In vitro growth, differentiation and biological characteristics of neural stem cells

OBJECTIVE： To summarize the biological characteristics of neural stem cells, and the separation, purification. differentiation and source of neural stem cells. DATA SOURCES ： An online search of Pubmed database was undertaken to identify English articles about the growth of neural stem cells in vitro published from January 2000 to October 2006 by using the keywords of ＂neural stem cells, bone marrow mesenchymal stem cells （BMSCs）, umbilical cord blood stem cells, embryonic stem cells （ESC）, separation methods, neural growth factor＂. And relevant articles published in IEEE/IEE Electronic Library （IEL） database, Springer Link database and Kluwer Online Journals were also searched, Chinese relevant articles published between January 2000 to October 2006 were searched with the same keywords in Chinese in Chinese journal full-text database. STUDY SELECTION ： The articles were primarily screened, and then the full-texts were searched. Inclusive criteria： （1） Articles relevant to the biological characteristics and classification of neural stem cells; （2） Articles about the source, separation and differentiation of the ESCs, BMSCs and umbilical cord blood stem cells. The repetitive studies and reviews were excluded. DATA EXTRACTION ： Thirty articles were selected from 203 relevant articles according to the inclusive criteria Articles were excluded because of repetition and reviews. DATA SYNTHESES ： Neural stem cells have the ability of self-renewing and high differentiation, and they are obtained from ESCs, nerve tissue, nerve system, BMSCs and umbilical cord blood stem cells. ESCs can be separated by means of mechanical dissociation is better than that of the trypsin digestion, BMSCs by density gradient centrifuge separation, hemolysis, whole-blood culture, etc., and umbilical cord blood stem ceils by Ficoil density gradient centrifugation, hydroxyethyl starch （HES） centrifugation sedimentation, etc. Neural growth factor （NGF） and other factors play an important role in the growth of NSCs, such as transforming growth factor （TGF） is an important player in repairing organs, NGF accelerates the process of growth, insulin-like growth factor serves importantly in the differentiation of stem cells into neuron-like cells. CONCLUSION ： As unipotent stem cells, NSCs have the abilities of self-renewal and potential of high differentiation. The method of mechanical dissociation is better than trypsin digestion in e separating ESCs. However, density gradient centrifuge separation is better than other methods in the separation of the BMSCs. NGF and other factors play an important role in the growth of NSCs.

Oral epithelial stem cells in tissue maintenance and disease: the first steps in a long journey

The identification and characterization of stem cells is a major focus of developmental biology and regenerative medicine.The advent of genetic inducible fate mapping techniques has made it possible to precisely label specific cell populations and to follow their progeny over time.When combined with advanced mathematical and statistical methods,stem cell division dynamics can be studied in new and exciting ways.Despite advances in a number of tissues,relatively little attention has been paid to stem cells in the oral epithelium.This review will focus on current knowledge about adult oral epithelial stem cells,paradigms in other epithelial stem cell systems that could facilitate new discoveries in this area and the potential roles of epithelial stem cells in oral disease.

Bridging the injured spinal cord with neural stem cells

Spinal cord injury （SCI） damages not only the gray matter neurons, but also the white matter axonal tracts that carry signals to and from the brain, re- suiting in permanent loss of function below injury. Neural stem cells （NSCs） have high therapeutic potential for reconstruction of the injured spinal cord since they can potentially fnrm neuronal relays to bridge functional con-nectivity between separated spinal cord segments. This requires host axonal regeneration into and connectivity with donor neurons, and axonal growth and connectivity of donor neurons to host central nervous system （CNS） circuitry. In this mini-review, we will discuss key studies that explore novel neuronal relay formation by grafting NSCs in models of SCI, with emphasis on long-distance axonal growth and connectivity of NSCs grafted into in-jured spinal cord.

Small regulators making big impacts:regulation of neural stem cells by small non-coding RNAs

Neurodegeneration and traumatic brain injuries are leading causes of disability and present an enormous disease burden both in terms of patient suffering and healthcare cost.Treatment of brain lesions remains as a major challenge in medicine largely because of the limited regenerative capacity of the adult brain.

Stem cells in the adult CNS revealed:examining their regulation by myelin basic protein

Neural stem cells（NSCs）are found along the entire neuraxis,through development and into adulthood and old age（Sachewsky et al.,2014;Xu et al.,2016）.There are two neurogenic niches in the adult CNS.One is the subgranular zone in the hippocampus and the other is found in the periventricular region throughout the extent of the neuraxis（Barnabé-Heider et al.,2010;Mirzadeh et al.,2010）.

Stem cells for treatment of cerebral ischemia

Three articles regarding the effects of gene-modified stem cell transplantation and the reinfocing effects of dl-3-butylphthalide on hematopoietic stem cell transplantation and endogenous stem cell mobilization in the treatment of cerebral ischemia were published in Neural Regeneration Research. We hope that our readers find these papers useful to their research.

Tuning of neocortical astrogenesis rates by Emx2 in neural stem cells

Generation of astrocytes within the murine developing cerebral cortex mainly takes place during the first postnatal week, after neuronogenesis and prior to the bulk of oligogenesis. This process involves a great variety of highly complex regulatory mechanisms. Astrocytic outputs depend on two primary factors： progressive commitment of multipotent precursors to astroglial fates and proper tuning of proliferation of astrocyte-committed progenitors. To date, several regulatory mechanisms have been identified for the former process, while very little is known about modulation of astroblast proliferation （reviewed in Mallamaci,

Lhx8基因沉默抑制NGF诱导的海马NSCs向胆碱能神经元分化的研究

目的:明确Lhx8在神经生长因子(nerve growth factors,NGF)促进海马神经干细胞向胆碱能神经元分化中的作用。方法:体外培养海马神经干细胞并应用NGF促进其向胆碱能神经元分化的过程中,将构建的Lhx8干扰慢病毒加入至培养液中,7 d后应用免疫荧光标记技术检测分化所得胆碱乙酰转移酶(choline acetyltransferase,Ch AT)和微管相关蛋白-2(microtubule-associated protein 2,MAP-2)双标阳性细胞。结果:在空白对照组中,仅检测到少量的Ch AT/MAP-2双标阳性细胞;在NGF组或是NGF联合阴性对照慢病毒组中则可检测到较多的Ch AT/MAP-2双标阳性细胞;在加入Lhx8干扰慢病毒的实验组中,分化所得的Ch AT/MAP-2双标阳性细胞数较NGF组或是NGF联合阴性慢病毒组明显减少。结论:Lhx8基因沉默抑制了NGF诱导的海马神经干细胞向胆碱能神经元的分化。

3D打印支架联合iPSCs-NSCs对大鼠脊髓损伤后神经细胞凋亡及运动功能的影响

目的探讨3D打印支架载重编程诱导性多能干细胞(iPSCs)-神经干细胞(NSCs)移植对大鼠脊髓损伤的作用机制。方法制备3D脊髓支架,将人尿液细胞来源iPSCs分化为NSCs,选择成年雄性SD大鼠42只,按随机数字表法分为假手术组、模型组、iPSCs-NSCs组,每组14只。采用改良Allen’s重物打击法制作脊髓损伤大鼠模型,1周后假手术组不做处理,模型组植入DMEM培养液0.2mL,i PSCs-NSCs组植入载iPSCs-NSCs的2~3mm支架预处理。于实验干预后1、3、7、14、28天采用BBB评分评估大鼠运动能力,28天后处死大鼠,苏木精-伊红(HE)染色观察伤段脊髓组织改变;免疫组化与RT-PCR检测脊髓组织中Bax、Bcl-2、Caspase-3的表达。结果(1)BBB评分:术后7、14、28天iPSCs-NSCs组与模型组下肢功能均有恢复(P<0.05),且iPSCs-NSCs组较模型组恢复更明显[(3.76±0.65)分比(2.22±0.46)分,(7.02±0.68)分比(4.41±0.42)分,(11.72±0.81)分比(7.52±0.53)分,P<0.05]。(2)HE染色:假手术组脊神经生长良好;模型组脊神经受损,组织水肿,细胞稀疏,细胞之间的间隙增大;iPSCs-NSCs组细胞生长较模型组紧密,各组织生长间隙缩小,空泡减小,组织水肿消失。(3)免疫组化检测:iPSCs-NSCs组Bcl-2阳性细胞的表达较模型组增加[(0.32±0.02)个/mm^(2)比(0.14±0.01)个/mm^(2),P<0.05],Bax阳性细胞的表达较模型组减少[(0.08±0.00)个/mm^(2)比(0.23±0.02)个/mm^(2),P<0.05];(4)RT-PCR检测:iPSCs-NSCs组Caspase-3 mRNA表达较模型组减少[(0.96±0.07)比(1.33±0.03),P<0.05]。结论3D打印支架联合iPSCs-NSCs移植可以显著改善脊髓损伤引起的运动功能下降,其机制可能与上调Bcl-2表达及下调Bax、Caspase-3表达,降低脊髓神经元细胞凋亡相关。

大鼠NSCs向多巴胺能神经元分化研究

目的:探讨IL-1β对神经干细胞(NSCs)分化为多巴胺能神经元作用。方法:体外培养和鉴定中脑来源NSCs,用免疫学方法检测分化细胞酪氨酸羟化酶(TH)表达。结果:血清组、IL-1β10pg/ml组、IL-1β120pg/ml组、IL-1β150pg/ml组、IL-1β200pg/ml组诱导7d后TH细胞分别平均为0.45%、0.6%、7.2%、12.5%、8.75%。结果显示IL-1β诱导NSCs明显提高TH细胞表达率,与血清组比较有显著性差异(P<0.05),在IL-1β150pg/ml剂量范围内TH细胞表达率与剂量呈正相关。结论:IL-1β有诱导NSC向多巴胺能神经元分化的显著作用。

Neurotoxic role of interleukin-17 in neural stem cell differentiation after intracerebral hemorrhage

Interleukin 17(IL-17)and its main producer,T cell receptorγδcells,have neurotoxic effects in the pathogenesis of intracerebral hemorrhage(ICH),aggravating brain injuries.To investigate the correlation between IL-17 and ICH,we dynamically screened serum IL-17 concentrations using enzyme-linked immunosorbent assay and explored the clinical values of IL-17 in ICH patients.There was a significant negative correlation between serum IL-17 level and neurological recovery status in ICH patients(r=–0.498,P<0.01).To study the neurotoxic role of IL-17,C57 BL/6 mice were used to establish an ICH model by injecting autologous blood into the caudate nucleus.Subsequently,the mice were treated with mouse neural stem cells(NSCs)and/or IL-17 neutralizing antibody for 72 hours.Flow cytometry,brain water content detection,Nissl staining,and terminal deoxynucleotidyl transferase-mediated dUTP nick end labeling results indicated that NSC transplantation significantly reduced IL-17 expression in peri-hematoma tissue,but there was no difference in T cell receptorγδcells.Compared with the ICH group,there were fewer apoptotic bodies and more Nissl bodies in the ICH+NSC group and the ICH+NSC+IL-17 group.To investigate the potential effect of IL-17 on directional differentiation of NSCs,we cultured mouse NSCs(NE-4 C)alone or co-cultured them with T cell receptorγδcells,which were isolated from mouse peripheral blood mononuclear cells,for 7 days.The results of western blot assays revealed that IL-17 secreted by T cell receptorγδcells reduced the differentiation of NSCs into astrocytes and neurons,while IL-17 neutralization relieved the inhibition of directional differentiation into astrocytes rather than neurons.In conclusion,serum IL-17 levels were elevated in the early stage of ICH and were negatively correlated with outcome in ICH patients.Animal experiments and cytological investigations therefore demonstrated that IL-17 probably has neurotoxic roles in ICH because of its inhibitory effects on the directional differentiation of NSCs.The application of IL-17 neutralizing antibody may promote the directional differentiation of NSCs into astrocytes.This study was approved by the Clinical Research Ethics Committee of Anhui Medical University of China(For human study:Approval No.20170135)in December 2016.All animal handling and experimentation were reviewed and approved by the Institutional Animal Care and Use Committee of Anhui Medical University(approval No.20180248)in December 2017.

Adult neural stem cell plasticity

Stem cells derived from adult tissues have long been consideredmultipotent, able to differentiate into a limited number of cell typesfound in their tissue of origin. Embryonic stem cells, in contrast,are pluripotent, which may differentiate into almost all cell types.With the ability to create induced pluripotent stem cells from somaticcells now available, the properties of multipotent stem cellsare being re-evaluated. If adult cells may be reverted to pluripotentstem cells, can multipotent stem cells also be manipulated towardspluripotency? Advancements in biotechnology now allow for bettermethods to investigate stem cell plasticity, such as the relativeinfluence of external versus intrinsic factors on cell fate. Recentstudies indicate that adult neural stem cells (NSCs) demonstrategreater plasticity under certain conditions, resulting in the derivationof a variety of cell types including muscle, hematopoietic, andepithelial cells. This suggests that NSCs may provide a potentialsource of rare cell types for clinical application as an alternative toembryonic stem cells. Producing rare cell types from NSCs ratherthan embryonic stem cells avoids the ethical issues surrounding theuse of this cell type. Further, NSCs may be an advantageous sourcecompared to induced pluripotent stem cells, which are difficult tocreate, expensive, and time-consuming to

Neural stem cell replacement: a possible therapy for neurodevelopmental disorders?

Neurodevelopmental disorders are characterized by an abnormal development of the central nervous system, leading to a myriad of symptoms and diseases, including intellectual disability, attention deficits, impairments in learning and memory, speech disorders and repetitive behavior （Telias and Ben-Yosef, 2014）. Common major neurodevelopmental disorders include autism and autism spectrum disorders （ASDs）, fragile X syndrome （FXS）, Down syndrome （DS）, and Rett syndrome （RTT）. They can be collectively described as disorders in which the plasticity of the brain has been severely impaired. The concept of plasticity refers to the brain＇s ability to adapt to and process new information and react accordingly, and it can be classified into three categories： a） molecular plasticity, whenever specific receptors, ion channels, enzymes,

Fortuitous benefits of activity-based rehabilitation in stem cell-based therapy for spinal cord repair: enhancing graft survival

Traumatic injuries to spinal cord elicit diverse signaling pathways leading to unselective and complex pathological outcomes：death of multiple classes of neural cells,formation of cystic cavities and glial scars,disruption of axonal connections,and demyelination of spared axons,all of which can contribute more or less to debilitating functional impairments found in patients with spinal cord injury.

Stem cell transplantation for repair of sciatic nerve injury

Three articles regarding transplantation of umbilical cord mesenchmal stem cells alone or in combination with Schwann cells and feridex and polylysine complex-labeled bone marrow stromal cell transplantation （MRI tracing） for repair of sciatic nerve injury were reported in Neural Regeneration

Regulation of neural stem/progenitor cell functions by P2X and P2Y receptors

Neural stem/progenitor cells：Radial glial cells constitute multipotent cells in the ventricular zone,lining the wall of the lateral ventricle of the embryonic brain.They have the capacity to give rise to cells belonging to all three major linages（neurons,astrocytes and oligodendrocytes）of the nervous system（Tang and Illes,2017）.

Epigenetic control on cell fate choice in neural stem cells

Derived from neural stem cells(NSCs)and progenitor cells originated from the neuroectoderm,the nervous system presents an unprecedented degree of cellular diversity,interwoven to ensure correct connections for propagating information and responding to environ-mental cues.NSCs and progenitor cells must integrate cell-intrinsic programs and environmental cues to achieve production of appropriate types of neurons and glia at appropriate times and places during develop-ment.These developmental dynamics are reflected in changes in gene expression,which is regulated by transcription factors and at the epigenetic level.From early commitment of neural lineage to functional plas-ticity in terminal differentiated neurons,epigenetic regulation is involved in every step of neural develop-ment.Here we focus on the recent advance in our un-derstanding of epigenetic regulation on orderly genera-tion of diverse neural cell types in the mammalian nervous system,an important aspect of neural devel-opment and regenerative medicine.

The application of patient-derived induced pluripotent stem cells for modeling and treatment of Alzheimer’s disease

Alzheimer’s disease(AD)is the most prevalent age-related neurodegenerative disease which is mainly caused by aggregated protein plaques in degenerating neurons of the brain.These aggregated protein plaques are mainly consisting of amyloidβ(Aβ)fibrils and neurofibrillary tangles(NFTs)of phosphorylated tau protein.Even though the transgenic murine models can recapitulate some of the AD phenotypes,they are not the human cell models of AD.Recent breakthrough in somatic cell reprogramming made it available to use induced pluripotent stem cells(i PSCs)for patientspecific disease modeling and autologous transplantation therapy.Human i PSCs provide alternative ways to obtain specific human brain cells of AD patients to study the molecular mechanisms and therapeutic approaches for familial and sporadic forms of AD.After differentiation into neuronal cells,i PSCs have enabled the investigation of the complex aetiology and timescale over which AD develops in human brain.Here,we first go over the pathological process of and transgenic models of AD.Then we discuss the application of i PSC for disease model and cell transplantation.At last the challenges and future applications of i PSCs for AD will be summarized to propose cell-based approaches for the treatment of this devastating disorder.