微囊化共培养诱导骨髓间充质干细胞体外定向成骨分化研究

为了模拟体内成骨微环境,为骨组织工程提供一种调控干细胞体外向成骨细胞定向分化的共培养新方法,SD大鼠骨髓间充质干细胞和包埋在海藻酸钠-聚赖氨酸-海藻酸钠(alginate-poly-lysine-alginate,APA)微胶囊中的SD大鼠成骨细胞进行体外共培养。共培养过程中,通过碱性磷酸酶(ALP)定量、定性分析以及钙化结节(von Kossa)染色等手段来评价骨髓间充质干细胞向成骨细胞定向分化。结果表明在体外微囊化共培养过程中,被诱导细胞的胞内ALP酶活性逐渐高于对照组的干细胞,接近于成骨细胞;ALP以及von Kossa定性染色证实被诱导细胞具有较高的ALP活性以及具有分泌钙基质的能力。微囊化成骨细胞和外部干细胞的共培养体系较好地模拟了体内干细胞向成骨细胞转化的成骨微环境,促进了干细胞向成骨细胞的体外定向分化;微胶囊膜将成骨细胞和干细胞进行了隔离,避免了两者的直接接触和可能的细胞交叉污染混合,同时利于分离目的细胞,这种微囊化共培养体系为骨组织工程提供了一种安全调控干细胞体外成骨定向分化的工程化新方法。     

骨髓间充质干细胞对海藻酸钙胶珠内神经干细胞增殖与分化的作用

神经干细胞(neural stem cells,NSCs)移植治疗神经损伤被认为是具有潜在应用价值的手段,但其来源困难;骨髓间充质干细胞(bone marrow mesenchymal stem cells,BMSCs)以其所具有的诸多优点,为神经损伤的治疗提供了一个新的思路。而BMSCs是否是通过作用于内源性的NSCs来促进神经修复,仍存在着争议。今采用海藻酸钙胶珠将NSCs包囊培养至一定大小的神经球后,再与BMSCs进行共培养,考察BMSCs对生长在海藻酸钙胶珠内的NSCs增殖与分化的作用,探讨BMSCs移植治疗神经疾病与损伤的作用机理。共培养过程中观察神经球结构的变化;共培养结束后计算NSCs的增殖倍数,对增殖条件下共培养的NSCs表型和多向分化潜能进行免疫荧光染色鉴定;对分化条件下共培养的NSCs向不同神经细胞分化的能力进行流式细胞仪检测。结果表明,BMSCs可使生长于支架内的NSCs迁出细胞球,对NSCs的增殖没有明显影响;但能够明显影响NSCs的分化,使其向少突胶质细胞分化的能力增加3倍,向星形胶质细胞分化的能力减弱1倍,而向神经元细胞分化的能力没有明显变化。BMSCs有可能是通过分泌某些因子增加了NSCs迁移及向少突胶质细胞分化的能力,从而促进神经损伤的修复。     

骨髓间充质干细胞向视网膜神经节样细胞的分化

目的探讨乳鼠视网膜细胞条件分化液诱导骨髓间充质干细胞(BMSCs)的神经分化情况,以期为视网膜退行性疾病提供治疗方案。方法体外分离培养Wistar大鼠乳鼠BMSCs,观察BMSCs的增殖情况并进行鉴定;制备乳鼠视网膜细胞条件分化液,以其诱导BMSCs,观察BMSCs的神经分化情况,并行免疫组化鉴定。结果体外培养获得了较纯的BMSCs;在乳鼠视网膜细胞条件分化液的环境中,诱导后72h,BMSCs胞体收缩成锥形或球形,细胞突起变细、变长,呈神经细胞的典型形态;免疫组化结果显示,部分细胞呈神经元特异性烯醇化酶(NSE)、巢蛋白(nestin)和Thy1.1阳性反应。结论乳鼠视网膜细胞条件分化液可诱导BMSCs分化成视网膜神经节样细胞。     

大鼠骨髓间充质干细胞向成骨与成脂分化过程中相关基因的表达变化

目的探讨大鼠骨髓间充质干细胞(bone marrow mesenchymal stem cells,BMSCs)向成骨与成脂分化过程中相关基因表达的变化。方法采用全贴壁法分离培养大鼠BMSCs,并观察其形态学特征的变化,MTT法检测其生长状况,并绘制生长曲线。分别采用成骨和成脂诱导剂对第4代BMSCs进行诱导分化,应用碱性磷酸酶试剂盒、茜素红和油红O染色液检测其ALP活性、成骨和成脂分化能力;RT-QPCR检测诱导0、7、14和21 d的成骨分化相关基因Runt相关转录因子2(Runx2)、骨钙素(osteocalcin,OCN)、碱性磷酸酶(ALP)及成脂分化相关基因过氧化物酶体增殖物激活受体γ(peroxidase proliferator activated receptor gamma,PPARγ)和脂肪酸结合蛋白(FABP4)的表达变化。结果全骨髓贴壁法能成功分离培养BMSCs,传代细胞生长增殖迅速,以长梭形细胞生长为主,细胞生长曲线呈S形。第4代BMSCs分别经成骨和成脂诱导剂诱导后,ALP、茜素红和油红O染色均呈阳性;诱导7、14和21 d后,Runx2、OCN、ALP、PPARγ和FABP4基因mRNA的表达量均显著高于0 d(P0.05);成骨分化过程中,Runx2和ALP在第7天时表达量最高,之后呈下降趋势,OCN的表达量呈稳定上升趋势;成脂分化过程中,PPARγ在第7天时表达量最高,FABP4始终高表达。结论 BMSCs具有易于体外分离培养、扩增和经诱导后具有多向分化潜能等特点,成骨和成脂分化相关基因的表达量随诱导时间延长而变化,呈明显的时序性表达差异,提示分别在成骨与成脂分化过程中起重要调控作用,为BMSCs在骨、细胞和基因等工程中的机制研究提供了实验依据。     

大鼠骨髓间充质干细胞向肝样细胞的定向诱导分化

目的 探讨肝细胞生长因子(Hepatocyte growth factor,HGF)和碱性成纤维细胞生长因子(Basic fibroblast growthfactor,bFGF)诱导大鼠骨髓间充质干细胞(Bone marrow mesenchymal stem cells,BM-MSCs)分化为肝样细胞的可行性。方法取SD大鼠股骨骨髓,直接贴壁法分离纯化BM-MSCs,并体外传代,流式细胞术和成骨诱导对其进行鉴定。取第3代BM-MSCs,分为2组:实验组用HGF(20 ng/ml)和bFGF(10 ng/ml)进行诱导,阴性对照组不加诱导剂,倒置显微镜下观察细胞形态变化;RT-PCR法检测诱导后细胞甲胎蛋白(Alpha fetoprotein,AFP)和白蛋白(Albumin,ALB)基因mRNA的转录水平;免疫细胞化学染色法检测诱导后细胞的AFP和ALB蛋白的表达。结果第3代BM-MSCs表型标志和功能特性均符合MSCs的特点。BM-MSCs经HGF和bFGF诱导后呈肝样细胞形态。实验组细胞可检测出AFP和ALB基因mRNA的表达。实验组细胞诱导后第7天,AFP蛋白开始表达,第14天时表达降低,第21天时不表达;ALB于诱导后第14天出现表达,并随诱导时间的延长表达逐渐增加。结论 HGF和bFGF具有体外诱导BM-MSCs向肝样细胞分化的作用。     

去上皮羊膜及其浸提液体外诱导骨髓间充质干细胞的分化

目的观察去上皮羊膜及其浸提液体外诱导骨髓间充质干细胞(Bone marrow mesenchymal stem cells,BMSCs)向上皮细胞的分化,并探讨其机制。方法从胎儿四肢长骨分离BMSCs,扩增后采用流式细胞术分析第3代(P3)细胞表面抗原(CD29、CD34、CD71和HLA-DR)的表达,并用4,6-乙酰基-2-苯基吲哚(DAPI)标记第4代BMSCs(P4-BMSCs)。机械法去除正常胎盘羊膜上皮,制成去上皮羊膜,并制备去上皮羊膜浸提液。将DAPI标记的BMSCs接种于羊膜上,设加或不加表皮细胞生长因子(Epidermal growth factor,EGF)、类胰岛素1号生长因子(Insulin-like growth factor 1,IGF-1)、羊膜浸提液诱导组及细胞爬片对照组,体外诱导培养后,采用免疫荧光组织(细胞)化学染色学法检测各组细胞角蛋白(Cytokeratin,CK)、EGF-R和IGF-1-R的表达,并于诱导后第10天计算CK阳性细胞率。结果原代BMSCs呈典型旋涡状生长,P3细胞表达CD29和CD71,不表达CD34和HLA-DR。羊膜组和细胞爬片组BMSCs在加入EGF或IGF-1诱导后,表达EGF-R和IGF-1-R的时间较未加生长因子的对照组提前2～4 d,表达CK的时间提前2～6 d,单用羊膜组或羊膜浸提液组的表达时间差异无统计学意义(P>0.05);诱导第10天,单用羊膜或羊膜浸提液诱导组的CK阳性细胞表达率明显高于细胞爬片对照组(P<0.05);羊膜与EGF、IGF-1联合诱导组高于单用羊膜组(P<0.05);EGF诱导组高于IGF-1诱导组(P<0.05)。结论羊膜及羊膜浸提液、外源性EGF和IGF-1在体外均可诱导BMSCs向上皮细胞分化,羊膜可能主要通过其所含的细胞因子诱导BMSCs向上皮分化。     

细胞传代对骨髓间充质干细胞成软骨细胞分化的影响

目的 观察在成软骨诱导培养条件下,细胞传代对骨髓间充质干细胞(MSCs)体外成软骨能力的影响.方法 不同代MSCs成软骨诱导后,观察细胞生物学特性以及通过免疫荧光,RT-PCR测定特异性软骨细胞外基质aggrecan的表达情况.结果 经成软骨诱导后,第2、4代MSCs表达aggrecan明显较第6、8代细胞高.结论 MSCs很可能由多种形态功能接近,分化潜能有略有差异的细胞组成;在成软骨诱导培养条件下,对此传代后成软骨能力减弱.     

成骨生长肽对鼠骨髓间充质干细胞增殖及成骨分化的作用

目的探讨成骨生长肽(osteogenic growth peptide,OGP)对鼠骨髓间充质干细胞(mouse bone marrow mesenchymal stem cell,mBMSC)增殖及成骨分化的作用及其分子机制。方法采用乳鼠骨片法分离mBMSC,流式细胞术测定mBMSC表面特征性分子。以10-5 mol/L OGP10-14作用于mBMSC,以不含OGP10-14的成骨诱导培养基作为对照组,MTS法检测OGP10-14对mBMSC增殖的影响;茜素红染色评价OGP10-14对mBMSC成骨分化的作用;qPCR及Western blot法检测OGP10-14干预下mBMSC骨分化相关因子β-catenin、RUNX2、BSP和细胞周期相关因子cyclin B1、CDK2、c-myc mRNA及蛋白表达水平。结果原代分离培养的mBMSC高表达CD29和CD90,低表达CD45和CD11b/c,符合BMSC的表型特征。与对照组相比,OGP10-14组mBMSC培养24、48及72 h时均促进细胞增殖(P <0.05)。茜素红染色显示,对照组部分细胞呈聚集生长,集落状,随诱...     

bFGF促增殖后骨髓间充质干细胞向多巴胺能神经元样细胞的分化

目的探讨碱性成纤维细胞生长因子(Basic fibroblast growth factor,bFGF)体外作用于骨髓间充质干细胞(Mesen-chymal stem cells,MSCs)后,诱导其向神经元样细胞和多巴胺能神经元样细胞定向分化的情况。方法从鼠骨髓中获得MSCs,培养传代,用MTT法检测bFGF对骨髓MSCs生长的影响。10 ng/ml bFGF作用2 d后,通过IBMX、细胞因子bFGF、GDNFI、L-1β、中脑神经胶质细胞条件培养基和中脑神经细胞膜碎片等分组联合诱导骨髓MSCs向神经元样细胞、多巴胺能神经元样细胞分化,免疫细胞化学方法鉴定特异标志NSE、MAP-2a,b和TH的表达。结果在一定范围内,bFGF对骨髓MSCs具有明显的促增殖作用。分化的神经元样细胞表达NSE、MAP-2a,b和TH,联合应用GDNFI、L-1β、中脑条件培养基和中脑神经细胞膜碎片诱导7 d后,NSE阳性率为(27.774±2.747)%,MAP-2a,b为(28.006±3.080)%,TH为(3.098±0.352)%。结论体外骨髓MSCs被诱导分化成神经元样细胞和多巴胺能神经元样细胞,为帕金森等中枢神经系统疾病的细胞移植治疗奠定了基础。     

大鼠骨髓间充质干细胞的体外分离培养与鉴定

目的建立大鼠骨髓间充质干细胞(Mesenchymal stem cells,MSCs)体外分离培养及鉴定的方法 ,为MSCs的系列研究奠定基础。方法采用全骨髓直接贴壁筛选法分离培养MSCs并传代,倒置相差显微镜下观察细胞形态,以MTT法检测细胞增殖水平并绘制生长曲线。取第3代MSCs,流式细胞术检测细胞周期和细胞表型,应用成骨细胞诱导液和脂肪样细胞诱导液诱导MSCs定向分化,鉴定其分化能力。结果全骨髓细胞培养5d,镜下可见贴壁细胞增殖明显,细胞形态较均一,大部分呈梭形,7d左右可传代,经2～3次传代后细胞呈单一梭形的成纤维样细胞,即MSCs;细胞生长曲线呈S形;经流式细胞仪检测,MSCs细胞76.01%处于G0/G1期,7.13%处于G2/M期,16.86%处于S期;MSCs表面不表达CD34;在特定诱导液作用下,MSCs可分别向成骨样细胞及脂肪样细胞分化。结论已成功建立了分离培养及鉴定MSCs的方法 ,可用来评价体外培养的MSCs。     

Mechanotransduction in Mesenchymal Stem Cells (MSCs) Differentiation: A Review

Mechanotransduction is the process by which physical force is converted into a biochemical signal that is used in development and physiology; meanwhile, it is intended for the ability of cells to sense and respond to mechanical forces by activating intracellular signals transduction pathways and the relative phenotypic adaptation. It encompasses the role of mechanical stimuli for developmental, morphological characteristics, and biological processes in different organs; the response of cells to mechanically induced force is now also emerging as a major determinant of disease. Due to fluid shear stress caused by blood flowing tangentially across the lumen surface, cells of the cardiovascular system are typically exposed to a variety of mechanotransduction. In the body, tissues are continuously exposed to physical forces ranging from compression to strain, which is caused by fluid pressure and compressive forces. Only lately, though, has the importance of how forces shape stem cell differentiation into lineage-committed cells and how mechanical forces can cause or exacerbate disease besides organizing cells into tissues been acknowledged. Mesenchymal stem cells (MSCs) are potent mediators of cardiac repair which can secret a large array of soluble factors that have been shown to play a huge role in tissue repair. Differentiation of MSCs is required to regulate mechanical factors such as fluid shear stress, mechanical strain, and the rigidity of the extracellular matrix through various signaling pathways for their use in regenerative medicine. In the present review, we highlighted mechanical influences on the differentiation of MSCs and the general factors involved in MSCs differentiation. The purpose of this study is to demonstrate the progress that has been achieved in understanding how MSCs perceive and react to their mechanical environment, as well as to highlight areas where more research has been performed in previous studies to fill in the gaps.     

Therapeutic Potential of Differentiated Mesenchymal Stem Cells for Treatment of Osteoarthritis

Osteoarthritis (OA) is a chronic, progressive, and irreversible degenerative joint disease. Conventional OA treatments often result in complications such as pain and limited activity. However, transplantation of mesenchymal stem cells (MSCs) has several beneficial effects such as paracrine effects, anti-inflammatory activity, and immunomodulatory capacity. In addition, MSCs can be differentiated into several cell types, including chondrocytes, osteocytes, endothelia, and adipocytes. Thus, transplantation of MSCs is a suggested therapeutic tool for treatment of OA. However, transplanted naïve MSCs can cause problems such as heterogeneous populations including differentiated MSCs and undifferentiated cells. To overcome this problem, new strategies for inducing differentiation of MSCs are needed. One possibility is the application of microRNA (miRNA) and small molecules, which regulate multiple molecular pathways and cellular processes such as differentiation. Here, we provide insight into possible strategies for cartilage regeneration by transplantation of differentiated MSCs to treat OA patients.     

Density-Dependent Differentiation of Tonsil-Derived Mesenchymal Stem Cells into Parathyroid-Hormone-Releasing Cells

Mesenchymal stem cells (MSCs) can differentiate into endoderm lineages, especially parathyroid-hormone (PTH)-releasing cells. We have previously reported that tonsil-derived MSC (T-MSC) can differentiate into PTH-releasing cells (T-MSC-PTHCs), which restored the parathyroid functions in parathyroidectomy (PTX) rats. In this study, we demonstrate quality optimization by standardizing the differentiation rate for a better clinical application of T-MSC-PTHCs to overcome donor-dependent variation of T-MSCs. Quantitation results of PTH mRNA copy number in the differentiated cells and the PTH concentration in the conditioned medium confirmed that the differentiation efficiency largely varied depending on the cells from each donor. In addition, the differentiation rate of the cells from all the donors greatly improved when differentiation was started at a high cell density (100% confluence). The large-scale expression profiling of T-MSC-PTHCs by RNA sequencing indicated that those genes involved in exiting the differentiation and the cell cycle were the major pathways for the differentiation of T-MSC-PTHCs. Furthermore, the implantation of the T-MSC-PTHCs, which were differentiated at a high cell density embedded in hyaluronic acid, resulted in a higher serum PTH in the PTX model. This standardized efficiency of differentiation into PTHC was achieved by initiating differentiation at a high cell density. Our findings provide a potential solution to overcome the limitations due to donor-dependent variation by establishing a standardized differentiation protocol for the clinical application of T-MSC therapy in treating hypoparathyroidism.     

Characterization and Evaluation of Neuronal Trans-Differentiation with Electrophysiological Properties of Mesenchymal Stem Cells Isolated from Porcine Endometrium

Endometrial stromal cells (EMSCs) obtained from porcine uterus (n = 6) were positive for mesenchymal stem cell markers (CD29, CD44 and CD90), and negative for epithelial marker CD9 and hematopoietic markers CD34, CD45 analyzed by flow cytometry. Further the cells were positive for expression of mesenchymal markers, CD105, CD140b, and CD144 by PCR. Pluripotent markers OCT4, SOX2, and NANOG were positively expressed in EMSCs analyzed by Western blotting and PCR. Further, differentiation into adipocytes and osteocytes was confirmed by cytochemical staining and lineage specific gene expression by quantitative realtime-PCR. Adipocyte (FABP, LPL, AP2) and osteocyte specific genes (ON, BG, RUNX2) in differentiated EMSCs showed significant (p < 0.05) increase in expression compared to undifferentiated control cells. Neurogenic transdifferentiation of EMSCs exhibited distinctive dendritic morphology with axon projections and neuronal specific genes, NFM, NGF, MBP, NES, B3T and MAP2 and proteins, B3T, NFM, NGF, and TRKA were positively expressed in neuronal differentiated cells. Functional analysis of neuronal differentiated EMSCs displayed voltage-dependence and kinetics for transient outward K⁺ currents (I_to), at holding potential of −80 mV, Na⁺ currents and during current clamp, neuronal differentiated EMSCs was more negative than that of control EMSCs. Porcine EMSCs is a suitable model for studying molecular mechanism of transdifferentiation, assessment of electrophysiological properties and their efficiency during in vivo transplantation.     

Anti-Inflammatory Fibronectin-AgNP for Regulation of Biological Performance and Endothelial Differentiation Ability of Mesenchymal Stem Cells

The engineering of vascular regeneration still involves barriers that need to be conquered. In the current study, a novel nanocomposite comprising of fibronectin (denoted as FN) and a small amount of silver nanoparticles (AgNP, ~15.1, ~30.2 or ~75.5 ppm) was developed and its biological function and biocompatibility in Wharton’s jelly-derived mesenchymal stem cells (MSCs) and rat models was investigated. The surface morphology as well as chemical composition for pure FN and the FN-AgNP nanocomposites incorporating various amounts of AgNP were firstly characterized by atomic force microscopy (AFM), UV-Visible spectroscopy (UV-Vis), and Fourier-transform infrared spectroscopy (FTIR). Among the nanocomposites, FN-AgNP with 30.2 ppm silver nanoparticles demonstrated the best biocompatibility as assessed through intracellular ROS production, proliferation of MSCs, and monocytes activation. The expression levels of pro-inflammatory cytokines, TNF-α, IL-1β, and IL-6, were also examined. FN-AgNP 30.2 ppm significantly inhibited pro-inflammatory cytokine expression compared to other materials, indicating superior performance of anti-immune response. Mechanistically, FN-AgNP 30.2 ppm significantly induced greater expression of vascular endothelial growth factor (VEGF) and stromal-cell derived factor-1 alpha (SDF-1α) and promoted the migration of MSCs through matrix metalloproteinase (MMP) signaling pathway. Besides, in vitro and in vivo studies indicated that FN-AgNP 30.2 ppm stimulated greater protein expressions of CD31 and von Willebrand Factor (vWF) as well as facilitated better endothelialization capacity than other materials. Furthermore, the histological tissue examination revealed the lowest capsule formation and collagen deposition in rat subcutaneous implantation of FN-AgNP 30.2 ppm. In conclusion, FN-AgNP nanocomposites may facilitate the migration and proliferation of MSCs, induce endothelial cell differentiation, and attenuate immune response. These finding also suggests that FN-AgNP may be a potential anti-inflammatory surface modification strategy for vascular biomaterials.     

CXCL13 Promotes the Effect of Bone Marrow Mesenchymal Stem Cells (MSCs) on Tendon-Bone Healing in Rats and in C3HIOT1/2 Cells

Objectives: Mesenchymal stem cells (MSCs) are potential effective therapy for tissue repair and bone regeneration. In present study, the effects of CXC chemokine ligand-13 (CXCL13) were evaluated on tendon-bone healing of rats. Methods: Tendon bone healing of the rat model was established and biomechanical testing was performed at 2, 4, 8 weeks after surgery. Murine mesenchymal cell line (C3HIOT1/2 cells) was cultured. The expression of miRNA-23a was detected by real-time PCR. The protein expression of ERK1/2, JNK and p38 was detected by western blotting. MiR-23a mimic and inhibitor were used to overexpress or silence the expression of miR-23a. Results: MSCs significantly elevated the levels of ultimate load to failure, stiffness and stress in specimens of rats, the effects of which were enhanced by CXCL13. The expression of miR-23a was down-regulated and the protein of ERK1/2 level was up-regulated by CXCL13 treatment in both in vivo and in vitro experiments. ERK1/2 expression was elevated by overexpression of miR-23a and reduced by miR-23a inhibitor. Conclusions: These findings revealed that CXCL13 promoted the tendon-bone healing in rats with MSCs treatment, and implied that the activation of ERK1/2 via miR-23a was involved in the process of MSCs treated bone regeneration.     

MicroRNAs Modulate Signaling Pathways in Osteogenic Differentiation of Mesenchymal Stem Cells

Mesenchymal stem cells (MSCs) have been identified in many adult tissues and they have been closely studied in recent years, especially in view of their potential use for treating diseases and damaged tissues and organs. MSCs are capable of self-replication and differentiation into osteoblasts and are considered an important source of cells in tissue engineering for bone regeneration. Several epigenetic factors are believed to play a role in the osteogenic differentiation of MSCs, including microRNAs (miRNAs). MiRNAs are small, single-stranded, non-coding RNAs of approximately 22 nucleotides that are able to regulate cell proliferation, differentiation and apoptosis by binding the 3′ untranslated region (3′-UTR) of target mRNAs, which can be subsequently degraded or translationally silenced. MiRNAs control gene expression in osteogenic differentiation by regulating two crucial signaling cascades in osteogenesis: the transforming growth factor-beta (TGF-β)/bone morphogenic protein (BMP) and the Wingless/Int-1(Wnt)/β-catenin signaling pathways. This review provides an overview of the miRNAs involved in osteogenic differentiation and how these miRNAs could regulate the expression of target genes.