猕猴胚胎干细胞无饲养层、无血清培养及诱导分化成O2A 胶质前体细胞的研究

灵长类胚胎干细胞（ES 细胞）不仅能为研究生殖发育生物学基础理论提供良好的 模型，而且可为细胞替代治疗提供大量的供体细胞，因此具有重要的研究价值。当前 灵长类ES 细胞研究还有很多问题需要解决，如分离建立更多的胚胎干细胞系，优化培 养体系，提高ES 细胞定向分化为特定细胞的比例，研究ES 细胞自我更新和分化的机 制等。本文一方面概括了灵长类ES 细胞的研究进展，另一方面并对制备抗体，免疫外 科手术法分离灵长类胚胎内细胞团，建立猕猴ES 细胞的无饲养层、无血清培养体系和 诱导猕猴ES 细胞分化成高纯度的O2A 神经胶质前体细胞进行了研究。主要结论如下： 1）分别以猕猴脾脏淋巴细胞和人外周血单个核细胞作为免疫原，免疫日本大耳白兔， 得到免疫血清。在补体介导的细胞毒作用下，兔抗人和兔抗猕猴免疫血清可以裂解人 和猕猴囊胚滋养层细胞，从而分离出内细胞团，用于分离培养人和猕猴胚胎干细胞。2） 猕猴ES 细胞在以层粘连蛋白（laminin）为胞外基质，含转化生长因子beta1（TGFβ1） 的无血清培养基（SFM）中可以稳定的增殖至少22 代，保持不分化，并具有分化成三 个胚层细胞的能力。进一步的研究发现去除TGFβ1 后，猕猴ES 细胞出现分化，整合 素表达降低，推测TGFβ1 可能通过促进猕猴ES 细胞整合素的表达，加强其与胞外基 质的相互作用，从而维持ES 细胞的自我更新。然而猕猴ES 细胞不能在纤粘连蛋白 （fibronectin）和明胶上生长。3）无饲养层、无血清培养体系中长期培养的猕猴ES 细 胞，分化出拟胚体，14 天的拟胚体在血清中分化培养一周后，在含碱性成纤维生长因 子bFGF、表皮生长因子EGF 和胰岛素＋转铁蛋白＋亚硒酸钠ITS 的培养基中培养， 获得97％的O2A 胶质前体细胞，得到的O2A 细胞能够稳定增殖，并且可以自发分化 为II 型星型胶质细胞和少突胶质细胞。本实验的结果有助于猕猴ES 细胞分离建系和培 养系统的优化、推动猕猴ES 细胞自我更新和诱导为神经胶质细胞机制的研究，便于建 立ES 细胞替代治疗的猕猴模型，从而为人类ES 细胞的临床疾病治疗提供参考。

猕猴胚胎干细胞培养以及定向分化成神经细胞的研究

灵长类胚胎干细胞（Es）的研究不仅对理解生殖发育生物学的基础理论、而且对实现细胞替代治疗具有重要意义。当前灵长类ES细胞还有很多问题需要解决，如ES细胞培养体系的改进、ES细胞定向分化成高纯度特定组织细胞的可能性、有效性以及分化机制等问题。本文一方面概述了灵长类ES细胞相关领域的研究进展；另一方面，以称猴胚胎干细胞（rEs）为材料，在改善rES细胞的培养体系、提高其定向分化成神经前体细胞（NPs）和少突细胞的比率进行了研究。实验采用同源称猴细胞系作为饲养层培养rES细胞，并在此基础上利用肝生长因子（HGF）和GS诱导rES细胞定向分化成高纯度的NPs和少突细胞，并评价了NPs是否具有移植功能。主要结论如下：1）四种称猴细胞系（MOF、MESF、MFG和CMESF）可作为饲养层支持rES细胞的生长，保持ES自我更新的能力和分化的多能性。而且这几种称猴饲养层支持ES细胞生长的能力存在明显的差异，进一步的研究表明这些差异主要是由于基因表达种类以及表达量上的差异而导致的。2）采用HGF和GS作为诱导因子添加到NDCM液中，诱导rES细胞分化成可移植的NPs。实验结果如下：单独的HGF或GS仅能诱导ES细胞分化成65±8.3％和69±14％NPs，而HGF和GS的联合使用NPs的比率达到88.3±8.1％，进一步纯化后获得98±1.2％的NPs。获得的NPs能在体内、外分化成三个谱系神经细胞，并能整合到大鼠脑部，发生迁移和分化。25％的NPs细胞8周后仍保持存活状态，其中65-80％的细胞发生了不同程度的迁移，而且细胞在脑部的分化种类以及数目与细胞在体内所处的微环境具有重要的关系。亚克隆实验也进一步证明采用HGF＋GS获得的部分单个NPs具有神经干细胞的特性，也能在体内、外分化成三个谱系的神经细胞，而另外的却只能分化成其中的一、两种谱系的细胞。3）利用五步法，ES细胞能分化成75±6.8％的少突祖细胞和81土8．6％的成熟少突细胞。HGF通过抑制NPs的凋亡和缩短NPs的复制周期，共同促进NPs的增殖。HGF也能诱导HGF+G5获得的NPs分化成少突祖细胞和成熟少突细胞，并且促进少突细胞成熟。而且HGF促进NPs分化成少突细胞的能力受到GS的调控，单独HGF作用将导致ES细胞分化成神经元。本实验的结果为促进rES细胞相关领域的研究，以及ES细胞在神经系统疾病临床应用上提供信息，也为研究NPs和少突细胞的发育提供典型的细胞模型。

猕猴胚胎干细胞自我更新机理及WNT 信号通路在猕猴胚胎早期发育中作用的研究

尽管大部分动物实验是在啮齿类动物上开展的，我们仍然相信涉及人类的许多问题，如胚胎干细胞的体内功能、调亡和肿瘤形成等只有在非人灵长类模型上才能得到最好的回答。猕猴(标准的非人灵长类动物模型)在解剖、生理和代谢方面都和人类非常相似。人类很多神经疾病，如阿尔茨海默氏病、帕金森病，只能在非人灵长类模型上才能精确建模。所以研究猕猴胚胎干细胞自我更新的原理及猕猴胚胎早期发育，对研究免疫排斥，检测基于胚胎干细胞的治疗的可行性，安全性和有效性具有重要意义。本文一方面对胚胎干细胞维持自我更新和多潜能性的机理研究进行了综述，另一方面对以下两个方面的内容进行了研究： 1）运用寡核苷酸芯片和定量PCR 验证的方法来分析五株猕猴饲养层细胞的表达模式，期望发现在支持性和非支持性的饲养层细胞中差异性表达的基因。我们着重定位于饲养层胞外空间和细胞膜上的细胞因子，因为这些因子可以通过直接接触或通过膜结合受体激活下游信号通路，并最终促进猕猴胚胎干细胞的自我更新。我们发现在支持性的饲养层中有八个基因是高表达的，他们是GREM2， bFGF，KITLG，DKK3，GREM1，AREG，SERPINF1 和LTBP1； 经定量PCR 验证的SCF，bFGF 和GREM2 的表达情况都和芯片数据吻合。 2）为了描述在IVF (in vitro fertilized, 体外受精)，ICSI (intracytoplasmic sperm injection, 单精注射)，SCNT (somatic cell nuclear transfer, 体细胞核移植)和孤雌生殖猕猴囊胚中WNT 信号通路的表达情况，我们运用了信号通路特异性PCR Array 系统及免疫细胞化学来检测mRNA 和蛋白表达水平。其中，ICSI 作为IVF 胚胎的参照组，以排除显微操作对胚胎质量的影响。结果，我们发现非经典WNT/JNK 信号，而不是经典WNT 信号通路，在IVF 正常胚胎发育中起作用。而体细胞核移植和孤雌生殖的胚胎的WNT 信号通路基因表达明显高于正常胚胎。WNT 信号通路基因的表达模式可以作为胚胎质量的一个指示标准，有助于回答为什么猕猴 SCNT 和孤雌生殖胚胎发育异常。

猕猴胚胎干细胞的神经谱系分化及胶质祖细胞迁移机理研究

由于伦理和材料来源的限制，目前对灵长类早期神经发育缺乏深入地了解。与啮齿类动物相比，猕猴在遗传和生理上与人类更接近，因此猕猴胚胎干细胞(rESCs)研究具有重要的研究价值，不仅能为研究发育生物学基础理论提供良好的模型，而且可为细胞替代性治疗提供大量的供体细胞。本文以rESCs为主要研究对象，在rESCs定向分化为神经细胞的基础上着重研究神经谱系分化及调控胶质祖细胞迁移的机理。主要结论如下：1) rESCs来源的神经上皮干/前体细胞(NEPs)主要变为辐射状胶质细胞(RG)后再通过中间类型的祖细胞——神经元祖细胞(NPs)和胶质祖细胞(GPs)——分别分化为神经元和胶质细胞。同时，NEPs/RG细胞群具有早期神经管背-腹和前-后轴空间特性。NEPs/RG的维持受Notch和FGFR信号作用。此外，实验中还纯化和鉴定了猕猴胶质限定性前体细胞(GRPs)。结果表明，rESCs的神经谱系分化能够模拟体内发育过程，并与啮齿类动物早期神经谱系变化过程相似。2) 气体信号分子NO(由10μM—250μM SNP供体释放)促进rESCs来源的A2B5+/Nestin/PSA-NCAM胶质祖细胞迁移。进一步研究发现Netrin-DCC信号通路介导了NO启动的细胞迁移过程。同时，Ca2也参与调控胶质祖细胞的迁移。此外，细胞外基质和整合素α6亦可能与Netrin-DCC相互作用调控细胞迁移。结果显示，NO通过激活一个复杂的信号网络系统调控胶质祖细胞迁移。本实验的研究结果有助于揭示灵长类中枢神经系统发育的机理，同时也能为治疗神经系统退行性疾病提供阶段特异性的供体细胞。

猕猴胚胎干细胞无饲养层培养体系的建立

与啮齿类动物相比，猕猴（Macaca mulatta）在遗传和生理上与人类更接近， 因此猕猴胚胎干细胞具有重要的研究价值，不仅是研究发育生物学基础理论的良 好材料，而且可为细胞替代性治疗提供很好的同种异体移植模型。猕猴胚胎干细 胞常规培养于小鼠胚胎成纤维细胞（mouse embryonic fibroblast, MEF）上，这极 大地限制了对猕猴胚胎干细胞的研究和应用，因此，需要建立猕猴胚胎干细胞的 无饲养层培养体系。 本文以猕猴胚胎干细胞系IVF3.2（本实验室自主分离建系，来源于猕猴体 外受精胚胎）为研究对象，研究了在以Matrigel (growth factor reduced, BD)作为 胞外基质，以MEF 条件培养基为培养基，以trypsin 消化传代的无饲养层培养体 系中，猕猴胚胎干细胞的生长及分化能力，并比较了猕猴胚胎干细胞IVF3.2 在 无饲养层和有饲养层两种不同培养条件下的细胞周期分布及冻存复苏效率。主要 结论如下：1）经过鉴定，在本研究建立的无饲养层培养体系中，猕猴胚胎干细 胞IVF3.2 能够保持胚胎干细胞的两个基本特征，即分化的多能性和自我更新的 无限增殖能力；2）两种培养体系下的IVF3.2 的细胞周期分布没有显著差异，均 具有胚胎干细胞独特的细胞周期结构之一，即大部分细胞处于S 期（>50%的细 胞）；3）无饲养层培养的IVF3.2 冻存后能高效复苏，采用常规慢速冷冻法冻存 无饲养层培养的IVF3.2，复苏后的细胞存活率高达83%，明显高于常规培养的 IVF3.2 的冻存效率。

Co-expression of CD173 (H2) and CD174 (Lewis Y) with CD44 suggests that fucosylated histo-blood group antigens are markers of breast cancer-initiating cells

Histo-blood group antigens CD173 (H2) and CD174 (Lewis Y) are known to be developmentally regulated carbohydrate antigens which are expressed to a varying degree on many human carcinomas. We hypothesized that they might represent markers of cancer-initiating cells (or cancer stem cells, CSC). In order to test this hypothesis, we examined the co-expression of CD173 and CD174 with stem cell markers CD44 and CD133 by flow cytometry analysis, immunocytochemistry, and immunohistochemistry on cell lines and tissue sections from breast cancer. In three breast cancer cell lines, the percentage of CD173(+)/CD44(+) cells ranged from 17% to > 60% and of CD174(+)/CD44(+) from 21% to 57%. In breast cancer tissue sections from 15 patients, up to 50% of tumor cells simultaneously expressed CD173, CD174, and CD44 antigens. Co-expression of CD173 and CD174 with CD133 was also observed, but to a lesser percentage. Co-immunoprecipitation and sandwich ELISA experiments on breast cancer cell lines suggested that CD173 and CD174 are carried on the CD44 molecule. The results show that in these tissues CD173 (H2) and CD174 (LeY) are associated with CD44 expression, suggesting that these carbohydrate antigens are markers of cancer-initiating cells or of early progenitors of breast carcinomas.

Species Variation in the Mechanisms of Mesenchymal Stem Cell-Mediated Immunosuppression

Bone marrow-derived mesenchymal stem cells (MSCs) hold great promise for treating immune disorders because of their immunoregulatory capacity, but the mechanism remains controversial. As we show here, the mechanism of MSC-mediated immunosuppression varies

A comparative approach to somatic cell nuclear transfer in the rhesus monkey

BACKGROUND: Despite the potential utility of primate somatic cell nuclear transfer (SCNT) to biomedical research and to the production of autologous embryonic stem (ES) cells for cell- or tissue-based therapy, a reliable method for SCNT is not yet availab

The innate immune response to grass carp hemorrhagic virus (GCHV) in cultured Carassius auratus blastulae (CAB) cells

Virus infection of mammalian cells activates an innate antiviral immune response characterized by production of interferon (IFN) and the subsequent transcriptional upregulation of IFN-stimulated genes (ISGs) by the JAK-STAT signaling pathway. Here, we report that a fish cell line, crucian carp (Carassius auratus L.) blastulae embryonic (CAB) cells, can produce IFN activity and then form an antiviral state after infection with UV-inactivated grass carp hemorrhagic virus (GCHV), a double-stranded (ds) RNA virus. From UV-inactivated GCHV-infected CAB cells, 15 pivotal genes were cloned and sequenced, and all of them were shown to be involved in IFN antiviral innate immune response. These IFN system genes include the dsRNA signal sensing factor TLR3, IFN, IFN signal transduction factor STAT1, IFN regulatory factor IRF7, putative IFN antiviral effectors Mx1, Mx2, PKR-like, Viperin, IFI56, and other IFN stimulated genes (ISGs) IFI58, ISG15-1, ISG15-2, USP18, Gig1 and Gig2. The identified fish IFN system genes were highly induced by active GCHV, UV-inactivated GCHV, CAB IFN or poly(I).poly(C), and showed similar expression patterns to mammals. The data indicate that an IFN antiviral innate immune response similar to that in mammals exists in the UV-inactivated GCHV-infected CAB cells, and the IFN response contributes to the formation of an antiviral state probably through JAK-STAT signaling pathway. This study provides strong evidence for existence of IFN antiviral innate immune response in fish, and will assist in elucidating the origin and evolution of vertebrate IFN system. (c) 2006 Elsevier Ltd. All rights reserved.

Identification of two novel interferon-stimulated genes from cultured CAB cells induced by UV-inactivated grass carp hemorrhage virus

Interferon (IFN) exerts its antiviral effect by inducing the expression of a number of IFN-stimulated genes (ISGs) to establish a host antiviral state. Earlier studies identified some important fish IFN system genes from IFN-induced CAB cells (crucian carp Carassius auratus L. embryonic blastulae cells) after treatment with UV-inactivated GCHV (grass carp hemorrhage virus). Herein, the cloning of 2 novel IFN-stimulated genes, termed Gig1 and Gig2, is described for the same cell system. The complete cDNA sequences of Gig1 and Gig2 contain 1244 bp encoding for a 194-amino-acid protein and 693 bp for a 158-amino-acid protein, respectively. A search of public databases revealed that these are 2 novel IFN-stimulated genes, since neither significant homologous genes nor conserved motifs were identified. Active GCHV, UV-inactivated GCHV and CAB IFN-containing supernatant (ICS) induced transcription of these genes and distinct kinetics were observed. An analysis of differences in expression between the 2 genes and the IFN signal factors CaSTAT1 and CaIRF7 indicated that GCHV infection activated different signal pathways for their up-regulation. Upon virus infection, the transcription of Gig1 but not of Gig2 is strongly suppressed by cycloheximide (CHX). In contrast, following treatment with CAB IFN-containing supernatant, CHX does not inhibit either gene transcription. The results suggest that GCHV infection can induce expression of both Gig1 and Gig2 via newly synthesized CAB IFN, most probably through the JAK-STAT signal pathway, and can also directly activate Gig2 transcription without ongoing protein synthesis.

Molecular characterization and IFN signal pathway analysis of Carassius auratus CaSTAT1 identified from the cultured cells in response to virus infection

Type I interferon (IFN) exerts its pleiotropic effects mainly through the JAK-STAT signaling pathway, which is presently best described in mammals. By subtractive suppression hybridization, two fish signaling factors, JAK1 and STAT1, had been identified in the IFN-induced crucian carp Carassius auratus L. blastulae embryonic (CAB) cells after treatment with UV-inactivated grass carp hemorrhagic virus (GCHV). Further, the full-length cDNA of STAT1, termed CaSTAT1, was obtained. It contains 2926 bp and encodes a protein of 718 aa. CaSTAT1 is most similar to rat STAT1 with 59% identity overall and displays all highly conserved domains that the STAT family possesses. Like human STAT1beta, it lacks the C-terminus acting as transcriptional activation domain in mammals. By contrast, only a single transcript was detected in virus-induced CAB cells. Expression analysis showed that CaSTAT1 could be activated by stimulation of CAB cells with poly I:C, active GCHV, UV-inactivated GCHV or CAB IFN, and displayed diverse expression patterns similar to that of mammalian STATI. Additionally, the expression of an antiviral gene CaMx1 was also induced under the same conditions, and expression difference between CaSTAT1 and CaMx1 was revealed by induction of CAB IFN. These results provide molecular evidence supporting the notion that the fish IFN signaling transduction pathway is similar to that in mammals. Fish IFN exerts its multiple functions, at least antiviral action, through a JAK-STAT pathway. (C) 2004 Elsevier Ltd. All rights reserved.

Cationic Lipid Bilayer Coated Gold Nanoparticles-mediated Transfection of Mammalian Cells

Here, we demonstrated dimethyldioctadecylammonium bromide (DODAB), a cationic lipid, bilayer coated Au nanoparticles (AuNPs) could efficiently deliver two types of plasmid DNA into human embryonic kidney cells (HEK 293) in the presence of serum. The transfection efficiency of AuNPs was about five times higher than that of DODAB. The interaction of AuNPs with DNA was characterized with dye intercalation assay and agarose gel electrophoresis. The morphology of the complex of AuNPs with DNA was observed with scanning electron microscope (SEM). The intracellular trafficking of the complex was monitored with transmission electron microscope (TEM).