Transplantation of primed human fetal neural stem cells improves cognitive function in rats after traumatic brain injury

Traumatic brain injury (TBI) often produces cognitive impairments by primary or secondary neuronal loss. Stem cells are a potential tool to treat TBI. However, most previous studies using rodent stem or progenitor cells failed to correlate cell grafting and cognitive improvement. Furthermore, the efficacy of fetal human neural stem cells (hNSCs) for ameliorating TBI cognitive dysfunction is undetermined. This study therefore characterized phenotypic differentiation, neurotrophic factor expression and release and functional outcome of grafting hNSCs into TBI rat brains. Adult Sprague-Dawley rats underwent a moderate parasagittal fluid percussion TBI followed by ipsilateral hippocampal transplantation of hNSCs or vehicle 1 day post-injury. Prior to grafting, hNSCs were treated in vitro for 7 days with our previously developed priming procedure. Significant spatial learning and memory improvements were detected by the Morris water maze (MWM) test in rats 10 days after receiving hNSC grafts. Morphological analyses revealed that hNSCs survived and differentiated mainly into neurons in the injured hippocampus at 2 weeks after grafting. Furthermore, hNSCs expressed and released glial-cell-line-derived neurotrophic factor (GDNF) in vitro and when grafted in vivo, as detected by RT-PCR, immunostaining, microdialysis and ELISA. This is the first direct demonstration of the release of a neurotrophic factor in conjunction with stem cell grafting. In conclusion, human fetal neural stem cell grafts improved cognitive function of rats with acute TBI. Grafted cells survived and differentiated into neurons and expressed and released GNDF in vivo, which may help protect host cells from secondary damage and aid host regeneration.     

Differentiation of endogenous neural precursors following spinal cord injury in adult rats☆

BACKGROUND： Studies have shown that cell death can activate proliferation of endogenous neural stem cells and promote newly generated cells to migrate to a lesion site.
OBJECTIVE： To observe regeneration and differentiation of neural cells following spinal cord injury in adult rats and to quantitatively analyze the newly differentiated cells.
DESIGN, TIME AND SETTING： A cell biology experiment was performed at the Institute of Orthopedics and Medical Experimental Center, Lanzhou University, between August 2005 and October 2007.
MATERIALS： Fifty adult, Wistar rats of both sexes; 5-bromodeoxyuridine （BrdU, Sigma, USA）; antibodies against neuron-specific enolase, glial fibrillary acidic protein, and myelin basic protein （Chemicon, USA）.
METHODS： Twenty-five rats were assigned to the spinal cord injury group and received a spinal cord contusion injury. Materials were obtained at day 1, 3, 7, 15, and 29 after injury, with 5 rats for each time point. Twenty-five rats were sham-treated by removing the lamina of the vertebral arch without performing a contusion.
MAIN OUTCOME MEASURES： The phenotype of BrdU-labeled cells, i.e., expression and distribution of surface markers for neurons （neuron-specific enolase）, astrocytes （glial fibrillary acidic protein）, and oligodendrocytes （myelin basic protein）, were identified with immunofluorescence double-labeling. Confocal microscopy was used to detect double-labeled cells by immunofluorescence. Quantitative analysis of newly generated cells was performed with stereological counting methods.
RESULTS： There was significant cell production and differentiation after adult rat spinal cord injury. The quantity of newly-generated BrdU-labeled cells in the spinal cord lesion was 75-fold greater than in the corresponding area of control animals. Endogenous neural precursor cells differentiated into astrocytes and oligodendrocytes, however spontaneous neuronal differentiation was not detected. Between 7 and 29 d after spinal cord injury, newl     

Differentiation of endogenous neural precursors following spinal cord injury in adult rats

BACKGROUND:Studies have shown that cell death can activate proliferation of endogenous neural stem cells and promote newly generated cells to migrate to a lesion site.OBJECTIVE:To observe regeneration and differentiation of neural cells following spinal cord injury in adult rats and to quantitatively analyze the newly differentiated cells.DESIGN,TIME AND SETTING:A cell biology experiment was performed at the Institute of Orthopedics and Medical Experimental Center,Lanzhou University.between August 2005 and October 2007.MATERIALS:Fifty adult,Wistar rats of both sexes;5-bromodeoxyuridine(BrdU,Sigma,USA);antibodies against neuron-specific enolase,glial fibrillary acidic protein,and myelin basic protein(Chemicon,USA).METHODS:Twenty-five rats were assigned to the spinal cord injury group and received a spinal cord contusion injury.Materials were obtained at day 1,3,7,15,and 29 after injury,with 5 rats for each time point.Twenty-five rats were sham-treated by removing the lamina of the vertebral arch without performing a contusion.MAIN OUTCOME MEASURES:The phenotype of BrdU-labeled cells,i.e.,expression and distribution of surface markers for neurons(neuron-specific enolase),astrocytes(glial fibrillary acidic protein),and oligodendrocytes(myelin basic protein),were identified with immunofluorescence double-labeling.Confocal microscopy was used to detect double-labeled cells by immunofluorescence.Quantitative analysis of newly generated cells was performed with stereological counting methods.RESULTS:There was significant cell production and differentiation after adult rat spinal cord injury.The quantity of newly-generated BrdU-labeled cells in the spinal cord lesion was 75-fold greater than in the corresponding area of control animals.Endogenous neural precursor cells differentiated into astrocytes and oligodendrocytes,however spontaneous neuronal difierentiation was not detected.Between 7 and 29 d after spinal cord injury,newly generated cells expressed increasingly more mature oligodendrocyte and astrocyte markers.CONCLUSION:Spinal cord injury is a direct inducer of regeneration and differentiation of neural cells.Endogenous neural precursor cells Can difierentiate into astrocytes and oligodendrocytes following adult rat spinal cord injury.     

Lineage-restricted neural precursors survive, migrate, and differentiate following transplantation into the injured adult spinal cord

Fetal spinal cord from embryonic day 14 (E14/FSC) has been used for numerous transplantation studies of injured spinal cord. E14/FSC consists primarily of neuronal (NRP)- and glial (GRP)-restricted precursors. Therefore, we reasoned that comparing the fate of E14/FSC with defined populations of lineage-restricted precursors will test the in vivo properties of these precursors in CNS and allow us to define the sequence of events following their grafting into the injured spinal cord. Using tissue derived from transgenic rats expressing the alkaline phosphatase (AP) marker, we found that E14/FSC exhibited early cell loss at 4 days following acute transplantation into a partial hemisection injury, but the surviving cells expanded to fill the entire injury cavity by 3 weeks. E14/FSC grafts integrated into host tissue, differentiated into neurons, astrocytes, and oligodendrocytes, and demonstrated variability in process extension and migration out of the transplant site. Under similar grafting conditions, defined NRP/GRP cells showed excellent survival, consistent migration out of the injury site and robust differentiation into mature CNS phenotypes, including many neurons. Few immature cells remained at 3 weeks in either grafts. These results suggest that by combining neuronal and glial restricted precursors, it is possible to generate a microenvironmental niche where emerging glial cells, derived from GRPs, support survival and neuronal differentiation of NRPs within the non-neurogenic and non-permissive injured adult spinal cord, even when grafted into acute injury. Furthermore, the NRP/GRP grafts have practical advantages over fetal transplants, making them attractive candidates for neural cell replacement.     

Pluripotent stem cells engrafted into the normal or lesioned adult rat spinal cord are restricted to a glial lineage

Proliferating populations of undifferentiated neural stem cells were isolated from the embryonic day 14 rat cerebral cortex or the adult rat subventricular zone. These cells were pluripotent through multiple passages, retaining the ability to differentiate in vitro into neurons, astrocytes, and oligodendrocytes. Two weeks to 2 months after engraftment of undifferentiated, BrdU-labeled stem cells into the normal adult spinal cord, large numbers of surviving cells were seen. The majority of the cells differentiated with astrocytic phenotype, although some oligodendrocytes and undifferentiated, nestin-positive cells were detected; NeuN-positive neurons were not seen. Labeled cells were also engrafted into the contused adult rat spinal cord (moderate NYU Impactor injury), either into the lesion cavity or into the white or gray matter both rostral and caudal to the injury epicenter. Up to 2 months postgrafting, the majority of cells either differentiated into GFAP-positive astrocytes or remained nestin positive. No BrdU-positive neurons or oligodendrocytes were observed. These results show robust survival of engrafted stem cells, but a differentiated phenotype restricted to glial lineages. We suggest that in vitro induction prior to transplantation will be necessary for these cells to differentiate into neurons or large numbers of oligodendrocytes.     

Epidermal neural crest stem cells and their use in mouse models of spinal cord injury

Epidermal neural crest stem cell (EPI-NCSC) grafts cause a significant improvement in sensory connectivity and touch perception in the contused mouse spinal cord. EPI-NCSC are derived from the embryonic neural crest but reside in a postnatal location, the bulge of hair follicles. Both mouse and human EPI-NCSC are multipotent adult stem cells capable of generating all major neural crest derivatives. EPI-NCSC of mouse and human origin express the neural crest stem cell molecular signature, genes that were initially used to create induced pluripotent stem (iPS) cells, and other neural crest and global stem cell genes. Due to their origin in the neural folds and because they share a higher order stem cell, neural crest cells, and thus EPI-NCSC, are closely related to neural tube stem cells. This close ontological relationship with the spinal cord makes EPI-NCSC attractive candidates for cell-based therapy in spinal cord injury. In two different contusion models of spinal cord injury, we have shown that EPI-NCSC integrate into the murine spinal cord tissue and that subsets differentiate into GABAergic neurons and myelinating oligodendrocytes. Intraspinal EPI-NCSC do not form tumours. In the presence of EPI-NCSC grafts, but not in control animals, there is a 24% improvement of sensory connectivity and a substantial improvement in touch perception. Unilateral transplants leading to bilateral functional improvements suggest that underlying mechanisms include diffusible molecules. EPI-NCSC indeed express genes that encode neurotrophins, other trophic factors, angiogenic factors and metalloproteases. Intraspinal EPI-NCSC thus have multiple effects in the contused spinal cord, the sum of which can explain the observed functional improvements.     

Transplantation of neural stem cells for spinal cord injury]

Neural progenitor cells, including neural stem cells (NSCs), are an important potential graft material for cell therapeutics of damaged spinal cord. Here we used as a source of graft material a NSC-enriched population derived from human fetal spinal cord (Embryonic week 8-9) and expanded in vitro by neurosphere formation. NSCs labeled with BrdU (TP) or culture medium (CON) were transplanted into the adult marmoset spinal cord after contusion injury at C5 level. Grafted NSCs survived and migrated up to 7 mm far from the lesion epicenter. Double-staining with TuJ1 for neuron, GFAP for astrocyte, or CNPase for oligodendrocyte and BrdU revealed that grafted NSCs differentiated into neurons and oligodendrocytes 8 weeks after transplantation. More neurofilaments were observed in TP than those of CON. Furthermore, behavioral assessment of forelimb muscle strength using bar grip test and amount of spontaneous motor activity using infrared-rays monitoring revealed that the grafted NSCs significantly increased both of them compared to those of CON. These results indicate that in vitro expanded NSCs derived from human fetal spinal cord are useful sources for the therapeutics of spinal cord injury in primates.     

Induced pluripotent stem cell-derived neural stem cell therapies for spinal cord injury

The greatest challenge to successful treatment of spinal cord injury is the limited regenerative capacity of the central nervous system and its inability to replace lost neurons and severed axons following injury. Neural stem cell grafts derived from fetal central nervous system tissue or embryonic stem cells have shown therapeutic promise by differentiation into neurons and glia that have the potential to form functional neuronal relays across injured spinal cord segments. However, implementation of fetal-derived or embryonic stem cell-derived neural stem cell therapies for patients with spinal cord injury raises ethical concerns. Induced pluripotent stem cells can be generated from adult somatic cells and differentiated into neural stem cells suitable for therapeutic use, thereby providing an ethical source of implantable cells that can be made in an autologous fashion to avoid problems of immune rejection. This review discusses the therapeutic potential of human induced pluripotent stem cell-derived neural stem cell transplantation for treatment of spinal cord injury, as well as addressing potential mechanisms, future perspectives and challenges.     

Treatment of spinal cord injury by transplantation of fetal neural precursor cells engineered to express BMP inhibitor

Spontaneous recovery after spinal cord injury is limited. Transplantation of neural precursor cells (NPCs) into lesioned adult rat spinal cord results in only partial functional recovery, and most transplanted cells tend to differentiate predominantly into astrocytes. In order to improve functional recovery after transplantation, it is important that transplanted neural precursor cells appropriately differentiate into cell lineages required for spinal cord regeneration. In order to modulate the fate of transplanted cells, we advocate transplanting gene-modified neural precursor cells. We demonstrate that gene modification to inhibit bone morphogenetic protein (BMP) signaling by noggin expression promoted differentiation of neural precursor cells into neurons and oligodendrocytes, in addition to astrocytes after transplantation. Furthermore, functional recovery of the recipient mice with spinal cord injury was observed when noggin-expressing neural precursor cells were transplanted. These observations suggest that gene-modified neural precursor cells that express molecules involved in cell fate modulation could improve central nervous system (CNS) regeneration.     

Bone morphogenetic proteins mediate cellular response and, together with Noggin, regulate astrocyte differentiation after spinal cord injury

Bone morphogenetic proteins (BMPs) play a critical role in regulating cell fate determination during central nervous system (CNS) development. In light of recent findings that BMP-2/4/7 expressions are upregulated after spinal cord injury, we hypothesized that the BMP signaling pathway is important in regulating cellular composition in the injured spinal cord. We found that BMP expressions were upregulated in neural stem cells (NSCs), neurons, oligodendrocytes and microglia/macrophages. Increased expression levels of pSmad1/5/8 (downstream molecules of BMP) were detected in neurons, NSCs, astrocytes, oligodendrocytes and oligodendroglial progenitor cells (OPCs). Active astrocytes which form the astroglial scar were probably derived from NSCs, OPCs and resident astrocytes. Since quiescent NSCs in the normal adult spinal cord will proliferate and differentiate actively into neural cells after traumatic injury, we proposed that BMPs can regulate cellular components by controlling NSC differentiation. Neurosphere culture from adult mouse spinal cord showed that BMP-4 promoted astrocyte differentiation from NSCs while suppressing production of neurons and oligodendrocytes. Conversely, inhibition of BMP-4 by Noggin notably decreased the ratio of astrocyte to neuron numbers. However, intrathecal administration of Noggin in the injured spinal cord failed to attenuate glial fibrillar acidic protein (GFAP) expression even though it effectively reduced pSmad expression. Noggin treatment did not block phosphorylation of Stat3 and the induction of GFAP in the injured spinal cord, suggesting that in addition to the BMP/Smad pathway, the JAK/STAT pathway may also be involved in the regulation of GFAP expression after spinal cord injury.     

甲基强的松龙和神经干细胞移植联合治疗大鼠脊髓损伤

目的：观察甲基强的松龙和神经干细胞移植对大鼠脊髓损伤后神经结构修复和功能恢复的治疗作用并探讨其作用机制。方法：制备大鼠胸10脊髓损伤模型，体外培养、诱导分化大鼠神经干细胞，定量评价甲基强的松龙和神经干细胞移植对脊髓损伤后神经结构修复和功能恢复的影响。结果：与对照组相比，移植组明显地增强了生长相关蛋白（GAP－43）mRNA的表达，促进了乙酰胆碱转移酶（ChAT)阳性脊髓运动神经元的再生、神经结构的修复和下肢运动功能的恢复（P＜0．05）。结论：甲基强的松龙和神经干细胞移植通过增强GAP－43 mRNA的表达、运动神经元的再生而促进了脊髓损伤后神经结构的修复和功能的恢复，是急性脊髓损伤的一种有效的治疗方案。     

Characteristics of Human Fetal Spinal Cord Grafts in the Adult Rat Spinal Cord: Influences of Lesion and Grafting Conditions

The present study evaluated the growth potential and differentiation of human fetal spinal cord (FSC) tissue in the injured adult rat spinal cord under different lesion and grafting conditions. Donor tissue at 6–9 weeks of gestational age was obtained through elective abortions and transplanted either immediately into acute resection (solid grafts) or into chronic contusion (suspension and solid grafts) lesions (i.e., 14–40 days after injury) in the thoracic spinal cord. The xenografts were then examined either histologically in plastic sections or immunocytochemically 1–3 months postgrafting. Intraspinal grafts in acute lesions demonstrated an 83% survival rate and developed as well-circumscribed nodules that were predominantly composed of immature astrocytes. Solid-piece grafts in chronic contusion lesions exhibited a 92% survival rate and also developed as nodular masses. These grafts, however, contained many immature neurons 2 months postgrafting. Suspension grafts in chronic contusion lesions had an 85% survival rate and expanded in a nonrestrictive, diffuse pattern. These transplants demonstrated large neuronally rich areas of neural parenchyma. Extensive neuritic outgrowth could also be seen extending from these grafts into the surrounding host spinal cord. These findings show that human FSC tissue reliably survives and differentiates in both acute and chronic lesions. However, both the lesion environment and the grafting techniques can greatly influence the pattern of differentiation and degree of host–graft integration achieved.     

Immunohistochemical and electron microscopic study of invasion and differentiation in spinal cord lesion of neural stem cells grafted through cerebrospinal fluid in rat

Neurospheres were obtained by culturing hippocampal cells from transgenic rat fetuses (E16) expressing green fluorescent protein (GFP). The neurosphere cells were injected into the cerebrospinal fluid (CSF) through the 4th ventricle of young rats (4 weeks old) that had been given a contusion injury at T8-9 of the spinal cord. The injected neural stem cells were transported through the CSF to the spinal cord, attached to the pial surface at the lesion, and invaded extensively into the spinal cord tissue as well as into the nerve roots. The grafted stem cells survived well in the host spinal cord for as long as 8 months after transplantation. Immunohistochemical study showed that many grafted stem cells had differentiated into astrocytes at 1-4 months, and some into oligodendrocytes at 8 months postoperatively. Immunoelectron microscopy showed that the grafted stem cells were well integrated into the host tissue, extending their processes around nerve fibers in the same manner as astrocytes. In addition, grafted stem cells within nerve roots closely surrounded myelinated fibers or were integrated into unmyelinated fiber bundles; those associated with myelinated fibers formed basal laminae on their free surface, whereas those associated with unmyelinated fibers were directly attached to axons and Schwann cells, indicating that grafted stem cells behaved like Schwann cells in the nerve roots.     

Transplantation of in vitro-expanded fetal neural progenitor cells results in neurogenesis and functional recovery after spinal cord contusion injury in adult rats

Neural progenitor cells, including neural stem cells, are a potential expandable source of graft material for transplantation aimed at repairing the damaged CNS. Here we present the first evidence that in vitro-expanded fetus-derived neurosphere cells were able to generate neurons in vivo and improve motor function upon transplantation into an adult rat spinal-cord-contusion injury model. As the source of graft material, we used a neural stem cell-enriched population that was derived from rat embryonic spinal cord (E14.5) and expanded in vitro by neurosphere formation. Nine days after contusion injury, these neurosphere cells were transplanted into adult rat spinal cord at the injury site. Histological analysis 5 weeks after the transplantation showed that mitotic neurogenesis occurred from the transplanted donor progenitor cells within the adult rat spinal cord, a nonneurogenic region; that these donor-derived neurons extended their processes into the host tissues; and that the neurites formed synaptic structures. Furthermore, analysis of motor behavior using a skilled reaching task indicated that the treated rats showed functional recovery. These results indicate that in vitro-expanded neurosphere cells derived from the fetal spinal cord are a potential source for transplantable material for treatment of spinal cord injury.     

Lavendustin A enhances axon elongation in VHL gene-transfected neural stem cells

Axonal elongation is necessary for neuronal regeneration of the spinal cord after spinal injury. Recently neural stem cells have been proposed as hopeful graft donors for regeneration of the central nervous system. However, most grafted stem cells are not able to differentiate into neurons, and grafted stem cells cannot usually grow axons. Here, we show the effect of the protein tyrosine kinase inhibitor lavendustin A on axonal growth of neurons differentiated from neural stem cells obtained from adult rat hippocampal cells transfected with the von Hippel-Lindau (VHL) gene. Significantly greater axonal outgrowth was observed for the transfected cells treated with the inhibitor than for those not so treated. Thus, protein-tyrosine kinase inhibition is effective for axonal outgrowth of neurons differentiated from neural stem cells and may prove to be useful for neuronal regeneration via transplanted stem cells, particularly in the case of spinal cord injuries.     

神经干细胞移植修复鼠脊髓损伤的实验研究

目的 :观察神经干细胞移植治疗对鼠脊髓损伤后神经结构修复和功能恢复的作用并探讨其作用机制。方法 :制备鼠T10 脊髓损伤模型 ,体外培养、诱导鼠神经干细胞 ,定量评价神经干细胞移植对脊髓损伤后神经结构修复和功能恢复的影响。结果 :与对照组相比 ,神经干细胞移植组明显的增强了GAP 43mRNA的表达 ,促进了脊髓ChAT阳性的运动神经元的再生、结构的修复和下肢运动功能的恢复。结论 :神经干细胞移植促进了脊髓损伤后神经结构的修复和功能的恢复 ,是急性脊髓损伤一种有效的治疗方案     

大鼠脊髓损伤后PLGA支架细胞髓内移植的组织学观察

目的 观察神经干细胞(NSC)、许旺细胞(SCs)和组织工程材料乙交酯-丙交酯共聚物(PLGA)大鼠髓内共移植后的病理形态学改变.方法 36只Wistar大鼠,随机分为PLGA移植组、NSC/PLGA组和NSC+SCs/PLGA组.体外培养、鉴定胚胎脊髓源NSC和SCs,制备和构建PLGA支架细胞复合体并移植到大鼠脊髓Tq半横断损伤部位,应用HE染色、电镜和免疫组织化学染色方法在形态结构上观察材料的组织相容性、轴突髓鞘再生及NSC在脊髓内的存活、迁移和分化情况.结果 HE染色观察损伤12周时移植材料内可见细胞生长及新生的毛细血管;扫描电镜观察随着时间的延长,PLGA逐渐降解;材料正中横断面透射电镜观察可见新牛的无髓及有髓神经纤维;脊髓标本免疫组织化学染色可见移植的NSC可以在宿主脊髓内存活、迁移并分化成类神经元样细胞和少枝胶质细胞,未分化成星形胶质细胞.结论 NSC、SCs和PLGA共移植可以在形态学上促进大鼠脊髓半横断损伤的修复.     

大鼠脊髓源性神经干细胞的培养分化及其特异性研究

目的 研究大鼠脊髓源性神经干细胞培养和分化的特异性。方法 从孕17d的SD大鼠胚胎脊髓中分离，培养神经干细胞并用血清诱导其分化，通过免疫荧光化学方法研究其特性。结果 在血清的诱导下，脊髓源性神经干细胞大多数分化成GFAP阳性的星形胶质细胞，少数分化为tubulin-β阳性的神经细胞；与脑源性神经干细胞分化的神经细胞相比较，其分化出的神经细胞的突起长度明显延长。结论 脊髓源性神经干细胞在体外具有多向分化潜能，但与脑源性神经干细胞有明显差别。     

神经干细胞生存因子在大鼠脊髓损伤前后的表达变化

目的观察大鼠脊髓损伤后干细胞来源的神经干细胞生存因子（SDNSF）mRNA在大鼠正常和损伤脊髓的农达变化,以及SDNSF的表达与Ⅵ类中间丝蛋白的表达之间的关系。方法按改良的Allen重物打击法制备大鼠脊髓损伤模型,采用RT—PCR、原位杂交方法,观察SDNSF mRNA在大鼠脊髓中的表达位置及在损伤脊髓中的表达变化。应用免疫组化的方法,显示脊髓中nestin的表达。结果RT-PCR检测SDNSF mRNA在正常大鼠脊髓中的表达,损伤后4天SDNSF的mRNA表达上升,损伤8天剑达高峰,此后SDNSF的mRNA表达逐渐减少,到16天恢复到正常水平;脊髓切片原位杂交结果发现SDNSF的mRNA阳性细胞主要分布十脊髓灰质细胞中,可能足神经元细胞,结果表明正常脊髓可表达SDNSF;脊髓损伤后8犬,原位杂交硅示SDNSF阳性细胞明显增多。同时与此切片相邻层面的切片免疫组化证实nestin阳性细胞增殖、变大、向周围发出突起,但这些阳性细胞在分布上与SDNSF无关。结论（1）SDNSF在脊髓中表达于灰质,脊髓损伤后SDNSF的mRNA表达随时间发生变化。（2）随着脊髓损伤的修复,nestin阳性细胞增殖,但是这些细胞并不表达SDNSF。