Human fetal neural stem cells grafted into contusion-injured rat spinal cords improve behavior

Grafted human neural stem cells (hNSCs) may help to alleviate functional deficits resulting from spinal cord injury by bridging gaps, replacing lost neurons or oligodendrocytes, and providing neurotrophic factors. Previously, we showed that primed hNSCs differentiated into cholinergic neurons in an intact spinal cord. In this study, we tested the fate of hNSCs transplanted into a spinal cord T10 contusion injury model. When grafted into injured spinal cords of adult male rats on either the same day or 3 or 9 days after a moderate contusion injury, both primed and unprimed hNSCs survived for 3 months postengraftment only in animals that received grafts at 9 days postinjury. Histological analyses revealed that primed hNSCs tended to survive better and differentiated at higher rates into neurons and oligodendrocytes than did unprimed counterparts. Furthermore, only primed cells gave rise to cholinergic neurons. Animals receiving primed hNSC grafts on the ninth day postcontusion improved trunk stability, as determined by rearing activity measurements 3 months after grafting. This study indicates that human neural stem cell fate determination in vivo is influenced by the predifferentiation stage of stem cells prior to grafting. Furthermore, stem cell-mediated facilitation of functional improvement depends on the timing of transplantation after injury, the grafting sites, and the survival of newly differentiated neurons and oligodendrocytes.     

Proactive transplantation of human neural stem cells prevents degeneration of striatal neurons in a rat model of Huntington disease

We have investigated the effectiveness of transplantation of human neural stem cells into adult rat striatum prior to induction of striatal damage with the mitochondrial toxin 3-nitropropionic acid (3-NP). Systemic 3-NP administration caused widespread neuropathological deficits similar to ones found in Huntington disease (HD) including impairment in motor function (rotarod balance test) and extensive degeneration of neuron-specific nuclear antigen (NeuN)(+) neurons, calbindin(+) neurons and glutamic acid decarboxylase (GAD)(+) striatal neurons. Animals receiving intrastriatal implantation of human neural stem cells (hNSCs) 1 week before 3-NP treatments exhibited significantly improved motor performance and reduced damage to striatal neurons compared with control sham injections. In contrast, transplantation of hNSCs at 12 h after the initial 3-NP administration did not lead to any improvement in motor performance or protect striatal neurons from the 3-NP-induced toxicity. These results indicate that the presence of grafted hNSCs before 3-NP treatment is required for host striatal neuronal protection and enhanced motor function. Immunoreactivity of brain-derived neurotrophic factor (BDNF) was found in vitro in cultured hNSCs and in vivo in grafted NSCs with expression and secretion of BDNF demonstrated by RT-PCR, immunocytochemistry, dot-blot, and ELISA analyses. Thus, protective effects of proactive transplantation of hNSCs may be due, in part, to effects mediated by BDNF. The findings in this work have particular relevance to a rat model of HD in that proactive transplanted hNSCs protect host striatal neurons against neuronal injury and improve motor impairment induced by 3-NP toxicity.     

Neural stem cells constitutively secrete neurotrophic factors and promote extensive host axonal growth after spinal cord injury

Neural stem cells (NSCs) offer the potential to replace lost tissue after nervous system injury. This study investigated whether grafts of NSCs (mouse clone C17.2) could also specifically support host axonal regeneration after spinal cord injury and sought to identify mechanisms underlying such growth. In vitro, prior to grafting, C17.2 NSCs were found for the first time to naturally constitutively secrete significant quantities of several neurotrophic factors by specific ELISA, including nerve growth factor, brain-derived neurotrophic factor, and glial cell line-derived neurotrophic factor. When grafted to cystic dorsal column lesions in the cervical spinal cord of adult rats, C17.2 NSCs supported extensive growth of host axons of known sensitivity to these growth factors when examined 2 weeks later. Quantitative real-time RT-PCR confirmed that grafted stem cells expressed neurotrophic factor genes in vivo. In addition, NSCs were genetically modified to produce neurotrophin-3, which significantly expanded NSC effects on host axons. Notably, overexpression of one growth factor had a reciprocal effect on expression of another factor. Thus, stem cells can promote host neural repair in part by secreting growth factors, and their regeneration-promoting activities can be modified by gene delivery.     

Intracerebral grafting of cell line or patient-derived neural stem cells for the treatment of neurological disorders]

Due to the development of molecular biology techniques, several types of neurotransmitter or neurotrophic factor secreting cell line can be established. These cell lines were grafted into the brain of animal models of Parkinson's disease and cerebral ischemia after encapsulating into the hollow fiber consisted of semipermeable membrane. Immunological reaction and tumor formation were prevented and functional effects were observed histologically, chemically and behaviorally. Current issues regarding encapsulated cell grafting are: delivery of neurotransmitter and neurotrophic factor simultaneously from one capsule, usage of human-derived cell lines and control of secretion from outside. There are two possible approaches regarding the usage of patient's own neural stem cells for regenerative therapy. Neural stem cells are collected from the subventricular zone of the lateral ventricle and these cells are differentiated into dopaminergic neurons using tyrosine hydroxylase induction cocktail (TH cocktail). Then, these neurons are grafted into the striatum of the patient. Another method is to inject TH cocktail into the patient's striatum in order to induce differentiation of dopaminergic neurons from the neural stem cells in vivo.     

Transplantation of rat neural stem cells reduces stereotypic behaviors in rats after intrastriatal microinfusion of Tourette syndrome sera

Tourette syndrome (TS) is a heterogenous neuropsychiatric disorder. In most cases, tics are self-limited or can be treated by behavioral or pharmacological therapy. However, for some individuals, tics can cause lifelong impairment and life-threatening symptoms, which are intractable to traditional treatment. Neural stem cell (NSC) is a potential tool to treat certain neurological diseases. In this study, we proposed to use neural stem cell transplantation as a novel therapy to treat TS and discussed its efficacy. Wistar rats were microinfused with TS sera into the striatum followed by the transplantation of NSCs or vehicle at the infusion site. The sera of the TS patients were identified to have enriched antineural antibodies. Prior to grafting, rat embryonic NSCs were co-cultured with 5-bromodeoxyuridine (Brdu) for 24 h. Stereotypic behaviors were counted at 1, 7, 14 and 21 days after transplantation of NSCs. Morphological analyses revealed that NSCs survived and differentiated into neurons and astrocytes in the striatum 3 weeks after grafting. To sum it up, rat embryonic neural stem cell grafts survived and differentiated in the striatum of TS rat may help relieve stereotypic behaviors of the host. Our results suggest that transplantation of NSCs intrastriatum may have therapeutic potential for TS.     

AAV2-mediated gene transfer of GDNF to the striatum of MPTP monkeys enhances the survival and outgrowth of co-implanted fetal dopamine neurons

Neural transplantation offers the potential of treating Parkinson's disease by grafting fetal dopamine neurons to depleted regions of the brain. However, clinical studies of neural grafting in Parkinson's disease have produced only modest improvements. One of the main reasons for this is the low survival rate of transplanted neurons. The inadequate supply of critical neurotrophic factors in the adult brain is likely to be a major cause of early cell death and restricted outgrowth of fetal grafts placed into the mature striatum. Glial derived neurotrophic factor (GDNF) is a potent neurotrophic factor that is crucial to the survival, outgrowth and maintenance of dopamine neurons, and so is a candidate for protecting grafted fetal dopamine neurons in the adult brain. We found that implantation of adeno-associated virus type 2 encoding GDNF (AAV2-GDNF) in the normal monkey caudate nucleus induced overexpression of GDNF that persisted for at least 6 months after injection. In a 6-month within-animal controlled study, AAV2-GDNF enhanced the survival of fetal dopamine neurons by 4-fold, and increased the outgrowth of grafted fetal dopamine neurons by almost 3-fold in the caudate nucleus of MPTP-treated monkeys, compared with control grafts in the other caudate nucleus. Thus, the addition of GDNF gene therapy to neural transplantation may be a useful strategy to improve treatment for Parkinson's disease.     

Long-term survival and integration of porcine expanded neural precursor cell grafts in a rat model of Parkinson's disease

Porcine fetal neural tissue has been considered as an alternative source to human allografts for transplantation in neurodegenerative disorders by virtue of the fact that it can overcome the ethical and practical difficulties using human fetal neural tissue. However, primary porcine neural xenografts are rejected while porcine expanded neural precursor neural cells (PNPCs) seem to be less immunogenic and thus survive better [Armstrong, R.J., Harrower, T.P., Hurelbrink, C.B., McLaughin, M., Ratcliffe, E.L., Tyers, P., Richards, A., Dunnett, S.B., Rosser, A.E., Barker, R.A., 2001a. Porcine neural xenografts in the immunocompetent rat: immune response following grafting of expanded neural precursor cells. Neuroscience 106, 201-216]. In this study, we extended these observations to investigate the long-term survival of such transplants in immunosuppressed rats. Unilateral 6 OHDA lesioned rats received grafts into the dopamine denervated striatum of either primary porcine fetal neural tissue dissected from the E26 cortex or cortically derived neural stem cells which had been derived from the same source but expanded in vitro for 21 days. All cortically derived neural stem cell grafts survived up to 5 months in contrast to the poor survival of primary porcine xenografts. Histological analysis demonstrated good graft integration with fibers extending into the surrounding host tissue including white matter with synapse formation, and in addition there was evidence of host vascularization and myelinated fibers within the graft area. This study has therefore shown for the first time the reliable long-term survival of grafts derived from porcine expanded neural precursors in a rat model of PD, with maturation and integration into the host brain. This demonstrates that such xenografted cells may be able to recreate the damaged circuitry in PD although strategies for dopaminergic differentiation of the porcine neural precursor cell remain to be refined.     

Pretreatment of donor cells with FGF-2 enhances survival of fetal hippocampal CA3 cell transplants in the chronically lesioned young adult hippocampus

The lesioned CA3 region of the young adult hippocampus is very conducive for robust survival and integration of fetal hippocampal CA3 cell grafts when transplanted at an early postlesion delay of 4 days. However, similar CA3 cell grafts placed at 45 days postlesion display significantly diminished cell survival, implying that the receptivity of the lesioned young adult host hippocampus to grafts decreases considerably with a prolonged postlesion transplantation delay. We hypothesize that decreased cell survival in grafts placed into the chronically lesioned hippocampus is due to a reduced level of host neurotrophic factors that support fetal hippocampal cells; hence, pretreatment and grafting of donor fetal CA3 cells with fibroblast growth factor-2 (FGF-2) considerably enhances graft neuronal integration into the chronically lesioned young adult hippocampus. We employed the optical fractionator cell counting method and rigorously quantified the number of surviving cells and neurons derived from 5'-bromodeoxyuridine-labeled Embryonic Day 19 CA3 cell grafts pretreated and transplanted with FGF-2 into the lesioned CA3 region of the young adult rat hippocampus, at a delay of 60 days after a unilateral intracerebroventricular administration of the kainic acid. For comparison, we also analyzed the survival of standard fetal CA3 cell grafts (i.e., without FGF-2 treatment) after similar transplantation. Pre treatment and transplantation of CA3 cell grafts with FGF-2 resulted in a robust yield of surviving cells (115% of injected cells) and neurons (100% of injected cells) from grafts. In contrast, standard CA3 cell grafts exhibited a reduced yield of surviving cells (29%) and neurons (25%). Thus, the yield of neurons from fetal hippocampal CA3 cell grafts placed into the chronically lesioned young adult hippocampus can be greatly enhanced by a simple pretreatment and grafting of donor fetal CA3 cells with FGF-2. These results have significance toward advancement of clinically feasible cell grafting strategies for repair of the damaged young adult hippocampus, particularly at extended periods after the injury or the onset of neurodegenerative diseases.     

Distinct efficacy of pre-differentiated versus intact fetal mesencephalon-derived human neural progenitor cells in alleviating rat model of Parkinson’s disease

Neural progenitor cells have shown the effectiveness in the treatment of Parkinson's disease, but the therapeutic efficacy remains variable. One of important factors that determine the efficacy is the necessity of pre-differentiation of progenitor cells into dopaminergic neurons before transplantation. This study therefore investigated the therapeutic efficacy of mesencephalon-derived human neural progenitor cells with or without the pre-differentiation in alleviating a rat model of Parkinson's disease. We found that a combination of 50 ng/ml fibroblast growth factor 8, 10 ng/ml glial cell line-derived neurotrophic factor and 10 microM forskolin facilitated the differentiation of human fetal mesencephalic progenitor cells into dopaminergic neurons in vitro. More importantly, after transplanted into the striatum of parkinsonian rats, only pre-differentiated grafts resulted in an elevated production of dopamine in the transplanted site and the amelioration of behavioral impairments of the parkinsonian rats. Unlike pre-differentiated progenitors, grafted intact progenitors rarely differentiated into dopaminergic neurons in vivo and emigrated actively away from the transplanted site. These data demonstrates the importance of pre-differentiation of human progenitor cells before transplantation in enhancing therapeutic potency for Parkinson's disease.     

Differentiation of embryonic versus adult rat neural stem cells into dopaminergic neurons in vitro

BACKGROUND:It has been reported that the conversion of neural stem cells into dopaminergic neurons in vitro can be increased through specific cytokine combinations. Such neural stem cell-derived dopaminergic neurons could be used for the treatment of Parkinson’s disease. However, little is known about the differences in dopaminergic differentiation between neural stem cells derived from adult and embryonic rats. OBJECTIVE: To study the ability of rat adult and embryonic-derived neural stem cells to differen...