Targeting β-secretase with RNAi in neural stem cells for Alzheimer's disease therapy

There are several major pathological changes in Alzheimer＇s disease, including apoptosis of cho- linergic neurons, overactivity or overexpression of 13-site amyloid precursor protein cleaving enzyme 1 （BACE1） and inflammation. In this study, we synthesized a 19-nt oligonucleotide targeting BACE1, the key enzyme in amyloid beta protein （AI3） production, and introduced it into the pSilenCircle vector to construct a short hairpin （shRNA） expression plasmid against the BACE1 gene. We transfected this vector into C17.2 neural stem cells and primary neural stem cells, resulting in downregulation of the BACE1 gene, which in turn induced a considerable reduction in reducing AI3 protein production. We anticipate that this technique combining cell transplantation and gene ther- apy will open up novel therapeutic avenues for Alzheimer＇s disease, particularly because it can be used to simultaneously target several pathogenetic changes in the disease.

Gene expression profile of Sox1,Sox2,p53,Bax and Nestin in neural stem cells and adult mouse brain tissues

Histone deacetylation is a key modulator involved in cell proliferation,apoptosis,and mRNA transcription.However,the effects of histone deacetylation on C17.2 neural stem cells(NSCs)remain unclear.Here,the histone deacetylase inhibitors nicotinamide and trichostatin A(TSA)were used to determine the role of histone deacetylation on gene transcription in NSCs.The results showed that the mRNA expression of p53,Sox1,Sox2,and Bax were significantly higher in E14.5 NSCs than in C17.2 NSCs.Nestin,a marker gene of neuronal differentiation,did not differ significantly between E14.5 NSCs and C17.2 NSCs.The transcription levels of p53 and Nestin were significantly higher in C17.2 NSCs than in differentiated brain tissues,and the expression of Bax,Sox1,and Sox2 was higher in the olfactory bulb than in other brain tissues.Nicotinamide and TSA treatment decreased the transcription of Sox2,p53,Nestin,and Bax in C17.2 NSCs,although the difference was statistically significant only for Sox2 and Nestin,Sox1 transcription was not detected.These results demonstrated that mRNA expression profiles differ between C17.2 NSCs,E14.5 NSCs,and adult mouse brain tissues,and HDAC inhibitors regulate gene expression by modulating histone acetylation.

In vivo imaging of endogenous neural stem cells in the adult brain

The discovery of endogenous neural stem cells(e NSCs) in the adult mammalian brain with their ability to self-renew and differentiate into functional neurons, astrocytes and oligodendrocytes has raised the hope for novel therapies of neurological diseases. Experimentally, those e NSCs can be mobilized in vivo, enhancing regeneration and accelerating functional recovery after, e.g., focal cerebral ischemia, thus constituting a most promising approach in stem cell research. In order to translate those current experimental approaches into a clinical setting in the future, non-invasive imaging methods are required to monitor e NSC activation in a longitudinal and intraindividual manner. As yet, imaging protocols to assess eNSC mobilization non-invasively in the live brain remain scarce, but considerable progress has been made in this field in recent years. This review summarizes and discusses the current imaging modalities suitable to monitor e NSCs in individual experimental animals over time, including optical imaging, magnetic resonance tomography and-spectroscopy, as well as positron emission tomography(PET). Special emphasis is put on the potential of each imaging method for a possible clinical translation, and on the specificity of the signal obtained. PET-imaging with the radiotracer 3'-deoxy-3'-[18F]fluoro-L-thymidine in particular constitutes a modality with excellent potential for clinical translation but low specificity; however, concomitant imaging of neuroinflammation is feasible and increases its specificity. The non-invasive imaging strategies presented here allow for the exploitation of novel treatment strategies based upon the regenerative potential of e NSCs, and will help to facilitate a translation into the clinical setting.

Effects of microtubule-associated protein tau expression on neural stem cell migration after spinal cord injury

Our preliminary proteomics analysis suggested that expression of microtubule-associated protein tau is elevated in the spinal cord after injury. Therefore, the first aim of the present study was to examine tau expression in the injured spinal cord. The second aim was to determine whether tau can regulate neural stem cell migration, a critical factor in the successful treatment of spinal cord injury. We established rat models of spinal cord injury and injected them with mouse hippocampal neural stem cells through the tail vein. We used immunohistochemistry to show that the expression of tau protein and the number of migrated neural stem cells were markedly increased in the injured spinal cord. Furthermore, using a Transwell assay, we showed that neural stem cell migration was not affected by an elevated tau concentration in the outer chamber, but it was decreased by changes in intracellular tau phosphorylation state. These results demonstrate that neural stem cells have targeted migration capability at the site of injury, and that although tau is not a chemokine for targeted migration of neural stem cells, intracellular tau phosphorylation/dephosphorylation can inhibit cell migration.

Apoptosis in glioma-bearing rats after neural stem cell transplantation

Abnormal activation of the Ras/Raf/Mek/Erk signaling cascade plays an important role in glioma. Inhibition of this aberrant activity could effectively hinder glioma cell proliferation and promote cell apoptosis. To investigate the mechanism of gJioblastoma treatment by neural stem ceiJ trans- plantation with respect to the Ras/Raf/Mek/Erk pathway, C6 glioma cells were prepared in sus- pension and then infused into the rat brain to establish a glioblastoma model. Neural stem cells isolated from fetal rats were then injected into the brain of this glioblastoma model. Results showed that Raf-1, Erk and Bcl-2 protein expression significantly increased, while Caspase-3 protein expression decreased. After transplantation of neural stem cells, Raf-1, Erk and Bcl-2 protein expression significantly decreased, while Caspase-3 protein expression significantly in-creased. Our findings indicate that transplantation of neural stem cells may promote apoptosis of glioma cells by inhibiting Ras/Raf/Mek/Erk signaling, and thus may represent a novel treatment approach for glioblastoma.

Contralateral C7 transfer combined with acellular nerve allografts seeded with differentiated adipose stem cells for repairing upper brachial plexus injury in rats

Nerve grafting has always been necessary when the contralateral C7 nerve root is transferred to treat brachial plexus injury. Acellular nerve allograft is a promising alternative for the treatment of nerve defects, and results were improved by grafts laden with differentiated adipose stem cells. However, use of these tissue-engineered nerve grafts has not been reported for the treatment of brachial plexus injury. The aim of the present study was to evaluate the outcome of acellular nerve allografts seeded with differentiated adipose stem cells to improve nerve regeneration in a rat model in which the contralateral C7 nerve was transferred to repair an upper brachial plexus injury. Differentiated adipose stem cells were obtained from Sprague-Dawley rats and transdifferentiated into a Schwann cell-like phenotype. Acellular nerve allografts were prepared from 15-mm bilateral sections of rat sciatic nerves. Rats were randomly divided into three groups: acellular nerve allograft, acellular nerve allograft + differentiated adipose stem cells, and autograft. The upper brachial plexus injury model was established by traction applied away from the intervertebral foramen with micro-hemostat forceps. Acellular nerve allografts with or without seeded cells were used to bridge the gap between the contralateral C7 nerve root and C5–6 nerve. Histological staining, electrophysiology, and neurological function tests were used to evaluate the effect of nerve repair 16 weeks after surgery. Results showed that the onset of discernible functional recovery occurred earlier in the autograft group first, followed by the acellular nerve allograft + differentiated adipose stem cells group, and then the acellular nerve allograft group;moreover, there was a significant difference between autograft and acellular nerve allograft groups. Compared with the acellular nerve allograft group, compound muscle action potential, motor conduction velocity, positivity for neurofilament and S100, diameter of regenerating axons, myelin sheath thickness, and density of myelinated fibers were remarkably increased in autograft and acellular nerve allograft + differentiated adipose stem cells groups. These findings confirm that acellular nerve allografts seeded with differentiated adipose stem cells effectively promoted nerve repair after brachial plexus injuries, and the effect was better than that of acellular nerve repair alone. This study was approved by the Animal Ethics Committee of the First Affiliated Hospital of Sun Yat-sen University of China(approval No. 2016-150) in June 2016.

Bone marrow stromal cell versus neural stem cell transplantation in a C6 glioma rat model

BACKGROUND： Embryonic neural stem cells （NSCs） have provided positive effects for the treatment of glioma. However, the source for embryonic NSCs remains limited and high amplification conditions are required. Bone marrow stromal cells （BMSCs） have been proposed for the treatment of glioma. OBJECTIVE： To investigate biological changes in NSCs and BMSCs following transplantation into rat models of glioma. DESIGN, TIME AND SETTING： A randomized, controlled, animal experiment was performed at the Embryonic Stem Cell Research Laboratory of Yunyang Medical College from February 2006 to August 2008. MATERIALS： The rat C6 glioma cell line was purchased from Institute of Biochemistry and Cell Biology, Shanghai Institutes for Biological Sciences, Chinese Academy of Sciences; mouse anti-bromodeoxyuridine （BrdU） monoclonal antibody and Cy3-1abeled goat anti-mouse IgG antibody was purchased from Upstate, USA. METHODS： A total of 95 Sprag6ue Dawley rats were randomly assigned to three groups： NSC （n = 35）, transplanted with 〉 6 × 10^6 NSCs via left medial hind limb; BMSC （n = 35）, transplanted with 〉 1 × 10^6 BMSCs via left medial hind limb; model group （n = 25）, injected with the same volume of 0.1 mmol/L phosphate buffered saline. MAIN OUTCOME MEASURES： Gliomal growth and size were assessed by nuclear magnetic resonance, and glioma morphological features were observed following hematoxylin-eosin staining and BrdU immunohistochemistry 3 and 4 weeks following transplantation. RESULTS： The average survival of rats in the BMSC, NSC, and model groups was 4.03, 4.28, and 3.88 weeks. At 3 weeks, there was no significant difference in the average glioma diameter between the BMSC and model groups （P 〉 0.05）. However, gliomal diameter was significantly decreased in the NSC group compared with the model group （P 〈 0.05）. At 4 weeks, there was no statistical difference between the groups （P 〉 0.05）. BrdU immunohistochemistry revealed that BMSCs and NSCs appeared to migrate to the gliomas. CONCLUSION： NSCs inhibited glioma cell growth and prolonged rat survival. BMSCs did not significantly suppress glioma cell growth.

ADAM10 facilitates rapid neural stem cell cycling and proper positioning within the subventricular zone niche via JAMC/RAP1Gap signaling

The mechanisms that regulate neural stem cell(NSC)lineage progression and maintain NSCs within diffe rent domains of the adult neural stem cell niche,the subventricular zone are not well defined.Quiescent NSCs are arranged at the apical ventricular wall,while mitotically activated NSCs are found in the basal,vascular region of the subventricular zone.Here,we found that ADAM 10(a disintegrin and metalloproteinase 10)is essential in NSC association with the ventricular wall,and via this adhesion to the apical domain,ADAM10 regulates the switch from quiescent and undiffe rentiated NSC to an actively prolife rative and differentiating cell state.Processing of JAMC(junctional adhesion molecule C)by ADAM 10 increases Rap1 GAP activity.This molecular machinery promotes NSC transit from the apical to the basal compartment and subsequent lineage progression.Understanding the molecular mechanisms responsible for regulating the proper positioning of NSCs within the subventricular zone niche and lineage progression of NSCs could provide new targets for drug development to enhance the regenerative prope rties of neural tissue.

Repetitive traumatic brain injury–induced complement C1–related inflammation impairs long-term hippocampal neurogenesis

Repetitive traumatic brain injury impacts adult neurogenesis in the hippocampal dentate gyrus,leading to long-term cognitive impairment.However,the mechanism underlying this neurogenesis impairment remains unknown.In this study,we established a male mouse model of repetitive traumatic brain injury and performed long-term evaluation of neurogenesis of the hippocampal dentate gyrus after repetitive traumatic brain injury.Our results showed that repetitive traumatic brain injury inhibited neural stem cell proliferation and development,delayed neuronal maturation,and reduced the complexity of neuronal dendrites and spines.Mice with repetitive traumatic brain injuryalso showed deficits in spatial memory retrieval.Moreover,following repetitive traumatic brain injury,neuroinflammation was enhanced in the neurogenesis microenvironment where C1q levels were increased,C1q binding protein levels were decreased,and canonical Wnt/β-catenin signaling was downregulated.An inhibitor of C1 reversed the long-term impairment of neurogenesis induced by repetitive traumatic brain injury and improved neurological function.These findings suggest that repetitive traumatic brain injury–induced C1-related inflammation impairs long-term neurogenesis in the dentate gyrus and contributes to spatial memory retrieval dysfunction.

HD02对慢性前脑缺血大鼠神经干细胞增殖分化的影响

目的:观察HD02对慢性前脑缺血大鼠神经干细胞增殖分化的变化。方法:结扎双侧颈总动脉制备慢性前脑缺血大鼠模型,采用免疫单标和双标方法检测成体大鼠神经干细胞及分化的功能细胞。给予模型大鼠HD02水煎剂灌胃,分别于造模后15,30d观察神经干细胞增殖分化的变化。结果:与正常对照组相比,慢性前脑缺血大鼠大脑皮质、室周区、海马BrdU阳性细胞数和BrdU+NF200,BrdU+NeuroD,BrdU+GFAP免疫荧光双标细胞数于造模后15d明显增多(P<0.01),但造模后30dBrdU阳性细胞数和BrdU+NF200,BrdU+NeuroD,BrdU+GFAP免疫荧光双标细胞数与正常对照组相比差异无显著性意义(P>0.05);造模后30d,HD02组BrdU阳性细胞数和BrdU+NF200,BrdU+NeuroD,BrdU+GFAP免疫荧光双标细胞数较慢性前脑缺血组明显增多(P<0.01)。

督脉电针与NSCs移植联合应用对大鼠脊髓全横断损伤组织NT-3含量及受体表达的影响

目的:探讨督脉电针与神经干细胞(NSCs)联合应用对大鼠脊髓全横断损伤组织神经营养素-3(NT-3)含量及其受体表达的影响。方法:将30只成年大鼠分为对照14d组、督脉电针14d组(电针14d组)、神经干细胞移植14d组(NSCs14d组)、督脉电针+神经干细胞移植14d组(电针NSCs14d组)、神经干细胞移植30d组(NSCs30d组)和督脉电针+神经干细胞移植30d组(电针NSCs30d组)6组,所有动物均实施T10段脊髓全横断手术,其中电针组和电针NSCs组于术后5d进行电针治疗。结果:①电针NSCs14d组受损伤的脊髓组织含有较高水平的NT-3,其次是电针14d组和NSCs14d组,对照14d组受损伤的脊髓组织含有较低水平的NT-3。②NSCs30d组和电针NSCs30d组脊髓全横断处的移植神经干细胞均有TrkC表达。结论:督脉电针与神经干细胞移植联合应用能够明显增高大鼠脊髓全横断损伤处邻近组织的NT-3水平;在大鼠脊髓损伤处及邻近组织有些移植神经干细胞表达TrkC。

大脑皮质细胞低氧条件液对神经干细胞增殖的影响及其信号转导通路的分析

目的观察和分析大脑皮质细胞低氧条件液对神经干细胞增殖的影响,并探讨磷脂酰肌醇3-激酶(PI3-K)和c-Jun氨基末端激酶(JNK)两条信号通路在此过程中的作用。方法原代培养出生后24 h内SD大鼠大脑皮质细胞5 d后,全量换液并在4%O2、1%O2和常氧环境下继续培养细胞6 h以制备低氧条件液和常氧条件液。分别用3种条件液及结合使用PI3-K、JNK信号通路抑制剂LY294002和SP600125悬浮培养神经干细胞,并用免疫荧光染色鉴定神经干细胞,使用增殖效率(神经球数量)和增殖速度(神经球直径)分析神经干细胞的增殖情况。结果 (1)4%低氧条件液组和常氧条件液组神经干细胞的增殖效率高于1%低氧条件液组(P<0.01),但前两者之间差异无统计学意义;(2)与常氧条件液相比,两个低氧条件液均提高了神经干细胞的增殖速度(P<0.01),且4%低氧条件液组神经干细胞的增殖速度较1%低氧条件液组快(P<0.01);(3)在4%低氧条件液中使用LY294002和SP600125同时抑制了神经干细胞的增殖效率和增殖速度,且LY294002抑制作用在24 h之后尤为明显。结论4%大脑皮质细胞低氧条件液能提高神经干细胞的增殖速度,PI3-K信号通路在此过程中发挥主要作用。

TRKC基因体外转染大鼠神经干细胞的方法

目的探讨体外转染TRKC基因的神经干细胞的制备方法。方法利用自行合成的引物进行PCR反应,定向克隆构建TRKC-cDNA质粒并进行DNA测序分析,将pEGFP-C1质粒和TRKC-cDNA质粒进行酶切、重组,构建出pEGFP-C1-TRKC质粒。用脂质体将重组质粒转染到体外培养的大鼠神经干细胞中。用W estern b lot、免疫荧光和MTT法观察转染基因的表达和转基因后神经干细胞的增殖活性。结果成功构建了TRKC-cDNA质粒,DNA测序证明所获得的目的基因与公布序列的一致性为99%,所获得的重组子符合研究要求。pEGFP-C1-TRKC质粒转染到神经干细胞后,宿主细胞能高效、稳定地表达目的基因产物GFP和TRKC。在NT-3作用下转TRKC基因神经干细胞的增殖活性有明显增强。结论以质粒为载体、脂质体为介导可成功地把TRKC基因转染到神经干细胞内,转染基因表达好且具有功能。

Nac-1在神经干/祖细胞自我更新维持中的作用

目的研究Nac-1在神经干/祖细胞(NSPCs)自我更新维持中的作用及其机制。方法以胚胎干细胞(ESCs)来源的NSPCs为细胞模型,利用RNA干扰法敲低Nac-1表达并通过定量RT-PCR和Western blot检测干扰效率;通过细胞计数和流式细胞技术,检测NSPCs的增殖和凋亡情况;并利用荧光素酶等实验检测Nac-1对c-Myc的转录调控作用。结果 Nac-1在NSPCs中高表达,分化后其mRNA水平下降了77%。与对照组相比,实验组(干扰组)NSPCs中Nac-1的mRNA水平显著下降,干扰效率分别是69%和66%。Nac-1敲低组的NSPCs增殖缓慢,凋亡增多,趋向于分化,c-Myc的mRNA水平降低46%和57%。荧光素酶分析显示,Nac-1敲低组中,c-Myc启动子的活性下降了24%和36%,提示Nac-1可以调节c-Myc基因的启动子活性。结论Nac-1促进NSPCs增殖并抑制其分化,是NSPCs自我更新维持所必需;Nac-1促自我更新的作用可能通过调控c-Myc的转录而实现。

神经干细胞移植对阿尔茨海默病大鼠行为学及不同脑区细胞色素C表达的影响

目的探讨神经干细胞移植(NSCs)对阿尔茨海默病(AD)大鼠行为学及不同脑区细胞色素C(Cyt-C)表达的影响。方法通过切断Wistar大鼠海马穹隆伞制备AD模型大鼠;培养胎鼠的NSCs,并把该细胞移植入AD模型大鼠脑内;等量生理盐水注射设为对照组。1个月后进行morris水迷宫检测实验鼠学习记忆能力;5 d后处死实验鼠,用Western bolt检测不同脑区Cyt-C的表达。结果NSCs移植后AD模型大鼠的学习记忆能力明显改善,与生理盐水对照组相比差异显著(P<0.01),与正常组相比无显著差异(P>0.05);海马与额叶的Cyt-C表达显示生理盐水对照组与其他各组之间有显著差异(P<0.01);各实验组海马内的Cyt-C表达均高于额叶。结论NSCs移植可以改善AD模型大鼠的学习记忆能力,降低AD模型大鼠脑内的Cyt-C含量,NSCs移植可以改善AD模型大鼠的痴呆症状。

常氧和低氧条件下介导神经干细胞增殖的信号通路分析

目的：观察常氧和低氧环境下大鼠大脑皮层神经干细胞（NSCs）体外增殖情况，并比较P13K／Akt、JNK和Notch3条信号通路在不同氧环境下NSCs增殖时所发挥作用的异同。方法：在常氧和4％02浓度下悬浮培养新生SD大鼠大脑皮层NSCs，在培养细胞24、36和48h时使用图像分析软件测量NSCs增殖后所形成的神经球直径。结果：在培养细胞24、36和48h后，在不同时间段低氧组神经球直径都大于常氧对照组；在常氧浓度环境下分别使用0．5％DMSO和10μmol／LLY294002（P13K／Akt抑制剂）、SP600125（JNK抑制剂）和DAPT（Notch抑制剂）培养细胞，在培养细胞36h和48h时，3个抑制剂组神经球直径都小于常氧DMSO对照组。在低氧浓度环境下培养细胞36h和48h时，LY294002和SP600125组神经球直径与低氧DMSO组相比均无差异，而DAPT组神经球直径明显小于低氧DMSO对照组。结论：P13K／Akt、JNK和Notch3条信号通路均介导了常氧浓度环境下NSCs增殖，但低氧浓度环境诱导的NSCs增殖主要由Notch信号通路介导。

脑微血管内皮细胞与体外培养神经干细胞共培养后Th1/Th2相关细胞因子的表达

目的体外观察脑微血管内皮细胞(MVECs)对来自大鼠海马神经干细胞(NSCs)免疫相关细胞因子表达的影响。方法采用Tran-swell建立神经干细胞与脑微血管内皮细胞共培养模型(NSCs+MVECs),用荧光免疫化学和RT-PCR测定NSCs中与Th1相关的IFN-γ、IL-2及与Th2相关的IL-4、IL-10的表达。结果两种细胞共培养后,神经干细胞呈INF-γ,IL-2,IL-4,IL-10阳性;同时INF-γ、IL-2 mRNA的表达上调,而IL-4、IL-10mRNA的表达下调,与空白对照组比较明显差异(P<0.01)。结论脑微血管内皮细胞(MVECs)有可能使神经干细胞的INF-γ、IL-2表达上调,IL-4、IL-10的表达下调。

西洛他唑对海马神经干细胞糖氧剥夺性损伤的影响及其作用机制

目的探讨抗血小板药西洛他唑对糖氧剥夺诱导海马神经干细胞(NSCs)损伤的保护作用,以及活化转录因子4(ATF-4)、C/EBP同源蛋白(CHOP)信号通路与西洛他唑保护性作用的关系。方法采用分离培养的新生C57BL/6幼鼠海马NSCs建立糖氧剥夺性NSCs损伤模型。将NSCs随机分为对照组、模型组、西洛他唑组、siRNA空白对照组、ATF-4 siRNA组。在接受糖氧剥夺3 h和药物作用24 h后,CCK-8法检测海马NSCs的增殖活力,免疫印迹法(Western Blotting)检测ATF-4、CHOP、Bax、Bcl-2蛋白表达量,采用针对NSCs标志分子巢蛋白(Nestin)的免疫荧光检测鉴定NSCs。结果免疫荧光检测显示分离培养的海马NSCs呈现典型Nestin阳性。CCK-8法检测和Western Blot检测结果显示,与对照组比较,模型组海马NSCs的增殖活力明显下降(P<0.01),Bax/Bcl-2、ATF-4和CHOP表达明显上调(P<0.01);高剂量西洛他唑组与模型组比较,ATF-4 siRNA组与SiRNA空白对照组比较,海马NSCs的增殖活力明显上调(P<0.01),凋亡指数Bax/Bcl-2、ATF-4和CHOP表达明显下调(P<0.01)。结论西洛他唑对糖氧剥夺诱导的海马NSCs损伤具有保护作用,其机制与抑制ATF-4、CHOP信号通路有关。

DCs和NSPCs共培养促进NSPCs增殖及其机制的初步研究

目的观察体外Transwell共培养系统中树突状细胞(dendritic cells,DCs)对神经干/前体细胞(neural stem/progenitor cells,NSPCs)增殖的影响,初步探讨神经营养因子-3(neurotrophin-3,NT-3)在DCs调控NSPCs中的作用机制。方法根据是否采用Transwell小室将DCs和NSPCs共培养分为分隔培养(DCs/NSPCs组)和混合培养(DCs+NSPCs组),ELISA法测定DCs组、NSPCs组、DCs+NSPCs组、DCs/NSPCs组共培养48 h上清中的NT-3的含量。为观察NT-3在DCs调控NSPCs中的作用及可能的机制,成球法检测NSPCs组、NSPCs/DCs+K252a组、NSPCs+DCs组、NSPCs+NT-3组的NSPCs增殖,免疫细胞荧光法和Western blot法检测各组NSPCs表面酪氨酸激酶受体C(TrkC)的表达。结果 ELISA实验结果显示,Transwell共培养48 h上清NT-3的含量,NSPCs/DCs组较DCs组和NSPCs组明显升高(P<0.05)。镜下观察、测量结果显示NSPCs/DCs组和NSPCs+NT-3组神经球数量增多,平均直径明显增大(P<0.05)。免疫细胞荧光和Western blot检测结果表明,NSPCs+DCs组和NSPCs+NT-3组中NSPCs的TrkC表达较NSPCs组和NSPCs/DCs+K252a组高(P<0.05)。结论体外DCs与NSPCs共培养,促进NSPCs增殖、NT-3的分泌及TrkC的表达,NT-3可能是通过TrkC受体参与NSPCs增殖的调控。

Proteins in DNA methylation and their role in neural stem cell proliferation and differentiation

Background:Epigenetic modifications,namely non-coding RNAs,DNA methylation,and histone modifications such as methylation,phosphorylation,acetylation,ubiquitylation,and sumoylation play a significant role in brain development.DNA methyltransferases,methyl-CpG binding proteins,and ten-eleven translocation proteins facilitate the maintenance,interpretation,and removal of DNA methylation,respectively.Different forms of methylation,including 5-methylcytosine,5-hydroxymethylcytosine,and other oxidized forms,have been detected by recently developed sequencing technologies.Emerging evidence suggests that the diversity of DNA methylation patterns in the brain plays a key role in fine-tuning and coordinating gene expression in the development,plasticity,and disorders of the mammalian central nervous system.Neural stem cells(NSCs),originating from the neuroepithelium,generate neurons and glial cells in the central nervous system and contribute to brain plasticity in the adult mammalian brain.Main body:Here,we summarized recent research in proteins responsible for the establishment,maintenance,interpretation,and removal of DNA methylation and those involved in the regulation of the proliferation and differentiation of NSCs.In addition,we discussed the interactions of chemicals with epigenetic pathways to regulate NSCs as well as the connections between proteins involved in DNA methylation and human diseases.Conclusion:Understanding the interplay between DNA methylation and NSCs in a broad biological context can facilitate the related studies and reduce potential misunderstanding.