技术资料

Several transcription factors (TFs) have been implicated in neuroectoderm (NE) development,and recently,the TF PAX6 was shown to be critical for human NE specification. However,microRNA networks regulating human NE development have been poorly documented. We hypothesized that microRNAs activated by PAX6 should promote NE development. Using a genomics approach,we identified PAX6 binding sites and active enhancers genome-wide in an in vitro model of human NE development that was based on neural differentiation of human embryonic stem cells (hESC). PAX6 binding to active enhancers was found in the proximity of several microRNAs,including hsa-miR-135b. MiR-135b was activated during NE development,and ectopic expression of miR-135b in hESC promoted differentiation toward NE. MiR-135b promotes neural conversion by targeting components of the TGF-β and BMP signaling pathways,thereby inhibiting differentiation into alternate developmental lineages. Our results demonstrate a novel TF-miRNA module that is activated during human neuroectoderm development and promotes the irreversible fate specification of human pluripotent cells toward the neural lineage. View Publication

We have previously reported the genetic correction of Huntington's disease (HD) patient-derived induced pluripotent stem cells using traditional homologous recombination (HR) approaches. To extend this work,we have adopted a CRISPR-based genome editing approach to improve the efficiency of recombination in order to generate allelic isogenic HD models in human cells. Incorporation of a rapid antibody-based screening approach to measure recombination provides a powerful method to determine relative efficiency of genome editing for modeling polyglutamine diseases or understanding factors that modulate CRISPR/Cas9 HR. View Publication

Embryonic stem (ES) and induced-pluripotent stem (iPS) cells can be grown indefinitely under appropriate conditions whilst retaining the ability to differentiate to cells representative of the three primary germ layers. Such cells have the potential to revolutionize medicine by offering treatment options for a wide range of diseases and disorders as well as providing a model system for elucidating mechanisms involved in development and disease. In recent years,evidence for the function of E-cadherin in regulating pluripotent and self-renewal signaling pathways in ES and iPS cells has emerged. In this review,we discuss the function of E-cadherin and its interacting partners in the context of development and disease. We then describe relevant literature highlighting the function of E-cadherin in establishing and maintaining pluripotent and self-renewal properties of ES and iPS cells. In addition,we present experimental data demonstrating that exposure of human ES cells to the E-cadherin neutralizing antibody SHE78.7 allows culture of these cells in the absence of FGF2-supplemented medium. View Publication

PURPOSE Demonstrate a novel manufacturing method to generate extracellular matrix scaffolds from cardiac fibroblasts (CF-ECM) as a therapeutic mesenchymal stem cell-transfer device. MATERIALS AND METHODS Rat CF were cultured at high-density (˜1.6×10(5)/cm(2)) for 10-14 days. Cell sheets were removed from the culture dish by incubation with EDTA and decellularized with water and peracetic acid. CF-ECM was characterized by mass spectrometry,immunofluorescence and scanning electron microscopy. CF-ECM seeded with human embryonic stem cell derived mesenchymal stromal cells (hEMSCs) were transferred into a mouse myocardial infarction model. 48 hours later,mouse hearts were excised and examined for CF-ECM scaffold retention and cell transfer. RESULTS CF-ECM scaffolds are composed of fibronectin (82%),collagens type I (13%),type III (3.4%),type V (0.2%),type II (0.1%) elastin (1.3%) and 18 non-structural bioactive molecules. Scaffolds remained intact on the mouse heart for 48 hours without the use of sutures or glue. Identified hEMSCs were distributed from the epicardium to the endocardium. CONCLUSIONS High density cardiac fibroblast culture can be used to generate CF-ECM scaffolds. CF-ECM scaffolds seeded with hEMSCs can be maintained on the heart without suture or glue. hEMSC are successfully delivered throughout the myocardium. View Publication

The purpose of this study was to examine the in vitro and in vivo osteogenic potential of human induced pluripotent stem cells (hiPSCs) against that of human bone marrow mesenchymal stem cells (hBMMSCs). Embryoid bodies (EBs),which were formed from undifferentiated hiPSCs,were dissociated into single cells and underwent osteogenic differentiation using the same medium as hBMMSCs for 14 days. Osteoinduced hiPSCs were implanted on the critical-size calvarial defects and long bone segmental defects in rats. The healing of defects was evaluated after 8 weeks and 12 weeks of implantation,respectively. Osteoinduced hiPSCs showed relatively lower and delayed in vitro expressions of the osteogenic marker COL1A1 and bone sialoprotein,as well as a weaker osteogenic differentiation through alkaline phosphatase staining and mineralization through Alizarin red staining compared with hBMMSCs. Calvarial defects treated with osteoinduced hiPSCs had comparable quality of new bone formation,including full restoration of bone width and robust formation of trabeculae,to those treated with hBMMSCs. Both osteoinduced hiPSCs and hBMMSCs persisted in regenerated bone after 8 weeks of implantation. In critical-size long bone segmental defects,osteoinduced hiPSC treatment also led to healing of segmental defects comparable to osteoinduced hBMMSC treatment after 12 weeks. In conclusion,despite delayed in vitro osteogenesis,hiPSCs have an in vivo osteogenic potential as good as hBMMSCs. View Publication

Mesenchymal stem cells (MSCs) are being tested in a wide range of human diseases; however,loss of potency and inconsistent quality severely limit their use. To overcome these issues,we have utilized a developmental precursor called the hemangioblast as an intermediate cell type in the derivation of a highly potent and replenishable population of MSCs from human embryonic stem cells (hESCs). This method circumvents the need for labor-intensive hand-picking,scraping,and sorting that other hESC-MSC derivation methods require. Moreover,unlike previous reports on hESC-MSCs,we have systematically evaluated their immunomodulatory properties and in vivo potency. As expected,they dynamically secrete a range of bioactive factors,display enzymatic activity,and suppress T-cell proliferation that is induced by either allogeneic cells or mitogenic stimuli. However,they also display unique immunophenotypic properties,as well as a smaller size and textgreater30,000-fold proliferative capacity than bone marrow-derived MSCs. In addition,this is the first report which demonstrates that hESC-MSCs can inhibit CD83 up-regulation and IL-12p70 secretion from dendritic cells and enhance regulatory T-cell populations induced by interleukin 2 (IL-2). This is also the first report which shows that hESC-MSCs have therapeutic efficacy in two different autoimmune disorder models,including a marked increase in survival of lupus-prone mice and a reduction of symptoms in an autoimmune model of uveitis. Our data suggest that this novel and therapeutically active population of MSCs could overcome many of the obstacles that plague the use of MSCs in regenerative medicine and serve as a scalable alternative to current MSC sources. View Publication

Many different culture systems have been developed for expanding human pluripotent stem cells (hESCs and hiPSCs). In general,4-10 ng/ml of bFGF is supplemented in culture media in feeder-dependent systems regardless of feeder cell types,whereas in feeder-free systems,up to 100 ng/ml of bFGF is required for maintaining long-term culture on various substrates. The amount of bFGF required in native hESCs growth niche is unclear. Here we report using inactivated adipose-derived human mesenchymal stem cells as feeder cells to examine long-term parallel cultures of two hESCs lines (H1 and H9) and one hiPSCs line (DF19-9-7T) in media supplemented with 0,0.4 or 4 ng/ml of bFGF for up to 23 passages,as well as parallel cultures of H9 and DF19 in media supplemented with 4,20 or 100 ng/ml bFGF for up to 13 passages for comparison. Across all cell lines tested,bFGF supplement demonstrated inhibitory effect over growth expansion,single cell colonization and recovery from freezing in a dosage dependent manner. In addition,bFGF exerted differential effects on different cell lines,inducing H1 and DF19 differentiation at 4 ng/ml or higher,while permitting long-term culture of H9 at the same concentrations with no apparent dosage effect. Pluripotency was confirmed for all cell lines cultured in 0,0.4 or 4 ng/ml bFGF excluding H1-4 ng,as well as H9 cultured in 4,20 and 100 ng/ml bFGF. However,DF19 demonstrated similar karyotypic abnormality in both 0 and 4 ng/ml bFGF media while H1 and H9 were karyotypically normal in 0 ng/ml bFGF after long-term culture. Our results indicate that exogenous bFGF exerts dosage and cell line dependent effect on human pluripotent stem cells cultured on mesenchymal stem cells,and implies optimal use of bFGF in hESCs/hiPSCs culture should be based on specific cell line and its culture system. View Publication

Self-renewable human pluripotent stem cells (hPSCs) serve as a potential unlimited ex vivo source of human cardiomyocytes (CMs) for cell-based disease modeling and therapies. Although recent advances in directed differentiation protocols have enabled more efficient derivation of hPSC-derived CMs with an efficiency of ∼50%-80% CMs and a final yield of ∼1-20 CMs per starting undifferentiated hPSC,these protocols are often not readily transferrable across lines without first optimizing multiple parameters. Further,the resultant populations are undefined for chamber specificity or heterogeneous containing mixtures of atrial,ventricular (V),and pacemaker derivatives. Here we report a highly cost-effective and reproducibly efficient system for deriving hPSC-ventricular cardiomyocytes (VCMs) from all five human embryonic stem cell (HES2,H7,and H9) and human induced PSC (hiPSC) (reprogrammed from human adult peripheral blood CD34(+) cells using nonintegrating episomal vectors) lines tested. Cardiogenic embryoid bodies could be formed by the sequential addition of BMP4,Rho kinase inhibitor,activin-A,and IWR-1. Spontaneously contracting clusters appeared as early as day 8. At day 16,up to 95% of cells were cTnT(+). Of which,93%,94%,100%,92%,and 92% of cardiac derivatives from HES2,H7,H9,and two iPSC lines,respectively,were VCMs as gauged by signature ventricular action potential and ionic currents (INa(+)/ICa,L(+)/IKr(+)/IKATP(+)); Ca(2+) transients showed positive chronotropic responses to $\$-adrenergic stimulation. Our simple,cost-effective protocol required the least amounts of reagents and time compared with others. While the purity and percentage of PSC-VCMs were comparable to a recently published protocol,the present yield and efficiency with a final output of up to 70 hPSC-VCMs per hPSC was up to 5-fold higher and without the need of performing line-specific optimization. These differences were discussed. The results may lead to mass production of hPSC-VCMs in bioreactors. View Publication

Blood-brain barrier (BBB) models are often used to investigate BBB function and screen brain-penetrating therapeutics,but it has been difficult to construct a human model that possesses an optimal BBB phenotype and is readily scalable. To address this challenge,we developed a human in vitro BBB model comprising brain microvascular endothelial cells (BMECs),pericytes,astrocytes and neurons derived from renewable cell sources. First,retinoic acid (RA) was used to substantially enhance BBB phenotypes in human pluripotent stem cell (hPSC)-derived BMECs,particularly through adherens junction,tight junction,and multidrug resistance protein regulation. RA-treated hPSC-derived BMECs were subsequently co-cultured with primary human brain pericytes and human astrocytes and neurons derived from human neural progenitor cells (NPCs) to yield a fully human BBB model that possessed significant tightness as measured by transendothelial electrical resistance (˜5,000 $\$(2)). Overall,this scalable human BBB model may enable a wide range of neuroscience studies. View Publication

Reprogramming somatic cells to induced pluripotent stem cells (iPSCs) eliminates many epigenetic modifications that characterize differentiated cells. In this study,we tested whether functional differences between chronic obstructive pulmonary disease (COPD) and non-COPD fibroblasts could be reduced utilizing this approach. Primary fibroblasts from non-COPD and COPD patients were reprogrammed to iPSCs. Reprogrammed iPSCs were positive for oct3/4,nanog,and sox2,formed embryoid bodies in vitro,and induced teratomas in nonobese diabetic/severe combined immunodeficient mice. Reprogrammed iPSCs were then differentiated into fibroblasts (non-COPD-i and COPD-i) and were assessed either functionally by chemotaxis and gel contraction or for gene expression by microarrays and compared with their corresponding primary fibroblasts. Primary COPD fibroblasts contracted three-dimensional collagen gels and migrated toward fibronectin less robustly than non-COPD fibroblasts. In contrast,redifferentiated fibroblasts from iPSCs derived from the non-COPD and COPD fibroblasts were similar in response in both functional assays. Microarray analysis identified 1,881 genes that were differentially expressed between primary COPD and non-COPD fibroblasts,with 605 genes differing by more than twofold. After redifferentiation,112 genes were differentially expressed between COPD-i and non-COPD-i with only three genes by more than twofold. Similar findings were observed with microRNA (miRNA) expression: 56 miRNAs were differentially expressed between non-COPD and COPD primary cells; after redifferentiation,only 3 miRNAs were differentially expressed between non-COPD-i and COPD-i fibroblasts. Interestingly,of the 605 genes that were differentially expressed between COPD and non-COPD fibroblasts,293 genes were changed toward control after redifferentiation. In conclusion,functional and epigenetic alterations of COPD fibroblasts can be reprogrammed through formation of iPSCs. View Publication

Research in the embryo and in culture has resulted in a sophisticated understanding of many regulators of pluripotent cell differentiation. As a consequence,protocols for the differentiation of pluripotent cells generally rely on a combination of exogenous growth factors and endogenous signalling. Little consideration has been given to manipulating other pathways to achieve pluripotent cell differentiation. The integrity of cell:cell contacts has been shown to influence lineage choice during pluripotent cell differentiation,with disruption of cell:cell contacts promoting mesendoderm formation and maintenance of cell:cell contacts resulting in the preferential formation of neurectoderm. Staurosporine is a broad spectrum inhibitor of serine/threonine kinases which has several effects on cell function,including interruption of cell:cell contacts,decreasing focal contact size,inducing epithelial to mesenchyme transition (EMT) and promoting cell differentiation. The possibility that staurosporine could influence lineage choice from pluripotent cells in culture was investigated. The addition of staurosporine to differentiating mouse EPL resulted in preferential formation of mesendoderm and mesoderm populations,and inhibited the formation of neurectoderm. Addition of staurosporine to human ES cells similarly induced primitive streak marker gene expression. These data demonstrate the ability of staurosporine to influence lineage choice during pluripotent cell differentiation and to mimic the effect of disrupting cell:cell contacts. Staurosporine induced mesendoderm in the absence of known inducers of formation,such as serum and BMP4. Staurosporine induced the expression of mesendoderm markers,including markers that were not induced by BMP4,suggesting it acted as a broad spectrum inducer of molecular gastrulation. This approach has identified a small molecule regulator of lineage choice with potential applications in the commercial development of ES cell derivatives,specifically as a method for forming mesendoderm progenitors or as a culture adjunct to prevent the formation of ectoderm progenitors during pluripotent cell differentiation. ?? 2014. View Publication

The key regulators of endothelial differentiation that is induced by shear stress are mostly unclear. Human atonal homolog 6 (Hath6 or ATOH8) is an endothelial-selective and shear-stress-responsive transcription factor. In this study,we sought to elucidate the role of Hath6 in the endothelial specification of embryonic stem cells. In a stepwise human embryonic stem cell to endothelial cell (hESC-EC) induction system,Hath6 mRNA was upregulated synchronously with endothelial determination. Subsequently,gain-of-function and loss-of-function studies of Hath6 were performed using the hESC-EC induction model and endothelial cell lines. The overexpression of Hath6,which mimics shear stress treatment,resulted in an increased CD45(-)CD31(+)KDR(+) population,a higher tubular-structure-formation capacity and increased endothelial-specific gene expression. By contrast,the knockdown of Hath6 mRNA markedly decreased endothelial differentiation. Hath6 also facilitated the maturation of endothelial cells in terms of endothelial gene expression,tubular-structure formation and cell migration. We further demonstrated that the gene encoding eNOS is a direct target of Hath6 through a reporter system assay and western blot analysis,and that the inhibition of eNOS diminishes hESC-EC differentiation. These results suggest that eNOS plays a key role in linking Hath6 to the endothelial phenotype. Further in situ hybridization studies in zebrafish and mouse embryos indicated that homologs of Hath6 are involved in vasculogenesis and angiogenesis. This study provides the first confirmation of the positive impact of Hath6 on human embryonic endothelial differentiation and function. Moreover,we present a potential signaling pathway through which shear stress stimulates endothelial differentiation. View Publication