技术资料

Crosstalk between intracellular signaling pathways has been extensively studied to understand the pluripotency of human pluripotent stem cells (hPSCs),including human embryonic stem cells and human induced pluripotent stem cells (hiPSCs); however,the contribution of NAD(+) -dependent pathways remains largely unknown. Here,we show that NAD(+) depletion by FK866 (a potent inhibitor of NAD(+) biosynthesis) was fatal in hPSCs,particularly when deriving pluripotent cells from somatic cells and maintaining pluripotency. NAD and its precursors (nicotinamide [NAM] and nicotinic acid) fully replenished the NAD(+) depletion by FK866 in hPSCs. However,only NAM effectively enhanced the reprogramming efficiency and kinetics of hiPSC generation and was also significantly advantageous for the maintenance of undifferentiated hPSCs. Our molecular and functional studies reveal that NAM lowers the barriers to reprogramming by accelerating cell proliferation and protecting cells from apoptosis and senescence by alleviating oxidative stress,reactive oxygen species accumulation,and subsequent mitochondrial membrane potential collapse. We provide evidence that the positive effects of NAM (occurring at concentrations well above the physiological range) on pluripotency control are molecularly associated with the repression of p53,p21,and p16. Our findings establish that adequate intracellular NAD(+) content is crucial for pluripotency; the distinct effects of NAM on pluripotency may be dependent not only on its metabolic advantage as a NAD(+) precursor but also on the ability of NAM to enhance resistance to cellular stress. View Publication

Sprouty (Spry) genes encode negative regulators of receptor tyrosine kinase (RTK) signaling,which plays important roles in human embryonic stem cells (hESCs). SPRY2 and SPRY4 are the two most highly expressed Sprouty family members in hESCs,suggesting that they may influence self-renewal. To test this hypothesis,we performed siRNA-mediated knock down (KD) studies. SPRY2 KD resulted in increased cell death and decreased proliferation,whereas SPRY4 KD enhanced survival. In both cases,after KD the cells were able to differentiate into cells of the three germ layers,although after SPRY2 KD there was a tendency toward increased ectodermal differentiation. SPRY2 KD cells displayed impaired mitochondrial fusion and cell membrane damage,explaining in part the increased cell death. These data indicate that Sprouty genes regulate pathways involved in proliferation and cell death in hESCs. View Publication

Human embryonic stem cells (hESCs) are emerging as an attractive alternative source for cell replacement therapy since the cells can be expanded in culture indefinitely and differentiated into any cell types in the body. In order to optimize cell-to-cell interaction,cell proliferation and differentiation into specific lineages as well as tissue organization,it is important to provide a microenvironment for the hESCs which mimics the stem cell niche. One approach is to provide a three-dimensional (3D) environment such as encapsulation. We present an approach to culture and differentiate hESCs into midbrain dopamine (mdDA) neurons in a 3D microenvironment using alginate microcapsules for the first time. A detailed gene and protein expression analysis during neuronal differentiation showed an increased gene and protein expression of various specific DA neuronal markers,particularly tyrosine hydroxylase (TH) by textgreater100 folds after 2weeks and at least 50% higher expression after 4weeks respectively,compared to cells differentiated under conventional two-dimensional (2D) platform. The encapsulated TH+ cells co-expressed mdDA neuronal markers,forkhead box protein A-2 (FOXA2) and pituitary homeobox-3 (PITX3) after 4weeks and secreted approximately 60pg/ml/106 cells higher DA level when induced. We propose that the 3D platform facilitated an early onset of DA neuronal generation compared to that with conventional 2D system which also secretes more DA under potassium-induction. It is a very useful model to study the proliferation and directed differentiation of hESCs to various lineages,particularly to mdDA neurons. This 3D system also allows the separation of feeder cells from hESCs during the process of differentiation and also has potential for immune-isolation during transplantation studies. ?? 2013 Elsevier B.V. View Publication

Transposon gene delivery systems offer an alternative,non-viral-based approach to generate induced pluripotent stem cells (iPSCs). Here we used the Sleeping Beauty (SB) transposon to generate four human iPSC lines from foetal fibroblasts. In contrast to other gene delivery systems,the SB transposon does not exhibit an integration bias towards particular genetic elements,thereby reducing the risk of insertional mutagenesis. Furthermore,unlike the alternative transposon piggyBac,SB has no SB-like elements within the human genome,minimising the possibility of mobilising endogenous transposon elements. All iPSC lines exhibited the expected characteristics of pluripotent human cells,including the ability to differentiate to derivatives of all three germ layers in vitro. Re-expression of the SB transposase in the iPSCs after reprogramming resulted in the mobilisation of some of the transposons. These results indicate that the SB transposon system is a useful addition to methods for generating human iPSCs,both for basic and applied biomedical research,and in the context of future therapeutic application. textcopyright 2013 International Society of Differentiation. View Publication

The neural differentiation of human embryonic stem cells (ESCs) is a potential tool for elucidating the key mechanisms involved in human neurogenesis. Nestin and ??-III-tubulin,which are cytoskeleton proteins,are marker proteins of neural stem cells (NSCs) and neurons,respectively. However,the expression patterns of nestin and ??-III-tubulin in neural derivatives from human ESCs remain unclear. In this study,we found that neural progenitor cells (NPCs) derived from H9 cells express high levels of nestin and musashi-1. In contrast,??-III-tubulin was weakly expressed in a few NPCs. Moreover,in these cells,nestin formed filament networks,whereas ??-III-tubulin was distributed randomly as small particles. As the differentiation proceeded,the nestin filament networks and the ??-III-tubulin particles were found in both the cell soma and the cellular processes. Moreover,the colocalization of nestin and ??-III-tubulin was found mainly in the cell processes and neurite-like structures and not in the cell soma. These results may aid our understanding of the expression patterns of nestin and ??-III-tubulin during the neural differentiation of H9 cells. ?? 2013 Elsevier Inc. View Publication

Reduced expression 1 (REX1) is a widely used pluripotency marker,but little is known about its roles in pluripotency. Here,we show that REX1 is functionally important in the reacquisition and maintenance of pluripotency. REX1-depleted human pluripotent stem cells (hPSCs) lose their self-renewal capacity and full differentiation potential,especially their mesoderm lineage potential. Cyclin B1/B2 expression was found to parallel that of REX1. REX1 positively regulates the transcriptional activity of cyclin B1/B2 through binding to their promoters. REX1 induces the phosphorylation of DRP1 at Ser616 by cyclin B/CDK1,which leads to mitochondrial fission and appears to be important for meeting the high-energy demands of highly glycolytic hPSCs. During reprogramming to pluripotency by defined factors (OCT4,SOX2,KLF4,and c-MYC),the reprogramming kinetics and efficiency are markedly improved by adding REX1 or replacing KLF4 with REX1. These improvements are achieved by lowering reprogramming barriers (growth arrest and apoptosis),by enhancing mitochondrial fission,and by conversion to glycolytic metabolism,dependent on the cyclin B1/B2-DRP1 pathway. Our results show that a novel pluripotency regulator,REX1,is essential for pluripotency and reprogramming. View Publication

Human macrophages are specialised hosts for HIV-1,dengue virus,Leishmania and Mycobacterium tuberculosis. Yet macrophage research is hampered by lack of appropriate cell models for modelling infection by these human pathogens,because available myeloid cell lines are,by definition,not terminally differentiated like tissue macrophages. We describe here a method for deriving monocytes and macrophages from human Pluripotent Stem Cells which improves on previously published protocols in that it uses entirely defined,feeder- and serum-free culture conditions and produces very consistent,pure,high yields across both human Embryonic Stem Cell (hESC) and multiple human induced Pluripotent Stem Cell (hiPSC) lines over time periods of up to one year. Cumulatively,up to ∼3×10(7) monocytes can be harvested per 6-well plate. The monocytes produced are most closely similar to the major blood monocyte (CD14(+),CD16(low),CD163(+)). Differentiation with M-CSF produces macrophages that are highly phagocytic,HIV-1-infectable,and upon activation produce a pro-inflammatory cytokine profile similar to blood monocyte-derived macrophages. Macrophages are notoriously hard to genetically manipulate,as they recognise foreign nucleic acids; the lentivector system described here overcomes this,as pluripotent stem cells can be relatively simply genetically manipulated for efficient transgene expression in the differentiated cells,surmounting issues of transgene silencing. Overall,the method we describe here is an efficient,effective,scalable system for the reproducible production and genetic modification of human macrophages,facilitating the interrogation of human macrophage biology. View Publication

In vitro neural differentiation of human embryonic stem cells (hESCs) is an advantageous system for studying early neural development. The process of early neural differentiation in hESCs begins by initiation of primitive neuroectoderm,which is manifested by rosette formation,with consecutive differentiation into neural progenitors and early glial-like cells. In this study,we examined the involvement of early neural markers - OTX2,PAX6,Sox1,Nestin,NR2F1,NR2F2,and IRX2 - in the onset of rosette formation,during spontaneous neural differentiation of hESC and human induced pluripotent stem cell (hiPSC) colonies. This is in contrast to the conventional way of studying rosette formation,which involves induction of neuronal differentiation and the utilization of embryoid bodies. Here we show that OTX2 is highly expressed at the onset of rosette formation,when rosettes comprise no more than 3-5 cells,and that its expression precedes that of established markers of early neuronal differentiation. Importantly,the rise of OTX2 expression in these cells coincides with the down-regulation of the pluripotency marker OCT4. Lastly,we show that cells derived from rosettes that emerge during spontaneous differentiation of hESCs or hiPSCs are capable of differentiating into dopaminergic neurons in vitro,and into mature-appearing pyramidal and serotonergic neurons weeks after being injected into the motor cortex of NOD-SCID mice. ?? 2013 Elsevier B.V. View Publication

The cell cycle is a series of integrated and coordinated physiological events that results in cell growth and replication. Besides observing the event of cell division it is not feasible to determine the cell cycle phase without fatal and/or perturbing invasive procedures such as cell staining,fixing,and/or dissociation. Raman microspectroscopy (RMS) is a chemical imaging technique that exploits molecular vibrations as a contrast mechanism; it can be applied to single living cells noninvasively to allow unperturbed analysis over time. We used RMS to determine the cell cycle phase based on integrating the composite 783 cm(-1) nucleic acid band intensities across individual cell nuclei. After correcting for RNA contributions using the RNA 811 cm(-1) band,the measured intensities essentially reflected DNA content. When quantifying Raman images from single cells in a population of methanol-fixed human embryonic stem cells,the histogram of corrected 783 cm(-1) band intensities exhibited a profile analogous to that obtained using flow-cytometry with nuclear stains. The two population peaks in the histogram occur at Raman intensities corresponding to a 1-fold and 2-fold diploid DNA complement per cell,consistent with a distribution of cells with a population peak due to cells at the end of G1 phase (1-fold) and a peak due to cells entering M phase (2-fold). When treated with EdU to label the replicating DNA and block cell division,cells with higher EdU-related fluorescence generally had higher integrated Raman intensities. This provides proof-of-principle of an analytical method for label-free RMS determination in situ of cell cycle phase in adherent monolayers or even single adherent cells. View Publication

Amyotrophic lateral sclerosis (ALS) is a fatal neurological disease characterized by the degeneration of motor neurons. Currently,there is no effective therapy for ALS. Stem cell transplantation is a potential therapeutic strategy for ALS,and the reprogramming of adult somatic cells into induced pluripotent stem cells (iPSCs) represents a novel cell source. In this study,we isolated a specific neural stem cell (NSC) population from human iPSCs based on high aldehyde dehydrogenase activity,low side scatter and integrin VLA4 positivity. We assessed the therapeutic effects of these NSCs on the phenotype of ALS mice after intrathecal or intravenous injections. Transplanted NSCs migrated and engrafted into the central nervous system via both routes of injection. Compared with control ALS,treated ALS mice exhibited improved neuromuscular function and motor unit pathology and significantly increased life span,in particular with the systemic administration of NSCs (15%). These positive effects are linked to multiple mechanisms,including production of neurotrophic factors and reduction of micro- and macrogliosis. NSCs induced a decrease in astrocyte number through the activation of the vanilloid receptor TRPV1. We conclude that minimally invasive injections of iPSC-derived NSCs can exert a therapeutic effect in ALS. This study contributes to advancements in iPSC-mediated approaches for treating ALS and other neurodegenerative diseases. View Publication

DNA repair plays a crucial role in embryonic and somatic stem cell biology and cell reprogramming. The Fanconi anemia (FA) pathway,which promotes error-free repair of DNA double-strand breaks,is required for somatic cell reprogramming to induced pluripotent stem cells (iPSC). Thus,cells from Fanconi anemia patients,which lack this critical pathway,fail to be reprogrammed to iPSC under standard conditions unless the defective FA gene is complemented. In this study,we utilized the oncogenes of high-risk human papillomavirus 16 (HPV16) to overcome the resistance of FA patient cells to reprogramming. We found that E6,but not E7,recovers FA iPSC colony formation and,furthermore,that p53 inhibition is necessary and sufficient for this activity. The iPSC colonies resulting from each of these approaches stained positive for alkaline phosphatase,NANOG,and Tra-1-60,indicating that they were fully reprogrammed into pluripotent cells. However,FA iPSC were incapable of outgrowth into stable iPSC lines regardless of p53 suppression,whereas their FA-complemented counterparts grew efficiently. Thus,we conclude that the FA pathway is required for the growth of iPSC beyond reprogramming and that p53-independent mechanisms are involved. IMPORTANCE A novel approach is described whereby HPV oncogenes are used as tools to uncover DNA repair-related molecular mechanisms affecting somatic cell reprogramming. The findings indicate that p53-dependent mechanisms block FA cells from reprogramming but also uncover a previously unrecognized defect in FA iPSC proliferation independent of p53. View Publication

THAP1 encodes a transcription factor but its regulation is largely elusive. TOR1A was shown to be repressed by THAP1 in vitro. Notably,mutations in both of these genes lead to dystonia (DYT6 or DYT1). Surprisingly,expressional changes of TOR1A in THAP1 mutation carriers have not been detected indicating additional levels of regulation. Here,we investigated whether THAP1 is able to autoregulate its own expression. Using in-silico prediction,luciferase reporter gene assays,and (quantitative) chromatin immunoprecipitation (ChIP),we defined the THAP1 minimal promoter to a 480. bp-fragment and demonstrated specific binding of THAP1 to this region which resulted in repression of the THAP1 promoter. This autoregulation was disturbed by different DYT6-causing mutations. Two mutants (Ser6Phe,Arg13His) were shown to be less stable than wildtype THAP1 adding to the effect of reduced binding to the THAP1 promoter. Overexpressed THAP1 is preferably degraded through the proteasome. Notably,endogenous THAP1 expression was significantly reduced in cells overexpressing wildtype THAP1 as demonstrated by quantitative PCR. In contrast,higher THAP1 levels were detected in induced pluripotent stem cell (iPS)-derived neurons from THAP1 mutation carriers. Thus,we identified a feedback-loop in the regulation of THAP1 expression and demonstrated that mutant THAP1 leads to higher THAP1 expression levels. This compensatory autoregulation may contribute to the mean age at onset in the late teen years or even reduced penetrance in some THAP1 mutation carriers. View Publication