技术资料

The resistance of glioma cells to a number of antitumor agents and the highly invasive nature of glioma cells that escape the primary tumor mass are key impediments to the eradication of tumors in glioma patients. In this study,we evaluated the therapeutic efficacy of a novel PI3-kinase/mTOR inhibitor,PI-103,in established glioma lines and primary CD133(+) glioma-initiating cells and explored the potential of combining PI-103 with stem cell-delivered secretable tumor necrosis factor apoptosis-inducing ligand (S-TRAIL) both in vitro and in orthotopic mouse models of gliomas. We show that PI-103 inhibits proliferation and invasion,causes G(0)-G(1) arrest in cell cycle,and results in significant attenuation of orthotopic tumor growth in vivo. Establishing cocultures of neural stem cells (NSC) and glioma cells,we show that PI-103 augments the response of glioma cells to stem cell-delivered S-TRAIL. Using bimodal optical imaging,we show that when different regimens of systemic PI-103 delivery are combined with NSC-derived S-TRAIL,a significant reduction in tumor volumes is observed compared with PI-103 treatment alone. To our knowledge,this is the first study that reveals the antitumor effect of PI-103 in intracranial gliomas. Our findings offer a preclinical rationale for application of mechanism-based systemically delivered antiproliferative agents and novel stem cell-based proapoptotic therapies to improve treatment of malignant gliomas. View Publication

Within high-grade gliomas,the precise identities and functional roles of stem-like cells remain unclear. In the normal neurogenic niche,ID (Inhibitor of DNA-binding) genes maintain self-renewal and multipotency of adult neural stem cells. Using PDGF- and KRAS-driven murine models of gliomagenesis,we show that high Id1 expression (Id1(high)) identifies tumor cells with high self-renewal capacity,while low Id1 expression (Id1(low)) identifies tumor cells with proliferative potential but limited self-renewal capacity. Surprisingly,Id1(low) cells generate tumors more rapidly and with higher penetrance than Id1(high) cells. Further,eliminating tumor cell self-renewal through deletion of Id1 has modest effects on animal survival,while knockdown of Olig2 within Id1(low) cells has a significant survival benefit,underscoring the importance of non-self-renewing lineages in disease progression. View Publication

The identification of succinate dehydrogenase (SDH),fumarate hydratase (FH) and isocitrate dehydrogenase (IDH) mutations in human cancers has rekindled the idea that altered cellular metabolism can transform cells. Inactivating SDH and FH mutations cause the accumulation of succinate and fumarate,respectively,which can inhibit 2-oxoglutarate (2-OG)-dependent enzymes,including the EGLN prolyl 4-hydroxylases that mark the hypoxia inducible factor (HIF) transcription factor for polyubiquitylation and proteasomal degradation. Inappropriate HIF activation is suspected of contributing to the pathogenesis of SDH-defective and FH-defective tumours but can suppress tumour growth in some other contexts. IDH1 and IDH2,which catalyse the interconversion of isocitrate and 2-OG,are frequently mutated in human brain tumours and leukaemias. The resulting mutants have the neomorphic ability to convert 2-OG to the (R)-enantiomer of 2-hydroxyglutarate ((R)-2HG). Here we show that (R)-2HG,but not (S)-2HG,stimulates EGLN activity,leading to diminished HIF levels,which enhances the proliferation and soft agar growth of human astrocytes. These findings define an enantiomer-specific mechanism by which the (R)-2HG that accumulates in IDH mutant brain tumours promotes transformation and provide a justification for exploring EGLN inhibition as a potential treatment strategy. View Publication

The detection of growth hormone (GH) and its receptor in germinal regions of the mammalian brain prompted our investigation of GH and its role in the regulation of endogenous neural precursor cell activity. Here we report that the addition of exogenous GH significantly increased the expansion rate in long-term neurosphere cultures derived from wild-type mice,while neurospheres derived from GH null mice exhibited a reduced expansion rate. We also detected a doubling in the frequency of large (i.e. stem cell-derived) colonies for up to 120 days following a 7-day intracerebroventricular infusion of GH suggesting the activation of endogenous stem cells. Moreover,gamma irradiation induced the ablation of normally quiescent stem cells in GH-infused mice,resulting in a decline in olfactory bulb neurogenesis. These results suggest that GH activates populations of resident stem and progenitor cells,and therefore may represent a novel therapeutic target for age-related neurodegeneration and associated cognitive decline. View Publication

In vitro exposure of neural progenitor cell (NPC) populations to reduced O(2) (e.g. 3% versus 20%) can increase their proliferation,survival and neuronal differentiation. Our objective was to determine if an acute (textless1hr),in vivo exposure to intermittent hypoxia (AIH) alters expansion and/or differentiation of subsequent in vitro cultures of NPC from the subventricular zone (SVZ). Neonatal C57BL/6 mice (postnatal day 4) were exposed to an AIH paradigm (20×1 minute; alternating 21% and 10% O(2)). Immediately after AIH,SVZ tissue was isolated and NPC populations were cultured and assayed either as neurospheres (NS) or as adherent monolayer cells (MASC). AIH markedly increased the capacity for expansion of cultured NS and MASC,and this was accompanied by increases in a proliferation maker (Ki67),MTT activity and hypoxia-inducible factor-1α (HIF-1α) signaling in NS cultures. Peptide blockade experiments confirmed that proteins downstream of HIF-1α are important for both proliferation and morphological changes associated with terminal differentiation in NS cultures. Finally,immunocytochemistry and Western blotting experiments demonstrated that AIH increased expression of the neuronal fate determination transcription factor Pax6 in SVZ tissue,and this was associated with increased neuronal differentiation in cultured NS and MASC. We conclude that in vivo AIH exposure can enhance the viability of subsequent in vitro SVZ-derived NPC cultures. AIH protocols may therefore provide a means to prime" NPC prior to transplantation into the injured central nervous system." View Publication

Insight into the normal function of PrP(C),and how it can be subverted to produce neurotoxic effects,is provided by PrP molecules carrying deletions encompassing the conserved central region. The most neurotoxic of these mutants,Δ105-125 (called ΔCR),produces a spontaneous neurodegenerative illness when expressed in transgenic mice,and this phenotype can be dose-dependently suppressed by co-expression of wild-type PrP. Whether the toxic activity of ΔCR PrP and the protective activity or wild-type PrP are cell-autonomous,or can be exerted on neighboring cells,is unknown. To investigate this question,we have utilized co-cultures of differentiated neural stem cells derived from mice expressing ΔCR or wild-type PrP. Cells from the two kinds of mice,which are marked by the presence or absence of GFP,are differentiated together to yield neurons,astrocytes,and oligodendrocytes. As a surrogate read-out of ΔCR PrP toxicity,we assayed sensitivity of the cells to the cationic antibiotic,Zeocin. In a previous study,we reported that cells expressing ΔCR PrP are hypersensitive to the toxic effects of several cationic antibiotics,an effect that is suppressed by co-expression of wild type PrP,similar to the rescue of the neurodegenerative phenotype observed in transgenic mice. Using this system,we find that while ΔCR-dependent toxicity is cell-autonomous,the rescuing activity of wild-type PrP can be exerted in trans from nearby cells. These results provide important insights into how ΔCR PrP subverts a normal physiological function of PrP(C),and the cellular mechanisms underlying the rescuing process. View Publication

Exercise has been shown to positively augment adult hippocampal neurogenesis; however,the cellular and molecular pathways mediating this effect remain largely unknown. Previous studies have suggested that microglia may have the ability to differentially instruct neurogenesis in the adult brain. Here,we used transgenic Csf1r-GFP mice to investigate whether hippocampal microglia directly influence the activation of neural precursor cells. Our results revealed that an exercise-induced increase in neural precursor cell activity was mediated via endogenous microglia and abolished when these cells were selectively removed from hippocampal cultures. Conversely,microglia from the hippocampi of animals that had exercised were able to activate latent neural precursor cells when added to neurosphere preparations from sedentary mice. We also investigated the role of CX(3)CL1,a chemokine that is known to provide a more neuroprotective microglial phenotype. Intraparenchymal infusion of a blocking antibody against the CX(3)CL1 receptor,CX(3)CR1,but not control IgG,dramatically reduced the neurosphere formation frequency in mice that had exercised. While an increase in soluble CX(3)CL1 was observed following running,reduced levels of this chemokine were found in the aged brain. Lower levels of CX(3)CL1 with advancing age correlated with the natural decline in neural precursor cell activity,a state that could be partially alleviated through removal of microglia. These findings provide the first direct evidence that endogenous microglia can exert a dual and opposing influence on neural precursor cell activity within the hippocampus,and that signaling through the CX(3)CL1-CX(3)CR1 axis critically contributes toward this process. View Publication

Stem cell (SC) lines that capture the genetics of disease susceptibility provide new research tools. To assess the utility of mouse central nervous system (CNS) SC-containing neurosphere cultures for studying heritable neurodegenerative disease,we compared neurosphere cultures from transgenic mice that express human tau with the P301L familial frontotemporal dementia (FTD) mutation,rTg(tau(P301L))4510,with those expressing comparable levels of wild type human tau,rTg(tau(wt))21221. rTg(tau(P301L))4510 mice express the human tau(P301L) variant in their forebrains and display cellular,histological,biochemical and behavioral abnormalities similar to those in human FTD,including age-dependent differences in tau phosphorylation that distinguish them from rTg(tau(wt))21221 mice. We compared FTD-hallmark tau phosphorylation in neurospheres from rTg(tau(P301L))4510 mice and from rTg(tau(wt))21221 mice. The tau genotype-specific phosphorylation patterns in neurospheres mimicked those seen in mice,validating use of neurosphere cultures as models for studying tau phosphorylation. Genotype-specific tau phosphorylation was observed in 35 independent cell lines from individual fetuses; tau in rTg(tau(P301L))4510 cultures was hypophosphorylated in comparison with rTg(tau(wt))21221 as was seen in young adult mice. In addition,there were fewer human tau-expressing cells in rTg(tau(P301L))4510 than in rTg(tau(wt))21221 cultures. Following differentiation,neuronal filopodia-spine density was slightly greater in rTg(tau(P301L))4510 than rTg(tau(wt))21221 and control cultures. Together with the recapitulation of genotype-specific phosphorylation patterns,the observation that neurosphere lines maintained their cell line-specific-differences and retained SC characteristics over several passages supports the utility of SC cultures as surrogates for analysis of cellular disease mechanisms. View Publication

Considerable progress has been made in identifying signaling pathways that direct the differentiation of human pluripotent stem cells (hPSCs) into specialized cell types,including neurons. However,differentiation of hPSCs with extrinsic factors is a slow,step-wise process,mimicking the protracted timing of human development. Using a small-molecule screen,we identified a combination of five small-molecule pathway inhibitors that yield hPSC-derived neurons at textgreater75% efficiency within 10 d of differentiation. The resulting neurons express canonical markers and functional properties of human nociceptors,including tetrodotoxin (TTX)-resistant,SCN10A-dependent sodium currents and response to nociceptive stimuli such as ATP and capsaicin. Neuronal fate acquisition occurs about threefold faster than during in vivo development,suggesting that use of small-molecule pathway inhibitors could become a general strategy for accelerating developmental timing in vitro. The quick and high-efficiency derivation of nociceptors offers unprecedented access to this medically relevant cell type for studies of human pain. View Publication

Activation of P2X(7) receptor (P2X(7)R) and pannexin have been implicated in membrane permeabilization associated with ischemic cell death and many other inflammatory processes. P2X(7)R has a unique property of forming large pore upon repeated or prolonged application of agonist like ATP or 2',3'-(4-benzoyl) benzoyl ATP. It has been proposed that pannexin 1 (panx1) hemichannel associates with P2X(7)R to form large pore,though the actual mechanism is not yet understood. Calcium concentration in extracellular milieu drops in many patho-physiological conditions,e.g. ischemia,when P2X(7)R/pannexin is also known to be activated. Therefore,we hypothesize that extracellular calcium ([Ca(2+)](o)) plays an important role in the coupling of P2X(7)R-panx1 and subsequent membrane permeabilization. In this study we show that membrane permeability of the P2X(7)R and panx1 expressing N2A cell increases in ([Ca(2+)](o))-free solution. In [Ca(2+)](o)-free solution,fluorescent dye calcein trapped cells exhibited time-dependent dye leakage resulting in about 50% decrease of fluorescence intensity in 30 min. Control cells in 2 mM [Ca(2+)](o) did not show such leakage. Like N2A cells,mixed culture of neuron and glia,derived from hippocampal progenitor cells showed similar dye leakage. Dye leakage was blocked either by pannexin-specific blocker,carbenoxolone or P2X(7)R antagonists,Brilliant Blue G,and oxidized ATP. Furthermore P2X(7)R and panx1 were co-immunoprecipitated. The amount of P2X(7)R protein pulled-down with panx1,increased by twofold when cells were incubated 30 min in [Ca(2+)](o)-free buffer. Taken together,the results of this study demonstrate the activation and association of P2X(7)R-panx1,triggered by the removal of [Ca(2+)](o). View Publication

BACKGROUND: Activity through NMDA type glutamate receptors sculpts connectivity in the developing nervous system. This topic is typically studied in the visual system in vivo,where activity of inputs can be differentially regulated,but in which individual synapses are difficult to visualize and mechanisms governing synaptic competition can be difficult to ascertain. Here,we develop a model of NMDA-receptor dependent synaptic competition in dissociated cultured hippocampal neurons. METHODOLOGY/PRINCIPAL FINDINGS: GluN1 -/- (KO) mouse hippocampal neurons lacking the essential NMDA receptor subunit were cultured alone or cultured in defined ratios with wild type (WT) neurons. The absence of functional NMDA receptors did not alter neuron survival. Synapse development was assessed by immunofluorescence for postsynaptic PSD-95 family scaffold and apposed presynaptic vesicular glutamate transporter VGlut1. Synapse density was specifically enhanced onto minority wild type neurons co-cultured with a majority of GluN1 -/- neighbour neurons,both relative to the GluN1 -/- neighbours and relative to sister pure wild type cultures. This form of synaptic competition was dependent on NMDA receptor activity and not conferred by the mere physical presence of GluN1. In contrast to these results in 10% WT and 90% KO co-cultures,synapse density did not differ by genotype in 50% WT and 50% KO co-cultures or in 90% WT and 10% KO co-cultures. CONCLUSIONS/SIGNIFICANCE: The enhanced synaptic density onto NMDA receptor-competent neurons in minority coculture with GluN1 -/- neurons represents a cell culture paradigm for studying synaptic competition. Mechanisms involved may include a retrograde 'reward' signal generated by WT neurons,although in this paradigm there was no 'punishment' signal against GluN1 -/- neurons. Cell culture assays involving such defined circuits may help uncover the rules and mechanisms of activity-dependent synaptic competition in the developing nervous system. View Publication

In congenital mitochondrial DNA (mtDNA) disorders,a mixture of normal and mutated mtDNA (termed heteroplasmy) exists at varying levels in different tissues,which determines the severity and phenotypic expression of disease. Pearson marrow pancreas syndrome (PS) is a congenital bone marrow failure disorder caused by heteroplasmic deletions in mtDNA. The cause of the hematopoietic failure in PS is unknown,and adequate cellular and animal models are lacking. Induced pluripotent stem (iPS) cells are particularly amenable for studying mtDNA disorders,as cytoplasmic genetic material is retained during direct reprogramming. Here,we derive and characterize iPS cells from a patient with PS. Taking advantage of the tendency for heteroplasmy to change with cell passage,we isolated isogenic PS-iPS cells without detectable levels of deleted mtDNA. We found that PS-iPS cells carrying a high burden of deleted mtDNA displayed differences in growth,mitochondrial function,and hematopoietic phenotype when differentiated in vitro,compared to isogenic iPS cells without deleted mtDNA. Our results demonstrate that reprogramming somatic cells from patients with mtDNA disorders can yield pluripotent stem cells with varying burdens of heteroplasmy that might be useful in the study and treatment of mitochondrial diseases. STEM CELLS2013;31:1287–1297 View Publication