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Cellular reprogramming from adult somatic cells into an embryonic cell-like state,termed induced pluripotency,has been achieved in several cell types. However,the ability to reprogram human amniotic epithelial cells (hAECs),an abundant cell source derived from discarded placental tissue,has only recently been investigated. Here we show that not only are hAECs easily reprogrammed into induced pluripotent stem cells (AE-iPSCs),but hAECs reprogram faster and more efficiently than adult and neonatal somatic dermal fibroblasts. Furthermore,AE-iPSCs express higher levels of NANOG and OCT4 compared to human foreskin fibroblast iPSCs (HFF1-iPSCs) and express decreased levels of genes associated with differentiation,including NEUROD1 and SOX17,markers of neuronal differentiation. To elucidate the mechanism behind the higher reprogramming efficiency of hAECs,we analyzed global DNA methylation,global histone acetylation,and the mitochondrial DNA A3243G point mutation. Whereas hAECs show no differences in global histone acetylation or mitochondrial point mutation accumulation compared to adult and neonatal dermal fibroblasts,hAECs demonstrate a decreased global DNA methylation compared to dermal fibroblasts. Likewise,quantitative gene expression analyses show that hAECs endogenously express OCT4,SOX2,KLF4,and c-MYC,all four factors used in cellular reprogramming. Thus,hAECs represent an ideal cell type for testing novel approaches for generating clinically viable iPSCs and offer significant advantages over postnatal cells that more likely may be contaminated by environmental exposures and infectious agents. View Publication

Human embryonic stem cells (hESCs) hold great promise for regenerative medicine because they can undergo unlimited self-renewal and retain the capability to differentiate into all cell types in the body. Although numerous genes/proteins such as Oct4 and Gata6 have been identified to play critical regulatory roles in self-renewal and differentiation of hESC,the majority of the regulators in these cellular processes and more importantly how these regulators co-operate with each other and/or with epigenetic modifications are still largely unknown. We propose here a systematic approach to integrate genomic and epigenomic data for identification of direct regulatory interactions. This approach allows reconstruction of cell-type-specific transcription networks in embryonic stem cells (ESCs) and fibroblasts at an unprecedented scale. Many links in the reconstructed networks coincide with known regulatory interactions or literature evidence. Systems-level analyses of these networks not only uncover novel regulators for pluripotency and differentiation,but also reveal extensive interplays between transcription factor binding and epigenetic modifications. Especially,we observed poised enhancers characterized by both active (H3K4me1) and repressive (H3K27me3) histone marks that contain enriched Oct4- and Suz12-binding sites. The success of such a systems biology approach is further supported by experimental validation of the predicted interactions. View Publication

Considerable progress has been made in identifying signaling pathways that direct the differentiation of human pluripotent stem cells (hPSCs) into specialized cell types,including neurons. However,differentiation of hPSCs with extrinsic factors is a slow,step-wise process,mimicking the protracted timing of human development. Using a small-molecule screen,we identified a combination of five small-molecule pathway inhibitors that yield hPSC-derived neurons at textgreater75% efficiency within 10 d of differentiation. The resulting neurons express canonical markers and functional properties of human nociceptors,including tetrodotoxin (TTX)-resistant,SCN10A-dependent sodium currents and response to nociceptive stimuli such as ATP and capsaicin. Neuronal fate acquisition occurs about threefold faster than during in vivo development,suggesting that use of small-molecule pathway inhibitors could become a general strategy for accelerating developmental timing in vitro. The quick and high-efficiency derivation of nociceptors offers unprecedented access to this medically relevant cell type for studies of human pain. View Publication

Embryonic development can be partially recapitulated in vitro by differentiating human embryonic stem cells (hESCs). Thalidomide is a developmental toxicant in vivo and acts in a species-dependent manner. Besides its therapeutic value,thalidomide also serves as a prototypical model to study teratogenecity. Although many in vivo and in vitro platforms have demonstrated its toxicity,only a few test systems accurately reflect human physiology. We used global gene expression and proteomics profiling (two dimensional electrophoresis (2DE) coupled with Tandem Mass spectrometry) to demonstrate hESC differentiation and thalidomide embryotoxicity/teratogenecity with clinically relevant dose(s). Proteome analysis showed loss of POU5F1 regulatory proteins PKM2 and RBM14 and an over expression of proteins involved in neuronal development (such as PAK2,PAFAH1B2 and PAFAH1B3) after 14 days of differentiation. The genomic and proteomic expression pattern demonstrated differential expression of limb,heart and embryonic development related transcription factors and biological processes. Moreover,this study uncovered novel possible mechanisms,such as the inhibition of RANBP1,that participate in the nucleocytoplasmic trafficking of proteins and inhibition of glutathione transferases (GSTA1,GSTA2),that protect the cell from secondary oxidative stress. As a proof of principle,we demonstrated that a combination of transcriptomics and proteomics,along with consistent differentiation of hESCs,enabled the detection of canonical and novel teratogenic intracellular mechanisms of thalidomide. View Publication

Linker histones are essential components of chromatin,but the distributions and functions of many during cellular differentiation are not well understood. Here,we show that H1.5 binds to genic and intergenic regions,forming blocks of enrichment,in differentiated human cells from all three embryonic germ layers but not in embryonic stem cells. In differentiated cells,H1.5,but not H1.3,binds preferentially to genes that encode membrane and membrane-related proteins. Strikingly,37% of H1.5 target genes belong to gene family clusters,groups of homologous genes that are located in proximity to each other on chromosomes. H1.5 binding is associated with gene repression and is required for SIRT1 binding,H3K9me2 enrichment,and chromatin compaction. Depletion of H1.5 results in loss of SIRT1 and H3K9me2,increased chromatin accessibility,deregulation of gene expression,and decreased cell growth. Our data reveal for the first time a specific and novel function for linker histone subtype H1.5 in maintenance of condensed chromatin at defined gene families in differentiated human cells. View Publication

Embryonic stem cells can replicate continuously in the absence of senescence and,therefore,are immortal in culture. Although genome stability is essential for the survival of stem cells,proteome stability may have an equally important role in stem-cell identity and function. Furthermore,with the asymmetric divisions invoked by stem cells,the passage of damaged proteins to daughter cells could potentially destroy the resulting lineage of cells. Therefore,a firm understanding of how stem cells maintain their proteome is of central importance. Here we show that human embryonic stem cells (hESCs) exhibit high proteasome activity that is correlated with increased levels of the 19S proteasome subunit PSMD11 (known as RPN-6 in Caenorhabditis elegans) and a corresponding increased assembly of the 26S/30S proteasome. Ectopic expression of PSMD11 is sufficient to increase proteasome assembly and activity. FOXO4,an insulin/insulin-like growth factor-I (IGF-I) responsive transcription factor associated with long lifespan in invertebrates,regulates proteasome activity by modulating the expression of PSMD11 in hESCs. Proteasome inhibition in hESCs affects the expression of pluripotency markers and the levels of specific markers of the distinct germ layers. Our results suggest a new regulation of proteostasis in hESCs that links longevity and stress resistance in invertebrates to hESC function and identity. View Publication

Developing an efficient culture system for controlled human pluripotent stem cell (hPSC) differentiation into selected lineages is a major challenge in realizing stem cell-based clinical applications. Here,we report the use of chitin-alginate 3D microfibrous scaffolds,previously developed for hPSC propagation,to support efficient neuronal differentiation and maturation under chemically defined culture conditions. When treated with neural induction medium containing Noggin/retinoic acid,the encapsulated cells expressed much higher levels of neural progenitor markers SOX1 and PAX6 than those in other treatment conditions. Immunocytochemisty analysis confirmed that the majority of the differentiated cells were nestin-positive cells. Subsequently transferring the scaffolds to neuronal differentiation medium efficiently directed these encapsulated neural progenitors into mature neurons,as detected by RT-PCR and positive immunostaining for neuron markers βIII tubulin and MAP2. Furthermore,flow cytometry confirmed that textgreater90% βIII tubulin-positive neurons was achieved for three independent iPSC and hESC lines,a differentiation efficiency much higher than previously reported. Implantation of these terminally differentiated neurons into SCID mice yielded successful neural grafts comprising MAP2 positive neurons,without tumorigenesis,suggesting a potential safe cell source for regenerative medicine. These results bring us one step closer toward realizing large-scale production of stem cell derivatives for clinical and translational applications. View Publication

BACKGROUND Strategies on the basis of doxycycline-inducible lentiviruses in mouse cells allowed the examination of mechanisms governing somatic cell reprogramming. RESULTS Using a doxycycline-inducible human reprogramming system,we identified unreported miRs enhancing reprogramming efficiency. CONCLUSION We generated a drug-inducible human reprogramming reporter system as an invaluable tool for genetic or chemical screenings. SIGNIFICANCE These cellular systems provide a tool to enable the advancement of reprogramming technologies in human cells. Reprogramming of somatic cells into induced pluripotent stem cells is achieved by the expression of defined transcription factors. In the last few years,reprogramming strategies on the basis of doxycycline-inducible lentiviruses in mouse cells became highly powerful for screening purposes when the expression of a GFP gene,driven by the reactivation of endogenous stem cell specific promoters,was used as a reprogramming reporter signal. However,similar reporter systems in human cells have not been generated. Here,we describe the derivation of drug-inducible human fibroblast-like cell lines that express different subsets of reprogramming factors containing a GFP gene under the expression of the endogenous OCT4 promoter. These cell lines can be used to screen functional substitutes for reprogramming factors or modifiers of reprogramming efficiency. As a proof of principle of this system,we performed a screening of a library of pluripotent-enriched microRNAs and identified hsa-miR-519a as a novel inducer of reprogramming efficiency. View Publication

Human embryonic stem cells (hESCs) provide a valuable window into the dissection of the molecular circuitry underlying the early formation of the human forebrain. However,dissection of signaling events in forebrain development using current protocols is complicated by non-neural contamination and fluctuation of extrinsic influences. Here,we show that SMAD7,a cell-intrinsic inhibitor of transforming growth factor-β (TGFβ) signaling,is sufficient to directly convert pluripotent hESCs to an anterior neural fate. Time course gene expression revealed downregulation of MAPK components,and combining MEK1/2 inhibition with SMAD7-mediated TGFβ inhibition promoted telencephalic conversion. Fibroblast growth factor-MEK and TGFβ-SMAD signaling maintain hESCs by promoting pluripotency genes and repressing neural genes. Our findings suggest that in the absence of these cues,pluripotent cells simply revert to a program of neural conversion. Hence,the primed" state of hESCs requires inhibition of the "default" state of neural fate acquisition. This has parallels in amphibians� View Publication

Biochemical factors can help reprogram somatic cells into pluripotent stem cells,yet the role of biophysical factors during reprogramming is unknown. Here,we show that biophysical cues,in the form of parallel microgrooves on the surface of cell-adhesive substrates,can replace the effects of small-molecule epigenetic modifiers and significantly improve reprogramming efficiency. The mechanism relies on the mechanomodulation of the cells' epigenetic state. Specifically,decreased histone deacetylase activity and upregulation of the expression of WD repeat domain 5 (WDR5)—a subunit of H3 methyltranferase—by microgrooved surfaces lead to increased histone H3 acetylation and methylation. We also show that microtopography promotes a mesenchymal-to-epithelial transition in adult fibroblasts. Nanofibrous scaffolds with aligned fibre orientation produce effects similar to those produced by microgrooves,suggesting that changes in cell morphology may be responsible for modulation of the epigenetic state. These findings have important implications in cell biology and in the optimization of biomaterials for cell-engineering applications. View Publication

BACKGROUND: A few reports suggested that low levels of Wnt signaling might drive cell reprogramming,but these studies could not establish a clear relationship between Wnt signaling and self-renewal networks. There are ongoing debates as to whether and how the Wnt/β-catenin signaling is involved in the control of pluripotency gene networks. Additionally,whether physiological β-catenin signaling generates stem-like cells through interactions with other pathways is as yet unclear. The nasopharyngeal carcinoma HONE1 cells have low expression of β-catenin and wild-type expression of p53,which provided a possibility to study regulatory mechanism of stemness networks induced by physiological levels of Wnt signaling in these cells.backslashnbackslashnRESULTS: Introduction of increased β-catenin signaling,haploid expression of β-catenin under control by its natural regulators in transferred chromosome 3,resulted in activation of Wnt/β-catenin networks and dedifferentiation in HONE1 hybrid cell lines,but not in esophageal carcinoma SLMT1 hybrid cells that had high levels of endogenous β-catenin expression. HONE1 hybrid cells displayed stem cell-like properties,including enhancement of CD24(+) and CD44(+) populations and generation of spheres that were not observed in parental HONE1 cells. Signaling cascades were detected in HONE1 hybrid cells,including activation of p53- and RB1-mediated tumor suppressor pathways,up-regulation of Nanog-,Oct4-,Sox2-,and Klf4-mediated pluripotency networks,and altered E-cadherin expression in both in vitro and in vivo assays. qPCR array analyses further revealed interactions of physiological Wnt/β-catenin signaling with other pathways such as epithelial-mesenchymal transition,TGF-β,Activin,BMPR,FGFR2,and LIFR- and IL6ST-mediated cell self-renewal networks. Using β-catenin shRNA inhibitory assays,a dominant role for β-catenin in these cellular network activities was observed. The expression of cell surface markers such as CD9,CD24,CD44,CD90,and CD133 in generated spheres was progressively up-regulated compared to HONE1 hybrid cells. Thirty-four up-regulated components of the Wnt pathway were identified in these spheres.backslashnbackslashnCONCLUSIONS: Wnt/β-catenin signaling regulates self-renewal networks and plays a central role in the control of pluripotency genes,tumor suppressive pathways and expression of cancer stem cell markers. This current study provides a novel platform to investigate the interaction of physiological Wnt/β-catenin signaling with stemness transition networks. View Publication

RATIONALE: Human embryonic stem cell (hESC) derivatives are attractive candidates for therapeutic use. The engraftment and survival of hESC derivatives as xenografts or allografts require effective immunosuppression to prevent immune cell infiltration and graft destruction.backslashnbackslashnOBJECTIVE: To test the hypothesis that a short-course,dual-agent regimen of two costimulation-adhesion blockade agents can induce better engraftment of hESC derivatives compared to current immunosuppressive agents.backslashnbackslashnMETHODS AND RESULTS: We transduced hESCs with a double fusion reporter gene construct expressing firefly luciferase (Fluc) and enhanced green fluorescent protein,and differentiated these cells to endothelial cells (hESC-ECs). Reporter gene expression enabled longitudinal assessment of cell engraftment by bioluminescence imaging. Costimulation-adhesion therapy resulted in superior hESC-EC and mouse EC engraftment compared to cyclosporine therapy in a hind limb model. Costimulation-adhesion therapy also promoted robust hESC-EC and hESC-derived cardiomyocyte survival in an ischemic myocardial injury model. Improved hESC-EC engraftment had a cardioprotective effect after myocardial injury,as assessed by magnetic resonance imaging. Mechanistically,costimulation-adhesion therapy is associated with systemic and intragraft upregulation of T-cell immunoglobulin and mucin domain 3 (TIM3) and a reduced proinflammatory cytokine profile.backslashnbackslashnCONCLUSIONS: Costimulation-adhesion therapy is a superior alternative to current clinical immunosuppressive strategies for preventing the post-transplant rejection of hESC derivatives. By extending the window for cellular engraftment,costimulation-adhesion therapy enhances functional preservation following ischemic injury. This regimen may function through a TIM3-dependent mechanism. View Publication