Mouse Neural Stem Cells Research Articles

LKB1 specifies neural crest cell fates through pyruvate-alanine cycling.

Metabolic processes underlying the development of the neural crest, an embryonic population of multipotent migratory cells, are poorly understood. Here, we report that conditional ablation of the Lkb1 tumor suppressor kinase in mouse neural crest stem cells led to intestinal pseudo-obstruction and hind limb paralysis. This phenotype originated from a postnatal degeneration of the enteric nervous ganglia and from a defective differentiation of Schwann cells. Metabolomic profiling revealed that pyruvate-alanine conversion is enhanced in the absence of Lkb1. Mechanistically, inhibition of alanine transaminases restored glial differentiation in an mTOR-dependent manner, while increased alanine level directly inhibited the glial commitment of neural crest cells. Treatment with the metabolic modulator AICAR suppressed mTOR signaling and prevented Schwann cell and enteric defects of Lkb1 mutant mice. These data uncover a link between pyruvate-alanine cycling and the specification of glial cell fate with potential implications in the understanding of the molecular pathogenesis of neural crest diseases.

Abstract 3934: Bcl2-expressing quiescent type B neural stem cells in the SVZ are resistant to concurrent temozolomide/X-irradiation

Abstract The subventricular zone (SVZ) is the largest source of neural stem cells (NSCs) in the adult brain. Emerging research indicates that NSCs within the SVZ may be cells of origin for WHO grade IV astrocytoma (glioblastoma, GBM)1. GBM consists of multiple fractions of proliferative and/or quiescent stem-like cells that are thought to be lineally related. GBM located adjacent to the SVZ are very resistant to standard of care concurrent temozolomide (TMZ)/X-irradiation (XRT) therapy, a consequence, it is hypothesized, of their NSC origin2. An important, unanswered question is the origin of this resistance. While a significant effort has been undertaken to study proliferating cells, the origins of quiescent cell resistance are not well understood. Normal NSCs adjacent to the SVZ are mainly quiescent. We rationalized that a fundamental understanding of the response of quiescent NSCs to TMZ/XRT would be informative and aid in our understanding of GBM resistance. For 5 consecutive days cohorts of C57BL/6 mice were administered TMZ (0 or 50 mg.kg i.p.). One hr later 0 or 2 Gy was administered to the brain. Transcardial perfusion was performed on day 6 for half the mice. The remaining mice received adjuvant TMZ (100 mg/kg) or vehicle on days 19-22 and transcardial perfusion was performed on day 82. 10 µm coronal brain sections were obtained and immunostained for well characterized markers of type B NSCs (GFAP and Sox2) and type A neuroblasts (Dcx). Immunofluorescence was imaged using a Leica Aperio Versa 200 slide scanning microscope. Cell Profiler software was used to quantify type B and A cells in the SVZ in all cohorts. Proliferating type A cells were exquisitely sensitive to 5 days of concurrent TMZ/XRT treatment whereas quiescent NSCs located within 30 µm of a dorsal or dorsolateral ventricle were very resistant. NSCs in mice exposed to concurrent and adjuvant therapy were also resistant and importantly, able to repopulate type A cells to sham/control levels. 53BP1 foci formation, a surrogate for DNA DSBs, was quantified in Sox2- and Dcx-expressing cells using confocal microscopy following a single TMZ/XRT exposure. Foci formation, measured 6 min to 24 hrs after TMZ/XRT, was not statistically different between cell types (P>0.05). Because TMZ/XRT induced an apoptotic response in A but not in B cells, as marked by cleaved Caspase-3 staining, we investigated expression of Bax and Bcl2 on a per cell basis. Bax expression was not significantly different for type A or B cells (P>0.05). In contrast, type B NSCs expressed 5-fold more Bcl2 than type A neuroblasts (P< 0.001). In conclusion, we demonstrate that type A neuroblasts are sensitive to TMZ/XRT but can be repopulated by inherently resistant type B NSCs given sufficient time. The resistance of quiescent NSCs to TMZ/XRT is associated with high basal expression of anti-apoptotic proteins. 1Lee et al Nature 2018, 560:243-47; 2Smith et al J Neurooncol 2016, 128:207-16 Citation Format: Brent D. Cameron, Geri Traver, Joseph T. Roland, Daniel Dean, Levi Johnson, Kelli L. Boyd, Rebecca A. Ihrie, Jialiang Wang, Michael L. Freeman. Bcl2-expressing quiescent type B neural stem cells in the SVZ are resistant to concurrent temozolomide/X-irradiation [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2019; 2019 Mar 29-Apr 3; Atlanta, GA. Philadelphia (PA): AACR; Cancer Res 2019;79(13 Suppl):Abstract nr 3934.

Abstract 3682: Therapeutic targeting of stem cell self-renewal in childhood medulloblastoma: Strategies for blocking recurrence

Abstract Introduction: Medulloblastoma (MB) is the most common malignant pediatric brain tumor. Group 3 MB patients face the highest incidence of metastasis and poor overall patient survival. The early onset and highly aggressive nature of MB suggest a stem cell origin, where a highly self-renewing transformed cell of the postnatal cerebellum drives MB tumorigenesis. In this work, we explore how WNT signaling and other essential drivers of self-renewal, BMI1 and MSI1, promote MB progression. We subsequently generate new strategies to therapeutically target mechanisms of MB stem cell self-renewal that drive treatment resistance and relapse in Group 3 MB. Experimental procedures: We apply stem cell assays, patient-derived human-mouse xenograft (PDX) models, and genomic and bioinformatic profiling of recurrent patient-derived MB. Our established brain tumor initiating cell (BTIC) model provides an excellent tool for the examination of developmental pathways implicated in MB. New Unpublished Data: A small molecule Bmi1 inhibitor, PTC-028, induced a remarkable decrease in self-renewal as well as reduction of local and spinal metastatic disease in recurrent MB, which is striking as no prior drug has shown efficacy against recurrent Group 3 MB. Although mouse and human neural stem cells (NSCs) express Bmi1 and are mildly sensitive to Bmi1 inhibitors, no significant toxicity was observed in either mouse or human NSCs upon PTC-028 treatment, at doses that induced efficacious killing of MB cells. Another novel therapeutic paradigm includes activating Wnt signaling in otherwise non-Wnt MB, which abrogates self-renewal and tumorigenicity of these highly aggressive tumors. For safe and non-toxic activation of Wnt in preclinical models, we identified L807mts, a novel inhibitor that functions through a substrate-to-inhibitor conversion mechanism within the catalytic site of GSK. A final therapeutic strategy to target self-renewal lies in the discovery of the targetable MB-specific interactome of the RNA binding protein (RBP) Musashi1, another key regulator of stem cell self-renewal. Msi1 is overexpressed in Group 3 MB compared to normal cerebellum, and is associated with poor patient prognosis. shRNA knockdown of Msi1 decreased the self-renewal capacity of MB stem cells and significantly decreased tumor burden and increased survival in our PDX model. Finally, comparative eCLIP (enhanced cross-linking and immunoprecipitation) of MB stem cells and normal NSCs, combined with mass spectrometry and RNA-sequencing of shMsi1 MB cells, has elucidated novel therapeutic targets in the RBP interactome of Msi1 Conclusion: Characterization and therapeutic targeting of self-renewal mechanisms unique to MB BTICs may provide an opportunity to limit treatment-resistant stem cell populations from driving patient relapse in recurrent Group 3 MB, a disease currently lacking any targeted therapies. Note: This abstract was not presented at the meeting. Citation Format: David Bakhshinyan, Michelle Kameda-Smith, Branavan Manoranjan, Ashley Adile, Chitra Venugopal, Sheila Kumari Singh. Therapeutic targeting of stem cell self-renewal in childhood medulloblastoma: Strategies for blocking recurrence [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2019; 2019 Mar 29-Apr 3; Atlanta, GA. Philadelphia (PA): AACR; Cancer Res 2019;79(13 Suppl):Abstract nr 3682.

Induction of chemokine CCL3 by NF-κB reduces methylmercury toxicity in C17.2 mouse neural stem cells

Methylmercury is an environmental pollutant that shows selective toxicity to the central nervous system. We previously reported that brain-specific expression of chemokine CCL3 increases in mice administered methylmercury. However, the relationship between CCL3 and methylmercury toxicity has not been elucidated. Here, we confirmed that induction of CCL3 expression occurs before pathological change by methylmercury treatment was observed in the mouse brain. This induction was also observed in C17.2 mouse neural stem cells before methylmercury-induced cytotoxicity. In addition, cells in which CCL3 was knocked-down showed higher methylmercury sensitivity than did control cells. Moreover, activation of transcription factor NF-κB was observed following methylmercury treatment, and methylmercury-mediated induction of CCL3 expression was partially suppressed by knockdown of p65, an NF-κB subunit. Our results suggest that NF-κB plays a role in the induction of methylmercury-mediated CCL3 expression and that this action may be a cellular response to methylmercury toxicity.

An Alternative In Vitro Method for Examining Nanoparticle-Induced Cytotoxicity.

Conventional in vitro assays are often used as initial screens to identify potential toxic effects of nanoparticles (NPs). However, many NPs have shown interference with conventional in vitro assays, resulting in either false-positive or -negative outcomes. Here, we report an alternative method for the in vitro assessment of NP-induced cytotoxicity utilizing Fluoro-Jade C (FJ-C). To provide proof of concept and initial validation data, Ag-NPs and Au-NPs were tested in 3 different cell cultures including rat brain microvessel endothelial cells, mouse neural stem cells, and the human SH-SY5Y cell line. Conventional 2,3-bis-(2-methoxy-4-nitro-5-sulfophenyl)-2H-tetrazolium-5-carboxanilide (XTT) and lactate dehydrogenase (LDH) assays were run in parallel with the new method and served as references. The results demonstrate for the first time that FJ-C labeling can be a useful tool for assessing NP-induced cytotoxicity in vitro. Using these approaches, it was also demonstrated that removal of Ag-NPs-while keeping the Ag-ions that were released from the Ag-NPs in culture media-abolished the measured cytotoxicity, indicating that Ag-NPs rather than Ag-ions in solution contributed to the observed cytotoxic effects. Further, co-treatment of Ag-NPs with N-acetyl cysteine (NAC) prevented the observed cytotoxicity, suggesting a protective role of NAC in Ag-NP-induced cytotoxicity. Thus, this alternative in vitro assay is well suited for identify potential cytotoxicity associated with exposure to NPs.

Rapid and Efficient Differentiation of Rodent Neural Stem Cells into Oligodendrocyte Progenitor Cells

Oligodendrocyte progenitor cells (OPCs) may have beneficial effects in cell replacement therapy of neurodegenerative disease owing to their unique capability to differentiate into myelinogenic oligodendrocytes (OLs) in response to extrinsic signals. Therefore, it is of significance to establish an effective differentiation methodology to generate highly pure OPCs and OLs from some easily accessible stem cell sources. To achieve this goal, in this study, we present a rapid and efficient protocol for oligodendroglial lineage differentiation from mouse neural stem cells (NSCs), rat NSCs, or mouse embryonic stem cell-derived neuroepithelial stem cells. In a defined culture medium containing Smoothened Agonist, basic fibroblast growth factor, and platelet-derived growth factor-AA, OPCs could be generated from the above stem cells over a time course of 4–6 days, achieving a cell purity as high as ∼90%. In particular, these derived OPCs showed high expandability and could further differentiate into myelin basic protein-positive OLs within 3 days or alternatively into glial fibrillary acidic protein-positive astrocytes within 7 days. Furthermore, transplantation of rodent NSC-derived OPCs into injured spinal cord indicated that it is a feasible strategy to treat spinal cord injury. Our results suggest a differentiation strategy for robust production of OPCs and OLs from rodent stem cells, which could provide an abundant OPC source for spinal cord injury.

Retracted: PPARs Expression in Adult Mouse Neural Stem Cells: Modulation of PPARs during Astroglial Differentiaton of NSC.

[This retracts the article DOI: 10.1155/2007/48242.].

Methylmercury induces the expression of chemokine CCL4 via SRF activation in C17.2 mouse neural stem cells

Methylmercury is an environmental pollutant that causes specific and serious damage to the central nervous system. We have previously shown that C-C motif chemokine ligand 4 (CCL4) protects cultured neural cells from methylmercury toxicity and expression of CCL4 is specifically induced in mouse brain by methylmercury. In this study, we examined the transcriptional regulatory mechanism that induces CCL4 expression by methylmercury using C17.2 mouse neural stem cells. The promoter region of the CCL4 gene was analyzed by a reporter assay, revealing that the region up to 50 bp upstream from the transcription start site was necessary for inducing expression of CCL4 by methylmercury. Nine transcription factors that might bind to this upstream region and be involved in the induction of CCL4 expression by methylmercury were selected, and the induction of CCL4 expression by methylmercury was suppressed by the knockdown of serum response factor (SRF). In addition, the nuclear level of SRF was elevated by methylmercury, and an increase in the amount bound to the CCL4 gene promoter was also observed. Furthermore, we examined the upstream signaling pathway involved in the induction of CCL4 expression by SRF, and confirmed that activation of p38 and ERK, which are part of the MAPK pathway, are involved. These results suggest that methylmercury induces the expression of CCL4 by activating SRF via the p38 and ERK signaling pathway. Our findings are important for elucidating the mechanism involved in the brain-specific induction of CCL4 expression by methylmercury.

Long-term self-renewal of naïve neural stem cells in a defined condition

During embryonic development, neural stem cells (NSCs) emerge as early as the neural plate stage and give rise to the nervous system. Early-stage NSCs express Sry-related-HMG box-1 (Sox1) and are biased towards neuronal differentiation. However, long-term maintenance of early-stage NSCs in vitro remains a challenge. Here, we report development of a defined culture condition for the long-term maintenance of Sox1-positive early-stage mouse NSCs. The proliferative ability of these Sox1-positive NSCs was confirmed by clonal propagation. Compared to the NSCs cultured using the traditional culture condition, the long-term self-renewing Sox1-positive NSCs efficiently differentiate into neurons and exhibit an identity representative of the anterior and midbrain regions. These early-stage Sox1-positive NSCs could also be switched to late-stage NSCs by being cultured with bFGF/EGF, which can then differentiate into astrocytes and oligodendrocytes. The long-term self-renewing Sox1-positive NSCs were defined as naïve NSCs, based on their high neuronal differentiation capacity and anterior regional identity. This culture condition provides a robust platform for further dissection of the NSC self-renewal mechanism and promotes potential applications of NSCs for cell-based therapy on nervous system disorders.

HEWL interacts with dissipated oleic acid micelles, and decreases oleic acid cytotoxicity.

Senile plaques are well-known hallmarks of Alzheimer’s Diseases (AD). However, drugs targeting tangles of the protein tau and plaques of β-amyloid have no significant effect on disease progression, and the studies on the underlying mechanism of AD remain in high demand. Growing evidence supports the protective role of senile plaques in local inflammation driven by S100A9. We herein demonstrate that oleic acid (OA) micelles interact with hen egg white lysozyme (HEWL) and promote its amyloid formation. Consequently, SH-SY5Y cell line and mouse neural stem cells are rescued from OA toxicity by co-aggregation of OA and HEWL. Using atomic force microscopy in combination with fluorescence microscopy, we revealed that HEWL forms round-shaped aggregates in the presence of OA micelles instead of protofibrils of HEWL alone. These HEWL amyloids act as a sink for toxic OA micelles and their co-aggregate form large clumps, suggesting a protective function in amyloid and OA cytotoxicity.

Opposite regulation of Wnt/β-catenin and Shh signaling pathways by Rack1 controls mammalian cerebellar development

The development of the cerebellum depends on intricate processes of neurogenesis, migration, and differentiation of neural stem cells (NSCs) and progenitor cells. Defective cerebellar development often results in motor dysfunctions and psychiatric disorders. Understanding the molecular mechanisms that underlie the complex development of the cerebellum will facilitate the development of novel treatment options. Here, we report that the receptor for activated C kinase (Rack1), a multifaceted signaling adaptor protein, regulates mammalian cerebellar development in a cell type-specific manner. Selective deletion of Rack1 in mouse NSCs or granule neuron progenitors (GNPs), but not Bergmann glial cells (BGs), causes severe defects in cerebellar morphogenesis, including impaired folia and fissure formation. NSCs and GNPs lacking Rack1 exhibit enhanced Wnt/β-catenin signaling but reduced Sonic hedgehog (Shh) signaling. Simultaneous deletion of β-catenin in NSCs, but not GNPs, significantly rescues the Rack1 mutant phenotype. Interestingly, Rack1 controls the activation of Shh signaling by regulating the ubiquitylation and stability of histone deacetylase 1 (HDAC1)/HDAC2. Suppression of HDAC1/HDAC2 activity in the developing cerebellum phenocopies the Rack1 mutant. Together, these results reveal a previously unknown role of Rack1 in controlling mammalian cerebellar development by opposite regulation of Wnt/β-catenin and Shh signaling pathways.

Two-Photon Image Tracking of Neural Stem Cells via Iridium Complexes Encapsulated in Polymeric Nanospheres.

Iridium(III) complexes have been shown to be promising probes in two-photon imaging to real-time track the transplanted cells in stem-cell-based therapy. Here, we report on polymeric nanocapsules loaded with red phosphorescence dye of bis(2-methyldibenzo[f,h]quinoxaline) (acetylacetonate) iridium(III) (Ir(MDQ)2acac) with excellent stability created by the double emulsion method. The Ir(MDQ)2acac nanocapsules present high biocompatibility and an efficient fluorescent labeling rate when incubated with cultured mouse neural stem cells (NSCs). More importantly, the Ir(MDQ)2acac nanocapsules had both one- and two-photon imaging properties with stable phosphorescence lasting for 72 h. Furthermore, data from in vivo tracking in nude mice demonstrated that the photoluminescence from Ir(MDQ)2acac nanocapsules in NSCs could be stably monitored for up to 21 days. Our data shed light on the potential clinical application of iridium complexes encapsulated in polymeric nanospheres for two-photon imaging in real-time tracking of the transplanted stem cells.

Identifying Transcriptional Regulatory Modules Among Different Chromatin States in Mouse Neural Stem Cells.

Gene expression regulation is a complex process involving the interplay between transcription factors and chromatin states. Significant progress has been made toward understanding the impact of chromatin states on gene expression. Nevertheless, the mechanism of transcription factors binding combinatorially in different chromatin states to enable selective regulation of gene expression remains an interesting research area. We introduce a nonparametric Bayesian clustering method for inhomogeneous Poisson processes to detect heterogeneous binding patterns of multiple proteins including transcription factors to form regulatory modules in different chromatin states. We applied this approach on ChIP-seq data for mouse neural stem cells containing 21 proteins and observed different groups or modules of proteins clustered within different chromatin states. These chromatin-state-specific regulatory modules were found to have significant influence on gene expression. We also observed different motif preferences for certain TFs between different chromatin states. Our results reveal a degree of interdependency between chromatin states and combinatorial binding of proteins in the complex transcriptional regulatory process. The software package is available on Github at - https://github.com/BSharmi/DPM-LGCP.

Human IL12p80 and Neural Stem Cells Enhance Sciatic Nerve Regeneration

Background: We previously identified mouse interleukin-12p80 (mIL12p80, a homodimer of IL12p40) in the cell extracts of implanted poly(L-lactic acid) (PLA) nerve conduit combined with neural stem cells (NSCs) and showed that mIL12p80 enhances the functional recovery and nerve regeneration in mice. Here, we showed that human IL12p80 (hIL12p80) improves the sciatic nerve regeneration in mice. Methods: Implantation of hIL12p80 and NSCs into nerve conduit promotes repair of the sciatic nerve injury in mouse model. Findings: NSCs transplanted with hIL12p80 showed the best recovery than the other groups in sciatic functional index (SFI), compound muscle action potential (CMAP) and Rotarod analyses. In addition, the group with Conduit+NSC+hIL12p80 (CNI) outperformed the other groups in SFI and Rotarod tests beginning at the fourth-week post-surgery. Immunohistochemistry showed that the CNI group increases the diameter of newly regenerated nerve 98%. In vitro studies showed that hIL12p80 stimulates differentiation of mouse NSCs to oligodendrocyte lineages through phosphorylation of Stat3 at Y705. Further, implantation using poly(L-lactic-co-glycolic acid) (PLGA) nerve conduits (C 2.0 and C 2.1) showed better recovery in Rotarod test and CMAP than using PLA conduits (C 1.0) in FVB/NJ (FVB) mice. In C57BL/6J (B6) mice, the group with C 2.1+NSC+hIL12p80 (C 2.1NI) not only promotes sciatic functional recovery but also reduces experimental autotomy. Interpretation: These results suggest that hIL12p80 together with NSCs enhance the functional recovery and accelerate the regeneration of damaged nerves in mice. These findings could be used in devising potential strategies for nerve injury treatment. Funding Statement: This research is supported by National Health Research Institutes, Taiwan (CS-107-PP-02), and Ministry of Science and Technology, Taiwan (107-1901-01-19-03; 107-0324-01-19-03). Declaration of Interests: The authors declare no potential conflicts of interest. Ethics Approval Statement: In this study, all animal experimental procedures followed ethical guidelines and were approved by the Institutional Animal Care and Use Committee (IACUC) of the National Health Research Institutes (Protocol No. NHRI-IACUC-101067A).

Circular RNA expression profiles during the differentiation of mouse neural stem cells

BackgroundCircular RNAs (circRNAs) have recently been found to be expressed in human brain tissue, and many lines ofevidence indicate that circRNAs play regulatory roles in neurodevelopment. Proliferation and differentiation of neural stem cells (NSCs) are critical parts during development of central nervous system (CNS).To date, there have been no reports ofcircRNA expression profiles during the differentiation of mouse NSCs. We hypothesizethat circRNAs mayregulate gene expression in the proliferation anddifferentiation of NSCs.ResultsIn this study, we obtained NSCs from the wild-type C57BL/6 J mouse fetal cerebral cortex. We extracted total RNA from NSCs in different differentiation stagesand then performed RNA-seq. By analyzing the RNA-Seq data, we found 37circRNAs and 4182 mRNAs differentially expressedduringthe NSC differentiation. Gene Ontology (GO) enrichment analysis of thecognate linear genes of these circRNAsrevealed that some enriched GO terms were related to neural activity. Furthermore, we performed a co-expression network analysis of these differentially expressed circRNAs and mRNAs. The result suggested a stronger GO enrichmentin neural features for both the cognate linear genes of circRNAs and differentially expressed mRNAs.ConclusionWe performed the first circRNA investigation during the differentiation of mouse NSCs. Wefound that12 circRNAs might have regulatory roles duringthe NSC differentiation, indicating that circRNAs might be modulated during NSC differentiation.Our network analysis suggested the possible complex circRNA-mRNA mechanisms during differentiation, and future experimental workis need to validate these possible mechanisms.

Neural Differentiation of Mouse Neural Stem Cells as a Tool to Assess Developmental Neurotoxicity of Drinking Water in Taihu Lake

In this study, we used neural stem cells (NSCs) as a toxicology tool to assess the potential developmental neurotoxicity of drinking water from Taihu Lake. We found that the condensed drinking water could inhibit the proliferation and differentiation of NSCs, especially the tap water. Inductively coupled plasma mass spectrometry and high-performance liquid chromatography analysis showed that nickel was detected in the tap water with a high concentration. Our study revealed that nickel could inhibit NSCs proliferation and differentiation, which is induced not only by the intracellular reactive oxygen species generation, but also by the protein levels upregulation of p-c-Raf, p-MEK1/2 and p-Erk1/2 through the axon guidance signal pathways. These findings will provide a new way of research insight for investigation of nickel-induced neurotoxicity. Meanwhile, our test method confirmed the feasibility and reliability of stem cell assays for developmental neurotoxicity testing.

Superparamagnetic iron oxide nanoparticles as a tool to track mouse neural stem cells in vivo.

Cell transplantation offers a promising approach in many neurological disorders. Neural stem (NS) cells are potential candidates for cell therapy. The ability to track the grafted cells in the host tissue will refine this therapy. Superparamagnetic iron oxide nanoparticles (SPION) have been suggested as a feasible method, but there is no consensus about its safety. Here we investigated the feasibility of label NS cells with SPION and track by MRI after transplantation into mouse striatum with SPION cells and its therapeutic effects by grafting the cells into mouse striatum. We demonstrated that SPION-labeled NS cells display normal patterns of cellular processes including proliferation, migration, differentiation and neurosphere formation. Transmission electron microscopy reveals SPION in the cytoplasm of the cells, which was confirmed by microanalysis. Neurons and astrocytes generated from SPION-labeled NS cells were able to carry nanoparticles after 7days under differentiation. SPION-labeled NS cells transplanted into striatum of mice were detected by magnetic resonance imaging (MRI) and microscopy 51days later. In agreement with others reports, we demonstrated that NS cells are able to incorporate SPION in vitro without altering the stemness, and can survive and be tracked by MRI after they have been grafted into mice striatum.

Isolation and Culture of Embryonic Mouse Neural Stem Cells.

Neural stem cells (NSCs) are multipotent and can give rise to the three major cell types of the central nervous system (CNS). In vitro culture and expansion of NSCs provide a suitable source of cells for neuroscientists to study the function of neurons and glial cells along with their interactions. There are several reported techniques for the isolation of neural stem cells from adult or embryo mammalian brains. During the microsurgical operation to isolate NSCs from different regions of the embryonic CNS, it is very important to reduce the damage to the brain cells to obtain the highest ratio of live and expandable stem cells. A possible technique for stress reduction during isolation of these cells from the mouse embryo brain is the reduction of surgical time. Here, we demonstrate a developed technique for rapid isolation of these cells from the E13 mouse embryo ganglionic eminence. Surgical procedures include harvesting E13 mouse embryos from the uterus, cutting the frontal fontanelle of the embryo with a bent needle tip, extracting the brain from the skull, microdissection of the isolated brain to harvest the ganglionic eminence, dissociation of the harvested tissue in NSC medium to gain a single cell suspension, and finally plating cells in suspension culture to generate neurospheres.

Isolation and Culture of Embryonic Mouse Neural Stem Cells

Isolation and Culture of Embryonic Mouse Neural Stem Cells

Biodegradable Nerve Guidance Conduit with Microporous and Micropatterned Poly(lactic-co-glycolic acid)-Accelerated Sciatic Nerve Regeneration.

An innovative technique combining capillary force lithography and phase separation method in one step is applied to fabricate artificial nerve guidance conduit (NGC) for peripheral nerve regeneration. Biodegradable porous, patterned NGC (PP-NGC) using poly(lactic-co-glycolic acid) is fabricated. It has micro-grooves and microporosity on the inner surface to promote axonal outgrowth and to enhance permeability for nutrient exchange. In this study, it is confirmed that the inner surface of micro-grooves can modulate neurite orientation and length of mouse neural stem cell compared to porous flat NGC (PF-NGC) in vitro. Coating with 3,4-dihydroxy-l-phenylalanine (DOPA) facilitates the hydrophilic inner surface of PF- and PP-NGCs via bioinspired catechol chemistry. For in vivo study, PF-NGC and PP-NGC coated with or without DOPA are implanted in the 10mm sciatic nerve defect margins between proximal and distal nerves in rats. Especially, PP-NGC coated with DOPA shows higher sciatic function index score, onset-to-peak amplitude, and muscle fiber diameter compared to other groups. The proposed hybrid-structured NGC not only can serve as a design for functional NGC without growth factor but also can be used in clinical application for peripheral nerve regeneration.