Mouse embryonic stem cell-derived feeder cells support the growth of their own mouse embryonic stem cells

Feeder cells are usually used in culturing embryonic stem cells (ESCs) to maintain their undifferentiated and pluripotent status. To test whether mouse embryonic stem cells (mESCs) may be a source of feeder cells to support their own growth, 48 fibroblast-like cell lines were isolated from the same mouse embryoid bodies (mEBs) at three phases (10th day, 15th day, 20th day), and five of them, mostly derived from 15th day mEBs, were capable of maintaining mESCs in an undifferentiated and pluripotent state over 10 passages, even up to passage 20. mESCs cultured on the feeder system derived from these five cell lines expressed alkaline phosphatase and specific mESCs markers, including SSEA-1, Oct-4, Nanog, and formed mEBs in vitro and teratomas in vivo. These results suggest that mEB-derived fibroblasts (mEB-dFs) could serve as feeder cells that could sustain the undifferentiated growth and pluripotency of their own mESCs in culture. This study not only provides a novel feeder system for mESCs culture, avoiding a lot of disadvantages of commonly used mouse embryonic fibroblasts as feeder cells, but also indicates that fibroblast-like cells derived from mESCs take on different functions. Investigating the molecular mechanisms of these different functional fibroblast-like cells to act on mESCs will contribute to the understanding of the mechanisms of mESCs self-renewal.     

The effect of extracellular matrix on the differentiation of mouse embryonic stem cells

Embryonic stem cells (ESCs) are promising research materials to investigate cell fate determination since they have the capability to differentiate. Stem cell differentiation has been extensively studied with various microenvironment mimicking structures to modify cellular dynamics associated with the cell-extracellular matrix (ECM) interactions and cell-cell communications. In the current study, our aim was to determine the effect of microenvironmental proteins with different concentrations on the capacity and differentiation capability of mouse ESCs (mESCs), combining the biochemical assays, imaging techniques, Fourier transform infrared (FTIR) spectroscopy, and unsupervised multivariate analysis. Based on our data, coating the surface of mESCs with Matrigel, used as an acellular matrix substrate, resulted in morphological and biochemical changes. mESCs exhibited alterations in their phenotype after growing on the Matrigel-coated surfaces, including their differentiation capacity, cell cycle phase pattern, membrane fluidity, and metabolic activities. In conclusion, mESCs can be stimulated physiologically, chemically, or mechanically to convert them a new phenotype. Thus, identification of ESCs’ behavior in the acellular microenvironment could be vital to elucidate the mechanism of diseases. It might also be promising to control the cell fate in the field of tissue engineering.     

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.     

Modeling signaling‐dependent pluripotency with Boolean logic to predict cell fate transitions

Pluripotent stem cells (PSCs) exist in multiple stable states, each with specific cellular properties and molecular signatures. The mechanisms that maintain pluripotency, or that cause its destabilization to initiate development, are complex and incompletely understood. We have developed a model to predict stabilized PSC gene regulatory network (GRN) states in response to input signals. Our strategy used random asynchronous Boolean simulations (R‐ABS) to simulate single‐cell fate transitions and strongly connected components (SCCs) strategy to represent population heterogeneity. This framework was applied to a reverse‐engineered and curated core GRN for mouse embryonic stem cells (mESCs) and used to simulate cellular responses to combinations of five signaling pathways. Our simulations predicted experimentally verified cell population compositions and input signal combinations controlling specific cell fate transitions. Extending the model to PSC differentiation, we predicted a combination of signaling activators and inhibitors that efficiently and robustly generated a Cdx2⁺Oct4^? cells from naïve mESCs. Overall, this platform provides new strategies to simulate cell fate transitions and the heterogeneity that typically occurs during development and differentiation.     

Cell damage evaluation of thermal inkjet printed Chinese hamster ovary cells

Thermal inkjet printing technology has been applied successfully to cell printing. However, there are concerns that printing process may cause cell damages or death. We conducted a comprehensive study of thermal inkjet printed Chinese hamster ovary (CHO) cells by evaluating cell viability and apoptosis, and possible cell membrane damages. Additionally, we studied the cell concentration of bio‐ink and found optimum printing of concentrations around 8 million cells per mL. Printed cell viability was 89% and only 3.5% apoptotic cells were observed after printing. Transient pores were developed in the cell membrane of printed cells. Cells were able to repair these pores within 2 h after printing. Green fluorescent protein (GFP) DNA plasmids were delivered to CHO‐S cells by co‐printing. The transfection efficiency is above 30%. We conclude that thermal inkjet printing technology can be used for precise cell seeding with minor effects and damages to the printed mammalian cells. The printing process causes transient pores in cell membranes, a process which has promising applications for gene and macroparticles delivery to induce the biocompatibility or growth of engineered tissues. Biotechnol. Bioeng. 2010;106: 963–969. © 2010 Wiley Periodicals, Inc.     

Evaluation of unrestricted somatic stem cells as a feeder layer to support undifferentiated embryonic stem cells

The use of unrestricted somatic stem cells (USSCs) holds great promise for future clinical applications. Conventionally, mouse embryonic fibroblasts (MEFs) or other animal‐based feeder layers are used to support embryonic stem cell (ESC) growth; the use of such feeder cells increases the risk of retroviral and other pathogenic infection in clinical trials. Implementation of a human‐based feeder layer, such as hUSSCs that are isolated from human sources, lowers such risks. Isolated cord blood USSCs derived from various donors were used as a novel, supportive feeder layer for growth of C4mES cells (Royan C4 ESCs). Complete cellular characterization using immunocytochemical and flow cytometric methods were performed on murine ESCs (mESCs) and hUSSCs. mESCs cultured on hUSSCs showed similar cellular morphology and presented the same cell markers of undifferentiated mESC as would have been observed in mESCs grown on MEFs. Our data revealed these cells had negative expression of Stat3, Sox2, and Fgf4 genes while showing positive expression for Pou5f1, Nanog, Rex1, Brachyury, Lif, Lifr, Tert, B2m, and Bmp4 genes. Moreover, mESCs cultured on hUSSCs exhibited proven differentiation potential to germ cell layers showing normal karyotype. The major advantage of hUSSCs is their ability to be continuously cultured for at least 50 passages. We have also found that hUSSCs have the potential to provide ESC support from the early moments of isolation. Further study of hUSSC as a novel human feeder layer may lead to their incorporation into clinical methods, making them a vital part of the application of human ESCs in clinical cell therapy. Mol. Reprod. Dev. 79: 709–718, 2012. © 2012 Wiley Periodicals, Inc.     

Role of voltage‐gated potassium channels in the fate determination of embryonic stem cells

Embryonic stem cells (ESCs) possess two unique characteristics: self‐renewal and pluripotency. In this study, roles of voltage‐gated potassium channels (K_v) in maintaining mouse (m) ESC characteristics were investigated. Tetraethylammonium (TEA⁺), a K_v blocker, attenuated cell proliferation in a concentration‐dependent manner. Possible reasons for this attenuation, including cytotoxicity, cell cycle arrest and differentiation, were examined. Blocking K_v did not change the viability of mESCs. Interestingly, K_v inhibition increased the proportion of cells in G₀/G₁ phase and decreased that in S phase. This change in cell cycle distribution can be attributed to cell cycle arrest or differentiation. Loss of pluripotency as determined at both molecular and functional levels was detected in mESCs with K_v blockade, indicating that K_v inhibition in undifferentiated mESCs directs cells to differentiate instead of to self‐renew and progress through the cell cycle. Membrane potential measurement revealed that K_v blockade led to depolarization, consistent with the role of K_v as the key determinant of membrane potential. The present results suggest that membrane potential changes may act as a “switch” for ESCs to decide whether to proliferate or to differentiate: hyperpolarization at G₁ phase would favor ESCs to enter S phase while depolarization would favor ESCs to differentiate. Consistent with this notion, S‐phase‐synchronized mESCs were found to be more hyperpolarized than G₀/G₁‐phase‐synchronized mESCs. Moreover, when mESCs differentiated, the differentiation derivatives depolarized at the initial stage of differentiation. This investigation is the first study to provide evidence that K_v and membrane potential affect the fate determination of ESCs. J. Cell. Physiol. 224:165–177, 2010 © 2010 Wiley‐Liss, Inc.     

Epidermal growth factor and three‐dimensional scaffolds provide conducive environment for differentiation of mouse embryonic stem cells into oocyte‐like cells

Three‐dimensional (3D) culture provides a biomimicry of the naive microenvironment that can support cell proliferation, differentiation, and regeneration. Some growth factors, such as epidermal growth factor (EGF), facilitate normal meiosis during oocyte maturation in vivo. In this study, a scaffold‐based 3D coculture system using purified alginate was applied to induce oocyte differentiation from mouse embryonic stem cells (mESCs). mESCs were induced to differentiate into oocyte‐like cells using embryoid body protocol in the two‐dimensional or 3D microenvironment in vitro. To increase the efficiency of the oocyte‐like cell differentiation from mESCs, we employed a coculture system using ovarian granulosa cells in the presence or absence of epidermal growth factor (+EGF or ?EGF) for 14 days and then the cells were assessed for germ cell differentiation, meiotic progression, and oocyte maturation markers. The cultures exposed to EGF in the alginate‐based 3D microenvironment showed the highest level of premeiotic (Oct4 and Mvh), meiotic (Scp1, Scp3, Stra8, and Rec8), and oocyte maturation (Gdf9, Cx37, and Zp2) marker genes (p < .05) in comparison to other groups. According to the gene‐expression patterns, we can conclude that alginate‐based 3D coculture system provided a highly efficient protocol for oocyte‐like cell differentiation from mESCs. The data showed that this culture system along with EGF improved the rate of in vitro oocyte‐like cell differentiation.     

The impact of fabrication parameters and substrate stiffness in direct writing of living constructs

Biomolecules and living cells can be printed in high‐resolution patterns to fabricate living constructs for tissue engineering. To evaluate the impact of processing cells with rapid prototyping (RP) methods, we modeled the printing phase of two RP systems that use biomaterial inks containing living cells: a high‐resolution inkjet system (BioJet) and a lower‐resolution nozzle‐based contact printing system (PAM²). In the first fabrication method, we reasoned that cell damage occurs principally during drop collision on the printing surface, in the second we hypothesize that shear stresses act on cells during extrusion (within the printing nozzle). The two cases were modeled changing the printing conditions: biomaterial substrate stiffness and volumetric flow rate, respectively, in BioJet and PAM². Results show that during inkjet printing impact energies of about 10^?8 J are transmitted to cells, whereas extrusion energies of the order of 10^?11 J are exerted in direct printing. Viability tests of printed cells can be related to those numerical simulations, suggesting a threshold energy of 10^?9 J to avoid permanent cell damage. To obtain well‐defined living constructs, a combination of these methods is proposed for the fabrication of scaffolds with controlled 3D architecture and spatial distribution of biomolecules and cells. © 2012 American Institute of Chemical Engineers Biotechnol. Prog., 2012     

MIR‐34c regulates mouse embryonic stem cells differentiation into male germ‐like cells through RARg

Embryonic stem cells (ESCs) have the capacity to differentiate into nearly all sorts of cell types, including germ cells, which were regarded as one type of highly specialized cells in mammals, taking the responsibility of transferring genetic materials to the next generation. Studies on induction differentiation of murine embryonic stem cells (mESCs) into male germ cells, but with a low efficiency, basic reason is that the regulation mechanism of germ cell development in mammals is still unclear. miRNA might play an important role in spermatogenesis in mammals. In this study, several miRNAs, which might be related to spermatogenesis, were initially selected and detected in the mouse tissues by semi‐polymerase chain reaction (PCR) and quantitative real time (qRT)‐PCR to find a testis‐specific miRNA. To study its effect on mESCs differentiation into male germ cells, miR‐34c mimics were synthesized and pri‐miR‐34c‐GFP plasmid was constructed, transfected into mESCs and combined with retinoic acid induction. The effects of miR‐34c were analysed by morphology, alkaline phosphatase staining, qRT‐PCR_and immunofluorescent staining. The results showed that miR‐34c promoted mESCs differentiation into male germ‐like cells, to some extent. Then miR‐34c targeted genes were predicted by bioinformatics; Retinoic acid receptor gamma (RARg) was selected, and two dual‐luciferase reporter vectors contained the normal and mutated 3′untranslated region of RARg were constructed, respectively. By miRNA mimics and vector co‐transfection experiment, the predicted target gene‐RARg was confirmed. In conclusion, we found a mammalian male germ cell specific miRNA—miR‐34c, and it might be pivotal in mESCs differentiation into male germ cells through its target—RARg. Copyright © 2012 John Wiley & Sons, Ltd.     

Effect of microgravity on proliferation and differentiation of embryonic stem cells in an automated culturing system during the TZ‐1 space mission

Objective

Despite a great number of studies analysing the effects of microgravity on stem cell proliferation and differentiation, few of them have focused on real‐time imaging estimates in space. Herein, we utilized the TZ‐1 cargo spacecraft, automatic cell culture equipment and live cell imaging techniques to examine the effects of real microgravity on the proliferation and differentiation of mouse embryonic stem cells (mESCs).

Materials and methods

Oct4‐GFP, Brachyury‐GFP mESC and Oct4‐GFP mESC‐derived EBs were used as experimental samples in the TZ‐1 spaceflight mission. These samples were seeded into chambers, cultured in an automatic cell culture device and were transported into space during the TZ‐1 mission. Over 15 days of spaceflight, bright field and fluorescent images of cell growth were taken in micrography, and the medium was changed every day. Real‐time image data were transferred to the ground for analysis.

Results

Space microgravity maintains stemness and long‐term survival of mESCs, promising 3D aggregate formation. Although microgravity did not significantly prevent the migration of EBs on the ECM substrate, it did prevent terminal differentiation of cells.

Conclusions

This study demonstrates that space microgravity might play a potential role in supporting 3D cell growth and maintenance of stemness in embryonic stem cells, while it may negatively affect terminal differentiation.

     

Increasing maternal age of blastocyst affects on efficient derivation and behavior of mouse embryonic stem cells

Mouse embryonic stem cells (mESCs) have the capability to undergo unlimited cell division and differentiate into derivatives of all three embryonic germ layers. These fundamental features enable mESCs to potentially be appropriate, efficient models for biological and medical research. Therefore, it is essential to produce high-performance mESCs. In the current study, we have produced mESCs from blastocysts that developed from fertilized oocytes of 2 (2-C57)-, 4 (4-C57)-, and 6 (6-C57)-month-old C57BL/6 mice. A comparison of isolated stem cells was done from the viewpoint of the efficiency of mESC derivation, self-renewal, and their differentiation capacity. All generated mESCs showed a similar expression of the molecular markers protein of pluripotency and AP activity. In the 3i medium, there was a significant decrease in undifferentiated marker genes expression in the 2-C57 cells compared with the other two groups ( P < 0.05) but developmental genes significantly increased in the 4-C57 and 6-C57 cells compared with the 2-C57 cells ( P < 0.05). The differentiation capacity into three germ layers through the embryoid body formation and percentage of cell lines with normal numbers of chromosomes reduced with increased maternal age. The highest DT and highest percentage of cells in the S phase belonged to 2-C57 cells. These data demonstrated that blastocysts which developed from fertilized oocytes of 2-, 4-, and 6-month-old C57BL/6 mice can generate pluripotent stem cells, and suggested that both the efficiency of mESC isolation and the behavior of these isolated mESCs including pluripotency, self-renewal, cell cycle, and DT changed with increasing maternal age.     

Differentiation of mouse embryonic stem cells into dental epithelial-like cells induced by ameloblasts serum-free conditioned medium

Embryonic stem cells (ESCs) possess an intrinsic self-renewal ability and can differentiate into numerous types of functional tissue cells; however, whether ESCs can differentiate toward the odontogenic lineage is still unknown. In this study, we developed an efficient culture strategy to induce the differentiation of murine ESCs (mESCs) into dental epithelial cells. By culturing mESCs in ameloblasts serum-free conditioned medium (ASF-CM), we could induce their differentiation toward dental epithelial cell lineages; however, similar experiments with the tooth germ cell-conditioned medium (TGC-CM) did not yield effective results. After culturing the cells for 14 days in the differentiation-inducing media, the expression of ameloblast-specific proteins such as cytokeratin (CK)14, ameloblastin (AMBN), and amelogenin (AMGN) was markedly higher in mESCs obtained with embryoid body (EB) formation than in mESCs obtained without EB formation. We observed that immunocompromised mice implanted with induced murine EBs (mEBs) showed tissue regenerative capacity and produced odontogenic epithelial-like structures, whereas those implanted with mSCE monolayer cells mainly formed connective tissues. Thus, for the first time, we report that ASF-CM provides a suitable microenvironment for inducing mESC differentiation along the odontogenic epithelial cell lineage. This result has important implications for tooth tissue engineering.     

Heparan sulfate facilitates FGF and BMP signaling to drive mesoderm differentiation of mouse embryonic stem cells

Heparan sulfate (HS) has been implicated in regulating cell fate decisions during differentiation of embryonic stem cells (ESCs) into advanced cell types. However, the necessity and the underlying molecular mechanisms of HS in early cell lineage differentiation are still largely unknown. In this study, we examined the potential of EXT1(-/-) mouse ESCs (mESCs), that are deficient in HS, to differentiate into primary germ layer cells. We observed that EXT1(-/-) mESCs lost their differentiation competence and failed to differentiate into Pax6(+)-neural precursor cells and mesodermal cells. More detailed analyses highlighted the importance of HS for the induction of Brachyury(+) pan-mesoderm as well as normal gene expression associated with the dorso-ventral patterning of mesoderm. Examination of developmental cell signaling revealed that EXT1 ablation diminished FGF and BMP but not Wnt signaling. Furthermore, restoration of FGF and BMP signaling each partially rescued mesoderm differentiation defects. We further show that BMP4 is more prone to degradation in EXT1(-/-) mESCs culture medium compared with that of wild type cells. Therefore, our data reveal that HS stabilizes BMP ligand and thereby maintains the BMP signaling output required for normal mesoderm differentiation. In summary, our study demonstrates that HS is required for ESC pluripotency, in particular lineage specification into mesoderm through facilitation of FGF and BMP signaling.     

Purification of pluripotent embryonic stem cells using dielectrophoresis and a flow control system

Pluripotent stem cells (PSCs) such as embryonic stem cells and induced PSCs can differentiate into all somatic cell types such as cardiomyocytes, nerve cells, and chondrocytes. However, PSCs can easily lose their pluripotency if the culture process is disturbed. Therefore, cell sorting methods for purifying PSCs with pluripotency are important for the establishment and expansion of PSCs. In this study, we focused on dielectrophoresis (DEP) to separate cells without fluorescent dyes or magnetic antibodies. The goal of this study was to establish a cell sorting method for the purification of PSCs based on their pluripotency using DEP and a flow control system. The dielectrophoretic properties of mouse embryonic stem cells (mESCs) with and without pluripotency were evaluated in detail, and mESCs exhibited varying frequency dependencies in the DEP response. Based on the variance in DEP properties, mixed cell suspensions of mESCs can be separated according to their pluripotency with an efficacy of approximately 90%.     

“The Good into the Pot,the Bad into the Crop!”—A New Technology to Free Stem Cells from Feeder Cells

A variety of embryonic and adult stem cell lines require an intial co-culturing with feeder cells for non-differentiated growth, self renewal and maintenance of pluripotency. However for many downstream ES cell applications the feeder cells have to be considered contaminations that might interfere not just with the analysis of experimental data but also with clinical application and tissue engineering approaches. Here we introduce a novel technique that allows for the selection of pure feeder-freed stem cells, following stem cell proliferation on feeder cell layers. Complete and reproducible separation of feeder and embryonic stem cells was accomplished by adaptation of an automated cell selection system that resulted in the aspiration of distinct cell colonies or fraction of colonies according to predefined physical parameters. Analyzing neuronal differentiation we demonstrated feeder-freed stem cells to exhibit differentiation potentials comparable to embryonic stem cells differentiated under standard conditions. However, embryoid body growth as well as differentiation of stem cells into cardiomyocytes was significantly enhanced in feeder-freed cells, indicating a feeder cell dependent modulation of lineage differentiation during early embryoid body development. These findings underline the necessity to separate stem and feeder cells before the initiation of in vitro differentiation. The complete separation of stem and feeder cells by this new technology results in pure stem cell populations for translational approaches. Furthermore, a more detailed analysis of the effect of feeder cells on stem cell differentiation is now possible, that might facilitate the identification and development of new optimized human or genetically modified feeder cell lines.