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Glioblastoma multiforme (GBM),the most common and lethal tumor of the adult brain,generally shows chemo- and radioresistance. MicroRNAs (miRs) regulate physiological processes,such as resistance of GBM cells to temozolomide (TMZ). Although miRs are attractive targets for cancer therapeutics,the effectiveness of this approach requires targeted delivery. Mesenchymal stem cells (MSCs) can migrate to the sites of cancers,including GBM. We report on an increase in miR-9 in TMZ-resistant GBM cells. miR-9 was involved in the expression of the drug efflux transporter,P-glycoprotein. To block miR-9,methods were developed with Cy5-tagged anti-miR-9. Dye-transfer studies indicated intracellular communication between GBM cells and MSCs. This occurred by gap junctional intercellular communication and the release of microvesicles. In both cases,anti-miR-9 was transferred from MSCs to GBM cells. However,the major form of transfer occurred with the microvesicles. The delivery of anti-miR-9 to the resistant GBM cells reversed the expression of the multidrug transporter and sensitized the GBM cells to TMZ,as shown by increased cell death and caspase activity. The data showed a potential role for MSCs in the functional delivery of synthetic anti-miR-9 to reverse the chemoresistance of GBM cells.Molecular Therapy-Nucleic Acids (2013) 2,e126; doi:10.1038/mtna.2013.60; published online 1 October 2013. View Publication

The endoplasmic reticulum (ER) is involved in Ca2+ signaling and protein folding. ER Ca2+ depletion and accumulation of unfolded proteins activate the molecular chaperone GRP78 (glucose-regulated protein 78) which in turn triggers the ER stress response (ERSR) pathway aimed to restore ER homeostasis. Failure to adapt to stress,however,results in apoptosis. We and others have shown that malignant cells are more susceptible to ERSR-induced apoptosis than their normal counterparts,implicating the ERSR as a potential target for cancer therapeutics. Predicated on these findings,we developed an assay that uses a GRP78 biosensor to identify small molecule activators of ERSR in glioma cells. We performed a quantitative high-throughput screen (qHTS) against a collection of ˜425,000 compounds and a comprehensive panel of orthogonal secondary assays was formulated for stringent compound validation. We identified novel activators of ERSR,including a compound with a 2,9-diazaspiro[5.5]undecane core,which depletes intracellular Ca2+ stores and induces apoptosis-mediated cell death in several cancer cell lines,including patient-derived and 3D cultures of glioma cells. This study demonstrates that our screening platform enables the identification and profiling of ERSR inducers with cytotoxic activity and advocates for characterization of these compound in in vivo models. View Publication

BACKGROUND Glioma is the most common form of primary malignant brain tumor in adults,with approximately 4 cases per 100 000 people each year. Gliomas,like many tumors,are thought to primarily metabolize glucose for energy production; however,the reliance upon glycolysis has recently been called into question. In this study,we aimed to identify the metabolic fuel requirements of human glioma cells. METHODS We used database searches and tissue culture resources to evaluate genotype and protein expression,tracked oxygen consumption rates to study metabolic responses to various substrates,performed histochemical techniques and fluorescence-activated cell sorting-based mitotic profiling to study cellular proliferation rates,and employed an animal model of malignant glioma to evaluate a new therapeutic intervention. RESULTS We observed the presence of enzymes required for fatty acid oxidation within human glioma tissues. In addition,we demonstrated that this metabolic pathway is a major contributor to aerobic respiration in primary-cultured cells isolated from human glioma and grown under serum-free conditions. Moreover,inhibiting fatty acid oxidation reduces proliferative activity in these primary-cultured cells and prolongs survival in a syngeneic mouse model of malignant glioma. CONCLUSIONS Fatty acid oxidation enzymes are present and active within glioma tissues. Targeting this metabolic pathway reduces energy production and cellular proliferation in glioma cells. The drug etomoxir may provide therapeutic benefit to patients with malignant glioma. In addition,the expression of fatty acid oxidation enzymes may provide prognostic indicators for clinical practice. View Publication

UNLABELLED Certain murine leukemia viruses (MLVs) are capable of inducing fatal progressive spongiform motor neuron disease in mice that is largely mediated by viral Env glycoprotein expression within central nervous system (CNS) glia. While the etiologic mechanisms and the glial subtypes involved remain unresolved,infection of NG2 glia was recently observed to correlate spatially and temporally with altered neuronal physiology and spongiogenesis. Since one role of NG2 cells is to serve as oligodendrocyte (OL) progenitor cells (OPCs),we examined here whether their infection by neurovirulent (FrCasE) or nonneurovirulent (Fr57E) ecotropic MLVs influenced their viability and/or differentiation. Here,we demonstrate that OPCs,but not OLs,are major CNS targets of both FrCasE and Fr57E. We also show that MLV infection of neural progenitor cells (NPCs) in culture did not affect survival,proliferation,or OPC progenitor marker expression but suppressed certain glial differentiation markers. Assessment of glial differentiation in vivo using transplanted transgenic NPCs showed that,while MLVs did not affect cellular engraftment or survival,they did inhibit OL differentiation,irrespective of MLV neurovirulence. In addition,in chimeric brains,where FrCasE-infected NPC transplants caused neurodegeneration,the transplanted NPCs proliferated. These results suggest that MLV infection is not directly cytotoxic to OPCs but rather acts to interfere with OL differentiation. Since both FrCasE and Fr57E viruses restrict OL differentiation but only FrCasE induces overt neurodegeneration,restriction of OL maturation alone cannot account for neuropathogenesis. Instead neurodegeneration may involve a two-hit scenario where interference with OPC differentiation combined with glial Env-induced neuronal hyperexcitability precipitates disease. IMPORTANCE A variety of human and animal retroviruses are capable of causing central nervous system (CNS) neurodegeneration manifested as motor and cognitive deficits. These retroviruses infect a variety of CNS cell types; however,the specific role each cell type plays in neuropathogenesis remains to be established. The NG2 glia,whose CNS functions are only now emerging,are a newly appreciated viral target in murine leukemia virus (MLV)-induced neurodegeneration. Since one role of NG2 glia is that of oligodendrocyte progenitor cells (OPCs),we investigated here whether their infection by the neurovirulent MLV FrCasE contributed to neurodegeneration by affecting OPC viability and/or development. Our results show that both neurovirulent and nonneurovirulent MLVs interfere with oligodendrocyte differentiation. Thus,NG2 glial infection could contribute to neurodegeneration by preventing myelin formation and/or repair and by suspending OPCs in a state of persistent susceptibility to excitotoxic insult mediated by neurovirulent virus effects on other glial subtypes. View Publication

Growing evidence suggests that a physiological activity of the cellular prion protein (PrP(C)) plays a crucial role in several neurodegenerative disorders,including prion and Alzheimer's diseases. However,how the functional activity of PrP(C) is subverted to deliver neurotoxic signals remains uncertain. Transgenic (Tg) mice expressing PrP with a deletion of residues 105-125 in the central region (referred to as ΔCR PrP) provide important insights into this problem. Tg(ΔCR) mice exhibit neonatal lethality and massive degeneration of cerebellar granule neurons,a phenotype that is dose dependently suppressed by the presence of wild-type PrP. When expressed in cultured cells,ΔCR PrP induces large,ionic currents that can be detected by patch-clamping techniques. Here,we tested the hypothesis that abnormal ion channel activity underlies the neuronal death seen in Tg(ΔCR) mice. We find that ΔCR PrP induces abnormal ionic currents in neurons in culture and in cerebellar slices and that this activity sensitizes the neurons to glutamate-induced,calcium-mediated death. In combination with ultrastructural and biochemical analyses,these results demonstrate a role for glutamate-induced excitotoxicity in PrP-mediated neurodegeneration. A similar mechanism may operate in other neurodegenerative disorders attributable to toxic,β-rich oligomers that bind to PrP(C). View Publication

Tumor-initiating cells are a subpopulation in aggressive cancers that exhibit traits shared with stem cells,including the ability to self-renew and differentiate,commonly referred to as stemness. In addition,such cells are resistant to chemo- and radiation therapy posing a therapeutic challenge. To uncover stemness-associated functions in glioma-initiating cells (GICs),transcriptome profiles were compared to neural stem cells (NSCs) and gene ontology analysis identified an enrichment of Ca2+ signaling genes in NSCs and the more stem-like (NSC-proximal) GICs. Functional analysis in a set of different GIC lines regarding sensitivity to disturbed homeostasis using A23187 and Thapsigargin,revealed that NSC-proximal GICs were more sensitive,corroborating the transcriptome data. Furthermore,Ca2+ drug sensitivity was reduced in GICs after differentiation,with most potent effect in the NSC-proximal GIC,supporting a stemness-associated Ca2+ sensitivity. NSCs and the NSC-proximal GIC line expressed a larger number of ion channels permeable to potassium,sodium and Ca2+. Conversely,a higher number of and higher expression levels of Ca2+ binding genes that may buffer Ca2+,were expressed in NSC-distal GICs. In particular,expression of the AMPA glutamate receptor subunit GRIA1,was found to associate with Ca2+ sensitive NSC-proximal GICs,and decreased as GICs differentiated along with reduced Ca2+ drug sensitivity. The correlation between high expression of Ca2+ channels (such as GRIA1) and sensitivity to Ca2+ drugs was confirmed in an additional nine novel GIC lines. Calcium drug sensitivity also correlated with expression of the NSC markers nestin (NES) and FABP7 (BLBP,brain lipid-binding protein) in this extended analysis. In summary,NSC-associated NES+/FABP7+/GRIA1+ GICs were selectively sensitive to disturbances in Ca2+ homeostasis,providing a potential target mechanism for eradication of an immature population of malignant cells. View Publication

Hypoxia is a near-universal feature of cancer,promoting glycolysis,cellular proliferation,and angiogenesis. The molecular mechanisms of hypoxic signaling have been intensively studied,but the impact of changes in oxygen partial pressure (pO2) on the state of signaling networks is less clear. In a glioblastoma multiforme (GBM) cancer cell model,we examined the response of signaling networks to targeted pathway inhibition between 21% and 1% pO2. We used a microchip technology that facilitates quantification of a panel of functional proteins from statistical numbers of single cells. We find that near 1.5% pO2,the signaling network associated with mammalian target of rapamycin (mTOR) complex 1 (mTORC1)--a critical component of hypoxic signaling and a compelling cancer drug target--is deregulated in a manner such that it will be unresponsive to mTOR kinase inhibitors near 1.5% pO2,but will respond at higher or lower pO2 values. These predictions were validated through experiments on bulk GBM cell line cultures and on neurosphere cultures of a human-origin GBM xenograft tumor. We attempt to understand this behavior through the use of a quantitative version of Le Chatelier's principle,as well as through a steady-state kinetic model of protein interactions,both of which indicate that hypoxia can influence mTORC1 signaling as a switch. The Le Chatelier approach also indicates that this switch may be thought of as a type of phase transition. Our analysis indicates that certain biologically complex cell behaviors may be understood using fundamental,thermodynamics-motivated principles. View Publication

Metazoan development depends on the accurate execution of differentiation programs that allow pluripotent stem cells to adopt specific fates. Differentiation requires changes to chromatin architecture and transcriptional networks,yet whether other regulatory events support cell-fate determination is less well understood. Here we identify the ubiquitin ligase CUL3 in complex with its vertebrate-specific substrate adaptor KBTBD8 (CUL3(KBTBD8)) as an essential regulator of human and Xenopus tropicalis neural crest specification. CUL3(KBTBD8) monoubiquitylates NOLC1 and its paralogue TCOF1,the mutation of which underlies the neurocristopathy Treacher Collins syndrome. Ubiquitylation drives formation of a TCOF1-NOLC1 platform that connects RNA polymerase I with ribosome modification enzymes and remodels the translational program of differentiating cells in favour of neural crest specification. We conclude that ubiquitin-dependent regulation of translation is an important feature of cell-fate determination. View Publication

A network of transcription factors (TFs) determines cell identity,but identity can be altered by overexpressing a combination of TFs. However,choosing and verifying combinations of TFs for specific cell differentiation have been daunting due to the large number of possible combinations of 2,000 TFs. Here,we report the identification of individual TFs for lineage-specific cell differentiation based on the correlation matrix of global gene expression profiles. The overexpression of identified TFs-Myod1,Mef2c,Esx1,Foxa1,Hnf4a,Gata2,Gata3,Myc,Elf5,Irf2,Elf1,Sfpi1,Ets1,Smad7,Nr2f1,Sox11,Dmrt1,Sox9,Foxg1,Sox2,or Ascl1-can direct efficient,specific,and rapid differentiation into myocytes,hepatocytes,blood cells,and neurons. Furthermore,transfection of synthetic mRNAs of TFs generates their appropriate target cells. These results demonstrate both the utility of this approach to identify potent TFs for cell differentiation,and the unanticipated capacity of single TFs directly guides differentiation to specific lineage fates. View Publication

Because neurons are difficult to obtain from humans,generating functional neurons from human induced pluripotent stem cells (hiPSCs) is important for establishing physiological or disease-relevant screening systems for drug discovery. To examine the culture conditions leading to efficient differentiation of functional neural cells,we investigated the effects of oxygen stress (2% or 20% O2) and differentiation medium (DMEM/F12:Neurobasal-based [DN] or commercial [PhoenixSongs Biologicals; PS]) on the expression of genes related to neural differentiation,glutamate receptor function,and the formation of networks of neurons differentiated from hiPSCs (201B7) via long-term self-renewing neuroepithelial-like stem (lt-NES) cells. Expression of genes related to neural differentiation occurred more quickly in PS and/or 2% O2 than in DN and/or 20% O2,resulting in high responsiveness of neural cells to glutamate,N-methyl-d-aspartate (NMDA),α-amino-3-hydroxy-5-methyl-4-isoxazolepropionate (AMPA),and (S)-3,5-d... View Publication

Methamphetamine (METH) is a highly addictive psychostimulant drug of abuse that negatively interferes with neurogenesis. In fact,we have previously shown that METH triggers stem/progenitor cell death and decreases neuronal differentiation in the dentate gyrus (DG). Still,little is known regarding its effect on DG stem cell properties. Herein,we investigate the impact of METH on mice DG stem/progenitor cell self-renewal functions. METH (10nM) decreased DG stem cell self-renewal,while 1nM delayed cell cycle in the G0/G1-to-S phase transition and increased the number of quiescent cells (G0 phase),which correlated with a decrease in cyclin E,pEGFR and pERK1/2 protein levels. Importantly,both drug concentrations (1 or 10nM) did not induce cell death. In accordance with the impairment of self-renewal capacity,METH (10nM) decreased Sox2(+)/Sox2(+) while increased Sox2(-)/Sox2(-) pairs of daughter cells. This effect relied on N-methyl-d-aspartate (NMDA) signaling,which was prevented by the NMDA receptor antagonist,MK-801 (10μM). Moreover,METH (10nM) increased doublecortin (DCX) protein levels consistent with neuronal differentiation. In conclusion,METH alters DG stem cell properties by delaying cell cycle and decreasing self-renewal capacities,mechanisms that may contribute to DG neurogenesis impairment followed by cognitive deficits verified in METH consumers. View Publication

The prion protein (PrP) is highly conserved and ubiquitously expressed,suggesting that it plays an important physiological function. However,despite decades of investigation,this role remains elusive. Here,by using animal and cellular models,we unveil a key role of PrP in the DNA damage response. Exposure of neurons to a genotoxic stress activates PRNP transcription leading to an increased amount of PrP in the nucleus where it interacts with APE1,the major mammalian endonuclease essential for base excision repair,and stimulates its activity. Preventing the induction of PRNP results in accumulation of abasic sites in DNA and impairs cell survival after genotoxic treatment. Brains from Prnp(-/-) mice display a reduced APE1 activity and a defect in the repair of induced DNA damage in vivo. Thus,PrP is required to maintain genomic stability in response to genotoxic stresses. View Publication