Primary Neurospheres Research Articles

Establishment and phenotyping of neurosphere cultures from primary neuroblastoma samples

Background: Primary cell culture using serum free media supplemented with growth factors has been used in a number of cancers to propagate primary cells with stem like properties, which form as spherical cellular aggregates. Methods: We systematically evaluated the capacity of freshly disaggregated neuroblastoma tumors to become established as neurospheres in stem cell media using a uniform protocol. 67 primary neuroblastoma samples from patients treated at a single institution were prospectively evaluated for their ability to become established in culture. Samples, either solid tissue or cells from surgical transit fluid both post chemotherapy and chemotherapy naïve, were evaluated from diagnostic needle biopsies or surgical resections. Results: Overall 37 neurosphere cultures were successfully established from 67 samples. In 11 out of 14 cases investigated by flow cytometry, uniform staining for neuroblastoma markers CD56 and GD2 was demonstrated in CD45 negative non-hemopoietic cells, confirming neuroblastoma origin. Conclusion: We present a simple and reproducible approach for producing primary neurospheres from neuroblastoma samples, which provides a reliable resource for future work including genetic analysis, stem cell research and models for therapeutics.

Jagged1 is Essential for Radial Glial Maintenance in the Cortical Proliferative Zone

Radial glial maintenance is essential for the proper development of the cortex. It is known that the evolutionarily conserved Notch signaling pathway is required for maintaining the pool of radial glial stem cells although the mechanisms involved are not entirely understood. Here, we study the Notch ligand, Jagged1, in the mouse ventricular zone at a late stage of embryonic development. We use a conditional loss of function allele to show that Jagged1 is required for maintaining radial glial cells and when absent, leads to defects in the cortical proliferation zone and expression of intermediate progenitor cells. Using in vitro approaches, we found that depletion of Jagged1 reduced the size of primary neurospheres and their capacity to self-renewal. Finally, Jagged1 mutants also showed precocious neuronal differentiation and cortical defects. Together, these data support a role for Jagged1 in radial glia maintenance in the neocortex.

Establishment and phenotyping of neurosphere cultures from primary neuroblastoma samples.

Background: Primary cell culture using serum free media supplemented with growth factors has been used in a number of cancers to propagate primary cells with stem like properties, which form as spherical cellular aggregates. Methods: We systematically evaluated the capacity of freshly disaggregated neuroblastoma tumors to become established as neurospheres in stem cell media using a uniform protocol. 67 primary neuroblastoma samples from patients treated at a single institution were prospectively evaluated for their ability to become established in culture. Samples, either solid tissue or cells from surgical transit fluid both post chemotherapy and chemotherapy naïve, were evaluated from diagnostic needle biopsies or surgical resections. Results: Overall 37 neurosphere cultures were successfully established from 67 samples. In 11 out of 14 cases investigated by flow cytometry, uniform staining for neuroblastoma markers CD56 and GD2 was demonstrated in CD45 negative non-hemopoietic cells, confirming neuroblastoma origin. Conclusion: We present a simple and reproducible approach for producing primary neurospheres from neuroblastoma samples, which provides a reliable resource for future work including genetic analysis, stem cell research and models for therapeutics.

The kinase inhibitor SI113 induces autophagy and synergizes with quinacrine in hindering the growth of human glioblastoma multiforme cells

BackgroundGlioblastoma multiforme (GBM), due to its location, aggressiveness, heterogeneity and infiltrative growth, is characterized by an exceptionally dismal clinical outcome. The small molecule SI113, recently identified as a SGK1 inhibitor, has proven to be effective in restraining GBM growth in vitro and in vivo, showing also encouraging results when employed in combination with other antineoplastic drugs or radiotherapy. Our aim was to explore the pharmacological features of SI113 in GBM cells in order to elucidate the pivotal molecular pathways affected by the drug. Such knowledge would be of invaluable help in conceiving a rational offensive toward GBM.MethodsWe employed GBM cell lines, either established or primary (neurospheres), and used a Reverse-Phase Protein Arrays (RPPA) platform to assess the effect of SI113 upon 114 protein factors whose post-translational modifications are associated with activation or repression of specific signal transduction cascades.ResultsSI113 strongly affected the PI3K/mTOR pathway, evoking a pro-survival autophagic response in neurospheres. These results suggested the use of SI113 coupled, for maximum efficiency, with autophagy inhibitors. Indeed, the association of SI113 with an autophagy inhibitor, the antimalarial drug quinacrine, induced a strong synergistic effect in inhibiting GBM growth properties in all the cells tested, including neurospheres.ConclusionsRPPA clearly identified the molecular pathways influenced by SI113 in GBM cells, highlighting their vulnerability when the drug was administered in association with autophagy inhibitors, providing a strong molecular rationale for testing SI113 in clinical trials in associative GBM therapy.

Abstract A045: Chlorotoxin redirects T-cells for specific and effective targeting against glioblastomas

Abstract Glioblastoma (GBM) is the most common type of primary brain tumor, with the standard therapy only modestly improving the prognosis, highlighting the necessity to develop advanced treatments. We and others have established the platform to potentiate immune response against GBMs using chimeric antigen receptor (CAR) engineered T-cells. Specifically, we have shown that intracranial administration of CAR T-cells can be well tolerated in patients with recurrent GBMs, together with some early clinical evidence of antitumor response. However, CAR T-cell therapy against GBMs is complicated by the inter- and intratumoral heterogeneity, while the single-targeting therapies only respond to a subset of tumor cells. The development of new CAR therapy would thus aim for targeting a wider range of tumor cells and bypassing antigen escape. Here, we took an approach different from conventional strategies of tumor antigen discovery, exploiting the tumor-binding potential of a natural peptide to develop CAR T-cells that broadly target GBMs. Chlorotoxin (CLTX) is a 36-amino acid peptide with demonstrated GBM-binding capability. Inspired by the utilization of CLTX in GBM tumor imaging, we used a fluorescence-conjugated CLTX to screen the freshly-dispersed primary GBM cells and patient-derived GBM neurospheres, and found that CLTX binding was more homogeneous than the expression of other GBM-associated antigens including EGFR, HER2 and IL13Rα2. Although CLTX has limited inhibitory effect on GBM growth, its broad binding to GBM cells illustrates the potential to be conjugated with a cytotoxic agent. Therefore, we generated CAR T-cells bearing CLTX as the antigen targeting domain. CLTX-CAR T-cells were able to get activated after stimulating with GBM cells, as indicated by their degranulation, cytokine production and immuno-synapse formation. Modification of CAR constructs revealed that CLTX-CAR T-cells with CD28 costimulatory signal exhibited potent effector activity, while the 4-1BB costimulation resulted in inadequate CAR activation. In both in vitro and in vivo models, CLTX-CAR T-cells effectively eliminated GBM cells and tumors, including the ones with no/low expression of EGFR, HER2 and IL13Rα2. Importantly, CLTX peptide exhibited negligible binding to a panel of normal cells from neural and other tissues, and CLTX-CAR T-cells showed no off-target effect against normal organs in tumor-bearing mouse models. Screening on patient-derived GBM neurospheres, we discovered that the expression of metalloproteinase (MMP)-2 on targeT-cells was correlated with the effector function of CLTX-CAR T-cells. Further, the antitumor function of CLTX-CAR T-cells was severely diminished against GBMs with MMP-2 knockdown. Consistent with the cytotoxicity of CLTX-CAR T-cells, MMP-2 expression was also present in a subgroup of GBM cells with undetectable levels of EGFR, HER2 and IL13Rα2 expression. Our results demonstrate for the first time that a peptide toxin can be successfully used as the tumor targeting domain of a CAR, which eliminates GBMs with high efficiency and selectivity. The CLTX-CAR has the potential to limit GBM heterogeneity and compensate current CAR T-cell therapies against solid tumors. Citation Format: Dongrui Wang, Vanessa Jonsson, Sarah Wright, Wen-Chung Chang, Xin Yang, Renate Starr, Alfonso Brito, Brenda Aguilar, Aniee Sarkissian, Lihong Weng, Stephen J Forman, Michael E Barish, Christine E. Brown. Chlorotoxin redirects T-cells for specific and effective targeting against glioblastomas [abstract]. In: Proceedings of the Fourth CRI-CIMT-EATI-AACR International Cancer Immunotherapy Conference: Translating Science into Survival; Sept 30-Oct 3, 2018; New York, NY. Philadelphia (PA): AACR; Cancer Immunol Res 2019;7(2 Suppl):Abstract nr A045.

Lineage‐Specific Commitment of Stem Cells with Organic and Graphene Oxide–Functionalized Nanofibers

AbstractControlling the differentiation to certain lineages is the main goal of current stem cell research, which might exploit new routes based on the interaction of cells with nanomaterials. Here it is shown that primary neurospheres from dental pulp stem cells grown on combinatorial surfaces with different fibrous morphology and graphene oxide functionalization exhibit different differentiation propensity. The developed materials strongly influence the stem cell fate, as highlighted by morphological, immunofluorescence, molecular biology, and functional analyses. Instructive cues lead to the increased expression of markers that are characteristic of selective differentiation into osteoblasts, glial cells, fibroblasts, and neurons even in basal medium conditions, and randomly oriented fibers are found to revert neuronal precommitment and to trigger osteoblastic differentiation. Graphene oxide coatings lead instead to the relatively enhanced expression of genes typical of either glial or neuronal commitment, depending on the underlying nanofibrous morphology. The mechanisms addressing cell fate are investigated, highlighting the correlation of wetting anisotropy and protein adsorption capacity of different surfaces, ultimate cell conformational changes reflected by skeletal and nuclear elongation, and directed cell commitment. Cues from the different surfaces are therefore lineage‐specific, unveiling remarkable potentialities for cellular programming by means of nanomaterials.

Carbonic Anhydrase XII Inhibitors Overcome P-Glycoprotein-Mediated Resistance to Temozolomide in Glioblastoma.

The role of carbonic anhydrase XII (CAXII) in the chemoresistance of glioblastoma is unexplored. We found CAXII and P-glycoprotein (Pgp) coexpressed in neurospheres derived from 3 of 3 patients with different genetic backgrounds and low response to temozolomide (time to recurrence: 6-9 months). CAXII was necessary for the Pgp efflux of temozolomide and second-line chemotherapeutic drugs, determining chemoresistance in neurospheres. Psammaplin C, a potent inhibitor of CAXII, resensitized primary neurospheres to temozolomide by reducing temozolomide efflux via Pgp. This effect was independent of other known temozolomide resistance factors present in the patients. The overall survival in orthotopic patient-derived xenografts of temozolomide-resistant neurospheres, codosed with Psammaplin C and temozolomide, was significantly increased over temozolomide-treated (P < 0.05) and untreated animals (P < 0.02), without detectable signs of systemic toxicity. We propose that a CAXII inhibitor in combination with temozolomide may provide a new and effective approach to reverse chemoresistance in glioblastoma stem cells. This novel mechanism of action, via the interaction of CAXII and Pgp, ultimately blocks the efflux function of Pgp to improve glioblastoma patient outcomes.

Adult neurogenic deficits in HIV-1 Tg26 transgenic mice

BackgroundEven in the antiretroviral treatment (ART) era, HIV-1-infected patients suffer from milder forms of HIV-1-associated neurocognitive disorders (HAND). While the viral proteins Tat and gp120 have been shown to individually inhibit the proliferation and neural differentiation of neural stem cells (NSCs), no studies have characterized the effects of all the combined viral proteins on adult neurogenesis.MethodsThe HIV-1 Tg26 transgenic mouse model was used due to its clinical relevance to ART-controlled HIV-1-infected patients who lack active viral replication but suffer from continuous stress from the viral proteins. Quantitative RT-PCR analysis was performed to validate the expression of viral genes in the neurogenic zones. In vitro stemness and lineage differentiation assays were performed in cultured NSCs from HIV-1 Tg26 transgenic mice and their wild-type littermates. Hippocampal neurogenic lineage analysis was performed to determine potential changes in initial and late differentiation of NSCs in the subgranular zone (SGZ). Finally, fluorescent retroviral labeling of mature dentate granule neurons was performed to assess dendritic complexity and dendritic spine densities.ResultsVarying copy numbers of partial gag (p17), tat (unspliced and spliced variants), env (gp120), vpu, and nef transcripts were detected in the neurogenic zones of Tg26 mice. Significantly fewer primary neurospheres and a higher percentage of larger sized primary neurospheres were generated from Tg26 NSCs than from littermated wild-type mouse NSCs, implying that Tg26 mouse NSCs exhibit deficits in initial differentiation. In vitro differentiation assays revealed that Tg26 mouse NSCs have reduced neuronal differentiation and increased astrocytic differentiation. In the SGZs of Tg26 mice, significantly higher amounts of quiescent NSCs, as well as significantly lower levels of active NSCs, proliferating neural progenitor cells, and neuroblasts, were observed. Finally, newborn mature granule neurons in the dentate gyri of Tg26 mice had deficiencies in dendritic arborization, dendritic length, and dendritic spine density.ConclusionsBoth in vitro and in vivo studies demonstrate that HIV-1 Tg26 mice have early- and late-stage neurogenesis deficits, which could possibly contribute to the progression of HAND. Future therapies should be targeting this process to ameliorate, if not eliminate HAND-like symptoms in HIV-1-infected patients.

Systemic Inflammation Impairs Proliferation of Hippocampal Type 2 Intermediate Precursor Cells.

Neurogenesis is a plastic event modulated by external cues. Systemic inflammation decreases neurogenesis in the dentate gyrus (DG) in part through the proliferative restrain of neural precursor cells (NPCs). To evaluate if inflammation affects the cell cycle progression of particular populations of NPCs, we treated young-adult mice with a single i.p. injection of saline or 1mg/kg LPS. After 7days, we analysed proliferation of new BrdU+/DCX+ cells through immunohistochemistry. We extracted the hippocampus and performed a neurosphere assay and a flow cytometric analysis to evaluate proliferation and to identify the phase of the cell cycle in specific populations of DG-derived NPCs. We show that the number of BrdU+/DCX+ cells diminishes in the LPS-treated group and that the number of primary neurospheres derived from LPS-injected animals is significantly reduced compared to the saline-injected group. Flow cytometry revealed that inflammation does not affect the total number of Type 1 BLBP+/TBR2- cells, while the total number of Type 2 intermediate precursor cells (IPCs) (TBR2+) from the LPS-treated group was increased. Cell cycle analysis shows a decrease in the total rate of NPCs in phases S, G2 and M in the LPS-treated group. The percentage of Type 1 BLBP+/TBR2- cells in each cell cycle phase was not different between groups, while there was a fewer number of Type 2 TBR2+ cells in S/G2/M phase. These results show that inflammation alters the appropriate cell cycle progression of Type 2 IPCs, which may contribute to the decrease in the birth rate of DG neurons.

Cellular fate decisions in the developing female anteroventral periventricular nucleus are regulated by canonical Notch signaling

The hypothalamic anteroventral periventricular nucleus (AVPV) is the major regulator of reproductive function within the hypothalamic-pituitary-gonadal (HPG) axis. Despite an understanding of the function of neuronal subtypes within the AVPV, little is known about the molecular mechanisms regulating their development. Previous work from our laboratory has demonstrated that Notch signaling is required in progenitor cell maintenance and formation of kisspeptin neurons of the arcuate nucleus (ARC) while simultaneously restraining POMC neuron number. Based on these findings, we hypothesized that the Notch signaling pathway may act similarly in the AVPV by promoting development of kisspeptin neurons at the expense of other neuronal subtypes. To address this hypothesis, we utilized a genetic mouse model with a conditional loss of Rbpj in Nkx2.1 expressing cells (Rbpj cKO). We noted an increase in cellular proliferation, as marked by Ki-67, in the hypothalamic ventricular zone (HVZ) in Rbpj cKO mice at E13.5. This corresponded to an increase in general neurogenesis and more TH-positive neurons. Additionally, an increase in OLIG2-positive early oligodendrocytic precursor cells was observed at postnatal day 0 in Rbpj cKO mice. By 5 weeks of age in Rbpj cKO mice, TH-positive cells were readily detected in the AVPV but few kisspeptin neurons were present. To elucidate the direct effects of Notch signaling on neuron and glia differentiation, an in vitro primary hypothalamic neurosphere assay was employed. We demonstrated that treatment with the chemical Notch inhibitor DAPT increased mKi67 and Olig2 mRNA expression while decreasing astroglial Gfap expression, suggesting Notch signaling regulates both proliferation and early glial fate decisions. A modest increase in expression of TH in both the cell soma and neurite extensions was observed after extended culture, suggesting that inhibition of Notch signaling alone is enough to bias progenitors towards a dopaminergic fate. Together, these data suggest that Notch signaling restricts early cellular proliferation and differentiation of neurons and oligodendrocytes both in vivo and in vitro and acts as a fate selector of kisspeptin neurons.

Lymphotoxin \u03b2 receptor-mediated NF\u03baB signaling promotes glial lineage differentiation and inhibits neuronal lineage differentiation in mouse brain neural stem/progenitor cells

BackgroundLymphotoxin (LT) is a lymphokine mainly expressed in lymphocytes. LTα binds one or two membrane-associated LTβ to form LTα2β1 or LTα1β2 heterotrimers. The predominant LTα1β2 binds to LTβ receptor (LTβR) primarily expressed in epithelial and stromal cells. Most studies on LTβR signaling have focused on the organization, development, and maintenance of lymphoid tissues. However, the roles of LTβR signaling in the nervous system, particularly in neurogenesis, remain unknown. Here, we investigated the role of LTβR-mediated NFκB signaling in regulating neural lineage differentiation.MethodsThe C57BL/6J wild-type and GFAP-dnIκBα transgenic mice were used. Serum-free embryoid bodies were cultured from mouse embryonic stem cells and further induced into neural stem/progenitor cells (NSCs/NPCs). Primary neurospheres were cultured from embryonic and adult mouse brains followed by monolayer culture for amplification/passage. NFκB activation was determined by adenovirus-mediated NFκB-firefly-luciferase reporter assay and p65/RelB/p52 nuclear translocation assay. LTβR mRNA expression was evaluated by quantitative RT-PCR and LTβR protein expression was determined by immunohistochemistry and Western blot analysis. Multilabeled immunocytochemistry or immunohistochemistry followed by fluorescent confocal microscopy and quantitative analysis of neural lineage differentiation were performed. Graphing and statistical analysis were performed with GraphPad Prism software.ResultsIn cultured NSCs/NPCs, LTα1β2 stimulation induced an activation of classical and non-classical NFκB signaling. The expression of LTβR-like immunoreactivity in GFAP+/Sox2+ NSCs was identified in well-established neurogenic zones of adult mouse brain. Quantitative RT-PCR and Western blot analysis validated the expression of LTβR in cultured NSCs/NPCs and brain neurogenic regions. LTβR expression was significantly increased during neural induction. LTα1β2 stimulation in cultured NSCs/NPCs promoted astroglial and oligodendrocytic lineage differentiation, but inhibited neuronal lineage differentiation. Astroglial NFκB inactivation in GFAP-dnIκBα transgenic mice rescued LTβR-mediated abnormal phenotypes of cultured NSCs/NPCs.ConclusionThis study provides the first evidence for the expression and function of LTβR signaling in NSCs/NPCs. Activation of LTβR signaling promotes glial lineage differentiation. Our results suggest that neurogenesis is regulated by the adaptive immunity and inflammatory responses.

The CNS penetrating taxane TPI 287 and the AURKA inhibitor alisertib induce synergistic apoptosis in glioblastoma cells.

Glioblastoma is a highly malignant disease in critical need of expanded treatment options. The AURKA inhibitor alisertib exhibits antiproliferative activity against glioblastoma in vitro and in vivo. Unlike current clinically used taxane drugs, the novel taxane TPI 287 penetrates the CNS. We tested for interactions between three selective AURKA inhibitors and TPI 287 against standard U87 and U1242 cells and primary glioblastoma neurospheres using colony formation assays. Bliss and Chou-Talalay analyses were utilized to statistically test for synergism. Morphological analysis, flow cytometry and annexin V binding were employed to examine cell cycle and apoptotic effects of these drug combinations. TPI 287 not only potentiated the cytotoxicity of the AURKA inhibitors alisertib, MLN8054 and TC-A2317, but was often potently synergistic. Morphologic and biochemical analysis of the combined effects of alisertib and TPI 287 consistently revealed synergistic induction of apoptosis. While each agent alone induces a mitotic block, slippage occurs allowing some tumor cells to avoid apoptosis. Combination treatment greatly attenuated mitotic slippage, committing the majority of cells to apoptosis. Alisertib and TPI 287 demonstrate significant synergism against glioblastoma cells largely attributable to a synergistic effect in inducing apoptosis. These results provide compelling rationale for clinical testing of alisertib and/or other AURKA inhibitors for potential combination use with TPI 287 against glioblastoma and other CNS neoplasms.

An efficient method for the transduction of primary pediatric glioma neurospheres

Pediatric high grade glioma (pHGG) and diffuse intrinsic pontine glioma (DIPG) are rare, but rapidly fatal malignancies of the central nervous system (CNS), and the leading cause of cancer-related death in children. Besides the scarcity of available biological material for research, the study of these diseases has been hampered by methodological problems. One of the major obstacles is the difficulty with which these cells can be genetically modified by conventional laboratory methods, such as lentiviral transduction. As a result, only very few successful stable modifications have been reported. As pHGG and DIPG cells are most often cultured as neurospheres, and therefore retain stem cell-like characteristics, we hypothesized that this culture method is also responsible for their resistance to transduction. We therefore developed a protocol in which pHGG and DIPG cells are temporarily forced to form an adherent monolayer by exposure to serum, to create a window-of-opportunity for lentiviral transduction. We here demonstrate that this protocol reliably and reproducibly introduces stable genetic modifications in primary DIPG and pHGG cells.•Short-term serum exposure enables lentiviral transduction of primary pediatric glioma neurospheres.

Temporal Changes in Transcription Factor Expression Associated with the Differentiation State of Cerebellar Neural Stem/Progenitor Cells During Development.

During central nervous development, multi-potent neural stem/progenitor cells located in the ventricular/subventricular zones are temporally regulated to mostly produce neurons during early developmental stages and to produce glia during later developmental stages. After birth, the rodent cerebellum undergoes further dramatic development. It is also known that neural stem/progenitor cells are present in the white matter (WM) of the postnatal cerebellum until around P10, although the fate of these cells has yet to be determined. In the present study, it was revealed that primary neurospheres generated from cerebellar neural stem/progenitor cells at postnatal day 3 (P3) mainly differentiated into astrocytes and oligodendrocytes. In contrast, primary neurospheres generated from cerebellar neural stem/progenitor cells at P8 almost exclusively differentiated into astrocytes, but not oligodendrocytes. These results suggest that the differentiation potential of primary neurospheres changes depending on the timing of neural stem/progenitor cell isolation from the cerebellum. To identify the candidate transcription factors involved in regulating this temporal change, we utilized DNA microarray analysis to compare global gene-expression profiles of primary neurospheres generated from neural stem/progenitor cells isolated from either P3 or P8 cerebellum. The expression of zfp711, zfp618, barx1 and hoxb3 was higher in neurospheres generated from P3 cerebellum than from P8 by real-time quantitative PCR. Several precursor cells were found to express zfp618, barx1 or hoxb3 in the WM of the cerebellum at P3, but these transcription factors were absent from the WM of the P8 cerebellum.

489: Characterization of fetal neuroprogenitor cells derived from cerebrospinal fluid at time of myelomeningocele repair

Isolation of neuroprogenitor cells (NPCs) at the time of fetal intervention would allow for a novel, safe and effective method of retrieval. Once retrieved and propagated in vitro, experimental use of NPCs will enable crucial translational research. The aims of the current study were to successfully retrieve NPCs from live fetuses undergoing fetoscopic myelomeningocele repair in a double-blind observational study, then propagate them in culture and characterize their cellular phenotype. Under IRB approval and informed subject consent, during fetoscopic surgical repair of myelomeningocele between 20 and 26 weeks gestation (n=14 subjects), CSF samples were extracted from the myelomeningocele and transported sterile and on ice. Extracted NPCs were grown in primary neurosphere cultures, and aliquots were thereafter preserved in supplemented DMEM media at -80°c . For confirmation of NPC differentiation, cells were fixed and labeled with neuroprogenitor markers (CD133, CD56) and compared against hematopoietic lineage markers (CD34, CD45). From fetal CSF that would have otherwise been discarded, specimens were successfully propagated in neurosphere culture (Fig.1A, 3 representative donor cultures of n=14) retained a minimum of 10% of live cells labeled as NPCs (CD133 positive, CD45 negative; Fig.1B). Given the median number of total cells recovered at time of MMC repair was 2.0x105 from a median of 0.89 mL CSF, we estimate the typical recovery of NPCs to be ∼2x104 total cells. The concentration of cells significantly negatively correlated with volume recovery (r=-0.74, p<0.008), but not ventricular size, motor function level, nor secondary characteristics (p>0.05). Additionally, there was no gross evidence of impact of exposure to CO2 (employed for insufflation) and capacity for cell recovery, viability in culture, nor NPC propagation in vitro. Neuroprogenitor cells can be successfully recovered at the time of fetoscopic myelomeningocele repair. Their propagation in culture allows for a novel renewable source of obtaining autologous NPCs. Future utilization of preserved specimens will include continual propagation with subsequent opportunities for analysis of cellular mechanisms involved in embryonic development, neural disease pathogenesis, and potential therapeutic interventions.

Cyclophilin A Maintains Glioma-Initiating Cell Stemness by Regulating Wnt/β-Catenin Signaling.

Purpose: Glioma-initiating cells (GIC) are glioma stem-like cells that contribute to glioblastoma (GBM) development, recurrence, and resistance to chemotherapy and radiotherapy. They have recently become the focus of novel treatment strategies. Cyclophilin A (CypA) is a cytosolic protein that belongs to the peptidyl-prolyl isomerase (PPIase) family and the major intracellular target of the immunosuppressive drug cyclosporin A (CsA). In this study, we investigate the functions of CypA and its mechanism of action in GICs' development.Experimental Design: We analyzed differences in CypA expression between primary tumors and neurospheres from the GDS database, both before and after GIC differentiation. A series of experiments was conducted to investigate the role of CypA in GIC stemness, self-renewal, proliferation, radiotherapy resistance, and mechanism. We then designed glutathione S-transferase (GST) pulldown and coimmunoprecipitation assays to detect signaling activity.Results: In this study, we demonstrated that CypA promotes GIC stemness, self-renewal, proliferation, and radiotherapy resistance. Mechanistically, we found that CypA binds β-catenin and is recruited to Wnt target gene promoters. By increasing the interaction between β-catenin and TCF4, CypA enhances transcriptional activity.Conclusions: Our results demonstrate that CypA enhances GIC stemness, self-renewal, and radioresistance through Wnt/β-catenin signaling. Due to its promotive effects on GICs, CypA is a potential target for future glioma therapy. Clin Cancer Res; 23(21); 6640-9. ©2017 AACR.

Cyclin-Dependent Kinase 4 Regulates Adult Neural Stem Cell Proliferation and Differentiation in Response to Insulin.

Insulin is one of the standard components used to culture primary neurospheres. Although it stimulates growth of different types of cells, the effects of insulin on adult neural stem cells (NSCs) have not been well characterized. Here, we reveal that insulin stimulates proliferation, but not survival or self-renewal, of adult NSCs. This effect is mediated by insulin receptor substrate 2 (IRS2) and subsequent activation of the protein kinase B (or Akt), leading to increased activity of the G1-phase cyclin-dependent kinase 4 (Cdk4) and cell cycle progression. Neurospheres isolated from Irs2-deficient mice are reduced in size and fail to expand in culture and this impaired proliferation is rescued by introduction of a constitutively active Cdk4 (Cdk4R24C/R24C ). More interestingly, activation of the IRS2/Akt/Cdk4 signaling pathway by insulin is also necessary for the generation in vitro of neurons and oligodendrocytes from NSCs. Furthermore, the IRS2/Cdk4 pathway is also required for neuritogenesis, an aspect of neuronal maturation that has not been previously linked to regulation of the cell cycle. Differentiation of NSCs usually follows exit from the cell cycle due to increased levels of CDK-inhibitors which prevent activation of CDKs. In contrast, our data indicate that IRS2-mediated Cdk4 activity in response to a mitogen such as insulin promotes terminal differentiation of adult NSCs. Stem Cells 2017;35:2403-2416.

MMP-2: A modulator of neuronal precursor activity and cognitive and motor behaviors

Matrix Metalloproteinase2, (MMP2, gelatinase A) is a zinc-containing enzyme with a broad substrate specificity including components of the extracellular matrix, cell surface molecules and a wide range bioactive molecules. MMP2 is known to play important roles in a variety of signaling pathways and processes in a wide range of cell types and tissues.In this report we elucidate the effects of the absence of MMP2 in Neural Precursor Cells (NPC) derived from C57BL/6 MMP2 KO mice and in primary and secondary neurosphere formation. We observed smaller neurosphere numbers and sizes, decreased NPC numbers, PCNA expression, DNA and Akt activation in MMP2 KO NPC compared to WT NPC. We also found decreased neurosphere formation and NPC migration outward from adherent neurospheres, decreased CXCR4 and nestin expression and increased GFAP and neuro-filament expression in MMP2 KO NPC compared to Wt NPC. MMP2 KO mice were found to exhibit increased anxiety manifested in open field activity assays compared to Wt mice. MMP2 KO mice also exhibited differences in motor activities manifested by decreased balance and endurance during Rota-rod testing.These studies illustrate an important role of MMP2 in cognitive and motor behaviors and confirm its importance in NPC activities crucial to brain development, growth and response to and recovery from injury.

MiR-203 Interplays with Polycomb Repressive Complexes to Regulate the Proliferation of Neural Stem/Progenitor Cells.

SummaryThe polycomb repressive complexes 1 (PRC1) and 2 (PRC2) are two distinct polycomb group (PcG) proteins that maintain the stable silencing of specific sets of genes through chromatin modifications. Although the PRC2 component EZH2 has been known as an epigenetic regulator in promoting the proliferation of neural stem/progenitor cells (NSPCs), the regulatory network that controls this process remains largely unknown. Here we show that miR-203 is repressed by EZH2 in both embryonic and adult NSPCs. MiR-203 negatively regulates the proliferation of NSPCs. One of PRC1 components, Bmi1, is a downstream target of miR-203 in NSPCs. Conditional knockout of Ezh2 results in decreased proliferation ability of both embryonic and adult NSPCs. Meanwhile, ectopic overexpression of BMI1 rescues the proliferation defects exhibited by miR-203 overexpression or EZH2 deficiency in NSPCs. Therefore, this study provides evidence for coordinated function of the EZH2-miR-203-BMI1 regulatory axis that regulates the proliferation of NSPCs.

DIPG-17. TELOMERE-INDUCED DAMAGE AS A NOVEL APPROACH TO TREAT DIFFUSE INTRINSIC PONTINE GLIOMA

AbstractDiffuse intrinsic pontine glioma (DIPG) is one of the deadliest brain tumors in children. Hence, there is an urgent need to identify actionable therapeutic targets. We have previously shown that over 70% of DIPGs demonstrate telomerase activity and elevated hTERT mRNA levels are associated with shorter overall survival. Thus, telomeres and telomerase represent ideal targets to treat DIPG. We recently validated a novel approach consisting of the incorporation of 6-thio-dG, a telomerase substrate analogue, into telomeres to treat therapy-resistant pediatric brain tumor cells. 6-thio-dG treatment of high-risk group 3 medulloblastoma, pediatric GBM and DIPG patients-derived neurospheres caused telomere damage leading to dose-dependent cell growth inhibition and complete abolition of sphere formation ability. Here, we present our results of the in vivo effectiveness of 6-thio-dG in orthotopic DIPG mouse models. Primary DIPG neurospheres were derived post-autopsy from patients’ tumor tissue. Luciferase positive cells were implanted in the pons of two strains of mice. The generated tumors were highly aggressive and the histopathological characterization of the xenograft showed close similarity with the original patient tumor. Relative to the original patient tissue and the derived neurospheres, telomerase expression and activity were sustained in the xenografts. Tumor bearing mice were treated with 6-thio-dG or the vehicle upon tumor establishment. Molecular analyses of the tumors showed that 6-thio-dG generated significantly higher number of telomere dysfunction-induced foci (TIFs) compared to the untreated tumors, indicating that 6-thio-dG reached the tumor tissue in the pons. Of note, 6-thio-dG treatment had no detectable effect on normal brain tissue. Results regarding tumor regression/stabilization and survival will be discussed. Our data suggest that 6-thio-dG-induced telomere damage is a promising novel approach to treat DIPG.