Survival Of Neural Stem Cells Research Articles

Initial graft size and not the innate immune response limit survival of engrafted neural stem cells.

Transplantation of neural stem cells (NSCs) appears to be a promising regenerative therapy for a variety of neurological disorders. Nevertheless, NSC engraftment is limited by the number of surviving cells. To maximize stem cell-mediated effects, timing of implantation and cell number have to be precisely evaluated. Here, a transgenic murine NSC line was optimized for high expression levels of the imaging reporters Luc2 and copGFP. NSCs of 150 000, 75 000, 15 000 or 1500 cells or Hanks buffered salt solution were implanted into the striatum of nude mice. The survival of NSCs was monitored with in vivo bioluminescence imaging (BLI) over 2weeks and brain sections were histologically analysed for glial cells of the innate immune system. The longitudinal in vivo BLI data revealed a significantly reduced viability with the highest rate for 150 000 engrafted NSCs. The cell loss was not correlated with the number of Iba-1+ immune cells nor GFAP+ astrocytes. Histological quantification of copGFP+ cells at 14days postimplantation confirmed the in vivo data with the highest density of copGFP+ cells in the 150 000-cell graft and the highest survival rate for 1500 cells/graft. In conclusion, regenerative therapies should strictly evaluate the maximal number of stem cells to be transplanted in one location, as the results suggest that there is a critical limit of cells able to survive in the adult brain. Survival is limited by availability of oxygen and nutrients but not the inflammatory response induced by the implantation.

Brain-derived Neurotrophic Factor Promotes Growth of Neurons and Neural Stem Cells Possibly by Triggering the Phosphoinositide 3-Kinase/ AKT/Glycogen Synthase Kinase-3β/β-catenin Pathway.

Brain-derived neurotrophic factor (BDNF) plays a crucial role in promoting survival and differentiation of neurons and neural stem cells (NSCs), but the downstream regulating mechanisms remain poorly understood. We investigated whether BDNF exerts its effect by triggering the phosphoinositide 3-kinase (PI3K), protein kinase B, PKB (AKT), glycogen synthase kinase-3β (GSK-3β) and β-catenin signaling pathway in cultured neurons and NSCs derived from the rat embryonic spinal cord. Immunocytochemistry was used to detect neuronal and NSCs characteristics. RT-PCR was used to detect PI3K/AKT/GSK3β/β-catenin pathway expression. Neurons and NSCs were successfully separated and cultured from Sprague-Dawley rat embryonic spinal cord and were respectively labeled using immunocytochemistry. Neuron-specific nuclear protein, neuronal class III β-tubulin, and neurofilament expression were detected in neurons; nestin, glial fibrillary acidic protein, microtubule-associated protein 2 and chondroitin sulfate glycosaminoglycan expression were detected in the NSCs. BDNF promoted significant neuronal growth (number, soma size, and average neurite length), as well as NSCs proliferation and differentiation, but BDNF antibody decreased neuronal growth and NSCs proliferation and differentiation. RT-PCR was used to detect changes in BDNF signal pathway components, showing that BDNF upregulated tropomyosin receptor kinase B, phosphoinositide 3-kinase (PI3K), AKT and β-catenin, but downregulated GSK-3β in the neurons and NSCs. BDNF antibody downregulated BDNF, tropomyosin receptor kinase B, PI3K, AKT, β-catenin and cellular-myelocytomatosis viral oncogene, but upregulated GSK- 3β, in the neurons and NSCs. Our findings suggested that BDNF contributed to neuronal growth and proliferation and differentiation of NSCs in vitro by stimulating PI3K/AKT/GSK3β/β-catenin pathways.

Multitype Bellman-Harris branching model provides biological predictors of early stages of adult hippocampal neurogenesis

BackgroundAdult hippocampal neurogenesis, the process of formation of new neurons, occurs throughout life in the hippocampus. New neurons have been associated with learning and memory as well as mood control, and impaired neurogenesis has been linked to depression, schizophrenia, autism and cognitive decline during aging. Thus, understanding the biological properties of adult neurogenesis has important implications for human health. Computational models of neurogenesis have attempted to derive biologically relevant knowledge, hard to achieve using experimentation. However, the majority of the computational studies have predominantly focused on the late stages of neurogenesis, when newborn neurons integrate into hippocampal circuitry. Little is known about the early stages that regulate proliferation, differentiation, and survival of neural stem cells and their immediate progeny.ResultsHere, based on the branching process theory and biological evidence, we developed a computational model that represents the early stage hippocampal neurogenic cascade and allows prediction of the overall efficiency of neurogenesis in both normal and diseased conditions. Using this stochastic model with a simulation program, we derived the equilibrium distribution of cell population and simulated the progression of the neurogenic cascade. Using BrdU pulse-and-chase experiment to label proliferating cells and their progeny in vivo, we quantified labeled newborn cells and fit the model on the experimental data. Our simulation results reveal unknown but meaningful biological parameters, among which the most critical ones are apoptotic rates at different stages of the neurogenic cascade: apoptotic rates reach maximum at the stage of neuroblasts; the probability of neuroprogenitor cell renewal is low; the neuroblast stage has the highest temporal variance within the cell types of the neurogenic cascade, while the apoptotic stage is short.ConclusionAt a practical level, the stochastic model and simulation framework we developed will enable us to predict overall efficiency of hippocampal neurogenesis in both normal and diseased conditions. It can also generate predictions of the behavior of the neurogenic system under perturbations such as increase or decrease of apoptosis due to disease or treatment.

Ferulic acid promotes survival and differentiation of neural stem cells to prevent gentamicin-induced neuronal hearing loss

Neural stem cells (NSCs) have exhibited promising potential in therapies against neuronal hearing loss. Ferulic acid (FA) has been widely reported to enhance neurogenic differentiation of different stem cells. We investigated the role of FA in promoting NSC transplant therapy to prevent gentamicin-induced neuronal hearing loss. NSCs were isolated from mouse cochlear tissues to establish in vitro culture, which were then treated with FA. The survival and differentiation of NSCs were evaluated. Subsequently, neurite outgrowth and excitability of the in vitro neuronal network were assessed. Gentamicin was used to induce neuronal hearing loss in mice, in the presence and absence of FA, followed by assessments of auditory brainstem response (ABR) and distortion product optoacoustic emissions (DPOAE) amplitude. FA promoted survival, neurosphere formation and differentiation of NSCs, as well as neurite outgrowth and excitability of in vitro neuronal network. Furthermore, FA restored ABR threshold shifts and DPOAE in gentamicin-induced neuronal hearing loss mouse model in vivo. Our data, for the first time, support potential therapeutic efficacy of FA in promoting survival and differentiation of NSCs to prevent gentamicin-induced neuronal hearing loss.

P 4 Bioluminescence imaging visualizes osteopontin-induced neurogenesis and neuroblasts migration in the mouse brain after stroke

Background: The phosphoglycoprotein osteopontin (OPN) is upregulated in the brain following cerebral ischemia, where is exerts neuroprotective properties. We previously demonstrated OPN to increase survival and proliferation of neural stem cells (NSC) in vitro and in vivo. In culture, OPN additionally promotes NSC migration as well as a neuronal differentiation fate. Based on these data, we hypothesized OPN to induce NSC migration as well as neurogenesis in vivo as well. We here aimed to establish and visualize these effects using non-invasive in vivo imaging. Methods: Transgenic mice expressing luciferase (luc) under the doublecortin (DCX) promoter were used for brain-specific bioluminescence imaging (BLI) of DCX + neuroblasts. Focal cerebral ischemia was induced via photothrombosis (PT) in n = 27 mice, while n = 16 mice served as healthy control (CNT). Mice were randomized to receive either OPN (n = 14 PT, n = 8 CNT), or saline (n = 13 PT, n = 8 CNT) via a single injection into the lateral ventricle of the brain. Magnetic resonance imaging (MRI) was performed to verify and localize infarcts. BLI data was repetitively obtained for a period of 28 days in each individual animal. Ex vivo, immunohistochemistry for DCX + neuroblasts served to validate imaging data at high resolution. Results: In both healthy as well as stroke mice treated with OPN intracerebroventricularly, we observed enhanced migration of DCX + neuroblasts towards the site of OPN injection over a period of 28 days, as assessed by BLI ( p 0.01 each). Moreover, the total flux of photons was increased in healthy mice 2 days after OPN injection, consistent with an expansion of neuroblasts numbers ( p 0.01 ). Under ischemic conditions, OPN increased neuroblast numbers as surrogate for neurogenesis throughout the observation period of 28 days, as assessed by BLI ( p 0.05 ). Conclusions: Data suggest positive effects of OPN on both the migration of neuroblasts as well as on neurogenesis in vivo. BLI visualizes and quantifies these effects non-invasively in the experimental animal in a longitudinal fashion, allowing to monitor the temporo-spatial dynamics of NSC mobilization under physiological conditions as well as in cerebral ischemia. The results confirm OPN as a promising drug to promote regeneration after stroke via its effects on neural stem cells.

Human neural stem cell transplantation into the corpus callosum of Alzheimer's mice.

The hippocampus has been the target of stem cell transplantations in preclinical studies focused on Alzheimer's disease, with results showing improvements in histological and behavioral outcomes. The corpus callosum is another structure that is affected early in Alzheimer's disease. Therefore, we hypothesize that this structure is a novel target for human neural stem cell transplantation in transgenic Alzheimer's disease mouse models. This study demonstrates the feasibility of targeting the corpus callosum and identifies an effective immunosuppression regimen for transplanted neural stem cell survival. These results support further preclinical development of the corpus callosum as a therapeutic target in Alzheimer's disease.

Effects of Human ES-Derived Neural Stem Cell Transplantation and Kindling in a Rat Model of Traumatic Brain Injury

Traumatic brain injury (TBI) is one of the leading causes of death and disability in the population worldwide, with a broad spectrum of symptoms and disabilities. Posttraumatic hyperexcitability is one of the most common neurological disorders that affect people after a head injury. A reliable animal model of posttraumatic hyperexcitability induced by TBI which allows one to test effective treatment strategies is yet to be developed. To address these issues, in the present study, we tested human embryonic stem cell–derived neural stem cell (NSC) transplantation in an animal model of posttraumatic hyperexcitability in which the brain injury was produced in one hemisphere of immunodeficient athymic nude rats by controlled cortical impact, and spontaneous seizures were produced by repeated electrical stimulation (kindling) in the contralateral hemisphere. At 14 wk posttransplantation, we report human NSC (hNSC) survival and differentiation into all 3 neural lineages in both sham and injured animals. We observed twice as many surviving hNSCs in the injured versus sham brain, and worse survival on the kindled side in both groups, indicating that kindling/seizures are detrimental to survival or proliferation of hNSCs. We also replicated our previous finding that hNSCs can ameliorate deficits on the novel place recognition task,33 but such improvements are abolished following kindling. We found no significant differences pre- or post-kindling on the elevated plus maze. No significant correlations were observed between hNSC survival and cognitive performance on either task. Together these findings suggest that Shef6-derived hNSCs may be beneficial as a therapy for TBI, but not in animals or patients with posttraumatic hyperexcitability.

HIF-1α promotes NSCs migration by modulating Slit2-Robo1 signaling after cerebral ischemia

Our previous studies have shown that transplantation of Hypoxia-inducible factor-1α (HIF-1α) gene modified neural stem cells (NSCs) reduced brain injury by improving the survival of NSCs and protecting the vascular system. HIF-1α plays pivotal roles during hypoxia, and its downstream pathways might be the primary mechanisms for the growth of NSCs. However, there are very few studies reported whether HIF-1α regulates NSCs migration. In this study, to test the hypothesis that HIF-1α modulates migration of NSCs after cerebral ischemia, we compared the injection of HIF-1α gene recombinant adenovirus, and control adenovirus in ischemia penumbra at 24 h after transient middle cerebral artery occlusion (tMCAO). BrdU labeled NSCs were transplanted in the lateral ventricle at the same time in both groups. The modified neurological severity score (NSS) was used to evaluate neurological deficits. Immunohistochemistry for HIF-1α, BrdU, Slit2 and Robo1 were performed. Comparing with vehicle group HIF-1α group showed better behavioral recovery on day 21 and 28. Expression of HIF-1α in HIF-1α group is higher than that in vehicle group. In HIF-1α group, more BrdU-positive cells were found than that in vehicle group. There are increased Slit2 in HIF-1α group. However, robo1, a receptor of Slits is decreased than that in vehicle group. Thus, we concluded that in cerebral ischemia rat model HIF-1α increased NSCs migration by inhibiting Slit2-Robo1 pathway, and improved the neurological behavior. In conclusion, our results indicate that HIF-1α may be a potential therapeutic target for ischemic stroke through promoting neuroregeneration.

Cardiotrophin-1 stimulates the neural differentiation of human umbilical cord blood-derived mesenchymal stem cells and survival of differentiated cells through PI3K/Akt-dependent signaling pathways.

Cardiotrophin-1 (CT1) plays an important role in the differentiation, development, and survival of neural stem cells. In this study, we analyzed its effects on the stimulation of human umbilical cord blood-derived mesenchymal stem cells in terms of their potential to differentiate into neuron-like cells, their survival characteristics, and the molecular mechanisms involved. The treatment of cells with neural induction medium (NIM) and CT1 generated more cells that were neuron-like and produced stronger expression of neural-lineage markers than cells treated with NIM and without CT1. Bcl-2 and Akt phosphorylation (p-Akt) expression levels increased significantly in cells treated with both NIM and CT1. This treatment also effectively blocked cell death following neural induction and decreased Bax, Bak and cleaved-caspase 3 expression compared with cells treated with NIM without CT1. In addition, the inhibition of phosphatidylinositol 3-kinase (PI3K) abrogated p-Akt and Bcl-2 expression. Thus, PI3K/Akt contribute to CT1-stimulated neural differentiation and to the survival of differentiated cells.

Survival, differentiation and migration of the spinal cord derived neural stem cells from transgenic mice transplanted into mouse models of spinal cord injury

Objective To observe the mice motion recovery and neural stem cell (NSCs) survival, migration and differentiation after the green fluorescent protein (GFP)+ -positive NSCs which was isolated and cultivated from mouse embryonic spinal cord was transplanted into mouse models of spinal cord injury lesions. Methods mice were randomly divided into control group (n=10), injury group (n=30) and cell transplanted group (n=30). The NSCs were transplanted into spinal cord injury after establishing the injured models. The Basso-Beattie-Bresnahan (BBB) function scores, inclined plane test and immunohistochemistry testing were respectively evaluated and recorded 1, 2, 4, 6, 8 weeks after the operation. Results The mouse hind limbs were paralyzed after hitting and BBB scores were 0. The transplanted group increased to 4.50 ± 1.04, injury group was 2.17 ± 0.75, scores began to appear differences at 2 weeks (P=0.023). The scores of transplanted group was 8.17±1.47 and injury group was 5.33±1.03 at 4 weeks (P=0.015). The scores of two groups were increased with the passage of time after 4 weeks. The scores of transplanted group was 10.8±1.47 and injury group was 8.33±0.81 at 6 weeks (P=0.017). The difference was biggest at 8 weeks, transplanted group was 15.50±1.37 and injury group was 11.17±1.16 (P=0.016). The angle of transplanted group was (17.17±3.18)°and injury group was (14.83±3.06)° at 1 weeks. At 2 weeks, the angle of transplanted group was (23.33±4.27)°and injury group was (18.17±2.40)°. The two groups’ results appeared significant differences at 4 weeks in inclined plane test (P=0.024). The transplanted group was (33.83±6.30)°, injury group was (23.50±1.76)°(P=0.029). The small difference of The difference was biggest at 8 weeks, transplanted group was (46.83±6.05)° and injury group was (36.33±7.23)°(P=0.019). The transplanted NSCs can survive and migrate in the body, some of which can remain undifferentiated state, a small part of which can differentiate into glia, less of which differentiate into neurons. Conclusion There was a promoting effect of NSCs for the recovery of spinal cord injury. It was forming a micro-environment conducive to resume by transplanting cells and increasing the proportion of neurons to promote recovery. Key words: Green fluorescent protein; Neural stem cells; Spinal cord injury; Cell transplantation; Mouses

Proteolytic processed form of CXCL12 abolishes migration and induces apoptosis in neural stem cells in vitro

The subventricular zone (SVZ) of the adult mammalian brain hosts full potential neural stem cells (NSCs). NSCs are able to respond to extracellular signals in the brain, amplifying the pool of progenitor cells and giving rise to neuroblasts that show ability to migrate towards an injury site. These signals can come from vascular system, cerebrospinal fluid, glial cells, or projections of neurons in adjoining regions. CXCL12, a chemokine secreted after brain injury, reaches the SVZ in a gradient manner and drives neuroblasts towards the lesion area. Among many other molecules, matrix metalloproteinase 2 and 9 (MMP-2/9) are also released during brain injury. MMP-2/9 can cleave CXCL12 generating a new molecule, CXCL12(5-67), and its effects on NSCs viability is not well described. Here we produced recombinant CXCL12 and CXCL12(5-67) and evaluated their effect in murine adult NSCs migration and survival in vitro. We showed CXCL12(5-67) does not promote NSCs migration, but does induce cell death. The NSC death induced by CXCL12(5-67) involves caspases 9 and 3/7 activation, implying the intrinsic apoptotic pathway in this phenomenon. Our evidences in vitro make CXCL12(5-67) and its receptor potential candidates for brain injuries and neurodegeneration studies.

Melatonin antagonizes interleukin-18-mediated inhibition on neural stem cell proliferation and differentiation.

Neural stem cells (NSCs) are self‐renewing, pluripotent and undifferentiated cells which have the potential to differentiate into neurons, oligodendrocytes and astrocytes. NSC therapy for tissue regeneration, thus, gains popularity. However, the low survivals rate of the transplanted cell impedes its utilities. In this study, we tested whether melatonin, a potent antioxidant, could promote the NSC proliferation and neuronal differentiation, especially, in the presence of the pro‐inflammatory cytokine interleukin‐18 (IL‐18). Our results showed that melatonin per se indeed exhibited beneficial effects on NSCs and IL‐18 inhibited NSC proliferation, neurosphere formation and their differentiation into neurons. All inhibitory effects of IL‐18 on NSCs were significantly reduced by melatonin treatment. Moreover, melatonin application increased the production of both brain‐derived and glial cell‐derived neurotrophic factors (BDNF, GDNF) in IL‐18‐stimulated NSCs. It was observed that inhibition of BDNF or GDNF hindered the protective effects of melatonin on NSCs. A potentially protective mechanism of melatonin on the inhibition of NSC's differentiation caused IL‐18 may attribute to the up‐regulation of these two major neurotrophic factors, BNDF and GNDF. The findings indicate that melatonin may play an important role promoting the survival of NSCs in neuroinflammatory diseases.

Human Induced Pluripotent Stem Cell Derived Neural Stem Cell Survival and Neural Differentiation on Polyethylene Glycol Dimethacrylate Hydrogels Containing a Continuous Concentration Gradient of N-Cadherin Derived Peptide His-Ala-Val-Asp-Ile.

Although preclinical models of spinal cord injury have shown that matrix inclusion in stem cell therapy leads to greater neurological improvements than that including cells alone, there has been insufficient matrix optimization for human cells. N-Cadherin influences the development and maintenance of neural tissue, but the effects of N-cadherin derived peptide His-Ala-Val-Asp-Ile (HAVDI) on the survival, neurite extension, and expression of neural differentiation markers in human induced pluripotent stem cell derived neural stems (hNSC) have not been widely examined. Using polyethylene glycol hydrogels containing a continuous gradient of HAVDI, this study identifies concentration dependent effects on hNSC survival and neural differentiation.

Arctigenin protects against neuronal hearing loss by promoting neural stem cell survival and differentiation.

Neuronal hearing loss has become a prevalent health problem. This study focused on the function of arctigenin (ARC) in promoting survival and neuronal differentiation of mouse cochlear neural stem cells (NSCs), and its protection against gentamicin (GMC) induced neuronal hearing loss. Mouse cochlea was used to isolate NSCs, which were subsequently cultured in vitro. The effects of ARC on NSC survival, neurosphere formation, differentiation of NSCs, neurite outgrowth, and neural excitability in neuronal network in vitro were examined. Mechanotransduction ability demonstrated by intact cochlea, auditory brainstem response (ABR), and distortion product optoacoustic emissions (DPOAE) amplitude in mice were measured to evaluate effects of ARC on GMC-induced neuronal hearing loss. ARC increased survival, neurosphere formation, neuron differentiation of NSCs in mouse cochlear in vitro. ARC also promoted the outgrowth of neurites, as well as neural excitability of the NSC-differentiated neuron culture. Additionally, ARC rescued mechanotransduction capacity, restored the threshold shifts of ABR and DPOAE in our GMC ototoxicity murine model. This study supports the potential therapeutic role of ARC in promoting both NSCs proliferation and differentiation in vitro to functional neurons, thus supporting its protective function in the therapeutic treatment of neuropathic hearing loss in vivo.

Optimization of trophic support for neural stem cell grafts in sites of spinal cord injury

Previously we utilized fibrin matrices and a cocktail of nine growth factors and a cell death inhibitor to promote survival and fill of neural stem cell (NSC) or neural progenitor cell (NPC) grafts to sites of spinal cord injury (SCI). In the current study, we examined whether the number of growth factors in a supportive matrix could be reduced to a more clinically practical number while retaining extensive NPC survival and fill of a spinal cord lesion site. NPCs derived from embryonic day 14 Fischer 344 rat spinal cords expressing green fluorescent protein (GFP) were embedded in fibrin matrices containing a defined growth factor cocktail: one to four factors were tested among nine different groups. Grafts were placed into C5 lateral hemisection lesion sites two weeks post-injury, and graft survival and fill was assessed two weeks later. We found that a four growth factor cocktail consisting of brain-derived neurotrophic factor (BDNF), basic-fibroblastic growth factor (bFGF), vascular endothelial growth factor (VEGF), and MDL28170, a cell death inhibitor, resulted in consistent graft survival, neuronal differentiation, and fill of the lesion site. Extensive stem cell-derived axonal outgrowth from the lesion site occurred, consistent with previous reports. Fewer than four growth factors resulted in suboptimal NPC fill of the lesion site. Collectively, these findings indicate that a simplified, four-component cocktail can support neural progenitor cell engraftment to a spinal cord lesion site to the same extent as a 10-component cocktail.

Regional- and sex-dependent effects of chronic ethanol and cocaine co-administration on adult neural stem cell survival and differentiation

Regional- and sex-dependent effects of chronic ethanol and cocaine co-administration on adult neural stem cell survival and differentiation

Strategies to Enhance Implantation and Survival of Stem Cells After Their Injection in Ischemic Neural Tissue.

High post-transplantation cell mortality is the main limitation of various approaches that are aimed at improving regeneration of injured neural tissue by an injection of neural stem cells (NSCs) and mesenchymal stromal cells (MStroCs) in and/or around the lesion. Therefore, it is of paramount importance to identify efficient ways to increase cell transplant viability. We have previously proposed the "evolutionary stem cell paradigm," which explains the association between stem cell anaerobic/microaerophilic metabolic set-up and stem cell self-renewal and inhibition of differentiation. Applying these principles, we have identified the main critical point in the collection and preparation of these cells for experimental therapy: exposure of the cells to atmospheric O2, that is, to oxygen concentrations that are several times higher than the physiologically relevant ones. In this way, the primitive anaerobic cells become either inactivated or adapted, through commitment and differentiation, to highly aerobic conditions (20%-21% O2 in atmospheric air). This inadvertently compromises the cells' survival once they are transplanted into normal tissue, especially in the hypoxic/anoxic/ischemic environment, which is typical of central nervous system (CNS) lesions. In addition to the findings suggesting that stem cells can shift to glycolysis and can proliferate in anoxia, recent studies also propose that stem cells may be able to proliferate in completely anaerobic or ischemic conditions by relying on anaerobic mitochondrial respiration. In this systematic review, we propose strategies to enhance the survival of NSCs and MStroCs that are implanted in hypoxic/ischemic neural tissue by harnessing their anaerobic nature and maintaining as well as enhancing their anaerobic properties via appropriate ex vivo conditioning.

Therapeutic value of nerve growth factor in promoting neural stem cell survival and differentiation and protecting against neuronal hearing loss.

Nerve growth factor (NGF) is a neurotrophic factor that modulates survival and differentiation of neural stem cells (NSCs). We investigated the function of NGF in promoting growth and neuronal differentiation of NSCs isolated from mouse cochlear tissue, as well as its protective properties against gentamicin (GMC) ototoxicity. NSCs were isolated from the cochlea of mice and cultured in vitro. Effect of NGF on survival, neurosphere formation, and differentiation of the NSCs, as well as neurite outgrowth and neural excitability in the subsequent in vitro neuronal network, was examined. Mechanotransduction capacity of intact cochlea and auditory brainstem response (ABR) threshold in mice were also measured following GMC treatment to evaluate protection using NGF against GMC-induced neuronal hearing loss. NGF improved survival, neurosphere formation, and neuronal differentiation of mouse cochlear NSCs in vitro, as well as promoted neurite outgrowth and neural excitability in the NSC-differentiated neuronal culture. In addition, NGF protected mechanotransduction capacity and restored ABR threshold in gentamicin ototoxicity mouse model. Our study supports a potential therapeutic value of NGF in promoting proliferation and differentiation of NSCs into functional neurons in vitro, supporting its protective role in the treatment of neuronal hearing loss.

Niche astrocytes promote the survival, proliferation and neuronal differentiation of co-transplanted neural stem cells following ischemic stroke in rats.

Niche astrocytes have been reported to promote neuronal differentiation through juxtacrine signaling. However, the effects of astrocytes on neuronal differentiation following ischemic stroke are not fully understood. In the present study, transplanted astrocytes and neural stem cells (NSCs) were transplanted into the ischemic striatum of transient middle cerebral artery occlusion (MCAO) model rats 48 h following surgery. It was observed that the co-transplantation of astrocytes and NSCs resulted in a higher ratio of survival and proliferation of the transplanted NSCs, and neuronal differentiation, in MCAO rats compared with NSC transplantation alone. These results demonstrate that the co-administration of astrocytes promotes the survival and neuronal differentiation of NSCs in the ischemic brain. These results suggest that the co-transplantation of astrocytes and NSCs is more effective than NSCs alone in the production of neurons following ischemic stroke in rats.

Serial in vivo imaging of transplanted allogeneic neural stem cell survival in a mouse model of amyotrophic lateral sclerosis

Neural stem cells (NSCs) are being investigated as a possible treatment for amyotrophic lateral sclerosis (ALS) through intraspinal transplantation, but no longitudinal imaging studies exist that describe the survival of engrafted cells over time. Allogeneic firefly luciferase-expressing murine NSCs (Luc+-NSCs) were transplanted bilaterally (100,000 cells/2μl) into the cervical spinal cord (C5) parenchyma of pre-symptomatic (63day-old) SOD1G93A ALS mice (n=14) and wild-type age-matched littermates (n=14). Six control SOD1G93A ALS mice were injected with saline. Mice were immunosuppressed using a combination of tacrolimus+sirolimus (1mg/kg each, i.p.) daily. Compared to saline-injected SOD1G93A ALS control mice, a transient improvement (p<0.05) in motor performance (rotarod test) was observed after NSC transplantation only at the early disease stage (weeks 2 and 3 post-transplantation). Compared to day one post-transplantation, there was a significant decline in bioluminescent imaging (BLI) signal in SOD1G93A ALS mice at the time of disease onset (71.7±17.9% at 4weeks post-transplantation, p<0.05), with a complete loss of BLI signal at endpoint (120day-old mice). In contrast, BLI signal intensity was observed in wild-type littermates throughout the entire study period, with only a 41.4±8.7% decline at the endpoint. In SOD1G93A ALS mice, poor cell survival was accompanied by accumulation of mature macrophages and the presence of astrogliosis and microgliosis. We conclude that the disease progression adversely affects the survival of engrafted murine Luc+-NSCs in SOD1G93A ALS mice as a result of the hostile ALS spinal cord microenvironment, further emphasizing the challenges that face successful cell therapy of ALS.