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Perhaps one of the most significant achievements in modern science is the discovery of human induced pluripotent stem cells (hiPSCs),which have paved the way for regeneration therapy using patients' own cells. Cardiomyocytes differentiated from hiPSCs (hiPSC-CMs) could be used for modelling patients with heart failure,for testing new drugs,and for cellular therapy in the future. However,the present cardiomyocyte differentiation protocols exhibit variable differentiation efficiency across different hiPSC lines,which inhibit the application of this technology significantly. Here,we demonstrate a novel myocyte differentiation protocol that can yield a significant,high percentage of cardiac myocyte differentiation (backslashtextgreater85%) in 2 hiPSC lines,which makes the fabrication of a human cardiac muscle patch possible. The established hiPSCs cell lines being examined include the transgene integrated UCBiPS7 derived from cord blood cells and non-integrated PCBC16iPS from skin fibroblasts. The results indicate that hiPSC-CMs derived from established hiPSC lines respond to adrenergic or acetylcholine stimulation and beat regularly for greater than 60 days. This data also demonstrates that this novel differentiation protocol can efficiently generate hiPSC-CMs from iPSC lines that are derived not only from fibroblasts,but also from blood mononuclear cells. View Publication

Human ES cells (hESC) exposed to bone morphogenic protein 4 (BMP4) in the absence of FGF2 have become widely used for studying trophoblast development,but the soundness of this model has been challenged by others,who concluded that differentiation was primarily toward mesoderm rather than trophoblast. Here we confirm that hESC grown under the standard conditions on a medium conditioned by mouse embryonic fibroblasts in the presence of BMP4 and absence of FGF2 on a Matrigel substratum rapidly convert to an epithelium that is largely KRT7+ within 48 h,with minimal expression of mesoderm markers,including T (Brachyury). Instead,they begin to express a series of trophoblast markers,including HLA-G,demonstrate invasive properties that are independent of the continued presence of BMP4 in the medium,and,over time,produce extensive amounts of human chorionic gonadotropin,progesterone,placental growth factor,and placental lactogen. This process of differentiation is not dependent on conditioning of the medium by mouse embryonic fibroblasts and is accelerated in the presence of inhibitors of Activin and FGF2 signaling,which at day 2 provide colonies that are entirely KRT7+ and in which the majority of cells are transiently CDX2+. Colonies grown on two chemically defined media,including the one in which BMP4 was reported to drive mesoderm formation,also differentiate at least partially to trophoblast in response to BMP4. The experiments demonstrate that the in vitro BMP4/hESC model is valid for studying the emergence and differentiation of trophoblasts. View Publication

We report that a single growth factor,NM23-H1,enables serial passaging of both human ES and iPS cells in the absence of feeder cells,their conditioned media or bFGF in a fully defined xeno-free media on a novel defined,xeno-free surface. Stem cells cultured in this system show a gene expression pattern indicative of a more naïve" state than stem cells grown in bFGF-based media. NM23-H1 and MUC1* growth factor receptor cooperate to control stem cell self-replication. By manipulating the multimerization state of NM23-H1� View Publication

In this study,we sought to establish a novel method to prospectively and dynamically identify live human oligodendrocyte precursor cells (OPCs) and oligodendrocyte lineage cells from brain dissociates and pluripotent stem cell culture. We selected a highly conserved enhancer element of the Sox10 gene,known as MCS5,which directs reporter expression to oligodendrocyte lineage cells in mouse and zebrafish. We demonstrate that lentiviral Sox10-MCS5 induced expression of GFP at high levels in a subpopulation of human CD140a/PDGF??R-sorted OPCs as well as their immature oligodendrocyte progeny. Furthermore,we show that almost all Sox10-MCS5:GFPhigh cells expressed OPC antigen CD140a and human OPCs expressing SOX10,OLIG2,and PDGFRA mRNAs could be prospectively identified using GFP based fluorescence activated cells sorting alone. Additionally,we established a human induced pluripotent cell (iPSC) line transduced with the Sox10-MCS5:GFP reporter using a Rex-Neo cassette. Similar to human primary cells,GFP expression was restricted to embryoid bodies containing both oligodendrocyte progenitor and oligodendrocyte cells and co-localized with NG2 and O4-positive cells respectively. As such,we have developed a novel reporter system that can track oligodendrocyte commitment in human cells,establishing a valuable tool to improve our understanding and efficiency of human oligodendrocyte derivation. ?? 2013 Elsevier Inc. View Publication

Huntington's disease is caused by expanded CAG repeats in HTT,conferring toxic gain of function on mutant HTT (mHTT) protein. Reducing mHTT amounts is postulated as a strategy for therapeutic intervention. We conducted genome-wide RNA interference screens for genes modifying mHTT abundance and identified 13 hits. We tested 10 in vivo in a Drosophila melanogaster Huntington's disease model,and 6 exhibited activity consistent with the in vitro screening results. Among these,negative regulator of ubiquitin-like protein 1 (NUB1) overexpression lowered mHTT in neuronal models and rescued mHTT-induced death. NUB1 reduces mHTT amounts by enhancing polyubiquitination and proteasomal degradation of mHTT protein. The process requires CUL3 and the ubiquitin-like protein NEDD8 necessary for CUL3 activation. As a potential approach to modulating NUB1 for treatment,interferon-β lowered mHTT and rescued neuronal toxicity through induction of NUB1. Thus,we have identified genes modifying endogenous mHTT using high-throughput screening and demonstrate NUB1 as an exemplar entry point for therapeutic intervention of Huntington's disease. View Publication

Herpesvirus saimiri (HVS) infects a range of human cell types with high efficiency. Upon infection,the viral genome can persist as high-copy-number,circular,nonintegrated episomes that segregate to progeny cells upon division. This allows HVS-based vectors to stably transduce a dividing cell population and provide sustained transgene expression in vitro and in vivo. Moreover,the HVS episome is able to persist and provide prolonged transgene expression during in vitro differentiation of mouse and human hemopoietic progenitor cells. Together,these properties are advantageous for induced pluripotent stem cell (iPSC) technology,whereby stem cell-like cells are generated from adult somatic cells by exogenous expression of specific reprogramming factors. Here we assess the potential of HVS-based vectors for the generation of induced pluripotent cancer stem-like cells (iPCs). We demonstrate that HVS-based exogenous delivery of Oct4,Nanog,and Lin28 can reprogram the Ewing's sarcoma family tumor cell line A673 to produce stem cell-like colonies that can grow under feeder-free stem cell culture conditions. Further analysis of the HVS-derived putative iPCs showed some degree of reprogramming into a stem cell-like state. Specifically,the putative iPCs had a number of embryonic stem cell characteristics,staining positive for alkaline phosphatase and SSEA4,in addition to expressing elevated levels of pluripotent marker genes involved in proliferation and self-renewal. However,differentiation trials suggest that although the HVS-derived putative iPCs are capable of differentiation toward the ectodermal lineage,they do not exhibit pluripotency. Therefore,they are hereby termed induced multipotent cancer cells. View Publication

Human embryonic stem cells (hESCs) can be differentiated into multiple cell types with great therapeutic potential. However,optimizing the often multi-week cultures to obtain sufficient differentiated cell yields has been in part limited by the high variability of even parallel hESC differentiation cultures. We describe the isolation and features of a subline of CA1 hESCs (CA1S) that display a very high 25% cloning efficiency while retaining many properties of the parental hESCs,including being karyotypically normal and their ability to generate teratomas containing all three germ layers. Although more detailed analysis revealed that CA1S cells have a 3.8 Mb genomic duplication on chromosome 20,they remain highly useful. In particular,CA1S cells are readily expanded at high yields in culture and possess greatly reduced well-to-well variation even when seeded at 100 cells/well. Thus,108 CA1S cells can be generated within one week from 106 cells to seed 106 wells. We determined that CA1S cells have the capacity to follow established in vitro differentiation protocols to pancreatic progenitors and subsequent hormone-positive cell types and used CA1S cells to explore definitive endoderm induction in a high performance screen (Z-factor = 0.97). This system revealed that CA1S cells do not require WNT3A to efficiently form definitive endoderm,a finding that was confirmed with H1 hESCs,although H1 cells did show modest benefits of high WNT3A doses. Proliferative index measurements of CA1S cells were shown to rapidly reflect their differentiation status in a high throughput system. Though results obtained with CA1S cells will need to be confirmed using conventional hESC lines,these cells should ease the development of optimized hESC growth and differentiation protocols. In particular,they should limit the more arduous secondary screens using hESCs to a smaller number of variables and doses. Biotechnol. Bioeng. 2013;110: 2706–2716. textcopyright 2013 Wiley Periodicals,Inc. View Publication

Aging is known to be the single most important risk factor for multiple diseases. Sirtuin 6,or SIRT6,has recently been identified as a critical regulator of transcription,genome stability,telomere integrity,DNA repair,and metabolic homeostasis. A knockout mouse model of SIRT6 has displayed dramatic phenotypes of accelerated aging. In keeping with its role in aging,we demonstrated that human dermal fibroblasts (HDFs) from older human subjects were more resistant to reprogramming by classic Yamanaka factors than those from younger human subjects,but the addition of SIRT6 during reprogramming improved such efficiency in older HDFs substantially. Despite the importance of SIRT6,little is known about the molecular mechanism of its regulation. We show,for the first,time posttranscriptional regulation of SIRT6 by miR-766 and inverse correlation in the expression of this microRNA in HDFs from different age groups. Our results suggest that SIRT6 regulates miR-766 transcription via a feedback regulatory loop,which has implications for the modulation of SIRT6 expression in reprogramming of aging cells. View Publication

Large-scale manufacture of human embryonic stem cells (hESCs) is prerequisite to their widespread use in biomedical applications. However,current hESC culture strategies are labor-intensive and employ highly variable processes,presenting challenges for scaled production and commercial development. Here we demonstrate that passaging of the hESC lines,HUES7,and NOTT1,with trypsin in feeder-free conditions,is compatible with complete automation on the CompacT SelecT,a commercially available and industrially relevant robotic platform. Pluripotency was successfully retained,as evidenced by consistent proliferation during serial passage,expression of stem cell markers (OCT4,NANOG,TRA1-81,and SSEA-4),stable karyotype,and multi-germlayer differentiation in vitro,including to pharmacologically responsive cardiomyocytes. Automation of hESC culture will expedite cell-use in clinical,scientific,and industrial applications. View Publication

Human embryonic stem (hES) cells represent a potential source for cell replacement therapy of many degenerative diseases. Most frequently,hES cell lines are derived from surplus embryos from assisted reproduction cycles,independent of their quality or morphology. Here,we show that hES cell lines can be obtained from poor-quality blastocysts with the same efficiency as that obtained from good- or intermediate-quality blastocysts. Furthermore,we show that the self-renewal,pluripotency,and differentiation ability of hES cell lines derived from either source are comparable. Finally,we present a simple and reproducible embryoid body-based protocol for the differentiation of hES cells into functional cardiomyocytes. The five new hES cell lines derived here should widen the spectrum of available resources for investigating the biology of hES cells and advancing toward efficient strategies of regenerative medicine. View Publication

Mouse embryonic stem (mES) cells will give rise to all of the cells of the adult mouse,but they failed to rejoin half of the DNA double-strand breaks (dsb) produced by high doses of ionizing radiation. A deficiency in DNA-PK(cs) appears to be responsible since mES cells expressed textless10% of the level of mouse embryo fibroblasts (MEFs) although Ku70/80 protein levels were higher than MEFs. However,the low level of DNA-PK(cs) found in wild-type cells appeared sufficient to allow rejoining of dsb after doses textless20Gy even in G1 phase cells. Inhibition of DNA-PK(cs) with wortmannin and NU7026 still sensitized mES cells to radiation confirming the importance of the residual DNA-PK(cs) at low doses. In contrast to wild-type cells,mES cells lacking H2AX,a histone protein involved in the DNA damage response,were radiosensitive but they rejoined double-strand breaks more rapidly. Consistent with more rapid dsb rejoining,H2AX(-/-) mES cells also expressed 6 times more DNA-PK(cs) than wild-type mES cells. Similar results were obtained for ATM(-/-) mES cells. Differentiation of mES cells led to an increase in DNA-PK(cs),an increase in dsb rejoining rate,and a decrease in Ku70/80. Unlike mouse ES,human ES cells were proficient in rejoining of dsb and expressed high levels of DNA-PK(cs). These results confirm the importance of homologous recombination in the accurate repair of double-strand breaks in mES cells,they help explain the chromosome abnormalities associated with deficiencies in H2AX and ATM,and they add to the growing list of differences in the way rodent and human cells deal with DNA damage. View Publication

The discovery of human embryonic stem cells (hESCs) has dramatically increased the tools available to medical scientists interested in regenerative medicine. However,direct injection of hESCs,and cells differentiated from hESCs,into living organisms has thus far been hampered by significant cell death,teratoma formation,and host immune rejection. Understanding the in vivo hESC behavior after transplantation requires novel imaging techniques to longitudinally monitor hESC localization,proliferation,and viability. Molecular imaging has given investigators a high-throughput,inexpensive,and sensitive means for tracking in vivo cell proliferation over days,weeks,and even months. This advancement has significantly increased the understanding of the spatio-temporal kinetics of hESC engraftment,proliferation,and teratoma-formation in living subjects. A major advance in molecular imaging has been the extension of noninvasive reporter gene assays from molecular and cellular biology into in vivo multi-modality imaging platforms. These reporter genes,under control of engineered promoters and enhancers that take advantage of the host cell s transcriptional machinery,are introduced into cells using a variety of vector and non-vector methods. Once in the cell,reporter genes can be transcribed either constitutively or only under specific biological or cellular conditions,depending on the type of promoter used. Transcription and translation of reporter genes into bioactive proteins is then detected with sensitive,noninvasive instrumentation (e.g.,CCD cameras) using signal-generating probes such as D-luciferin. To avoid the need for excitatory light to track stem cells in vivo as is required for fluorescence imaging,bioluminescence reporter gene imaging systems require only an exogenously administered probe to induce light emission. Firefly luciferase,derived from the firefly Photinus pyralis,encodes an enzyme that catalyzes D-luciferin to the optically active metabolite,oxyluciferin. Optical activity can then be monitored with an external CCD camera. Stably transduced cells that carry the reporter construct within their chromosomal DNA will pass the reporter construct DNA to daughter cells,allowing for longitudinal monitoring of hESC survival and proliferation in vivo. Furthermore,because expression of the reporter gene product is required for signal generation,only viable parent and daughter cells will create bioluminescence signal; apoptotic or dead cells will not. In this video,the specific materials and methods needed for tracking stem cell proliferation and teratoma formation with bioluminescence imaging will be described. View Publication