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Human induced pluripotent stem cells (iPSC) can be used to understand the pathological mechanisms of human disease. These cells are a promising source for cell-replacement therapy. However,such studies require genetically defined conditions. Such genetic manipulations can be performed using the novel Transcription Activator-Like Effector Nucleases (TALENs),which generate site-specific double-strand DNA breaks (DSBs) with high efficiency and precision. Combining the TALEN and iPSC methods,we developed two iPS cell lines by generating the point mutation A5768G in the SCN1A gene,which encodes the voltage-gated sodium channel Nav1.1 α subunit. The engineered iPSC maintained pluripotency and successfully differentiated into neurons with normal functional characteristics. The two cell lines differ exclusively at the epilepsy-susceptibility variant. The ability to robustly introduce disease-causing point mutations in normal hiPS cell lines can be used to generate a human cell model for studying epileptic mechanisms and for drug screening. View Publication

Down's syndrome (DS),caused by trisomy of human chromosome 21,is the most common genetic cause of intellectual disability. Here we use induced pluripotent stem cells (iPSCs) derived from DS patients to identify a role for astrocytes in DS pathogenesis. DS astroglia exhibit higher levels of reactive oxygen species and lower levels of synaptogenic molecules. Astrocyte-conditioned medium collected from DS astroglia causes toxicity to neurons,and fails to promote neuronal ion channel maturation and synapse formation. Transplantation studies show that DS astroglia do not promote neurogenesis of endogenous neural stem cells in vivo. We also observed abnormal gene expression profiles from DS astroglia. Finally,we show that the FDA-approved antibiotic drug,minocycline,partially corrects the pathological phenotypes of DS astroglia by specifically modulating the expression of S100B,GFAP,inducible nitric oxide synthase,and thrombospondins 1 and 2 in DS astroglia. Our studies shed light on the pathogenesis and possible treatment of DS by targeting astrocytes with a clinically available drug. View Publication

Definitive endoderm can be derived from human embryonic stem cells using low serum medium with cytokines involved in the epithelial-to-mesenchymal transition,including Activin A and Wnt3A. The purpose of this study was to develop an improved protocol that permits the induction of definitive endoderm while avoiding the high rate of cell death that often occurs with existing protocols. By including insulin and other nutrients,we demonstrate that cell viability can be preserved throughout differentiation. In addition,modifying a matrigel sandwich method previously reported to induce precardiac mesoderm allows for enhanced endodermal differentiation based on expression of endoderm-associated genes. The morphological and migratory characteristics of cells cultured by the technique,as well as gene expression patterns,indicate that the protocol can emulate key events in gastrulation towards the induction of definitive endoderm. View Publication

For years,our ability to study pathological changes in neurological diseases has been hampered by the lack of relevant models until the recent groundbreaking work from Yamanaka's group showing that it is feasible to generate induced pluripotent stem cells (iPSCs) from human somatic cells and to redirect the fate of these iPSCs into differentiated cells. In particular,much interest has focused on the ability to differentiate human iPSCs into neuronal progenitors and functional neurons for relevance to a large number of pathologies including mental retardation and behavioral or degenerative syndromes. Current differentiation protocols are time-consuming and generate limited amounts of cells,hindering use on a large scale. We describe a feeder-free method relying on the use of a chemically defined medium that overcomes the need for embryoid body formation and neuronal rosette isolation for neuronal precursors and terminally differentiated neuron production. Four days after induction,expression of markers of the neurectoderm lineage is detectable. Between 4 and 7 days,neuronal precursors can be expanded,frozen,and thawed without loss of proliferation and differentiation capacities or further differentiated. Terminal differentiation into the different subtypes of mature neurons found in the human brain were observed. At 6-35 days after induction,cells express typical voltage-gated and ionotrophic receptors for GABA,glycine,and acetylcholine. This specific and efficient single-step strategy in a chemically defined medium allows the production of mature neurons in 20-40 days with multiple applications,especially for modeling human pathologies. View Publication

Pluripotent human embryonic stem cells (hESCs) can be efficiently directed to become immature neuroepithelial precursor cells (NPCs) and functional mature neural cells,including neurotransmitter-secreting neurons and glial cells. Investigating the susceptibility of these hESCs-derived neural cells to neurotrophic viruses,such as Japanese encephalitis virus (JEV),provides insight into the viral cell tropism in the infected human brain. We demonstrate that hESC-derived NPCs are highly vulnerable to JEV infection at a low multiplicity of infection (MOI). In addition,glial fibrillary acid protein (GFAP)-expressing glial cells are also susceptible to JEV infection. In contrast,only a few mature neurons were infected at MOI 10 or higher on the third day post-infection. In addition,functional neurotransmitter-secreting neurons are also resistant to JEV infection at high MOI. Moreover,we discover that vimentin intermediate filament,reported as a putative neurovirulent JEV receptor,is highly expressed in NPCs and glial cells,but not mature neurons. These results indicate that the expression of vimentin in neural cells correlates to the cell tropism of JEV. Finally,we further demonstrate that membranous vimentin is necessary for the susceptibility of hESC-derived NPCs to JEV infection. View Publication

The application of stem-cell-based therapies in regenerative medicine is hindered by the tumorigenic potential of residual human pluripotent stem cells. Previously,we identified a human pluripotent stem-cell-specific lectin probe,called rBC2LCN,by comprehensive glycome analysis using high-density lectin microarrays. Here we developed a recombinant lectin-toxin fusion protein of rBC2LCN with a catalytic domain of Pseudomonas aeruginosa exotoxin A,termed rBC2LCN-PE23,which could be expressed as a soluble form from the cytoplasm of Escherichia coli and purified to homogeneity by one-step affinity chromatography. rBC2LCN-PE23 bound to human pluripotent stem cells,followed by its internalization,allowing intracellular delivery of a cargo of cytotoxic protein. The addition of rBC2LCN-PE23 to the culture medium was sufficient to completely eliminate human pluripotent stem cells. Thus,rBC2LCN-PE23 has the potential to contribute to the safety of stem-cell-based therapies. View Publication

Human pluripotent stem cells (hPSCs) represent very promising resources for cell-based regenerative medicine. It is essential to determine the biological implications of some fundamental physiological processes (such as glycogen metabolism) in these stem cells. In this report,we employ electron,immunofluorescence microscopy,and biochemical methods to study glycogen synthesis in hPSCs. Our results indicate that there is a high level of glycogen synthesis (0.28 to 0.62 $$g/$$g proteins) in undifferentiated human embryonic stem cells (hESCs) compared with the glycogen levels (0 to 0.25 $$g/$$g proteins) reported in human cancer cell lines. Moreover,we found that glycogen synthesis was regulated by bone morphogenetic protein 4 (BMP-4) and the glycogen synthase kinase 3 (GSK-3) pathway. Our observation of glycogen bodies and sustained expression of the pluripotent factor Oct-4 mediated by the potent GSK-3 inhibitor CHIR-99021 reveals an altered pluripotent state in hPSC culture. We further confirmed glycogen variations under different naïve pluripotent cell growth conditions based on the addition of the GSK-3 inhibitor BIO. Our data suggest that primed hPSCs treated with naïve growth conditions acquire altered pluripotent states,similar to those naïve-like hPSCs,with increased glycogen synthesis. Furthermore,we found that suppression of phosphorylated glycogen synthase was an underlying mechanism responsible for altered glycogen synthesis. Thus,our novel findings regarding the dynamic changes in glycogen metabolism provide new markers to assess the energetic and various pluripotent states in hPSCs. The components of glycogen metabolic pathways offer new assays to delineate previously unrecognized properties of hPSCs under different growth conditions. View Publication

The ability to derive and stably maintain ground-state human pluripotent stem cells (hPSCs) that resemble the cells seen in vivo in the inner cell mass has the potential to be an invaluable tool for researchers developing stem cell-based therapies. To date,derivation of human naive-like pluripotent stem cell lines has been limited to a small number of lineages,and their long-term culturing remains problematic. We describe a protocol for genetic and phenotypic tagging,selecting and maintaining naive-like hPSCs. We tag hPSCs by GFP,expressed by the long terminal repeat (LTR7) of HERVH endogenous retrovirus. This simple and efficient protocol has been reproduced with multiple hPSC lines,including embryonic and induced pluripotent stem cells,and it takes ∼6 weeks. By using the reporter,homogeneous hPSC cultures can be derived,characterized and maintained for the long term by repeated re-sorting and re-plating steps. The HERVH-expressing cells have a similar,but nonidentical,expression pattern to other naive-like cells,suggesting that alternative pluripotent states might exist. View Publication

Encapsulation of donor islets using a hydrogel material is a well-studied strategy for islet transplantation,which protects donor islets from the host immune response. Replacement of donor islets by human embryonic stem cell (hESC) derived islets will also require a means of immune-isolating hESCs by encapsulation. However,a critical consideration of hESC differentiation is the effect of surrounding biophysical environment,in this case capsule biophysical properties,on differentiation. The objective of this study,thus,was to evaluate the effect of capsule properties on growth,viability,and differentiation of encapsulated hESCs throughout pancreatic induction. It was observed that even in the presence of soluble chemical cues for pancreatic induction,substrate properties can significantly modulate pancreatic differentiation,hence necessitating careful tuning of capsule properties. Capsules in the range of 4-7. kPa supported cell growth and viability,whereas capsules of higher stiffness suppressed cell growth. While an increase in capsule stiffness enhanced differentiation at the intermediate definitive endoderm (DE) stage,increased stiffness strongly suppressed pancreatic progenitor (PP) induction. Signaling pathway analysis indicated an increase in pSMAD/pAKT levels with substrate stiffness likely the cause of enhancement of DE differentiation. In contrast,sonic hedgehog inhibition was more efficient under softer gel conditions,which is necessary for successful PP differentiation. Statement of Significance: Cell replacement therapy for type 1 diabetes (T1D),affecting millions of people worldwide,requires the immunoisolation of insulin-producing islets by encapsulation with a semi-impermeable material. Due to the shortage of donor islets,human pluripotent stem cell (hPSC) derived islets are an attractive alternative. However,properties of the encapsulating substrate are known to influence hPSC cell fate. In this work,we determine the effect of substrate stiffness on growth and pancreatic fate of encapsulated hPSCs. We precisely identify the range of substrate properties conducive for pancreatic cell fate,and also the mechanism by which substrate properties modify the cell signaling pathways and hence cell fate. Such information will be critical in driving regenerative cell therapy for long term treatment of T1D. View Publication

Pericytes (PCs) are endothelium-associated cells that play an important role in normal vascular function and maintenance. We developed a method comparable to GMP quality protocols for deriving self-renewing perivascular progenitors from the human embryonic stem cell (hESC),line ESI-017. We identified a highly scalable,perivascular progenitor cell line that we termed PC-A,which expressed surface markers common to mesenchymal stromal cells. PC-A cells were not osteogenic or adipogenic under standard differentiation conditions and showed minimal angiogenic support function in vitro. PC-A cells were capable of further differentiation to perivascular progenitors with limited differentiation capacity,having osteogenic potential (PC-O) or angiogenic support function (PC-M),while lacking adipogenic potential. Importantly,PC-M cells expressed surface markers associated with pericytes. Moreover,PC-M cells had pericyte-like functionality being capable of co-localizing with human umbilical vein endothelial cells (HUVECs) and enhancing tube stability up to 6 days in vitro. We have thus identified a self-renewing perivascular progenitor cell line that lacks osteogenic,adipogenic and angiogenic potential but is capable of differentiation toward progenitor cell lines with either osteogenic potential or pericyte-like angiogenic function. The hESC-derived perivascular progenitors described here have potential applications in vascular research,drug development and cell therapy. View Publication