大鼠BMSCs条件培养基对NSCs形态、生长及分化的影响

通过对SD大鼠骨髓间充质干细胞(bone mesenchymal stem cells,BMSCs)及新生鼠神经干细胞(neural stem cells,NSCs)进行体外分离、培养及鉴定后,观察BMSCs条件培养基对NSCs向神经细胞分化的影响。采用全贴壁培养法培养BMSCs,并采用流式细胞术鉴定其特异性表面抗原标记。无血清技术培养NSCs,采用免疫荧光技术鉴定其特异性抗原标记。BMSCs条件培养基(含10%胎牛血清的DMEM培养基)对NSCs诱导7 d后,镜下观察细胞形态和生长,并采用免疫荧光技术检测NSCs分化。BMSCs高表达CD90、CD29(90%),而CD45呈阴性表达。免疫荧光染色显示,NSCs标记蛋白Nestin、SOX2为阳性。NSCs经BMSCs培养液诱导分化7 d后经免疫荧光鉴定,MAP-2及GFAP呈阳性,阳性率分别为73.80%和50.47%;NSCs经胎牛血清(fetal bovine serum,FBS)诱导分化7 d后经免疫荧光鉴定,MAP-2及GFAP呈阳性,阳性率分别为42.14%和31.90%。BMSCs条件培养基可诱导NSCs分化为神经元及星形胶质细胞,其中BMSCs分泌的细胞因子在诱导分化中可能发挥重要作用。     

大鼠骨髓间充质干细胞培养、鉴定与成胰岛样β细胞诱导

为治疗糖尿病寻找新的胰岛β细胞替代物,该研究对大鼠骨髓间充质干细胞(bone marrow mesenchymal stem cells,BMSCs)进行了体外分离培养、鉴定及成胰岛样β细胞诱导。应用全骨髓离心贴壁培养法分离大鼠BMSCs,进行培养、传代、表面标志物检测,利用DMSO和高糖环境对BMSCs进行胰岛样β细胞诱导。结果显示,大鼠BMSCs体外培养细胞形态呈成纤维细胞样,可以稳定传代;CD13、CD44和CD106表达呈阳性,CD49d呈阴性。在成胰诱导条件下,BMSCs可形成胰岛样圆形细胞团,双硫腙染色呈棕红色,PDX1(pancreatic duodenal homeodomain 1)、CK19(cytokeratin 19)、巢蛋白、胰岛素免疫组化染色均呈阳性;经RT-PCR检测发现,成胰诱导后的BMSCs中表达胰岛素、PDX1和glucagon基因;经q-PCR检测发现,成胰诱导后的BMSCs中胰岛素m RNA水平是大鼠胰腺成体干细胞(pancreas adult stem cells,PASCs)的1.09倍(P0.05);同时,有相应量的胰岛素合成。结果表明,分离得到大鼠BMSCs体外生长稳定,能转分化为胰岛样细胞,该研究结果为糖尿病治疗提供了新的实验依据。     

阿尔巴斯绒山羊骨髓间充质干细胞体外分离培养及鉴定

探讨阿尔巴斯绒山羊骨髓间充质干细胞(Arbas cashmere goat bone marrow-derived mesenchymal stem cells,g BMMSCs)体外分离培养,并对其生物学特性进行系统的鉴定,进一步深入分析体外诱导时多向分化相关基因动态表达情况。结果显示,原代培养的g BM-MSCs呈梭形或纺锤形、放射状排列的细胞集落,能够连续稳定传代至15代以上;免疫荧光及流式细胞术检测显示,g BM-MSCs表达间质系特异性表面标志物,如:CD13、CD29、CD44、CD106、CD90及CD166,不表达造血干细胞表面标志物CD45及CD34;体外诱导实验证实该细胞具有多向分化潜能,能够向脂肪细胞、成骨细胞和软骨细胞分化;荧光定量PCR实验结果显示,g BM-MSCs多向分化相关基因的表达水平随着诱导天数的增加呈上升趋势。实验结果证实阿尔巴斯绒山羊骨髓中分离培养的细胞具备g BM-MSCs的生物学特性。     

DDR2基因缺失对小鼠骨髓间充质干细胞生物学特性的影响

目的:骨髓间充质干细胞(Bone Mesenchymal Stem Cells,BMSCs)是骨再生工程中重要的种子细胞,它对骨组织缺损的修复有着良好的效果。但是BMSCs向成骨细胞分化并修复骨组织缺损是是由细胞外因子共同作用产生的结果。DDR2(Discoidin Domain Receptor 2)作为I型胶原的特异性受体在成骨细胞的分化中发挥重要的调节作用。而对于其在BMSCs向成骨细胞的分化过程中的所起到的作用还鲜有研究,对其作用机理尚不明确。因此我们希望通过分离、培养并鉴定比较DDR2基因缺失小鼠与野生型小鼠来源的骨髓间充质干细胞了解其生物学特性,为后续的实验奠定理论基础。方法:采用改良型的全骨髓贴壁细胞分离方法分离培养两种小鼠来源的骨髓间充质干细胞,采用流式细胞技术鉴定其表面标记物的表达,并利用诱导培养液诱导骨髓间充质干细胞向成骨细胞和成脂肪细胞分化。结果:分离培养的两种骨髓间充质干细胞形态一致,增殖能力和自我更新能力强,流式细胞术检测其表面标记物CD29,Sca-1均表达阳性,CD105,CD45表达为阴性,分离得到的两种细胞均有向成骨细胞和成脂肪细胞分化的能力,但可以明显观察到DDR2基因缺失小鼠的骨髓间充质干细胞的成骨分化能力减弱。结论:本实验通过对于DDR2基因缺失小鼠BMSCs分离、培养和鉴定,初步探索DDR2基因缺失在在成骨过程中的作用结果,为进一步研究提高BMSCs的成骨分化能力奠定理论基础。经实验证明,DDR2基因缺失小鼠来源的骨髓间充质干细胞虽然仍具备干细胞的生物学特性,但其向成骨细胞的分化能力明显减弱,说明DDR2基因缺失对其骨髓间充质干细胞的成骨分化等有着重要的影响。     

HSV-1感染大鼠骨髓间充质干细胞及形成潜伏感染的初步研究

在体外培养大鼠骨髓间充质干细胞(BMSCs),观察单纯疱疹病毒1型感染骨髓间充质干细胞情况.分离并鉴定BMSCs;HSV-1感染BMSCs,观察细胞病变(CPE);建立BMSCs的HSV-1潜伏感染模型.提取总DNA,PCR法扩增BMSCs内的HSV-1特异性片段,检测HSV-1感染BMSCs及潜伏感染.结果显示骨髓间充质干细胞经14d诱导后,碱性磷酸酶含量增高、形成钙结节,表现出成骨细胞特性.HSV-1感染BMSCs,出现典型的CPE,PCR法证实BMSCs内存在HSV-1的特异性片段.HSV-1潜伏感染的BMSCs,未出现明显的CPE,细胞传至7代,仍可测到HSV-1的基因片段,表明BMSCs有可能形成HSV-1的潜伏感染.大鼠骨髓间充质干细胞在体外可以向成骨细胞方向分化,可作为组织工程学的种子细胞.HSV-1可以在体外感染骨髓间充质干细胞并有形成潜伏感染的趋势.     

M-CSF诱导人骨髓间充质干细胞分化为肝样细胞的分子机制

本研究主要目的是明确M-CSF诱导骨髓间充质干细胞分化为肝样细胞的分子机制,为临床中的肝移植和治疗肝病提供新思路。对取自于本院骨科治疗的患者的股骨骨髓间充质干细胞进行提取、分离、传代培养及鉴定。流式细胞仪检测BMSCs的表面表型。为了诱导BMSCs的肝分化,本研究将BMSCs加入到培养基中。骨髓间充质干细胞诱导21 d后,BMSCs表达了肝细胞特异性标志物a-蛋白(AFP)和细胞角蛋白18(CK18),通过免疫荧光染色证实了分化与为分化的BMSCs表达的差异性。分化的BMSCs还显示了肝细胞的体外功能特征,包括白蛋白产生、尿素分泌和糖原储存。本研究结果表明,BMSCs在M-CSF诱导下可分化为功能性肝细胞样细胞,可作为肝病治疗的细胞来源。     

脱细胞神经移植物对骨髓间充质干细胞的诱导分化

目的探讨脱细胞神经移植物诱导大鼠骨髓间充质干细胞分化为施旺细胞样细胞的可行性。方法将分离纯化的SD大鼠骨髓间充质干细胞进行体外培养扩增,行表型鉴定后,取第5代细胞,诱导组采用脱细胞神经移植物匀浆进行诱导,非诱导组加入等量无血清培养基,倒置相差显微镜观察诱导后细胞形态变化,免疫细胞化学染色检测诱导后细胞S-100,神经胶质纤维酸性蛋白(glial fibrillary acidic protein GFAP)的表达情况。结果BMSCs表型鉴定为CD44+、CD54+、CD34-,免疫细胞化学染色GFAP、S-100的阳性表达率分别为为(42±4)%和(64±5)%。结果 脱细胞神经移植物可诱导骨髓间充质干细胞分化为施旺细胞样细胞。     

大鼠骨髓间充质干细胞诱导分化为脂肪细胞的免疫细胞化学研究

目的 探讨大鼠骨髓间充质干细胞(mesenchymal stem cells,MSC)分离、纯化和体外诱导分化为脂肪细胞。方法 用密度梯度离心结合贴壁培养、定期换液,分离纯化出生大鼠MSC,传代扩增,并用免疫细胞化学法鉴定大鼠MSC的表面抗原。含地塞米松、3-异丁基-1-甲基黄嘌呤和胰岛素的培养液诱导MSC分化后,油红O染色鉴定。结果 大鼠MSC体外扩增10代以上,稳定表达CD44、CD54、CD106。油红O染色显示诱导后,71.2％有脂滴积聚。结论 从大鼠骨髓分离、纯化、体外诱导培养MSC,可定向分化为脂肪细胞表型。     

Wistar大鼠BMSCs的分离与生物学特性分析

该文建立了一种简便、高效的Wistar大鼠骨髓间充质干细胞(bone marrow mesenchymal stem cells,BMSCs)分离方法,为研究其生物学特性奠定了基础。采用全骨髓贴壁培养与密度梯度离心结合筛选法无菌分离Wistar大鼠BMSCs,常规传代和成骨、成脂诱导后,经显微观察、细胞计数、免疫印迹、q PCR和流式细胞术检测,分析细胞形态、增殖与分化特性。结果表明,分离细胞传至3代后细胞呈漩涡状生长、形态为长梭形,细胞生长曲线呈"S"形,表面分子CD29、CD34、CD44、CD45和CD90的阳性率分别为98.21%、0.78%、91.62%、0.93%和99.27%。成脂和成骨诱导后,过氧化物酶体增殖物激活受体-γ2(PPAR-γ2)、脂蛋白脂肪酶(LPL)、骨髓基质细胞核心结合因子α1(Runx2)和骨形态发生蛋白-2(BMP-2)表达水平显著升高,细胞内分别出现了大量的红色脂滴和钙化结节。该研究运用全骨髓贴壁培养与密度梯度离心结合筛选法成功分离了BMSCs,分离细胞具有向成骨和成脂细胞分化的潜能与骨髓间充质干细胞的生物学特性。     

SD大鼠骨髓间充质干细胞分离培养及鉴定的实验研究

摘要 目的：探讨应用全骨髓贴壁法体外分离培养SD大鼠骨髓间充质干细胞（BMSCs)的可行性,研究其生物学特性,为骨组织工程提供种子细胞。方法：取SPF级5周龄健康SD大鼠2只,脱颈处死,分离双下肢股骨、胫骨,全骨髓贴壁法分离培养、纯化BMSCs;通过倒置显微镜观察原代、传代细胞生长情况、绘制生长、贴壁率曲线,研究其生物学特性;流式细胞仪检测表面标志物、诱导成成骨等方法进行鉴定。结果：应用全骨髓贴壁法可在体外分离出活性好、纯度高的BMSCs。倒置显微镜下可见原代细胞呈梭形、多角形,传代细胞形态均一呈纤维样;P3代BMSCs经流式细胞鉴定：CD44、CD90高表达,CD31、CD45低表达;定向诱导向成骨细胞分化,可见明显矿化结节。结论：证实应用全骨髓贴壁培养法体外可成功分离BMSCs,所分离培养、纯化的细胞生物学稳定,纯度高、活性好,具有多向分化潜能,能为骨组织工程、骨质疏松症和骨折不愈合疾病的研究提供种子细胞。     

Fusion of Tumour Cells with Host Cells

THE A9 cell is an 8-azaguanine-resistant derivative of the L cell line¹. It lacks the enzyme inosinic acid pyrophosphorylase and is thus unable to grow in media such as HAT² in which endogenous synthesis of nucleic acid is blocked by aminopterin. The A9 line has little ability to grow progressively in vivo. Inocula of 5 × 10⁴ to 2 × 10⁶ cells produced progressive tumours in only 12% of X-irradiated newborn syngeneic C3H mice³. One of these tumours was explanted as a cell suspension into Eagle's minimal essential medium containing 15% foetal calf serum and then subcultivated in this medium with 5% foetal calf serum. At each passage, cells were inoculated into X-irradiated newborn syngeneic C3H or semi-allogeneic C3H×X F₁ mice (X designates a number of different allogeneic parents). Between 80 and 90% of the inoculated animals developed progressive tumours. The cell line was therefore designated A9HT (high take incidence). The karyotype of the A9HT line was found to be similar to that of the A9 line, but with a slightly reduced total chromosome number. The modal chromosome number of A9HT was about 53, compared with about 57 for A9 (see ref. 4). A9 and A9HT both had between 20 and 30 bi-armed chromosomes and a number of marker chromosomes in common. A detailed comparison of the karyotypes of the two lines examined by the quinacrine fluorescence technique has been made⁵. The A9HT line, like its A9 parent, lacks inosinic acid pyrophos-phorylase and is unable to grow in HAT medium.     

肿瘤干细胞及肝癌肿瘤干细胞

肿瘤干细胞理论认为只有存在于肿瘤中的少量干细胞性质的细胞群体对肿瘤发生和发展起着决定作用,肿瘤是由干细胞突变积累而形成的无限增殖的异常组织,这一理论的提出使人们对肿瘤发生机制的认识上升到了一个新的高度,也引起了研究者的广泛关注;肝癌是我国常见的恶性肿瘤之一,我国肝癌死亡率居世界之首,目前对肝癌的研究是我国恶性肿瘤防治的重点工作,现对当前肿瘤干细胞与肝癌肿瘤干细胞相关方面的最新研究进展作一概述。     

Oocyte-like Cells Induced from Mouse Spermatogonial Stem Cells

ABSTRACT: BACKGROUND: During normal development primordial germ cells (PGCs) derived from the epiblast are the precursors of spermatogonia and oogonia. In culture, PGCs can be induced to dedifferentiate to pluripotent embryonic germ (EG) cells in the presence of various growth factors. Several recent studies have now demonstrated that spermatogonial stem cells (SSCs) can also revert back to pluripotency as embryonic stem (ES)-like cells under certain culture conditions. However, the potential dedifferentiation of SSCs into PGCs or the potential generation of oocytes from SSCs has not been demonstrated before. RESULTS: We report that mouse male SSCs can be converted into oocyte-like cells in culture. These SSCs-derived oocytes (SSC-Oocs) were similar in size to normal mouse mature oocytes. They expressed oocyte-specific markers and give rise to embryos through parthenogenesis. Interestingly, the Y- and X-linked testis-specific genes in these SSC-Oocs were significantly down-regulated or turned off, while oocyte-specific X-linked genes were activated. The gene expression profile appeared to switch to that of the oocyte across the X chromosome. Furthermore, these oocyte-like cells lost paternal imprinting but acquired maternal imprinting. CONCLUSIONS: Our data demonstrate that SSCs might maintain the potential to be reprogrammed into oocytes with corresponding epigenetic reversals. This study provides not only further evidence for the remarkable plasticity of SSCs but also a potential system for dissecting molecular and epigenetic regulations in germ cell fate determination and imprinting establishment during gametogenesis.     

IDS Transfer from Overexpressing Cells to IDS-Deficient Cells

Iduronate sulfatase (IDS) is responsible for mucopolysaccharidosis type II, a rare recessive X-linked lysosomal storage disease. The aim of this work was to test the ability of overexpressing cells to transfer IDS to deficient cells. In the first part of our work, IDS processing steps were compared in fibroblasts, COS cells, and lymphoblastoid cell lines and shown to be identical: the two precursor forms (76 and 90 kDa) were processed by a series of intermediate forms to the 55- and 45-kDa mature polypeptides. Then IDS transfer to IDS-deficient cells was tested either by incubation with cell-free medium of overexpressing cells or by coculture. Endocytosis and coculture experiments between transfected Lβ and deleted fibroblasts showed that IDS transfer occurred preferentially by cell-to-cell contact as IDS precursors are poorly secreted by transfected Lβ. The 76- and 62-kDa IDS polypeptides transferred to deleted fibroblasts were correctly processed to the mature 55- and 45-kDa forms. Lβ were not able to internalize the 90-kDa phosphorylated precursor forms excreted in large amounts in the medium of overexpressing fibroblasts. Enzyme transfer occurred only by cell-to-cell contact, but the precursor forms transferred in Lβ after cell-to-cell contact were not processed. This absence of maturation was probably due to a mistargeting of IDS precursors in these cells.     

Dendritic Cells: Migratory Cells that are Attractive

Dendritic cells (DC) are professional antigen presenting cells, playing an important role in the initiation of T- and T cell dependent immune responses. DC are highly mobile cells and the sequential migration of DC in and out of tissues is accompanied by phenotypical as well as functional changes instrumental to their function as sentinels of the immune system. Herein, we will review recent progress in understanding the origin of DC, their migratory behaviour and their capacity to attract and interact with lymphocytes, with emphasis on the chemokine system.     

Place Cells,Grid Cells,and Memory

The hippocampal system is critical for storage and retrieval of declarative memories, including memories for locations and events that take place at those locations. Spatial memories place high demands on capacity. Memories must be distinct to be recalled without interference and encoding must be fast. Recent studies have indicated that hippocampal networks allow for fast storage of large quantities of uncorrelated spatial information. The aim of the this article is to review and discuss some of this work, taking as a starting point the discovery of multiple functionally specialized cell types of the hippocampal–entorhinal circuit, such as place, grid, and border cells. We will show that grid cells provide the hippocampus with a metric, as well as a putative mechanism for decorrelation of representations, that the formation of environment-specific place maps depends on mechanisms for long-term plasticity in the hippocampus, and that long-term spatiotemporal memory storage may depend on offline consolidation processes related to sharp-wave ripple activity in the hippocampus. The multitude of representations generated through interactions between a variety of functionally specialized cell types in the entorhinal–hippocampal circuit may be at the heart of the mechanism for declarative memory formation.The scientific study of human memory started with Herman Ebbinghaus, who initiated the quantitative investigation of associative memory processes as they take place (Ebbinghaus 1885). Ebbinghaus described the conditions that influence memory formation and he determined several basic principles of encoding and recall, such as the law of frequency and the effect of time on forgetting. With Ebbinghaus, higher mental functions were brought to the laboratory. In parallel with the human learning tradition that Ebbinghaus started, a new generation of experimental psychologists described the laws of associative learning in animals. With behaviorists like Pavlov, Watson, Hull, Skinner, and Tolman, a rigorous program for identifying the laws of animal learning was initiated. By the middle of the 20th century, a language for associative learning processes had been developed, and many of the fundamental relationships between environment and behavior had been described. What was completely missing, though, was an understanding of the neural activity underlying the formation of the memory. The behaviorists had deliberately shied away from physiological explanations because of the intangible nature of neural activity at that time.Then the climate began to change. Karl Lashley had shown that lesions in the cerebral cortex had predictable effects on behavior in animals (Lashley 1929, 1950), and Donald Hebb introduced concepts and ideas to account for complex brain functions at the neural circuit level, many of which have retained a place in modern neuroscience (Hebb 1949). Both Lashley and Hebb searched for the engram, but they found no specific locus for it. A significant turning point was reached when Scoville and Milner (1957) reported severe loss of memory in an epileptic patient, patient H.M., after bilateral surgical removal of the hippocampal formation and the surrounding medial temporal lobe areas. “After operation this young man could no longer recognize the hospital staff nor find his way to the bathroom, and he seemed to recall nothing of the day-to-day events of his hospital life.” This tragic misfortune inspired decades of research on the function of the hippocampus in memory. H.M.’s memory impairment could be reproduced in memory tasks in animals and studies of H.M., as well as laboratory animals, pointed to a critical role for the hippocampus in declarative memory—memory, which, in humans, can be consciously recalled and declared, such as memories of experiences and facts (Milner et al. 1968; Mishkin 1978; Cohen and Squire 1980; Squire 1992; Corkin 2002). What was missing from these early studies, however, was a way to address the neuronal mechanisms that led information to be stored as memory.The aim of this article is to show how studies of hippocampal neuronal activity during the past few decades have brought us to a point at which a mechanistic basis of memory formation is beginning to surface. An early landmark in this series of investigations was the discovery of place cells, cells that fire selectively at one or few locations in the environment. At first, these cells seemed to be part of the animal’s instantaneous representation of location, independent of memory, but gradually, over the course of several decades, it has become clear that place cells express current as well as past and future locations. In many ways, place cells can be used as readouts of the memories that are stored in the hippocampus. More recent work has also shown that place cells are part of a wider network of spatially modulated neurons, including grid, border, and head direction cells, each with distinct roles in the representation of space and spatial memory. In this article, we shall discuss potential mechanisms by which these cell types, particularly place and grid cells, in conjunction with synaptic plasticity, may form the basis of a mammalian system for fast high-capacity declarative memory.     

体细胞重编程逆转为干细胞的研究进展

目前细胞和发育生物学上的研究成果为生物医学研究提供了广泛的前景.将完全分化的细胞重编程,不经过胚胎逆转为多能干细胞状态,这点燃了再生医学应用的新希望,这一成果从法律、道德、伦理等不同方面被人们所接受.通过体细胞克隆胚胎获得干细胞所面临的破坏胚胎的伦理限制,促使研究者去寻求将分化细胞重编程逆转为干细胞的新方法.主要论述了体细胞重编程的原理、过程及不经过胚胎逆转为多能干细胞的方法.     

Dendritic Cells and Regulatory T Cells in Atherosclerosis

Although macrophages and other immune system cells, especially T cells, have been shown to play disease-promoting roles in atherosclerosis, less is known about the role of antigen presenting cells. Functional, immune stimulating dendritic cells (DCs) have recently been detected in aortic intima, the site of origin of atherosclerosis. We had compared DCs with macrophages in mice with experimental atherosclerosis, to clearly define cell types by developmental and functional criteria. This review summarizes recent advances in studies of DCs in humans and in mouse models of atherosclerosis, as well as providing a simple strategy to measure regulatory T (Treg) cells in the mouse aorta.