A novel feeder-free system for human embryonic stem cells and characterization of their sublines with autogenic and allogenic cultivation

We developed a feeder-free system for human embryonic stem cells (ESCs) based on extracellular matrix protein (ECM) as the substrate. ECM was synthesized by mesenchymal stem cells (SC5-MSC) derived from an original ESC line, SC5. The ECM proteins fibronectin and laminin facilitate ESC growth in the feeder-free system. An important component of this system is a conditioned medium from SC5-MSC cells. Two ESC sublines were obtained: SC5-FF cells were cultured in an autogenic, and SC7-FF in an allogenic, feeder-free system. SC5-FF and SC7-FF underwent more than 300 and 115 population doublings, respectively, and retain a normal diploid karyotype. Histochemical and immunofluorescence assays showed that both sublines express undifferentiated ESC markers—alkaline phosphatase, Oct-4, SSEA-4, and TRA-1-81—as well as multidrug resistance transporter ABCG2. PCR assay revealed that undifferentiated SC5-FF cells, like the original SC5 line, maintained on feeder cells express OCT4 and NANOG genes common for somatic cells and DPPA3/STELLA and DAZL genes common for germ line cells. Expression of these genes was gradually diminished during differentiation of embryoid bodies, whereas expression of genes specific for early differentiated cells increased: GATA4, AFP (extraembryonic and embryonic endoderm), PAX6 (neuroectoderm), and BRY (mesoderm). ESC properties (karyotype structure, average time of population doubling, undifferentiated cell number in population) of the SC5 and SC7 and SC5-FF and SC7-FF sublines derived from original ESCs were not altered. It shows that the feeder-free systems, which are more stable than any feeder systems, maintain key ESC properties and may be recommended for fundamental, biomedical, and pharmacological studies performed with human ESCs.     

Attachment and growth of human embryonic stem cells on microcarriers

The use of human embryonic stem cells (hESCs) for cell-based therapies will require large quantities of genetically stable pluripotent cells and their differentiated progeny. Traditional hESC propagation entails adherent culture and is sensitive to enzymatic dissociation. These constraints hamper modifying method from 2-dimensional flat-bed culture, which is expensive and impractical for bulk cell production. Large-scale culture for clinical use will require innovations such as suspension culture for bioprocessing. Here we describe the attachment and growth kinetics of both murine embryonic stem cells (mESCs) and hESCs on trimethyl ammonium-coated polystyrene microcarriers for feeder-free, 3-dimensional suspension culture. mESCs adhered and expanded according to standard growth kinetics. For hESC studies, we tested aggregate (collagenase-dissociated) and single-cell (TrypLE-dissociated) culture. Cells attached rapidly to beads followed by proliferation. Single-cell cultures expanded 3-fold over approximately 5 days, slightly exceeding that of hESC aggregates. Importantly, single-cell cultures were maintained through 6 passages with a 14-fold increase in cell number while still expressing the undifferentiated markers Oct-4 and Tra 1-81. Finally, hESCs retained their capacity to differentiate towards pancreatic, neuronal, and cardiomyocyte lineages. Our studies provide proof-of-principle of suspension-based expansion of hESCs on microcarriers, as a novel, economical and practical feeder-free means of bulk hESC production.     

Deciphering the Importance of Three Key Media Components in Human Embryonic Stem Cell Cultures

Development of a serum free, feeder-free (SFFF) culture platform for human embryonic stem cells (hESC) will be important for the expansion of hESC for future cell therapy applications. However, currently, culture of hESC consists of a combination of basal media, basic fibroblast growth factor (bFGF), serum replacer (SR) and conditioned media (CM) from feeders, and it is unclear which components of the mixture are absolutely critical in the maintenance of hESC. To evaluate the relative contributions of these media components in the development of SFFF culture, each was systematically eliminated and pluripotency assayed by dual embryonic stem cell markers, Oct-4 and TRA-1-60. We concluded that SR was the most critical component in the platform, followed by bFGF and CM produced by feeders, where down-regulation of Oct-4 occurred after 2, 5 and 5 passages, respectively, upon their withdrawal from the complete media.     

Immortalized feeders for the scale-up of human embryonic stem cells in feeder and feeder-free conditions

Human embryonic stem cells (hESC) are pluripotent cells that proliferate indefinitely in culture, whilst retaining their capacity for differentiation into different cell types. However, hESC cultures require culture in direct contact with feeder cells or conditioned medium (CM) from feeder cells. The most common source of feeders has been primary mouse embryonic fibroblast (MEF). In this study, we immortalized a primary MEF line with the E6 and E7 genes from HPV16. The immortal line, DeltaE-MEF, was able to proliferate beyond 7-9 passages and has an extended lifespan beyond 70 passages. When tested for its ability to support hESC growth, it was found that hESC continue to maintain the undifferentiated morphology for >40 passages both in co-culture with DeltaE-MEF and in feeder-free cultures supplemented with CM from DeltaE-MEF. The cultures also continue to express the pluripotent markers, Oct-4, SSEA-4, Tra-1-60, Tra-1-81, alkaline phosphatase and maintain a normal karyotype. In addition, these hESC formed teratomas when injected into SCID mice. Lastly, we demonstrated the feasibility of scaling-up significant quantities of undifferentiated hESC (>10(8) cells) using DeltaE-MEF in cell factories. The results from this study suggest that immortalized feeders can provide a consistent and reproducible source of feeders for hESC expansion and research.     

The development of 'feeder' cells for the preparation of clinical grade hES cell lines: challenges and solutions

The development of human embryonic stem cell (hESC) lines for research and therapy is hampered by the need to improve the basic methodologies for cell culture expansion. In most current methods hESC lines are cultured on a mouse or human feeder cell layer which appears to be the most reliable way to maintain cells stably in the undifferentiated state. However, co-culture introduces complications for studying stem cell biology and the delivery of safe therapies for the future. This article reviews the specific risks associated with any proposed clinical use of feeder cells of mouse origin and compares these with the benefits and risks of using human feeder cells. The further work required to establish clinical grade feeder cell lines for hESC line culture is significant and costly. Much work is being done to find feeder-free culture systems but these are at an early stage of development and there may be consequences that affect the value of the hESCs for research and development. These challenges should be viewed in the context of the huge amount of work that will be required over many years to develop robust differentiation protocols and establish fully defined procedures and adequate safety data for embryonic stem cell products.     

Identification of proteins from feeder conditioned medium that support human embryonic stem cells

The maintenance of undifferentiated human embryonic stem cells (hESC) requires feeder cells, either in co-culture or feeder-free with conditioned medium (CM) from the feeders. In this study, we compared the CM of a supporting primary mouse embryonic feeder (MEF) and an isogenic but non-supporting MEF line (DeltaE-MEF) in order to gain an insight to the differential expression profile of secreted factors. Using two-dimensional electrophoresis (2-DE) and matrix-assisted laser desorption/ionization-time of flight (MALDI) tandem mass spectrometry, 13 protein identities were found to be downregulated in DeltaE-MEF compared to MEF, of which 4 were found to be soluble factors and 3 proteins were membrane-associated or related to the extracellular matrix. In addition, four other proteins were identified to be differentially expressed in MEF-CM using high pressure liquid chromatography (HPLC) and cytokine arrays. In functional experiments where CM was replaced with six of the factors identified, hESC were able to proliferate for five continuous passages whilst maintaining 68-82% and 74-98% expression of pluripotent markers, Oct-4 and Tra-1-60, respectively. Using proteomic tools, important proteins from CM that supports hESC culture have been identified, which when replaced with recombinant proteins, continue to support undifferentiated hESC growth in a feeder-free culture platform.     

Clonal derivation and characterization of human embryonic stem cell lines

Human embryonic stem cells (hESC) are isolated as clusters of cells from the inner cell mass of blastocysts and thus should formally be considered as heterogeneous cell populations. Homogenous hESC cultures can be obtained through subcloning. Here, we report the clonal derivation and characterization of two new hESC lines from the parental cell line SA002 and the previously clonally derived cell line AS034.1, respectively. The hESC line SA002 was recently reported to have an abnormal karyotype (trisomy 13), but within this population of cells we observed rare individual cells with an apparent normal karyotype. At a cloning efficiency of 5%, we established 33 subclones from SA002, out of which one had a diploid karyotype and this subline was designated SA002.5. From AS034.1 we established one reclone designated AS034.1.1 at a cloning efficiency of 0.1%. These two novel sublines express cell surface markers indicative of undifferentiated hESC (SSEA-3, SSEA-4, TRA-1-60, and TRA-1-81), Oct-4, alkaline phosphatase, and they display high telomerase activity. In addition, the cells are pluripotent and form derivatives of all three embryonic germ layers in vitro as well as in vivo. These results, together with the clonal character of SA002.5 and AS034.1.1 make these homogenous cell populations very useful for hESC based applications in drug development and toxicity testing. In addition, the combination of the parental trisomic hESC line SA002 and the diploid subclone SA002.5 provides a unique experimental system to study the molecular mechanisms underlying the pathologies associated with trisomy 13.     

Derivation of a new human embryonic stem cell line, Endeavour-2, and its characterization

Here, we describe the derivation of a novel human embryonic stem cell (hESC) line, Endeavour-2 (E-2), propagated on human fetal fibroblasts (HFF) in a serum-replacement media. The inner cell mass (ICM) was manually dissected from the blastocyst without using immunodissection and, therefore, antibodies from animal sources. A total of 20 embryos were thawed and cultured, eight embryos were hatched, and five ICMs were obtained. They were transferred onto HFF used as feeder layer, and one colony representing the initial cell proliferation of a new hESC line, E-2, was obtained. The newly emerged hESC colony was passaged first by physical dissection and subsequently by enzymatic dissociation. E-2 has been in culture for over 6 months and has been shown to possess typical features of a pluripotent hESC line including expression of stem cell surface markers (SSEA4, TRA-160, and integrin alpha-6), intracellular alkaline phosphatase, and pluripotency gene markers, OCT4 and NANOG. This hESC line shows lineage-specific differentiation into various representative cell types expressing markers characteristic of the three somatic germ layers under both in vitro and in vivo conditions. E-2 line shows a normal karyotype (46 XX) and has been successfully cryopreserved and thawed several times using slow-freezing procedures. E-2 adds to the repertoire of existing hESC lines for research and development purposes in the field of regenerative medicine.     

Feeder-free culture of human embryonic stem cells in conditioned medium for efficient genetic modification

Realizing the potential of human embryonic stem cells (hESCs) in research and commercial applications requires generic protocols for culture, expansion and genetic modification that function between multiple lines. Here we describe a feeder-free hESC culture protocol that was tested in 13 independent hESC lines derived in five different laboratories. The procedure is based on Matrigel adaptation in mouse embryonic fibroblast conditioned medium (CM) followed by monolayer culture of hESC. When combined, these techniques provide a robust hESC culture platform, suitable for high-efficiency genetic modification via plasmid transfection (using lipofection or electroporation), siRNA knockdown and viral transduction. In contrast to other available protocols, it does not require optimization for individual lines. hESC transiently expressing ectopic genes are obtained within 9 d and stable transgenic lines within 3 weeks.     

Derivation and characterisation of the human embryonic stem cell lines, NOTT1 and NOTT2

The ability to maintain human embryonic stem cells (hESCs) during long-term culture and yet induce differentiation to multiple lineages potentially provides a novel approach to address various biomedical problems. Here, we describe derivation of hESC lines, NOTT1 and NOTT2, from human blastocysts graded as 3BC and 3CB, respectively. Both lines were successfully maintained as colonies by mechanical passaging on mouse embryonic feeder cells or as monolayers by trypsin-passaging in feeder-free conditions on Matrigel. Undifferentiated cells retained expression of pluripotency markers (OCT4, NANOG, SSEA-4, TRA-1-60 and TRA-1-81), a stable karyotype during long-term culture and could be transfected efficiently with plasmid DNA and short interfering RNA. Differentiation via formation of embryoid bodies resulted in expression of genes associated with early germ layers and terminal lineage specification. The electrophysiology of spontaneously beating NOTT1-derived cardiomyocytes was recorded and these cells were shown to be pharmacologically responsive. Histological examination of teratomas formed by in vivo differentiation of both lines in severe immunocompromised mice showed complex structures including cartilage or smooth muscle (mesoderm), luminal epithelium (endoderm) and neuroectoderm (ectoderm). These observations show that NOTT1 and NOTT2 display the accepted characteristics of hESC pluripotency.     

Feeder-free growth of undifferentiated human embryonic stem cells

Previous studies have shown that maintenance of undifferentiated human embryonic stem (hES) cells requires culture on mouse embryonic fibroblast (MEF) feeders. Here we demonstrate a successful feeder-free hES culture system in which undifferentiated cells can be maintained for at least 130 population doublings. In this system, hES cells are cultured on Matrigel or laminin in medium conditioned by MEF. The hES cells maintained on feeders or off feeders express integrin alpha6 and beta1, which may form a laminin-specific receptor. The hES cell populations in feeder-free conditions maintained a normal karyotype, stable proliferation rate, and high telomerase activity. Similar to cells cultured on feeders, hES cells maintained under feeder-free conditions expressed OCT-4, hTERT, alkaline phosphatase, and surface markers including SSEA-4, Tra 1-60, and Tra 1-81. In addition, hES cells maintained without direct feeder contact formed teratomas in SCID/beige mice and differentiated in vitro into cells from all three germ layers. Thus, the cells retain fundamental characteristics of hES cells in this culture system and are suitable for scaleup production.     

Improved genetic manipulation of human embryonic stem cells

Low efficiency of transfection limits the ability to genetically manipulate human embryonic stem cells (hESCs), and differences in cell derivation and culture methods require optimization of transfection protocols. We transiently transferred multiple independent hESC lines with different growth requirements to standardized feeder-free culture, and optimized conditions for clonal growth and efficient gene transfer without loss of pluripotency. Stably transfected lines retained differentiation potential, and most lines displayed normal karyotypes.     

GROα regulates human embryonic stem cell self-renewal or adoption of a neuronal fate

Previously we reported that feeders formed from human placental fibroblasts (hPFs) support derivation and long-term self-renewal of human embryonic stem cells (hESCs) under serum-free conditions. Here, we show, using antibody array and ELISA platforms, that hPFs secrete ～6-fold higher amounts of the CXC-type chemokine, GROα, than IMR 90, a human lung fibroblast line, which does not support hESC growth. Furthermore, immunocytochemistry and immunoblot approaches revealed that hESCs express CXCR, a GROα receptor. We used this information to develop defined culture medium for feeder-free propagation of hESCs in an undifferentiated state. Cells passaged as small aggregates and maintained in the GROα-containing medium had a normal karyotype, expressed pluripotency markers, and exhibited apical-basal polarity, i.e., had the defining features of pluripotent hESCs. They also differentiated into the three primary (embryonic) germ layers and formed teratomas in immunocompromised mice. hESCs cultured as single cells in the GROα-containing medium also had a normal karyotype, but they downregulated markers of pluripotency, lost apical-basal polarity, and expressed markers that are indicative of the early stages of neuronal differentiation-βIII tubulin, vimentin, radial glial protein, and nestin. These data support our hypothesis that establishing and maintaining cell polarity is essential for the long-term propagation of hESCs in an undifferentiated state and that disruption of cell-cell contacts can trigger adoption of a neuronal fate.     

Propagation of human embryonic and induced pluripotent stem cells in an indirect co-culture system

We have developed and validated a microporous poly(ethylene terephthalate) membrane-based indirect co-culture system for human pluripotent stem cell (hPSC) propagation, which allows real-time conditioning of the culture medium with human fibroblasts while maintaining the complete separation of the two cell types. The propagation and pluripotent characteristics of a human embryonic stem cell (hESC) line and a human induced pluripotent stem cell (hiPSC) line were studied in prolonged culture in this system. We report that hPSCs cultured on membranes by indirect co-culture with fibroblasts were indistinguishable by multiple criteria from hPSCs cultured directly on a fibroblast feeder layer. Thus this co-culture system is a significant advance in hPSC culture methods, providing a facile stem cell expansion system with continuous medium conditioning while preventing mixing of hPSCs and feeder cells. This membrane culture method will enable testing of novel feeder cells and differentiation studies using co-culture with other cell types, and will simplify stepwise changes in culture conditions for staged differentiation protocols.     

Patient-specific stem cell lines derived from human parthenogenetic blastocysts

Parthenogenetic activation of human oocytes may be one way to produce histocompatible cells for cell-based therapy. We report the successful derivation of six pluripotent human embryonic stem cell (hESC) lines from blastocysts of parthenogenetic origin. The parthenogenetic human embryonic stem cells (phESC) demonstrate typical hESC morphology, express appropriate markers, and possess high levels of alkaline phosphatase and telomerase activity. The phESC lines have a normal 46, XX karyotype, except one cell line, and have been cultured from between 21 to 35 passages. The phESC lines form embryoid bodies in suspension culture and teratomas after injection to immunodeficient animals and give differentiated derivatives of all three embryonic germ layers. DNA profiling of all six phESC lines demonstrates that they are MHC matched with the oocyte donors. The study of imprinted genes demonstrated further evidence of the parthenogenetic origin of the phESC lines. Our research has resulted in a protocol for the production of human parthenogenetic embryos and the derivation of stem cell lines from them, which minimizes the presence of animal-derived components, making the derived phESC lines more suitable for potential clinical use.     

一种新的人胚胎干细胞无饲养层培养方法的建立

目的:以转染碱性成纤维细胞生长因子(bFGF)的人胎肝基质细胞株(FLSC)培养人胚胎干细胞(hESC),寻找更加安全、有效的体外培养扩增方法。方法:通过ELISA方法定量检测转基因的人FLSC条件培养基中bFGF的分泌量;以商业化的mTeSR1无血清无饲养层培养基、常规小鼠胚胎成纤维细胞(MEF)条件培养基,以及转染bFGF的人FLSC条件培养基(bFGF/FLSC-CM)分别培养扩增H9细胞。通过观察hESC形态、免疫荧光染色、流式细胞检测及RT-PCR,检测hESC全能性标志物的表达。结果:ELISA方法检测bFGF/FLSC-CM中bFGF因子的分泌量为(770.09±17.28)pg/mL,而MEF-CM中bFGF因子的分泌量为(55.59±0.61)pg/mL,两者存在显著差异(P0.01);在3种培养体系下,免疫荧光检测hESC全能性标志Oct-4、Tra-1-81抗体的表达均呈阳性,流式检测细胞表面阶段特异性胚胎抗原4(SSEA-4)抗体阳性细胞的比例均在99%左右;RT-PCR检测到hESC特异的转录因子Oct-4、Nanog、Sox-2的表达。结论:以转染bFGF的人FLSC条件培养基可以有效扩增hESC,可为临床应用提供一种安全、高效、低成本的无饲养层培养方法。     

Toward xeno-free culture of human embryonic stem cells

The culture of human embryonic stem cells (hESCs) is limited, both technically and with respect to clinical potential, by the use of mouse embryonic fibroblasts (MEFs) as a feeder layer. The concern over xenogeneic contaminants from the mouse feeder cells may restrict transplantation to humans and the variability in MEFs from batch-to-batch and laboratory-to-laboratory may contribute to some of the variability in experimental results. Finally, use of any feeder layer increases the work load and subsequently limits the large-scale culture of human ES cells. Thus, the development of feeder-free cultures will allow more reproducible culture conditions, facilitate scale-up and potentiate the clinical use of cells differentiated from hESC cultures. In this review, we describe various methods tested to culture cells in the absence of MEF feeder layers and other advances in eliminating xenogeneic products from the culture system.     

Generation of new human embryonic stem cell lines with diploid and triploid karyotypes

Human pluripotent embryonic stem cells (hESC) have great promise for research into human developmental biology and the development of cell therapies for the treatment of diseases. To meet the increased demand for characterized hESC lines, we present the derivation and characterization of five hESC lines on mouse embryonic fibroblast cells. Our stem cell lines are characterized by morphology, long-term expansion, and expression profiles of a number of specific markers, including TRA-1-60, TRA-1-81, alkaline phosphatase, connexin 43, OCT-4, NANOG, CXCR4, NODAL, LEFTY2, THY-1, TDGF1, PAX6, FOXD3, SOX2, EPHA2, FGF4, TAL1, AC133 and REX-1. The pluripotency of the cell line was confirmed by spontaneous differentiation under in vitro conditions. Whereas all of the cell lines expressed all the characteristics of undifferentiated pluripotent hESC, two of the cell lines carried a triploid karyotype.