Impact of chemokines on the properties of spinal cord‐derived neural progenitor cells in a rat spinal cord lesion model

The existence of endogenous neural progenitor cells (NPCs) in the adult spinal cord (sc) provides the potential for tailored repair therapies after spinal cord injury (SCI). This study investigates the impact of inflammatory mediators on properties of NPC cultures derived from adult rats after SCI. The Infinite Horizon impactor was used to apply 200‐kdyn thoracic sc lesions in adult rats. Control groups received laminectomies to equivalent sc regions. Thoracic sc segments were taken for neurosphere cell cultures. Cell proliferation was found to be significantly higher in lesion groups. Neurosphere‐derived cells differentiated into neurons, oligodendroglia, and astroglia. Lesion cultures exhibited significantly higher amounts of glial fibrillary acidic protein (GFAP) mRNA (P < 0.0005) and β‐III‐tubulin mRNA (P < 0.05) compared with sham animals. Neurospheres from different treatment groups exhibited the same amounts of tumor necrosis factor‐α, interleukin (IL)−1β, and IL‐6 mRNA. C‐C chemokine receptor (CCR) expression on neurospheres was examined by real‐time RT‐PCR. CCR1 was expressed most consistently in mRNA levels in neurospheres from both treatment groups. After cell differentiation, CCR1 mRNA amounts decreased. CCR1 was detectable by immunohistochemistry in neurospheres and differentiated cells of both groups. Application of CCL3 during differentiation cycles led to significantly higher GFAP mRNA amounts in sham animals compared with CCL3‐free cultures; in contrast, CCL3 had no impact on cell differentiation in the lesion group. In conclusion, impact SCI alters differentiation tendencies and proliferation rates of adult‐derived sc NPCs. Thereby, CCR1/CCL3 promotes specifically astroglial differentiation of NPCs, which provides a potential target for future neurorestorative approaches. © 2014 Wiley Periodicals, Inc.     

Bone marrow stromal cells enhance differentiation of cocultured neurosphere cells and promote regeneration of injured spinal cord

Transplantation of bone marrow stromal cells (MSCs) has been regarded as a potential approach for promoting nerve regeneration. In the present study, we investigated the influence of MSCs on spinal cord neurosphere cells in vitro and on the regeneration of injured spinal cord in vivo by grafting. MSCs from adult rats were cocultured with fetal spinal cord-derived neurosphere cells by either cell mixing or making monolayered-feeder cultures. In the mixed cell cultures, neuroshpere cells were stimulated to develop extensive processes. In the monolayered-feeder cultures, numerous processes from neurosphere cells appeared to be attracted to MSCs. In an in vivo experiment, grafted MSCs promoted the regeneration of injured spinal cord by enhancing tissue repair of the lesion, leaving apparently smaller cavities than in controls. Although the number of grafted MSCs gradually decreased, some treated animals showed remarkable functional recovery. These results suggest that MSCs might have profound effects on the differentiation of neurosphere cells and be able to promote regeneration of the spinal cord by means of grafting.     

Isolation of neural stem cells from the forebrain of deceased early postnatal and adult rats with protracted post-mortem intervals

Neural stem cells were isolated from deceased early postnatal and adult rats with varying post-mortem intervals. Animals were killed by deep anesthesia and stored in a refrigerator at 4 degrees C for 1-6 days before use. Neurospheres were obtained from the forebrain tissue, including the lateral ventricle in the early postnatal rats, and from the striatal wall of lateral ventricle, including the subventricular zone (SVZ) in adult rats. The number of neurospheres obtained in the primary culture from early postnatal animals was much larger than that from the adult rats. There was no significant difference in the population of neurospheres between the living and the deceased animals at least within 2 days after death. A few neurospheres were still obtainable at 6 days after death in early postnatal animals, but almost no neurospheres were obtained at 5 days after death in the adult rats. The differentiation capacity of neural stem cells in neurospheres was similar between the deceased and the living animals. The rich vascular bed in the SVZ of the lateral ventricle suggests that the vascular architecture might be in part responsible for the survival of the neural stem cells in the deceased animals. Neurosphere cells derived from deceased adult rats survived and differentiated mainly into glial cells in the host spinal cord tissue after transplantation into the injured spinal cord. Therefore, the neural stem cells from deceased animals express the same phenotypes as those from living animals in terms of neurosphere formation, proliferation, and differentiation at least 2 days after death. The neural stem cells from cadavers have great significance in terms of their clinical use as homografts for CNS regeneration.     

The cellular fate of cortical progenitors is not maintained in neurosphere cultures

Neural progenitors of the mouse forebrain can be propagated in vitro as neurospheres in the presence of bFGF and EGF. However, less is understood whether regional characteristics or developmental stage properties of these cells are maintained in neurosphere cultures. Here we show that the original cell fate is lost in neurosphere cultures. We isolated neural progenitors from the dorsal telencephalon of D6-GFP mice and cultured them in vitro. The expression profile was specifically changed in cultured cells in just three passages. Markers of the dorsal forebrain were downregulated and several ventrally-expressed genes were induced. The altered gene expression led to a profound phenotypic change of cultured cells. D6-GFP positive cortical progenitors produce excitatory neurons in the cortex and few astrocytes in vivo but after culture in vitro, these cells differentiate into many astrocytes and also oligodendrocytes and inhibitory neurons. Wnt signaling in cultured neurospheres was downregulated in the same manner as other dorsal markers but dominant active Wnt signaling slowed down the loss of the dorsal identity in neurospheres.     

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.     

Neurosphere-derived neural cells show region-specific behaviour in vitro

Neurosphere cultures provide a useful model to study neural stem/progenitor cells (NSC/NPCs). The degree to which neurospheres (NS) retain their regional identity in vitro has, however, been questioned. Here, NS obtained from mouse embryonic cortex, striatum or spinal cord were compared after differentiation. Neurons from cortical NS formed well ordered clusters containing astrocytes, those from striatal NS formed an external ring at the borderof the astrocyte layer, whereas those from spinal cord NS spread radially like the astrocytes. Such in-vitro neural behaviour was region-specific and persisted in clonal conditions, providing evidence of the maintenance of positional cues in NS cultures.     

Multipotent Neurospheres Can Be Derived from Forebrain Subependymal Zone and Spinal Cord of Adult Mice after Protracted Postmortem Intervals

The adult mammalian CNS harbors a population of multipotent stem/progenitor cells that can be induced to grow as proliferative neurospheres in vitro. We demonstrate here that neurosphere-generating cells can be isolated from adult mouse spinal cord and forebrain subependymal zone after postmortem intervals of up to 140 h, when kept at 4 degrees C, and up to 30 h when kept at room temperature. Although there was an inverse relationship between postmortem interval and the number of neurospheres generated, neurospheres derived under these conditions were proliferative and could give rise to both neurons and glia.     

两种神经球制片方法的比较研究

目的 探讨两种神经球制片方法--贴片法和切片法的差异,并初探神经球内部的细胞结构.方法 分离培养新生小鼠端脑神经干细胞,收集原代或传代培养7 d的神经球用于制片;贴片法是将神经球整体贴于载玻片上,切片法是将神经球用OCT包埋,冷冻切片机切片;通过比较两种制片方法的巢蛋白(nestin)免疫荧光染色的差异说明两种制片方法的差异;用HE染色方法将神经球切片染色,进一步观察其内部结构.结果 成功分离培养的新生小鼠端脑神经干细胞在体外培养中形成神经球;贴片法制片神经球表面细胞染色良好,内部细胞不能着色,而且细胞形态显示不清晰,切片法制片神经球表面和内部细胞均能着色,细胞形态显示清晰:HE染色见神经球细胞之间借助突起相互连接,形成错综复杂的细胞网络.结论 切片法制片较贴片法制片更有利于神经球的形态学研究;神经球是一个复杂的立体的细胞生长模式.     

Dynamic behavior of cells within neurospheres in expanding populations of neural precursors

Large-scale expansion of neural stem and progenitor cells will be essential for clinically treating the large number of patients suffering from neurodegenerative disorders such as Parkinson's disease. Other applications of neural stem cell technology include further research in areas such as neural development or drug testing. Neural stem cells can be grown in vitro as tissue aggregates known as neurospheres, and in the current study, experiments were performed to determine the spatial arrangement and behavior of the cells within the neurosphere structure. A protocol utilizing sulfonated lipophilic fluorescent dyes was developed to effectively label populations of neural stem and progenitor cells without compromising cell density during culture. Cells retained the labels for at least 7 days. Using the labeling protocol, we discovered that the cells within the neurospheres were mobile and, moreover, the cells on the periphery of the neurospheres could migrate into the center of the neurospheres. Most important, the mixing time of two merging neurospheres was observed to be the same order of magnitude as the neural stem cell doubling time (approximately 20 h). This study is the first to show that the neurosphere system is dynamic, and these results will serve as a stepping stone to more in-depth studies of the neurosphere microenvironment.     

Chemokine receptor CXCR4 signaling modulates the growth factor-induced cell cycle of self-renewing and multipotent neural progenitor cells

CXC chemokine receptor CXCR4 is expressed in vitro in both human and rodent adult neural progenitor cells (NPCs). It has been suggested that the CXCL12-CXCR4 axis potentially enhances the proliferation of NPCs. However, whether CXCR4 is expressed in the neural stem cells (NSCs), a subset of self-renewing and multipotent NPCs, and whether CXCR4 signaling is directly required for their proliferation are not clear. In this study, we report that CXCR4 is expressed in a subpopulation of NPCs in the early embryonic ventricular zone. In studies of a CXCR4(eGFP) bacterial artificial chromosomal (BAC) transgenic mouse line, we further isolated NPCs from E12.5 transgenic telencephalon and GFP(+) cells demonstrated self-renewal and multipotency in neurosphere assays in vitro. Consistent with these observations, we enriched GFP(+)/CXCR4(+) cells by fluorescence activated cell sorting (FACS) with either CXCR4 antibody 12G5 or GFP. Furthermore, we observed that CXCL12 alone did not activate the self-renewal of NPCs or increase the proliferation of NPCs that are induced by bFGF/EGF. However, we found that blocking CXCR4 receptor with antagonist AMD3100 impaired the bFGF/EGF-induced expansion of GFP(+) NPCs through modulating their cell cycling. In addition, AMD3100 treatment of pregnant mice reduced the generation of neurospheres from E12.5 embryos. Our data suggest that CXCR4 is a potential cell surface marker for early embryonic NSCs and modulates growth-factor signaling.     

Lithium enhances proliferation and neuronal differentiation of neural progenitor cells in vitro and after transplantation into the adult rat spinal cord

Transplantation of neural progenitor cells (NPCs) holds great potential for the treatment of spinal cord injuries. The survival and differential fates of transplanted NPCs in the cord are key factors contributing to the success of the therapy. In this study, we investigate the effects of lithium, a widely used antidepressant drug, on the survival, proliferation and differentiation of spinal cord-derived NPCs in cultures and after transplantation into the spinal cord. Our results show that clinically relevant doses of lithium increase the proliferation of grafted NPCs at 2 weeks post-grafting and neuronal generation by grafted NPCs at 2 weeks and 4 weeks post-grafting. However, lithium does not cause preferential differentiation of NPCs into astrocytes or oligodendrocytes both in vitro and after transplantation. Our results also show that chronic treatment with lithium (up to 4 weeks) reduces microglia and macrophage activation, indicating that lithium treatment can affect the host immune response. The results of the present study provide evidence that lithium may have therapeutic potential in cell replacement strategies for CNS injury due to its ability to promote proliferation and neuronal generation of grafted NPCs and reduce the host immune reaction.     

Survival of neural precursor cells in growth factor-poor environment: implications for transplantation in chronic disease

A key issue for therapeutic neural stem cell transplantation in chronic diseases is the long-term survival of transplanted cells in the brain. The normal adult central nervous system does not support the survival of transplanted cells. Presumably, the limited availability of trophic factors maintains the survival of resident cells but is insufficient for supporting the survival of transplanted cells. Specifically, in multiple sclerosis, a chronic relapsing disease, it would be necessary to maintain long-term survival of transplanted cells through phases of relapses and remissions. It may be beneficial to transplant cells as early as possible, in a form that will keep their survival independent of tissue support and ready for immediate mobilization upon tissue demand during disease relapse. In the present study, we examined whether, in the form of neurospheres, multipotential neural precursor cells (NPCs) survive in a growth factor-poor environment while maintaining their potential to respond to environmental cues. We found that after removal of growth factors from the culture medium of neurospheres in vitro, NPC proliferation decreased significantly, but most cells survived for a prolonged time and maintained their stem cell characteristics. After re-exposure to growth factors, neurosphere cells resumed proliferation and could differentiate along neural lineages. Furthermore, neurospheres, but not single NPCs, that were transplanted into the brain ventricles of intact animals survived within the ventricles for at least a month and responded to induction of experimental autoimmune encephalomyelitis and brain inflammation by extensive migration into the brain white matter and differentiated into glial lineage cells.     

Transplantation of EGF-responsive neurospheres from GFP transgenic mice into the eyes of rd mice

The isolation of stem cells from various regions of the central nervous system has raised the possibility of using them as a donor cell source for cell transplantation, where they offer great promise for repair of the diseased brain, spinal cord, and retina. Here, we have studied the migration, integration, and differentiation of EGF-responsive neurospheres isolated from the brains of green fluorescent protein transgenic mice and transplanted into the eyes of mature rd mice, a model of retinitis pigmentosa. While grafts of freshly isolated postnatal day 8 retina expressed many markers characteristic of mature retina (e.g. rhodopsin, protein kinase C), very few of the grafted cells migrated into host retina. EGF-responsive neurospheres, conversely, readily migrated into and integrated with the remaining host retina, but showed a very limited ability to differentiate into mature retinal neurons. While the progenitor cells used here show remarkable ability to integrate with host retina and develop some attributes of retinal cells, the failure to fully differentiate into retinal cells suggests that they already express some level of terminal commitment that precludes using them to replace lost photoreceptors.     

Neuronal differentiation following transplantation of expanded mouse neurosphere cultures derived from different embryonic forebrain regions

In vitro, expanded neurospheres exhibit multipotent properties and can differentiate into neurons, astrocytes and oligodendrocytes. In vivo, cells from neurospheres derived from mouse fetal forebrain have previously been reported to predominantly differentiate into glial cells, and not into neurons. Here we isolated stem/progenitor cells from E13.5 lateral ganglionic eminence (LGE), medial ganglionic eminence (MGE) and cortical primordium, of a green fluorescent protein (GFP)-actin transgenic mouse. Free-floating neurospheres were expanded in the presence of epidermal growth factor (EGF) and basic fibroblast growth factor (bFGF) and implanted after five to six passages into the striatum, hippocampus and cortex of neonatal rats. Cell suspensions of primary LGE tissue were prepared and grafted in parallel. Grafted cells derived from the primary tissue displayed widespread incorporation into all regions, as visualized with the mouse-specific antibody M2, or mouse satellite DNA in situ hybridization, and differentiated into both neurons, astrocytes and oligodendrocytes. Grafts of neurosphere cells derived from the LGE, MGE and cortical primordium differentiated primarily into astrocytes, but contained low but significant numbers of GFP-immunoreactive neurons. Neurons derived from LGE neurospheres were of three types: cells with the morphology of medium-sized densely spiny projection neurons in the striatum; cells with interneuron-like morphologies in striatum, cortex and hippocampus; and cells integrating into SVZ and migrating along the RMS to the olfactory bulb. MGE- or cortical primordium-derived neurospheres differentiated into interneuron-like cells in both striatum and hippocampus. The results demonstrate the ability of in vitro expanded neural stem/progenitor cells to generate both neurons and glia after transplantation into neonatal recipients, and differentiate in a region-specific manner into mature neurons with morphological features characteristic for each target site.     

Transplantation of embryonic spinal cord-derived neurospheres support growth of supraspinal projections and functional recovery after spinal cord injury in the neonatal rat

Great interest exists in using cell replacement strategies to repair the damaged central nervous system. Previous studies have shown that grafting rat fetal spinal cord into neonate or adult animals after spinal cord injury leads to improved anatomic growth/plasticity and functional recovery. It is clear that fetal tissue transplants serve as a scaffold for host axon growth. In addition, embryonic Day 14 (E14) spinal cord tissue transplants are also a rich source of neural-restricted and glial-restricted progenitors. To evaluate the potential of E14 spinal cord progenitor cells, we used in vitro-expanded neurospheres derived from embryonic rat spinal cord and showed that these cells grafted into lesioned neonatal rat spinal cord can survive, migrate, and differentiate into neurons and oligodendrocytes, but rarely into astrocytes. Synapses and partially myelinated axons were detected within the transplant lesion area. Transplanted progenitor cells resulted in increased plasticity or regeneration of corticospinal and brainstem-spinal fibers as determined by anterograde and retrograde labeling. Furthermore, transplantation of these cells promoted functional recovery of locomotion and reflex responses. These data demonstrate that progenitor cells when transplanted into neonates can function in a similar capacity as transplants of solid fetal spinal cord tissue.     

Prospective characterization of neural stem cells by flow cytometry analysis using a combination of surface markers

Neural stem cells (NSCs) with self-renewal and multilineage differentiation properties can potentially repair degenerating or damaged neural tissue. Here, we have enriched NSCs from neurospheres, which make up a heterogeneous population, by fluorescence-activated cell sorting (FACS) with antibodies against syndecan-1, Notch-1, and integrin-beta1, which were chosen as candidates for hematopoietic cell-or somatic stem cell-markers. Antigen-positive cells readily initiated neurosphere formation, but cells lacking these markers did so less readily. Doubly positive cells expressing both syndecan-1 and Notch-1 underwent neurosphere formation more efficiently than did singly positive cells. The progeny of sorted cells could differentiate into neurons and glial cells both in vitro and in vivo. These antibodies were also useful for isolating cells from the murine embryonic day 14.5 brain that efficiently formed neurospheres. In contrast, there was no distinct difference in neurosphere formation efficiency between Hoechst 33342-stained side population cells and main population cells, although the former are known to have a stem cell phenotype in various tissues. These results indicate the usefulness of syndecan-1, Notch-1, and integrin-beta1 as NSC markers.     

人胎脑神经球及其构成细胞的成熟表型标志

目的 观察体外培养人胎脑神经干细胞球的形成，并鉴别球内是否有成熟的神经细胞存在，证实神经球的异质性。方法用添加表皮生长因子(EGF，20ng／mL)和成纤维细胞生长因子2(FGF2，10ng／mL)的无血清N2培养基，从人胎脑培养获得神经干细胞球，在倒置显微镜下观察其形成过程，用间接免疫荧光技术检测神经球的细胞表型标志神经丝（NF)、胶质纤维酸性蛋白(GFAP)、半乳糖脑苷脂(GalC)和巢蛋白(nestin)的表达，并计算出阳性细胞球的百分比。结果前6d，培养中形成大量的细胞集落，检测的细胞标志中，只有nestin ，其余标志均为阴性。培养至12d左右，细胞球的数量减少约1／3．球体的形态和大小也不相同。培养30d的神经球中，69．2％神经球为NF ，81．8％为GFAP ，100％为nestin ．未观察到GalC 。结论神经球有个成熟过程，神经球之间具有异质性,球内的细胞构成也具有异质性。     

Isolation of neural stem cells from the spinal cords of low temperature preserved abortuses

In the present study, we show that neural stem cells can be obtained from the spinal cords of low temperature preserved abortuses. Fourteen weeks old abortuses were stored in a refrigerator at 4 degrees C for 2 h, 6 h and 12 h before use. Neural stem cells were isolated from cervical cord, thoracic cord and lumbar/sacral cord separately and induced to differentiate with fetal bovine serum. Clonal culture was carried out to demonstrate that the isolated cells met the standard of stem cells. Fluorescent immunocytochemistry was used to examine the expression of neural stem cell marker (nestin), neuronal marker (MAP2), astrocyte marker (GFAP) and cholinergic marker (ChAT). The stem cells in different cultures were compared. As a result, neural stem cells were obtained from all the spinal cord segments with different postmortem intervals. The lumbar/sacral cord cultures gave rise to the most abundant primary neurospheres. When the preservation was prolonged to 12 h, the number of primary neurospheres decreased sharply. Neurospheres in all cultures showed nestin positive immunoreactivity and could yield astrocytes and neurons including cholinergic neurons in differential cultures. The clonal formation and phenotype capacity were similar in all cultures. In conclusion, spinal neural stem cells can be isolated from low temperature preserved abortuses and represent an alternative source for both experimentation and potential therapeutic uses.