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Using time-lapse imaging,we have identified a series of bottlenecks that restrict growth of early-passage human embryonic stem cells (hESCs) and that are relieved by karyotypically abnormal variants that are selected by prolonged culture. Only a minority of karyotypically normal cells divided after plating,and these were mainly cells in the later stages of cell cycle at the time of plating. Furthermore,the daughter cells showed a continued pattern of cell death after division,so that few formed long-term proliferating colonies. These colony-forming cells showed distinct patterns of cell movement. Increasing cell density enhanced cell movement facilitating cell:cell contact,which resulted in increased proportion of dividing cells and improved survival postplating of normal hESCs. In contrast,most of the karyotypically abnormal cells reentered the cell cycle on plating and gave rise to healthy progeny,without the need for cell:cell contacts and independent of their motility patterns. ?? 2014 The Authors. View Publication

Fanconi anemia (FA) is an autosomal recessive disorder characterized by progressive bone marrow failure (BMF) during childhood,aside from numerous congenital abnormalities. FA mouse models have been generated; however,they do not fully mimic the hematopoietic phenotype. As there is mounting evidence that the hematopoietic impairment starts already in utero,a human pluripotent stem cell model would constitute a more appropriate system to investigate the mechanisms underlying BMF in FA and its developmental basis. Using zinc finger nuclease (ZFN) technology,we have created a knockout of FANCA in human embryonic stem cells (hESC). We introduced a selection cassette into exon 2 thereby disrupting the FANCA coding sequence and found that whereas mono-allelically targeted cells retain an unaltered proliferation potential,disruption of the second allele causes a severe growth disadvantage. As a result,heterogeneous cultures arise due to the presence of cells still carrying an unaffected FANCA allele,quickly outgrowing the knockout cells. When pure cultures of FANCA knockout hESC are pursued either through selection or single cell cloning,this rapidly results in growth arrest and such cultures cannot be maintained. These data highlight the importance of a functional FA pathway at the pluripotent stem cell stage. ?? 2014. View Publication

Coxsackie virus and adenovirus receptor,CXADR (CAR),is present during embryogenesis and is involved in tissue regeneration,cancer and intercellular adhesion. We investigated the expression of CAR in human preimplantation embryos and embryonic stem cells (hESC) to identify its role in early embryogenesis and differentiation. CAR protein was ubiquitously present during preimplantation development. It was localised in the nucleus of uncommitted cells,from the cleavage stage up to the precursor epiblast,and corresponded with the presence of soluble CXADR3/7 splice variant. CAR was displayed on the membrane,involving in the formation of tight junction at compaction and blastocyst stages in both outer and inner cells,and CAR corresponded with the full-length CAR-containing transmembrane domain. In trophectodermal cells of hatched blastocysts,CAR was reduced in the membrane and concentrated in the nucleus,which correlated with the switch in RNA expression to the CXADR4/7 and CXADR2/7 splice variants. The cells in the outer layer of hESC colonies contained CAR on the membrane and all the cells of the colony had CAR in the nucleus,corresponding with the transmembrane CXADR and CXADR4/7. Upon differentiation of hESC into cells representing the three germ layers and trophoblast lineage,the expression of CXADR was downregulated. We concluded that CXADR is differentially expressed during human preimplantation development. We described various CAR expressions: i) soluble CXADR marking undifferentiated blastomeres; ii) transmembrane CAR related with epithelial-like cell types,such as the trophectoderm (TE) and the outer layer of hESC colonies; and iii) soluble CAR present in TE nuclei after hatching. The functions of these distinct forms remain to be elucidated. View Publication

MED13L is a component subunit of the Mediator complex,an important regulator of transcription that is highly conserved across eukaryotes. Here we report MED13L disruption in a translocation t(12;19) breakpoint of a patient with Pierre-Robin syndrome,moderate intellectual disability (ID),craniofacial anomalies,and muscular defects. The phenotype is similar to previously described patients with MED13L haploinsufficiency. Knockdown of MED13L orthologue in zebrafish,med13b,showed early defective migration of cranial neural crest cells (NCCs) that contributed into cartilage structure deformities in the later stage,recapitulating craniofacial anomalies seen in human patients. Notably,we observed abnormal distribution of developing neurons in different brain regions of med13b morphant embryos,which could be rescued upon introduction of full-length human MED13L mRNA. To compare with mammalian system,we suppressed MED13L expression by short-hairpin RNA in ES-derived human neural progenitors,and differentiated them into neurons. Transcriptome analysis revealed differential expression of components of Wnt and FGF signalling pathways in MED13L-deficient neurons. Our finding provides a novel insight into the mechanism of overlapping phenotypic outcome targeting NCCs derivatives organs in patients with MED13L haploinsufficiency,and emphasizes a clinically recognizable syndromic phenotype in these patients. This article is protected by copyright. All rights reserved. View Publication

Bromodomain-containing protein 4 (BRD4) is an important epigenetic reader implicated in the pathogenesis of a number of different cancers and other diseases. Brd4-null mouse embryos die shortly after implantation and are compromised in their ability to maintain the inner cell mass,which gives rise to embryonic stem cells (ESCs). Here we report that BRD4 regulates expression of the pluripotency factor Nanog in mouse ESCs and preimplantation embryos,as well as in human ESCs and embryonic cancer stem cells. Inhibition of BRD4 function using a chemical inhibitor,small interfering RNAs,or a dominant-negative approach suppresses Nanog expression,and abolishes the self-renewal ability of ESCs. We also find that BRD4 associates with BRG1 (brahma-related gene 1,aka Smarca4 (SWI/SNF-related,matrix-associated,actin-dependent regulator of chromatin,subfamily a,member 4)),a key regulator of ESC self-renewal and pluripotency,in the Nanog regulatory regions to regulate Nanog expression. Our study identifies Nanog as a novel BRD4 target gene,providing new insights for the biological function of BRD4 in stem cells and mouse embryos. Knowledge gained from these non-cancerous systems will facilitate future investigations of how Brd4 dysfunction leads to cancers.Cell Death and Differentiation advance online publication,22 August 2014; doi:10.1038/cdd.2014.124. View Publication

Human pluripotent stem cells (hPSCs) are proving to be a valuable source of endothelial cells (ECs),pericytes,and vascular smooth muscle cells (vSMCs). Although an increasing number of phenotypic markers are becoming available to determine the phenotypes of these cells in vitro,the ability to integrate and form functional vessels in the host organism,typically mouse,remains critical for the assessment of EC functional competence. However,current mouse models require relatively large numbers of cells that might be difficult to derive simultaneously from multiple hPSCs lines. Therefore,there is an urgent need for new functional assays that are robust and can be performed with small numbers of cells. Here we describe a novel zebrafish xenograft model to test functionality of hPSC-derived ECs. The assay can be performed in 10 days and requires only ˜100-400 human cells per embryo. Thus,the zebrafish xenograft model can be useful for the accurate and rapid assessment of functionality of hPSC-derived ECs in a lower vertebrate model that is widely viewed by regulatory authorities as a more acceptable alternative to adult mice. View Publication

BackgroundX-chromosome inactivation silences one X chromosome in females to achieve dosage compensation with the single X chromosome in males. While most genes are silenced on the inactive X chromosome,the gene for the long non-coding RNA XIST is silenced on the active X chromosome and expressed from the inactive X chromosome with which the XIST RNA associates,triggering silencing of the chromosome. In mouse,an alternative Xist promoter,P2 is also the site of YY1 binding,which has been shown to serve as a tether between the Xist RNA and the DNA of the chromosome. In humans there are many differences from the initial events of mouse Xist activation,including absence of a functional antisense regulator Tsix,and absence of strictly paternal inactivation in extraembryonic tissues,prompting us to examine regulatory regions for the human XIST gene.ResultsWe demonstrate that the female-specific DNase hypersensitivity site within XIST is specific to the inactive X chromosome and correlates with transcription from an internal P2 promoter. P2 is located within a CpG island that is differentially methylated between males and females and overlaps conserved YY1 binding sites that are only bound on the inactive X chromosome where the sites are unmethylated. However,YY1 binding is insufficient to drive P2 expression or establish the DHS,which may require a development-specific factor. Furthermore,reduction of YY1 reduces XIST transcription in addition to causing delocalization of XIST.ConclusionsThe differentially methylated DNase hypersensitive site within XIST marks the location of an alternative promoter,P2,that generates a transcript of unknown function as it lacks the A repeats that are critical for silencing. In addition,this region binds YY1 on the unmethylated inactive X chromosome,and depletion of YY1 untethers the XIST RNA as well as decreasing transcription of XIST. View Publication

Incurable neurological disorders such as Parkinson's disease (PD),Huntington's disease (HD),and Alzheimer's disease (AD) are very common and can be life-threatening because of their progressive disease symptoms with limited treatment options. To provide an alternative renewable cell source for cell-based transplantation and as study models for neurological diseases,we generated induced pluripotent stem cells (iPSCs) from human dermal fibroblasts (HDFs) and then differentiated them into neural progenitor cells (NPCs) and mature neurons by dual SMAD signaling inhibitors. Reprogramming efficiency was improved by supplementing the histone deacethylase inhibitor,valproic acid (VPA),and inhibitor of p160-Rho associated coiled-coil kinase (ROCK),Y-27632,after retroviral transduction. We obtained a number of iPS colonies that shared similar characteristics with human embryonic stem cells in terms of their morphology,cell surface antigens,pluripotency-associated gene and protein expressions as well as their in vitro and in vivo differentiation potentials. After treatment with Noggin and SB431542,inhibitors of the SMAD signaling pathway,HDF-iPSCs demonstrated rapid and efficient differentiation into neural lineages. Six days after neural induction,neuroepithelial cells (NEPCs) were observed in the adherent monolayer culture,which had the ability to differentiate further into NPCs and neurons,as characterized by their morphology and the expression of neuron-specific transcripts and proteins. We propose that our study may be applied to generate neurological disease patient-specific iPSCs allowing better understanding of disease pathogenesis and drug sensitivity assays. View Publication

Directed neural differentiation of human embryonic stem cells (ESCs) enables researchers to generate diverse neuronal populations for human neural development study and cell replacement therapy. To realize this potential,it is critical to precisely understand the role of various endogenous and exogenous factors involved in neural differentiation. Cell density,one of the endogenous factors,is involved in the differentiation of human ESCs. Seeding cell density can result in variable terminal cell densities or localized cell densities (LCDs),giving rise to various outcomes of differentiation. Thus,understanding how LCD determines the differentiation potential of human ESCs is important. The aim of this study is to highlight the role of LCD in the differentiation of H9 human ESCs into neuroectoderm (NE),the primordium of the nervous system. We found the initially seeded cells form derived cells with variable LCDs and subsequently affect the NE differentiation. Using a newly established method for the quantitative examination of LCD,we demonstrated that in the presence of induction medium supplemented with or without SMAD signaling blockers,high LCD promotes the differentiation of NE. Moreover,SMAD signaling blockade promotes the differentiation of NE but not non-NE germ layers,which is dependent on high LCDs. Taken together,this study highlights the need to develop innovative strategies or techniques based on LCDs for generating neural progenies from human ESCs. View Publication

We here report that doxycycline,an antibacterial agent,exerts dramatic effects on human embryonic stem and induced pluripotent stem cells (hESC/iPSCs) survival and self-renewal. The survival-promoting effect was also manifest in cultures of neural stem cells (NSCs) derived from hESC/iPSCs. These doxycycline effects are not associated with its antibacterial action,but mediated by direct activation of a PI3K-AKT intracellular signal. These findings indicate doxycycline as a useful supplement for stem cell cultures,facilitating their growth and maintenance. View Publication

Neural crest is a population of multipotent progenitor cells that form at the border of neural and non-neural ectoderm in vertebrate embryos,and undergo epithelial-mesenchymal transition and migration. According to the traditional view,the neural crest is specified in early embryos by signaling molecules including BMP,FGF,and Wnt proteins. Here,we identify a novel signaling pathway leading to neural crest specification,which involves Rho-associated kinase (ROCK) and its downstream target nonmuscle Myosin II. We show that ROCK inhibitors promote differentiation of human embryonic stem cells (hESCs) into neural crest-like progenitors (NCPs) that are characterized by specific molecular markers and ability to differentiate into multiple cell types,including neurons,chondrocytes,osteocytes,and smooth muscle cells. Moreover,inhibition of Myosin II was sufficient for generating NCPs at high efficiency. Whereas Myosin II has been previously implicated in the self-renewal and survival of hESCs,we demonstrate its role in neural crest development during ESC differentiation. Inhibition of this pathway in Xenopus embryos expanded neural crest in vivo,further indicating that neural crest specification is controlled by ROCK-dependent Myosin II activity. We propose that changes in cell morphology in response to ROCK and Myosin II inhibition initiate mechanical signaling leading to neural crest fates. View Publication

There is no consensus in the stem cell field as to what constitutes the mature cardiac myocyte. Thus,helping formalize a molecular signature for cardiac myocyte maturation would advance the field. In the mammalian heart,inactivation of the fetal" TNNI gene� View Publication