and activation of GIMs is a translatable therapeutic strategy for glioma patients.

CNSC-02. INVESTIGATING THE ROLE OF THE WNT SIGNALING TRANSDUCTION PATHWAY IN GLIOMA BLOOD-BRAIN-BARRIER INTEGRITY

Abstract The WNT signaling transduction pathway has been linked to cancer stem cell self-renewal, differentiation, and blood brain barrier (BBB) development. Previous studies have shown that WNT pathway inhibition increased BBB permeability, specifically in WNT medulloblastoma. Glioblastoma, an aggressive malignant tumor with poor prognosis, has also been shown to have high WNT expression and variable BBB permeability. We hypothesize that activating WNT pathway inhibition in glioblastoma stem cells (GSCs) will inhibit glioma progression, increase BBB permeability within the tumor microenvironment, and enhance overall treatment responsiveness. We transduced primary pediatric derived glioma stem cells with overexpressing vectors for WNT inhibitors (DKK1 or WIF1). To characterize effects of DKK1 or WIF1 overexpression, we evaluated cell migration patterns via RTCA xCelligence, cell cycle progression via Annexin 5 assays, and cell viability via cell-titer glo. Brain endothelial cell integrity was evaluated with the treatment of CHIR99021, WNT pathway activator, or GSC condition media with immunoblotting for junctional protein expression (Claudin-5, Claudin-3, Occludin, ZO-1, VE-Cadherin). Verification of WNT inhibitory overexpressing GSCs for DKK1 and WIF1 was performed using RNAseq, proteomics, and immunoblotting. DKK1-GSCs demonstrated a statistically significant impairment in the migratory slope compared to empty vector GSCs. Cell cycle analysis also revealed that DKK1-GSCs were arrested in G0/1 phase while WIF1-GSCs were arrested in S/G2M phase. CHIR99021 endothelial treatment resulted in increased secretion of WNT inhibitors DKK1 and SFRP1 and resultantly, there was a decrease in junctional protein expression. Overall, WNT inhibitor overexpressing GSCs exhibited unique cellular patterns and indirectly disrupted endothelial cell integrity. Future studies will evaluate orthotopic WNT inhibitor overexpressing transplant rodent models to determine BBB integrity, drug permeability, model survival, and chemotherapeutic treatment response. By enhancing our understanding of the WNT pathway in GSCs, we anticipate understanding the use of future therapeutic WNT pathway targeting to increase chemotherapeutic responsiveness and improve glioblastoma prognosis.

Sertindole inhibits autophagic flux and glioma progression

AbstractGliomas, the most lethal brain tumors, often exhibit resistance to conventional chemotherapy and/or radiotherapy. This study reveals that sertindole, a potent dopamine D2 receptor antagonist primarily designed as an antipsychotic medication for schizophrenia, effectively inhibits glioma progression. Our findings demonstrate that sertindole suppresses the proliferation of U251 and U87 tumor cells, impedes cell cycle progression in vitro, and curtails xenograft tumor growth in vivo. Moreover, we present compelling evidence demonstrating the ability of sertindole to enhance the cellular response to the chemotherapeutic agent temozolomide both in vitro and in vivo. Additionally, our findings reveal that sertindole effectively suppresses the self‐renewal capacity and expression of stemness‐associated genes, such as Nanog and Sox2, in glioma tumor cells and glioma stem cells. A mechanistic investigation demonstrated that sertindole enhances the formation of autophagosome–lysosome complexes while concurrently impeding autophagic flux through the inhibition of lysosomal hydrolytic enzymes CTSD and CTSB, ultimately resulting in decreased growth of tumor cells. In conclusion, our findings suggest that sertindole has the potential to develop into a potent antiglioma therapeutic agent.

M1 macrophage-derived exosomes containing miR-150 inhibit glioma progression by targeting MMP16

A large amount of clinical and experimental evidence indicates that M1 macrophages can inhibit tumor progression and expansion; however, the molecular mechanism by which macrophage-derived exosomes inhibit the proliferation of glioblastoma cells has not yet been elucidated. Here, we used M1 macrophage exosomes encapsulating microRNAs to inhibit the proliferation of glioma cells. Exosomes derived from M1 macrophages exhibited high expression levels of miR-150, and the inhibition of glioma cell proliferation mediated by exosomes derived from M1 macrophages was dependent on this microRNA. Mechanistically, miR-150 is transferred to glioblastoma cells through M1 macrophages and binds to MMP16, downregulating its expression and inhibiting glioma progression. Overall, these findings indicate that M1 macrophage-derived exosomes carrying miR-150 inhibit the proliferation of glioblastoma cells through targeted binding to MMP16. This dynamic mutual influence between glioblastoma cells and M1 macrophages provides new opportunities for the treatment of glioma.

P53 inhibits the Urea cycle and represses polyamine biosynthesis in glioma cell lines.

Glioma is the most common malignant tumor of the central nervous system. The urea cycle (UC) is an essential pathway to convert excess nitrogen and ammonia into the less toxic urea in humans. However, less is known about the functional significance of the urea cycle in glioma. p53 functions as a tumor suppressor and modulates several cellular functions and disease processes. In the present study, we aimed to explore whether p53 influences glioma progression by regulating the urea cycle. Here, we demonstrated the inhibitory impact of p53 on the expression of urea cycle enzymes and urea genesis in glioma cells. The level of polyamine, a urea cycle metabolite, was also regulated by p53 in glioma cells. Carbamoyl phosphate synthetase-1 (CPS1) is the first key enzyme involved in the urea cycle. Functionally, we demonstrated that CPS1 knockdown suppressed glioma cell proliferation, migration and invasion. Mechanistically, we demonstrated that the expression of ornithine decarboxylase (ODC), which determines the generation of polyamine, was regulated by CPS1. In addition, the impacts of p53 knockdown on ODC expression, glioma cell growth and aggressive phenotypes were significantly reversed by CPS1 inhibition. In conclusion, these results demonstrated that p53 inhibits polyamine metabolism by suppressing the urea cycle, which inhibits glioma progression.

MUC1 promotes glioblastoma progression and TMZ resistance by stabilizing EGFRvIII

Epidermal growth factor receptor variant III (EGFRvIII) is a mutant isoform of EGFR with a deletion of exons 2–7 making it insensitive to EGF stimulation and downstream signal constitutive activation. However, the mechanism underlying the stability of EGFRvIII remains unclear. Based on CRISPR-Cas9 library screening, we found that mucin1 (MUC1) is essential for EGFRvIII glioma cell survival and temozolomide (TMZ) resistance. We revealed that MUC1-C was upregulated in EGFRvIII-positive cells, where it enhanced the stability of EGFRvIII. Knockdown of MUC1-C increased the colocalization of EGFRvIII and lysosomes. Upregulation of MUC1 occurred in an NF-κB dependent manner, and inhibition of the NF-κB pathway could interrupt the EGFRvIII-MUC1 feedback loop by inhibiting MUC1-C. In a previous report, we identified AC1Q3QWB (AQB), a small molecule that could inhibit the phosphorylation of NF-κB. By screening the structural analogs of AQB, we obtained EPIC-1027, which could inhibit the NF-κB pathway more effectively. EPIC-1027 disrupted the EGFRvIII-MUC1-C positive feedback loop in vitro and in vivo, inhibited glioma progression, and promoted sensitization to TMZ. In conclusion, we revealed the pivotal role of MUC1-C in stabilizing EGFRvIII in glioblastoma (GBM) and identified a small molecule, EPIC-1027, with great potential in GBM treatment.