Regulatory T-cells (Tregs) are immunosuppressive T-cells, which arrest immune responses to ‘Self’ tissues. Some immunosuppressive Tregs that recognize seminal epitopes suppress immune responses to the proteins in semen, in both men and women. We postulated that GBMs express reproductive-associated proteins to manipulate reproductive Tregs and to gain immune privilege. We analyzed four GBM transcriptome databases representing ≈900 tumors for hypoxia-responsive Tregs, steroidogenic pathways, and sperm/testicular and placenta-specific genes, stratifying tumors by expression. In silico analysis suggested that the presence of reproductive-associated Tregs in GBM tumors was associated with worse patient outcomes. These tumors have an androgenic signature, express male-specific antigens, and attract reproductive-associated Related Orphan Receptor C (RORC)-Treg immunosuppressive cells. GBM patient sera were interrogated for the presence of anti-sperm/testicular antibodies, along with age-matched controls, utilizing monkey testicle sections. GBM patient serum contained anti-sperm/testicular antibodies at levels > six-fold that of controls. Myeloid-derived suppressor cells (MDSCs) and tumor-associated macrophages (TAMs) are associated with estrogenic tumors which appear to mimic placental tissue. We demonstrate that RORC-Tregs drive poor patient outcome, and Treg infiltration correlates strongly with androgen levels. Androgens support GBM expression of sperm/testicular proteins allowing Tregs from the patient’s reproductive system to infiltrate the tumor. In contrast, estrogen appears responsible for MDSC/TAM immunosuppression.
Background: Glioblastoma (GBM) can use metabolic fuels other than glucose (Glc). The ability of GBM to use galactose (Gal) as a fuel via the Leloir pathway is investigated. Methods: Gene transcript data were accessed to determine the association between expression of genes of the Leloir pathway and patient outcomes. Growth studies were performed on five primary patient-derived GBM cultures using Glc-free media supplemented with Gal. The role of Glut3/Glut14 in sugar import was investigated using antibody inhibition of hexose transport. A specific inhibitor of GALK1 (Cpd36) was used to inhibit Gal catabolism. Gal metabolism was examined using proton, carbon and phosphorous NMR spectroscopy, with 13C-labeled Glc and Gal as tracers. Results: Data analysis from published databases revealed that elevated levels of mRNA transcripts of SLC2A3 (Glut3), SLC2A14 (Glut14) and key Leloir pathway enzymes correlate with poor patient outcomes. GBM cultures proliferated when grown solely on Gal in Glc-free media and switching Glc-grown GBM cells into Gal-enriched/Glc-free media produced elevated levels of Glut3 and/or Glut14 enzymes. The 13C NMR-based metabolic flux analysis demonstrated a fully functional Leloir pathway and elevated pentose phosphate pathway activity for efficient Gal metabolism in GBM cells. Conclusion: Expression of Glut3 and/or Glut14 together with the enzymes of the Leloir pathway allows GBM to transport and metabolize Gal at physiological glucose concentrations, providing GBM cells with an alternate energy source. The presence of this pathway in GBM and its selective targeting may provide new treatment strategies.
Malignant gliomas, including glioblastomas, are extremely difficult to treat. The median survival for glioblastoma patients with optimal therapeutic intervention is 15 months. We developed a novel MAO-B-selectively activated prodrug, N,N-bis(2-chloroethyl)-2-(1-methyl-1,2,3,6-tetrahydropyridin-4-yl)propanamide (MP-MUS), for the treatment of gliomas based on 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP). The design of neutral MP-MUS involved the use of a seeker molecule capable of binding to mitochondrial MAO-B, which is up-regulated ≥fourfold in glioma cells. Once the binding occurs, MP-MUS is converted into a positively charged moiety, P(+) -MUS, which accumulates inside mitochondria at a theoretical maximal value of 1000:1 gradient. The LD50 of MP-MUS against glioma cells is 75 μM, which is two- to threefold more potent than temozolomide, a primary drug for gliomas. Importantly, MP-MUS was found to be selectively toxic toward glioma cells. In the concentration range of 150-180 μM MP-MUS killed 90-95 % of glioma cells, but stimulated the growth of normal human astrocytes. Moreover, maturation of MP-MUS is highly dependent on MAO-B, and inhibition of MAO-B activity with selegiline protected human glioma cells from apoptosis.
BACKGROUND We have recently shown that GBM use D-galactose (Gal) as a substrate, in vitro and in vivo. Gal is imported via Glut3 and/or Glut14 and metabolized through the Leloir pathway. We investigated 4-deoxy-4-fluorogalactose (4DFG) as the lead compound in a family of galactose-based antimetabolites. 4DFG is a potent chemotherapeutic in monotherapy and can bolster existing therapies. METHODS We examined the alteration of glioma metabolism in vitro and in vivo induced by 4DFG. 1H/13C-NMR and optical probes were used to interrogate the effects of 4DFG on glycolysis and mitochondrial respiration in primary glioma cell cultures. Labeled lectins were used to assay for the disruption of glycan synthesis induced by 4DFG. An intracranial model of primary GBM was used to assess efficacy and toxicity in vivo. RESULTS NMR reveals that at physiological concentrations of glucose, low concentrations of 4DFG (5 μM) is able to inhibit glycolytic and mitochondrial flux by approximately 12%, p< 0.05. Analysis using lectins shows a collapse in general glycan synthesis, but most especially in the incorporation of both Gal and GalNAc sugars. In nude mice with intracranial primary GBM, six treatments of 4DFG increased survival from 23 to 50 days, p< 0.002. DISCUSSION The ability of GBM to scavenge galactose allows us to target the Glut3/14 import and Leloir metabolic pathway using galactose-based anti-metabolites. Our first-generation compound is highly effective as a monotherapy, inhibiting glucose metabolism and glycan synthesis.
Based on the postulate that glioblastoma (GBM) tumors generate anti-inflammatory prostaglandins and bile salts to gain immune privilege, we analyzed 712 tumors in-silico from three GBM transcriptome databases for prostaglandin and bile synthesis/signaling enzyme-transcript markers. A pan-database correlation analysis was performed to identify cell-specific signal generation and downstream effects. The tumors were stratified by their ability to generate prostaglandins, their competency in bile salt synthesis, and the presence of bile acid receptors nuclear receptor subfamily 1, group H, member 4 (NR1H4) and G protein-coupled bile acid receptor 1 (GPBAR1). The survival analysis indicates that tumors capable of prostaglandin and/or bile salt synthesis are linked to poor outcomes. Tumor prostaglandin D2 and F2 syntheses are derived from infiltrating microglia, whereas prostaglandin E2 synthesis is derived from neutrophils. GBMs drive the microglial synthesis of PGD2/F2 by releasing/activating complement system component C3a. GBM expression of sperm-associated heat-shock proteins appears to stimulate neutrophilic PGE2 synthesis. The tumors that generate bile and express high levels of bile receptor NR1H4 have a fetal liver phenotype and a RORC-Treg infiltration signature. The bile-generating tumors that express high levels of GPBAR1 are infiltrated with immunosuppressive microglia/macrophage/myeloid-derived suppressor cells. These findings provide insight into how GBMs generate immune privilege and may explain the failure of checkpoint inhibitor therapy and provide novel targets for treatment.
Introduction We have reported that GBM utilize sex-steroids and reproduction-specific proteins to hijack the granting of immune-privilege to male/partner-specific antigens/epitopes. We have extended upon this foundation to examine other examples of immunosuppressive tissue-mimicry mechanisms that GBM deploy. The generation of prostaglandins D2, E2 and F2 and reproductive proteins are used by GBM tumors to activate discrete immune-cell types and to drive vascularization and growth. METHODS Three GBM-transcriptome databases were mined and analyzed utilizing pathway, stratification, correlation and survival analysis. RESULTS PGD2 and PGF2 synthesis is driven by C3AR1 microglial signaling, in response to complement C3a activation by GBM expression of C3 and CFB. PGD2 is expressed in hypoxic tumors and PGF2 is expressed in normoxic ones. PGF2 drives the hematopoietic stem cell angiogenic pathway, via TPBG/CXCL12/CXCR4. This is the primary pathway promoting early placental vascularization and vascular development/repair of mucosal tissues. Microglial synthesized PGD2 drives the CCL5/CCR5 axis, a pathway central to cyclic vascularization of uterine tissues and in wound healing, via VEGFA. Generation of CCL5 also recruits CCR5-positive monocytes, which are then driven into M2-TAM phenotype. CCL5 also recruits and drive myeloid cells into MDSCs. SOX9 drives masculinization of embryonic gonads. GBM expression of SOX9 correlates with seminal heat shock protein expression. These reproductive HSPs are associated with neutrophil generation of PGE2 in GBM tumors, mirroring their role in the semenized female reproductive tract, where they support PGE2 synthesis and aid EGFR driven vascularization CONCLUSIONS The ability of GBM to modulate the anti-tumor response is central to their lethality. The discrete, cell-specific mechanisms revealed will allow personalized medicine using off-the-shelf drug therapy.
A series of reduced graphene oxide and indium–gallium–zinc mixed oxide (RGO/IGZ) nanocomposites were successfully synthesised by a simple one‐step hydrothermal method. The as‐synthesised nanocomposites were characterised by crystallographic, microscopic, and spectroscopic methods to explore the robust photocatalytic activity of the prepared materials. XRD patterns confirmed the formation of highly pure, single‐phase, hexagonal In2Ga2ZnO7 with no impurity‐related peaks. All the photocatalysts absorbed visible light as observed from the diffuse reflectance UV/Vis spectra. The electron–hole recombination is effectively minimised by the formation of an RGO/metal oxide nanocomposite, which was successfully derived from a photoluminescence (PL) study and photoelectrochemical measurements. The decoration of IGZ nanocrystals onto reduced graphene sheets leads to significant quenching of its luminescent intensity, dramatically improved photocurrent generation (33 times more than neat IGZ) and significantly enhanced photostability. The high photocatalytic activity for H2 production is explained by the strong interaction between the IGZ nanocrystals with RGO sheets, low PL intensity, high photocurrent and large surface area.
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