人胚胎干细胞在3种培养体系中的生长

人胚胎干细胞(human embryonic stem cells.hESCs)的培养一直是干细胞研究的重要内容.用本实验室独立建系的两株hESCs,建立3种不同的培养体系:小鼠胚胎成纤维细胞(mouse embryonic fibroblasts,MEFs)做饲养层,永生化人成纤维细胞(immortalized human adult fibroblasts,HAFi)做饲养层,无饲养层条件培养基培养体系(condition medium,CM),观察在3种培养体系中,干细胞的增殖和分化情况.发现3种培养体系中的hESCs都可以表达一致的生物学特性,但也有不同之处,相对于CM干细胞在MEFs和HAFi饲养层体系的分化率低,增殖快;但MEFs来源于鼠类是异源细胞,HAFi虽不舍鼠源性成分却繁殖很慢;无饲养层的体系便于操作,无外源细胞存在.实验所得出的结果可以引导研究人员针对于临床、科研不同的需要,选择最适合的培养体系.     

胰蛋白酶消化法和组织块法原代培养人包皮成纤维细胞的比较

小鼠胚胎成纤维细胞(MEFs)是目前国际上公认的人胚胎干细胞(hESCs)体外培养的饲养层细胞,但MEFs存在寿命短、动物源性污染等问题,需要探索适于hESCs体外培养且寿命长的人源性饲养层.采用胰蛋白酶消化法和组织块法分别原代培养人包皮成纤维细胞(hFFs),探索hFFs原代培养的最佳方法,为hFFs作为饲养层在hESCs研究中的应用提供可靠的科学依据;通过倒置显微镜下观察其生长状态和免疫细胞化学染色鉴定,结果显示两种原代培养方法获得的hFFs的形态及生物学特性均符合成纤维细胞;通过测定细胞生长曲线及MTT法检测,结果显示两种原代培养方法获得的不同代数的hFFs均具有较高的增殖活性,传代10余代仍能保持较好的细胞形态,可以制备成饲养层用于hESCs的研究.     

人胚胎干细胞传代培养及细胞化学染色特性

目的 体外建立人胚胎干细胞传代培养方法,研究人胚胎干细胞细胞化学染色特性.方法 以小鼠胚胎成纤维细胞作为饲养层传代培养人胚胎干细胞,检测人胚胎干细胞、自发分化克隆及拟胚体的细胞化学染色特性.结果 人胚胎干细胞在小鼠胚胎成纤维细胞饲养层上传30代以上其形态保持不变;人胚胎十细胞碱性磷酸酶、过碘酸-雪夫反应、α-醋酸萘酚酯酶染色阳性,自发分化克隆细胞阳性程度明显减弱;人胚胎干细胞形成的拟胚体碱性磷酸酶染色弱阳性,过碘酸-雪夫反应、α-醋酸萘酚酯酶染色阳性.结论 小鼠胚胎成纤维细胞能支持人胚胎干细胞传代培养,细胞化学染色结果能初步鉴别人胚胎干细胞未分化特性.     

人胚胎干细胞的体外定向分化

人胚胎干细胞（human embryonic stem cells,hESCs）由囊胚期胚胎内细胞团分离培养获得,具有保持未分化状态的无限增殖能力。hESCs具有多向分化潜能,在体内和体外均可分化形成所有三个胚层（外胚层、中胚层、内胚层）的衍生物。hESCs一般在鼠胚胎成纤维细胞（mouse embryonic fibroblast,MEF）饲养层上培养和扩增。为了优化培养条件,目前人们已发展了多种人类细胞饲养层和无饲养层、非条件培养基体系。hESCs可以在体外定向诱导分化为多种细胞类型,为揭示人胚早期发育机制和发展多种疾病的细胞移植治疗奠定了基础。hESCs可以在体外进行遗传修饰,将有助于揭示特定基因在发育过程中的调控和功能。对hESCs的深入研究将极大地推动医学和生命科学的进展,并将最终应用于临床,造福人类。     

一种新的培养人胚胎干细胞的包被基质

目的开发一种新的培养人胚胎干细胞(hESCs)的包被基质,使hESCs的培养更加简便。方法用甲醇固定的小鼠胚胎成纤维细胞(MEF)作为包被基质,人胚胎干细胞系X-01在该基质上生长,每隔5~6 d传代一次,培养10代后,对人胚胎干细胞特性进行检测,包括细胞形态、碱性磷酸酶染色、相关多能性基因的表达和分化能力。结果 hESCs在新的基质上生长良好,经10次传代后仍能保持典型的hESCs克隆形态。碱性磷酸酶染色阳性,免疫荧光染色Oct4、SSEA4、Tra-1-60为阳性,体外分化可形成拟胚体。结论此种固定的基质可以大量制备,长期保存,并可以长期维持hESCs的未分化状态,为人胚胎干细胞的体外扩增探索出了一个新的途径。     

用饲养层分离胚胎干细胞集落的实验初探

目的 用饲养层分离胚胎干细胞集落。方法 用胚龄为13~14 d的小鼠胚胎分离原代成纤维细胞,制成饲养层,用于囊胚的培养。结果 小鼠原代胚胎成纤维细胞（PMEF）贴壁能力较好,增殖快,易铺层。囊胚和内细胞团（ICM）在饲养层上贴壁生长良好,当培养4~5 d时,其增殖率为16/28（57%）。在ICM离散48 h后,各种胚胎干细胞（ES）集落开始出现。此种集落经碱性磷酸酶染色成阳性。结论 用饲养层分离胚胎干细胞获得初步成功。     

一种新的人胚胎干细胞自身来源的滋养层支持其体外培养

摘要: 通过人胚胎干细胞(Human embryonic stem cells, hESCs)经体内分化获取间充质干细胞(Mesenchymal stem cells, MSCs)为人胚胎干细胞提供一种新的滋养层。将约5×106个hESCs注射入重症免疫联合缺陷小鼠形成畸胎瘤, 8周后再从畸胎瘤中分离MSCs并鉴定, 将MSCs作为hESCs的滋养层细胞, 并检测和观察hESCs的生长情况、细胞特性和分化能力。从畸胎瘤中获得了纯度较高的具有类似骨髓来源的MSC特性的细胞群, 其形态相似、表面抗原标志相似(CD34和CD45阴性, CD29、CD49b、CD105、CD73和CD90阳性), 经诱导可以向成骨细胞和成脂细胞分化。将hESCs在MSCs滋养层细胞上传代培养10代以上, hESCs依然具有正常的细胞形态, 反转录PCR证实其特异转录因子Oct4、Nanog的表达, 干细胞表面标记SSEA-1显示为阴性, SSEA-4、TRA-1-60、TRA-1-81显示为阳性, 碱性磷酸酶染色显示为阳性, 并且核型正常。体外EB形成和体内畸胎瘤形成证明了其全能性。因此来源于hESCs本身的MSCs可以被用来作为支持胚胎干细胞生长并维持其未分化状态的滋养层细胞。     

人脐带间充质干细胞作为维持人胚胎干细胞生长饲养层细胞的研究

目的寻找可以维持人胚胎干细胞未分化生长的人源性细胞作为饲养层细胞,从而解决使用鼠源性细胞作为饲养层带来的安全问题。方法尝试以人脐带间充质干细胞作为饲养层细胞来培养人胚胎干细胞,检验其是否可以维持人胚胎干细胞的未分化生长状态。用胶原酶消化法分离人脐带间充质干细胞,光镜下观察细胞形态;流式细胞仪检测其表面标志;诱导人脐带间充质干细胞向成骨细胞和脂肪细胞进行分化。将人胚胎干细胞系H1接种于丝裂霉素C灭活后的人脐带间充质干细胞上,每隔5d进行一次传代。培养20代后,对人胚胎干细胞特性进行相关检测,包括细胞形态、碱性磷酸酶染色、相关多能性基因的表达、分化能力。结果从人脐带中分离出的间充质干细胞为梭形,呈平行排列生长或漩涡状生长;细胞高表达CD44、CD29、CD73、CD105、CD90、CD86、CD147、CD117,不表达CD14、CD38、CD133、CD34、CD45、HLA-DR;具有分化成脂肪细胞和成骨细胞的潜能。人胚胎干细胞在人脐带间充质干细胞饲养层上培养20代后,继续保持人胚胎干细胞的典型形态,碱性磷酸酶染色为阳性,免疫荧光染色显示OCT4、Nanog、SSEA4、TRA-1-81、TRA-1-60的表达为阳性,SSEA1表达为阴性,体外悬浮培养可以形成拟胚体。结论人脐带间充质干细胞可以作为人胚胎干细胞的饲养层细胞,支持其生长,并维持其未分化生长状态。     

无饲养层培养人胚胎干细胞方法的建立

人胚胎干细胞(human embryonic stem cell,hES细胞)是当前医学研究的热点之一．然而hES细胞培养条件苛刻,通常需要采用鼠胚胎成纤维细胞(mouse embryonic fibroblast,MEFs)饲养层来维持其未分化状态,成为目前hES细胞研究的瓶颈之一、本实验成功地将hES细胞接种在细胞外基质包被的六孔板上培养,传代20次后细胞仍然保持良好的未分化状态,各种hES细胞生物学特性(如表面标志物SSEA-3、SSEA-4、TRA-1-60和TRA-1-8l,OCT-4,碱性磷酸酶及体内外分化潜能等)均无改变;其冻存、复苏效果与生长在饲养层上的hES细胞无明显差异．因此,该无饲养层培养体系可以用于培养hES细胞,并为hES细胞转基因研究及大规模培养打下良好的基础．     

鸭胚胎干细胞分离与鉴定

采用药勺法分离仙湖3号肉鸭鸭胚的胚盘细胞,并以鸭胚成纤维细胞作为饲养层,培养鸭胚胎干细胞。在此基础上,通过对体外培养的鸭胚胎干细胞形态观察,碱性磷酸酶染色(AKP)以及胚胎阶段表面特异性抗原(SSEA-1)免疫组化等方法,分离与鉴定鸭胚胎干细胞。结果表明传至第3代的鸭胚胎干细胞经AKP和SSEA-1鉴定均为阳性,AKP染色为深蓝色,SSEA-1染色呈绿色荧光,表明培养至第3代的鸭胚胎干细胞仍保持干细胞未分化特性,具有胚胎干细胞的特征。结果提示本试验分离、培养的鸭胚盘细胞为鸭胚胎干细胞。     

Factors derived from mouse embryonic stem cells promote self-renewal of goat embryonic stem-like cells

Goat embryonic stem (ES)-like cells could be isolated from primary materials-inner cell masses (ICMs) and remain undifferentiated for eight passages in a new culture system containing mouse ES cell conditioned medium (ESCCM) and on a feeder layer of mouse embryo fibroblasts (MEFs). However, when cultured in medium without mouse ESCCM, goat ES-like cells could not survive for more than three passages. In addition, no ES-like cells could be obtained when ICMs were cultured on goat embryo fibroblasts or the primary materials-whole goat blastocysts were cultured on MEFs. Goat ES-like cells isolated from ICMs had a normal karyotype and highly expressed alkaline phosphatase. Multiple differentiation potency of the ES-like cells was confirmed by differentiation into neural cells and fibroblast-like cells in vitro. These results suggest that mouse ES cells might secrete factors playing important roles in promoting goat ES-like cells' self-renewal, moreover, the feeder layers and primary materials could also influence the successful isolation of goat ES-like cells.     

SNL fibroblast feeder layers support derivation and maintenance of human induced pluripotent stem cells

Induced pluripotent stem(iPS)cells can be derived from human somatic cells by cellular reprogramming.This technology provides a potential source of non-controversial therapeutic cells for tissue repair,drug discovery,and opportunities for studying the molecular basis of human disease.Normally,mouse embryonic fibroblasts(MEFs)are used as feeder layers in the initial derivation of iPS lines.The purpose of this study was to determine whether SNL fibroblasts can be used to support the growth of human iPS cells reprogrammed from somatic cells using lentivirai expressed reprogramming factors.In our study,iPS cells expressed common pluripotency markers,displayed human embryonic stern cells(hESCs)morphology and unmethylated promoters of NANOG and OCT4.These data demonstrate that SNL feeder cells can support the derivation and maintenance of human iPS cells.     

A human endothelial cell feeder system that efficiently supports the undifferentiated growth of mouse embryonic stem cells

Feeder cells are commonly used to culture embryonic stem cells to maintain their undifferentiated and pluripotent status. Conventionally, mouse embryonic fibroblasts (MEFs), supplemented with leukemia inhibitory factor (LIF), are used as feeder cells to support the growth of mouse embryonic stem cells (mESCs) in culture. To prepare for fresh MEF feeder or for MEF-conditioned medium, sacrifice of mouse fetuses repeatedly is unavoidable in these tedious culture systems. Here we report the discovery of a human endothelial cell line (ECV-304 cell line) that efficiently supports growth of mESCs LIF-free conditions. mESCs that were successfully cultured for eight to 20 passages on ECV-304 feeders showed morphological characteristics similar to cells cultured in traditional feeder cell systems. These cells expressed the stem cell markers Oct3/4, Nanog, Sox2, and SSEA-1. Furthermore, cells cultured on the ECV-304 cell line were able to differentiate into three germ layers and were able to generate chimeric mice. Compared with traditional culture systems, there is no requirement for mouse fetuses and exogenous LIF does not need to be added to the culture system. As a stable cell line, the ECV-304 cell line efficiently replaces MEFs as an effective feeder system and allows the efficient expansion of mESCs.     

Comparative study of mouse and human feeder cells for human embryonic stem cells

Various types of feeder cells have been adopted for the culture of human embryonic stem cells (hESCs) to improve their attachment and provide them with stemness-supporting factors. However, feeder cells differ in their capacity to support the growth of undifferentiated hESCs. Here, we compared the expression and secretion of four well-established regulators of hESC pluripotency and/or differentiation among five lines of human foreskin fibroblasts and primary mouse embryonic fibroblasts throughout a standard hESC culture procedure. We found that human and mouse feeder cells secreted comparable levels of TGF beta 1. However, mouse feeder cells secreted larger quantities of activin A than human feeder cells. Conversely, FGF-2, which was produced by human feeder cells, could not be detected in culture media from mouse feeder cells. The quantity of BMP-4 was at about the level of detectability in media from all feeder cell types, although BMP-4 dimers were present in all feeder cells. Production of TGF beta 1, activin A, and FGF-2 varied considerably among the human-derived feeder cell lines. Low- and high-producing human feeder cells as well as mouse feeder cells were evaluated for their ability to support the undifferentiated growth of hESCs. We found that a significantly lower proportion of hESCs maintained on human feeder cell types expressed SSEA3, an undifferentiated cell marker. Moreover, SSEA3 expression and thus the pluripotent hESC compartment could be partially rescued by addition of activin A. Cumulatively, these results suggest that the ability of a feeder layer to promote the undifferentiated growth of hESCs is attributable to its characteristic growth factor production.     

Generation of Sheffield (Shef) human embryonic stem cell lines using a microdrop culture system

The conventional method for the derivation of human embryonic stem cells (hESCs) involves inner cell mass (ICM) co-culture with a feeder layer of inactivated mouse or human embryonic fibroblasts in an in vitro fertilisation culture dish. Growth factors potentially involved in primary derivation of hESCs may be lost or diluted in such a system. We established a microdrop method which maintained feeder cells and efficiently generated hESCs. Embryos were donated for stem cell research after fully informed patient consent. A feeder cell layer was made by incubating inactivated mouse embryonic fibroblasts (MEFs) feeder cells in a 50 μl drop of medium (DMEM/10% foetal calf serum) under mineral oil in a small tissue culture dish. MEFs formed a confluent layer and medium was replaced with human embryonic stem medium supplemented with 10% Plasmanate (Bayer) and incubated overnight. Cryopreserved embryos were thawed and cultured until the blastocyst stage and the zona pellucida removed with pronase (2 mg/ml; Calbiochem). A zona-free intact blastocyst was placed in the feeder microdrop and monitored for ES derivation with medium changed every 2-3 d. Proliferating hESCs were passaged into other feeder drops and standard feeder preparation by manual dissection until a stable cell line was established. Six hESC lines (Shef 3-8) were derived. From a total of 46 blastocysts (early to expanded), five hESC lines were generated (Shef 3-7). Shef 3-6 were generated on MEFs from 25 blastocysts. Shef7 was generated on human foetal gonadal embryonic fibroblasts from a further 21 blastocysts. From our experience, microdrop technique is more efficient than conventional method for derivation of hESCs and it is much easier to monitor early hESC derivation. The microdrop method lends itself to good manufacturing practice derivation of hESCs.     

Expansion of human embryonic stem cells in defined serum-free medium devoid of animal-derived products

Human embryonic stem cells (hESCs) can serve as an unlimited cell source for cellular transplantation and tissue engineering due to their prolonged proliferation capacity and their unique ability to differentiate into derivatives of all three-germ layers. In order to reliably and safely produce hESCs, use of reagents that are defined, qualified, and preferably derived from a non-animal source is desirable. Traditionally, mouse embryonic fibroblasts (MEFs) have been used as feeder cells to culture undifferentiated hESCs. We recently reported a scalable feeder-free culture system using medium conditioned by MEFs. The base and conditioned medium (CM) still contain unknown bovine and murine-derived components, respectively. In this study, we report the development of a hESC culture system that utilizes a commercially available serum-free medium (SFM) containing human sourced and recombinant proteins supplemented with recombinant growth factor(s) and does not require conditioning with feeder cells. In this system, which employs human laminin coated surface and high concentration of hbFGF, the hESCs maintained undifferentiated hESC morphology and had a twofold increase in expansion compared to hESCs grown in MEF-CM. The hESCs also expressed surface markers SSEA-4 and Tra-1-60 and maintained expression of hTERT, Oct4, and Cripto genes similar to cells cultured in MEF-CM. In addition, hESCs maintained in this culture system were able to differentiate in vitro and in vivo into cells of all three-germ layers. The cells maintained a normal karyotype after prolonged culture in SFM. In summary, this study demonstrates that the hESCs cultured in defined non-conditioned serum-free medium (NC-SFM) supplemented with growth factor(s) retain the characteristics and replicative potential of hESCs. The use of defined culture system with NC-SFM on human laminin simplifies scale-up and allows for reproducible generation of hESCs under defined and controlled conditions that would serve as a starting material for production of hESC derived cells for therapeutic use.