通过形成类胚体诱导人羊水多能干细胞向心肌细胞分化

由人羊水中分离羊水多能性干细胞,通过形成类胚体诱导其向心肌细胞分化.取人羊水标本进行体外培养,分离得到人羊水干细胞,已连续传代培养至42代,采用免疫细胞化学、RT-PCR和流式细胞仪技术对羊水干细胞的生物学特性进行检测.取10～15代羊水干细胞,悬浮培养使其形成类胚体,进而向心肌细胞诱导分化.培养的羊水干细胞呈成纤维样,表达部分胚胎干细胞特异标志基因,悬浮培养可形成类胚体.类胚体碱性磷酸酶(AP)检测呈阳性,表达三胚层特异标志基因fgf5、ζ-globin和α-fetoprotein.羊水干细胞形成类胚体后进行诱导,得到α-actin阳性细胞,表达心肌细胞特异标志基因Tbx5、Nkx2.5、GATA4和α-MHC.试验结果表明,从人羊水标本中可分离得到具有胚胎干细胞特性的细胞,经初步检测确定为羊水干细胞,并能通过形成类胚体诱导其向心肌细胞分化.     

骨髓基质干细胞向心肌细胞诱导分化的实验研究

目的探讨大鼠骨髓基质干细胞在体外和体内向心肌细胞诱导分化的能力,为下一步的细胞移植治疗心肌梗死提供实验基础.方法体外诱导实验中,将不同浓度的5-氮胞苷作用于不同培养时间的骨髓基质干细胞,摸索5-氮胞苷的最佳诱导时机和浓度,观察诱导后细胞形态变化,并用免疫细胞化学染色检测心肌特异性肌钙蛋白T的表达;在体内实验中,培养扩增的骨髓基质干细胞经BrdU标记后,自体移植于正常心肌内,分别通过BrdU和心肌特异性肌钙蛋白T免疫组织化学染色检测移植细胞的存活和分化情况.结果体外诱导实验中,5-氮胞苷的诱导作用以10μmol/L的浓度对传代细胞进行两次诱导,效果最好,不仅能诱导出表达心肌特异蛋白的心肌样细胞,而且这些细胞在体外能够自发搏动.体内诱导实验中,移植的细胞在正常心肌微环境中能够存活并分化为心肌细胞.结论骨髓基质干细胞在体外化学诱导和体内心肌微环境诱导时均能分化为心肌细胞,可用于细胞移植治疗心肌梗死的实验.     

诱导人脐带间充质干细胞向心肌细胞分化及对小鼠心肌梗死的治疗作用

目的研究脐带间充质干细胞(UC-MSC)体外分化为心肌细胞的可行性以及观察UC-MSC体内移植对心肌梗死模型小鼠的治疗效果。方法 10μmol/L 5-氮胞苷(5-aza)体外诱导UC-MSC 14 d,通过RT-PCR、免疫荧光染色鉴定其分化效果;采用腹腔注射盐酸异丙肾上腺素(ISO)每只3.0 mg/(kg/d),制作心肌梗死模型鼠;在注射ISO 48 h后,实验组将DAPI标记的UC-MSC经两次尾静脉移植给心肌梗死模型鼠,移植后第4周和第8周,分别采集实验小鼠的心脏、脾脏,以未移植细胞组的小鼠心肌损伤模型作为对照,通过心脏指数和脾脏指数测量,免疫荧光和碱性复红-苦味酸(HBFP)染色鉴定其体内分化和修复作用。结果 RT-PCR分析表明诱导的UC-MSC表达心肌特异性基因:心肌α-actin、TBX5、GATA4和NKx2.5,免疫荧光染色显示诱导细胞呈心肌α-actin和NKx2.5阳性,且呈双核现象。尾静脉移植后第4周和第8周,模型受体鼠心脏均发现有DAPI阳性细胞迁移至心肌组织且呈现心肌α-actin阳性,HBFP染色及心脏和脾脏指数结果显示移植UC-MSC对心肌损伤的模型鼠有明显的修复和治疗效果。结论 UC-MSC在体外经5-aza诱导可定向分化为心肌细胞,尾静脉体内移植UC-MSC对心肌损伤小鼠有明显的治疗效果。     

骨髓基质干细胞向心肌样细胞分化的实验研究

目的探讨大鼠骨髓基质干细胞向心肌样细胞分化后超微结构和细胞因子表达的变化,为下一步细胞移植治疗扩张型心肌病提供理论依据。方法在体外扩增、定向诱导骨髓基质干细胞向心肌样细胞分化的基础上,电镜下观察骨髓基质干细胞诱导前后超微结构的改变,RT-PCR检测心肌特异性因子ANP、BNP、α-MHC、β-MHC的表达,并与原代培养的心肌细胞比较,观察二者之间的生物学异同。结果免疫组化法证实诱导后的骨髓基质干细胞向心肌样细胞分化,电镜下胞浆内可见糖原颗粒,肌原纤维排列与原代培养的心肌细胞相似;RT-PCR证实诱导后的骨髓基质干细胞表达心肌特异性因子ANP、BNP、α-MHC、β-MHC。结论骨髓基质干细胞经5-氮胞苷定向诱导后在超微结构和细胞因子的表达上类似于心肌细胞,已向心肌样细胞分化。     

脂肪干细胞与间充质干细胞体外诱导分化为心肌细胞的差别

本文旨在探讨脂肪干细胞(adipose-derived stem cells, ASCs)和骨髓间充质干细胞(mesenchymal stem cells, MSCs)在组织含量、体外培养和诱导分化为心肌细胞方面的差别.ASCs从新西兰白兔皮下脂肪组织提取,MSCs从大鼠四肢长骨骨髓提取,体外培养扩增,免疫细胞学方法鉴定.采用细胞集落形成法检测组织中干细胞的含量.将不同代的干细胞用不同浓度的5-氮胞苷诱导,观察其形态变化,免疫细胞化学方法检测诱导后细胞是否转化为心肌细胞.结果显示,体外培养的ASCs呈短梭形,分布均匀,生长迅速,细胞形态单一、稳定.MSCs原代生长非常缓慢,呈簇生长,细胞纯度偏低,容易混杂其它细胞类型,传代细胞容易分化和老化.脂肪组织中ASCs含量显著高于骨髓中MSCs含量,且前者含量受年龄影响小.5-氮胞苷诱导ASCs分化为心肌细胞的有效浓度为6～9μmol/L,而MSCs在3～15μmol/L 5-氮胞苷诱导下可见心肌细胞形成.ASCs诱导分化的心肌细胞呈球形细胞团,MSCs分化的心肌细胞呈条形或棒状,其心肌细胞分化率低于ASCs.幼年动物MSCs的组织含量和心肌细胞分化率均高于老年动物,而ASCs受动物年龄影响较小.结果表明,ASCs在组织含量、细胞纯度、生长速度和心肌细胞分化率等方面均明显优于骨髓MSCs,在心肌细胞再生方面较MSCs具有更大的优势.     

抑制NHE1活性对干细胞向心肌分化的影响

Na /H 交换蛋白1(NHE1)在心肌细胞发育过程中发挥重要的调节功能.为深入探索NHEl活性对干细胞向心肌分化过程中产生的影响,采用二甲基亚砜(DMSO)诱导P19干细胞向心肌细胞分化,同时在培养液中添加NHE1抑制荆EMD87580,对诱导后形成的类胚体进行检测.通过细胞形态观察、免疫组织化学染色及检测心肌特异表达基因等方法证明,经诱导形成的类胚体贴壁生长后,会向心肌细胞分化并出现跳动细胞团.而经过抑制剂处理的P19干细胞尽管能够形成类胚体且贴壁培养后细胞仍具有增殖活力,细胞团周边也较整齐,但未出现向心肌细胞分化的现象.这一结果表明,抑制NHE1的活性,能够影响P19干细胞向心肌细胞的分化作用.     

人胚胎干细胞向心肌细胞定向诱导分化

最近已有多种方案用于人胚胎干细胞向心肌细胞分化,但是分化效率相对较低。因此,有必要研究更恰当的分化方法,来加强心肌细胞分化,从而产生满足细胞移植治疗需要的大量细胞。本研究表明,早期拟胚体形成阶段使用含血清培养基对人胚胎干细胞向心肌分化具有至关重要的作用。在EB形成阶段的第5-7天,加入维生素C、二甲基亚砜和5-氮杂2′-脱氧胞苷处理,能够促进具有自发节律性收缩的心肌细胞的分化。用0.1mmol／L AA,特别是与5-aza-dC联合能诱导分化更多的搏动心肌细胞。大部分自发节律收缩的细胞团的收缩频率与成人心脏搏动频率一致,并持续至194天。     

定向诱导小鼠ES细胞向心肌细胞的分化

为了提高体外诱导ES细胞向心肌细胞分化的效率 ,对以往的诱导方法加以改进 ,采用直接悬浮培养和 0 8%DMSO诱导 ,建立了简便、高效的定向诱导ES细胞向心肌细胞分化的体系 .诱导第 9d起可见自发性、有节律跳动的类胚体出现 ,第 14d达到高峰 ,约有 70 %的拟胚体产生跳动 .用RT PCR的方法在跳动的拟胚体中检测到心肌细胞特异性标志物的表达 ,采用免疫荧光染色的方法在蛋白水平检测到心肌特异的α辅肌动蛋白 (α actinin)的表达 ,并可见清晰肌小节 ,表明在改进的体外诱导条件下ES细胞可分化为成熟的心肌细胞 .     

血管紧张素Ⅱ在胚胎干细胞向心肌细胞分化中的作用

为检测血管紧张素Ⅱ（angiotensin Ⅱ,AⅡ）对小鼠胚胎干细胞（embryonic stem cells,ESCs）向心肌细胞方向分化的作用,采用10-4 mol/L维生素C诱导小鼠R1胚胎干细胞分化为心肌细胞. Western印记检测胚胎干细胞诱导分化的心肌细胞中表达血管紧张素Ⅱ1 型受体(angiotensin Ⅱ type 1 receptor,AT1R).诱导分化期间用1 μmol/L AⅡ刺激胚胎干细胞,计数搏动拟胚体的比例;诱导分化第14 d用real-time RT-PCR 和Western 印记检测心肌标志物的表达确定其作用. 结果显示,与对照组相比,1 μmol/L AⅡ处理组可显著增加搏动拟胚体的比例,上调心肌标志物mRNA的表达. 预先用1 μmol/L洛沙坦处理1 h后可显著阻碍这种上调作用. 本实验结果表明,AⅡ通过AT1R可促进小鼠R1胚胎干细胞向心肌细胞分化.     

体外化学诱导人骨髓间充质干细胞分化为心肌样细胞

为了探讨人骨髓间充质干细胞(MSCs)的体外培养及化学诱导向心肌细胞分化的过程及条件,我们用1.073g/mL密度梯度离心法分离健康人骨髓单个核细胞,经骨髓间充质干细胞培养基传代培养后用流式细胞仪检测细胞表面抗原,在完全培养基中分别加入3、5、10μmol/L的5氮胞苷(每组n=5)进行化学诱导分化,阴性对照组采用完全培养基培养,诱导后21天细胞爬片免疫荧光法鉴定,透射电镜观察细胞超微结构。结果显示人MSCs为形态均一的梭形细胞,生长旺盛时呈旋涡样分布,流式细胞仪检测细胞表面CD44阳性,CD34、CD45阴性;5、10μmol/L的5氮胞苷进行化学诱导后细胞形态变长,诱导后14天时20%-30%细胞融合形成多核肌管样结构,3μmol/L组MSCs未出现肌管结构,诱导后21天5、10μmol/L组MSCs中desmin、心肌早期转录因子GATA4、心肌特异性cTnI及闰盘蛋白connexin43的表达阳性,10μmol/L组cTnI阳性染色细胞数目(65.3±4.7%)高于5μmol/L诱导组(48.2±5.4%)(p<0.05);3μmol/L组及阴性对照组无心肌特异性蛋白的表达。细胞诱导后28天透射电镜下可见肌丝形成。本实验说明,人MSCs在体外经化学诱导可分化为心肌样细胞,而且5-氮胞苷对于心肌相关蛋白的表达呈浓度依赖性正相关。     

Isolation of U1-snRNP(s) from mouse teratocarcinoma cells using immunochemical and biochemical procedures: high proportion of U1a-snRNP to U1b-snRNP

An attempt was made to immunochemically and biochemically purify and characterize the U1-snRNP(s) of mouse embryonal carcinoma cells. The results obtained by RNA analysis of U1-snRNP(s) purified immunochemically from embryoid bodies, F9 cells and PYS-2 cells indicated that the U1-snRNP(s) in these cells consisted of U1a-snRNP and U1b-snRNP. The proportion of U1a-snRNP to U1b-snRNP was also found to be high in the embryoid bodies and F9 cells. The U1a-snRNP predominance in U1-snRNP population was also detected in PYS-2 cells. The immunochemically purified U1-snRNP population from liver nuclei of 129 syngeneic male mouse (129/sv), a host mouse for transplantable tetratocarcinoma OTT6050, and ICR male mouse, contained approximately equal levels of the two U1-snRNP species (U1a- and U1b-snRNP). Partially purified U1-snRNP from embryoid bodies was also obtained by elution from a DEAE-Sepharose column at around 0.18 M NH4Cl or by fractionation by 5-20% linear sucrose gradient centrifugation. The electrophoretic RNA profiles of the partially purified U1-snRNP of embryoid bodies were similar to those obtained immunochemically.     

Influence of regulatory genes of type 1 human immunodeficiency virus on proliferation and differentiation of murine embryonic stem cells

Spontaneous formation of embryoid bodies and subsequent differentiation of some cells into cardiomyocytes were demonstrated on murine embryonic stem cells of R1 line. The lines of embryonic stem cells were obtained that had been transfected with genetic constructs carrying expressing regulatory genes of the human immunodeficiency virus tat and nef and "green protein" gene (GFP). The transfection of embryonic stem cells with the gene tat stimulated their proliferative activity, while this activity decreased in the cells transfected with the gene nef. The time necessary for the formation of embryoid bodies by all lines of transfected cells was similar to that in the control cells. In the cultures of cells transfected with nef and tat, the number of embryoid bodies and the percentage of embryoid bodies with contracting cardiomyocytes were higher and lower than in the control, respectively. Thus, an inverse correlation was observed between the effects of regulatory genes of the human immunodeficiency virus on proliferation and differentiation embryonic stem cells.     

Induction of the expression of retinol-binding protein and transthyretin in F9 embryonal carcinoma cells differentiated to embryoid bodies

Studies were conducted to determine if the expression of the gene for retinol-binding protein (RBP) and/or transthyretin (TTR) could be induced upon differentiation of F9 teratocarcinoma cells to either visceral endoderm or parietal endoderm. Both TTR mRNA and RBP mRNA were undetectable in the undifferentiated F9 stem cells and in F9 cells differentiated to parietal endoderm. However, TTR mRNA and RBP mRNA were both detected in F9 cell aggregates differentiated to embryoid bodies (which contain visceral endoderm-like cells) by treatment of the aggregates in suspension with retinoic acid. TTR mRNA was observed at 3 days, and RBP mRNA at 5 days, after treatment of the F9 cell aggregates with retinoic acid. Both TTR mRNA and RBP mRNA were found to be specifically localized by in situ hybridization in the outer layer of cells (the visceral endoderm-like cells) of the embryoid bodies. Finally, synthesis and secretion of both RBP and TTR by F9 cell embryoid bodies was demonstrated by specific immunoprecipitation of each newly synthesized protein from the culture medium. These data thus demonstrate the production and presence of RBP mRNA and TTR mRNA, and the synthesis and secretion of RBP and TTR, by F9 cell embryoid bodies (specifically by visceral endoderm-like cells). This finding suggests that these two proteins may be synthesized by rodent embryos extremely early in embryonic development.     

Use of developmental marker genes to define temporal and spatial patterns of differentiation during embryoid body formation.

Mouse embryonic stem cells are pluripotent cells that are derived from the inner cell mass of blastocysts. When induced to synchronously enter a program of differentiation in vitro, they form embryoid bodies that contain cells of the mesodermal, hematopoietic, endothelial, muscle, and neuronal lineages. Here, we used a panel of marker genes with early expression within the germ layers (oct-3, Brachyury T, Fgf-5, nodal, and GATA-4) or a variety of lineages (flk-1, Nkx-2.5, EKLF, and Msx3) to determine how progressive differentiation of embryoid bodies in culture correlated with early postimplantation development of mouse embryos. Using RNA in situ hybridization, we found that the temporal and spatial relationships existing between these marker genes in vivo were maintained also in vitro. Studying the onset of marker gene expression allowed us also to determine the time course of differentiation during the formation of embryoid bodies. Thus, stages equivalent to embryogenesis between implantation and the beginning of gastrulation (4.5-6.5 d.p.c.) occur within the first two days of embryoid body differentiation. Between days 3 and 5, embryoid bodies contain cell lineages found in embryos during gastrulation at 6.5 to 7.0 d.p.c., and after day 6 in culture, embryoid bodies are equivalent to early organogenesis-stage embryos (7.5 d.p.c.). In addition, we demonstrate that the panel of developmental markers can be applied in a screen for stage- or lineage-specific genes. Reporter gene expression from entrapment vector insertions can be co-localized with expression of specific markers within the same cell during embryoid body formation as well as during embryogenesis. Our results thus demonstrate the power of embryoid body formation as an in vitro model system to study early lineage determination and organogenesis in mammals, and indicate that they will prove to be useful tools for identifying developmental genes whose expression is restricted to particular lineages.     

Cell autonomous sorting and surface positioning in the formation of primitive endoderm in embryoid bodies

The differentiation and formation of the primitive endoderm in early embryos can be mimicked in vitro by the aggregation of embryonic stem cells to form embryoid bodies. We present morphological evidence that primitive endoderm cells often first locate in the interior of embryoid bodies and subsequently migrate to the surface. Cell mixing experiments indicate that surface positioning is an intrinsic property of endoderm epithelial cells. Moreover, Disabled-2 (Dab2) is required for surface sorting and positioning of the endoderm cells: when Dab2 expression was eliminated, the differentiated endoderm epithelial cells distributed throughout the interior of the embryoid bodies. Surprisingly, E-cadherin is dispensable for primitive endoderm differentiation and surface sorting in embryoid bodies. These results support the model that primitive endoderm cells first emerge in the interior of the inner cell mass and are subsequently sorted to the surface to form the primitive endoderm.     

X-chromosome inactivation in differentiating mouse embryonic stem cells carrying X-linked GFP and lacZ transgenes

Three new female ES cell lines (GLM1, GLP1 and GLP2) were established from mouse embryos carrying GFP (green fluorescent protein) and HMG-lacZ transgenes on one of two X chromosomes in cis. Using these cell lines, we studied the temporal relationships among three events relevant to X-chromosome inactivation: replication asynchrony of the X chromosome, and quenching of GFP fluorescence and beta-galactosidase (beta-gal) activity, during cell differentiation induced by embryoid body (EB) formation and retinoic acid (RA) treatment. In embryoid bodies adhering to the bottom of culture dishes, GFP-negative cells appeared first in the peripheral outgrowths 4 days after the initiation of EB formation, followed about 24 hours later by the appearance of cells negative for beta-gal and those having a single allocyclic X chromosome. Although the frequency of cells with an allocyclic X chromosome could reach 80% in adherent embryoid bodies, it tended to remain low and variable in embryoid bodies maintained in suspension. In spite of apparently parallel extinction of GFP and lacZ in embryoid bodies, their concurrent occurrence did not always characterize RA-induced differentiation. Moreover, an allocyclic X chromosome was identified in not more than 20 percent of informative metaphase cells up to 10 days after initiation of RA treatment. These findings suggest that RA-induced differentiation of female ES cells does not always accompany X-inactivation.     

THE PROCESS OF DIFFERENTIATION OF EMBRYOID BODIES IN THE LUNG OF SYNGENEIC MICE

The process of differentiation of embryoid bodies of mouse teratocarcinoma OTT6050 transplanted into the lung of syngeneic mice (129/Sv) is described. Embryoid bodies took more than 2 weeks to differentiate, and several kinds of differentiated tissues appeared often in the colonies derived from a single embryoid body. All the colonies with differentiated tissues were larger than 100μm in diameter.
Three steps on the differentiation of embryoid bodies can be distinguished by microscopic observations on histological preparations of tumors at different periods after injection. The first step is the deformation of the embryoid bodies and the disappearance of the outer endodermal cells, which occurs within a few days after injection. In the second step, which begins 5–7 days after injection, clusters of embryonal carcinoma cells in the colony are identified by the PAS reaction. The third step starts about 10 days after injection, and is characterized by the formation of tubular structures in some clusters.