技术资料

Human embryonic stem cells (hESCs) is a potential unlimited ex vivo source of ventricular (V) cardiomyocytes (CMs),but hESC-VCMs and their engineered tissues display immature traits. In adult VCMs,sarcolemmal (sarc) and mitochondrial (mito) ATP-sensitive potassium (KATP) channels play crucial roles in excitability and cardioprotection. In this study,we aim to investigate the biological roles and use of sarcKATP and mitoKATP in hESC-VCM. We showed that SarcIK,ATP in single hESC-VCMs was dormant under baseline conditions,but became markedly activated by cyanide (CN) or the known opener P1075 with a current density that was ˜8-fold smaller than adult; These effects were reversible upon washout or the addition of GLI or HMR1098. Interestingly,sarcIK,ATP displayed a ˜3-fold increase after treatment with hypoxia (5% O2). MitoIK,ATP was absent in hESC-VCMs. However,the thyroid hormone T3 up-regulated mitoIK,ATP,conferring diazoxide protective effect on T3-treated hESC-VCMs. When assessed using a multi-cellular engineered 3D ventricular cardiac micro-tissue (hvCMT) system,T3 substantially enhanced the developed tension by 3-folds. Diazoxide also attenuated the decrease in contractility induced by simulated ischemia (1% O2). We conclude that hypoxia and T3 enhance the functionality of hESC-VCMs and their engineered tissues by selectively acting on sarc and mitoIK,ATP. View Publication

Wnt signaling plays essential roles in both embryonic pattern formation and postembryonic tissue homoestasis. High levels of Wnt activity repress foregut identity and facilitate hindgut fate through forming a gradient of Wnt signaling activity along the anterior-posterior axis. Here,we examined the mechanisms of Wnt signaling in hindgut development by differentiating human embryonic stem cells (hESCs) into the hindgut progenitors. We observed severe morphological changes when Wnt signaling was blocked by using Wnt antagonist Dkk1. We performed deep-transcriptome sequencing (RNA-seq) and identified 240 Wnt-activated genes and 2023 Wnt-repressed genes,respectively. Clusters of Wnt targets showed enrichment in specific biological functions,such as gastrointestinal or skeletal development" in the Wnt-activated targets and "neural or immune system development" in the Wnt-repressed targets. Moreover� View Publication

The sodium bicarbonate co-transporter (NBC) is the major bicarbonate-dependent acid-base transporter in mammalian astrocytes and has been implicated in ischemic brain injury. A malfunction of astrocytes could have great impact on the outcome of stroke due to their participation in the formation of blood-brain barrier,synaptic transmission,and electrolyte balance in the human brain. Nevertheless,the role of NBC in the ischemic astrocyte death has not been well understood. In this work,we obtained skin biopsies from healthy human subjects and had their fibroblasts grown in culture and reprogrammed into human-induced pluripotent stem cells (hiPSCs). These hiPSCs were further differentiated into neuroprogenitor cells (NPCs) and then into human astrocytes. These astrocytes express GFAP and S100β and readily propagate calcium waves upon mechanical stimulation. Using pH-sensitive dye BCECF [2',7'-bis-(carboxyethyl)-5-(and-6)-carboxyfluorescein] and qPCR technique,we have confirmed that these astrocytes express functional NBC including electrogenic NBC (NBCe). In addition,astrocytes exposed to an ischemic solution (IS) that mimics the ischemic penumbral environment enhanced both mRNA and protein expression level of NBCe1 in astrocytes. Using IS and a generic NBC blocker S0859,we have studied the involvement of NBC in IS-induced human astrocytes death. Our results show that a 30μM S0859 induced a 97.5±1.6% (n=10) cell death in IS-treated astrocytes,which is significantly higher than 43.6±4.5%,(n=10) in the control group treated with IS alone. In summary,a NBC blocker exaggerates IS-induced cell death,suggesting that NBC activity is essential for astrocyte survival when exposed to ischemic penumbral environment. View Publication

Fate allocation in the gastrulating embryo is spatially organized as cells differentiate into specialized cell types depending on their positions with respect to the body axes. There is a need for in vitro protocols that allow the study of spatial organization associated with this developmental transition. Although embryoid bodies and organoids can exhibit some spatial organization of differentiated cells,methods that generate embryoid bodies or organoids do not yield consistent and fully reproducible results. Here,we describe a micropatterning approach in which human embryonic stem cells are confined to disk-shaped,submillimeter colonies. After 42 h of BMP4 stimulation,cells form self-organized differentiation patterns in concentric radial domains,which express specific markers associated with the embryonic germ layers,reminiscent of gastrulating embryos. Our protocol takes 3 d; it uses commercial microfabricated slides (from CYTOO),human laminin-521 (LN-521) as extracellular matrix coating,and either conditioned or chemically defined medium (mTeSR). Differentiation patterns within individual colonies can be determined by immunofluorescence and analyzed with cellular resolution. Both the size of the micropattern and the type of medium affect the patterning outcome. The protocol is appropriate for personnel with basic stem cell culture training. This protocol describes a robust platform for quantitative analysis of the mechanisms associated with pattern formation at the onset of gastrulation. View Publication

Patient-derived induced pluripotent stem cells (iPSCs) provide a novel tool to investigate the pathophysiology of poorly known diseases,in particular those affecting the nervous system,which has been difficult to study for its lack of accessibility. In this emerging and promising field,recent iPSCs studies are mostly used as proof-of-principle" experiments that are confirmatory of previous findings obtained from animal models and postmortem human studies; its promise as a discovery tool is just beginning to be realized. A recent number of studies point to the functional similarities between in vitro neurogenesis and in vivo neuronal development� View Publication

The mechanisms underlying human germ cell development are largely unknown,partly due to the scarcity of primordial germ cells and the inaccessibility of the human germline to genetic analysis. Human embryonic stem cells can differentiate to germ cells in vitro and can be genetically modified to study the genetic requirements for germ cell development. Here,we studied NANOS3 and DAZL,which have critical roles in germ cell development in several species,via their over expression in human embryonic stem cells using global transcriptional analysis,in vitro germ cell differentiation,and in vivo germ cell formation assay by xenotransplantation. We found that NANOS3 over expression prolonged pluripotency and delayed differentiation. In addition,we observed a possible connection of NANOS3 with inhibition of apoptosis. For DAZL,our results suggest a post-transcriptional regulation mechanism in hES cells. In addition,we found that DAZL suppressed the translation of OCT4,and affected the transcription of several genes associated with germ cells,cell cycle arrest,and cell migration. Furthermore,DAZL over expressed cells formed spermatogonia-like colonies in a rare instance upon xenotransplantation. These data can be used to further elucidate the role of NANOS3 and DAZL in germ cell development both in vitro and in vivo. View Publication

A new method of spatially controlled gene regulation in 3D-cultured human embryonic stem cells is developed using hollow gold nanoshells (HGNs) and near-infrared (NIR) light. Targeted cell(s) are discriminated from neighboring cell(s) by focusing NIR light emitted from a two-photon microscope. Irradiation of cells that have internalized HGNs releases surface attached siRNAs and leads to concomitant gene downregulation. View Publication

Fibrodysplasia ossificans progressiva (FOP) patients carry a missense mutation in ACVR1 [617G textgreater A (R206H)] that leads to hyperactivation of BMP-SMAD signaling. Contrary to a previous study,here we show that FOP fibroblasts showed an increased efficiency of induced pluripotent stem cell (iPSC) generation. This positive effect was attenuated by inhibitors of BMP-SMAD signaling (Dorsomorphin or LDN1931890) or transducing inhibitory SMADs (SMAD6 or SMAD7). In normal fibroblasts,the efficiency of iPSC generation was enhanced by transducing mutant ACVR1 (617G textgreater A) or SMAD1 or adding BMP4 protein at early times during the reprogramming. In contrast,adding BMP4 at later times decreased iPSC generation. ID genes,transcriptional targets of BMP-SMAD signaling,were critical for iPSC generation. The BMP-SMAD-ID signaling axis suppressed p16/INK4A-mediated cell senescence,a major barrier to reprogramming. These results using patient cells carrying the ACVR1 R206H mutation reveal how cellular signaling and gene expression change during the reprogramming processes. View Publication

Human induced pluripotent stem cell (hiPSC) utility is limited by variations in the ability of these cells to undergo lineage-specific differentiation. We have undertaken a transcriptional comparison of human embryonic stem cell (hESC) lines and hiPSC lines and have shown that hiPSCs are inferior in their ability to undergo neuroectodermal differentiation. Among the differentially expressed candidates between hESCs and hiPSCs,we identified a mitochondrial protein,CHCHD2,whose expression seems to correlate with neuroectodermal differentiation potential of pluripotent stem cells. We provide evidence that hiPSC variability with respect to CHCHD2 expression and differentiation potential is caused by clonal variation during the reprogramming process and that CHCHD2 primes neuroectodermal differentiation of hESCs and hiPSCs by binding and sequestering SMAD4 to the mitochondria,resulting in suppression of the activity of the TGFβ signaling pathway. Using CHCHD2 as a marker for assessing and comparing the hiPSC clonal and/or line differentiation potential provides a tool for large scale differentiation and hiPSC banking studies. View Publication

The CRISPR/Cas9 system is a rapid and customizable tool for gene editing in mammalian cells. In particular,this approach has widely opened new opportunities for genetic studies in neurological disease. Human neurons can be differentiated in vitro from hPSC (human Pluripotent Stem Cells),hNPCs (human Neural Precursor Cells) or even directly reprogrammed from fibroblasts. Here,we described a new platform which enables,rapid and efficient CRISPR/Cas9-mediated genome targeting simultaneously with three different paradigms for in vitro generation of neurons. This system was employed to inactivate two genes associated with neurological disorder (TSC2 and KCNQ2) and achieved up to 85% efficiency of gene targeting in the differentiated cells. In particular,we devised a protocol that,combining the expression of the CRISPR components with neurogenic factors,generated functional human neurons highly enriched for the desired genome modification in only 5 weeks. This new approach is easy,fast and that does not require the generation of stable isogenic clones,practice that is time consuming and for some genes not feasible. View Publication

The creation of a humanized chimeric mouse nervous system permits the study of human neural development and disease pathogenesis using human cells in vivo. Humanized glial chimeric mice with the brain and spinal cord being colonized by human glial cells have been successfully generated. However,generation of humanized chimeric mouse brains repopulated by human neurons to possess a high degree of chimerism have not been well studied. Here we created humanized neuronal chimeric mouse brains by neonatally engrafting the distinct and highly neurogenic human induced pluripotent stem cell (hiPSC)-derived rosette-type primitive neural progenitors. These neural progenitors predominantly differentiate to neurons,which disperse widely throughout the mouse brain with infiltration of the cerebral cortex and hippocampus at 6 and 13 months after transplantation. Building upon the hiPSC technology,we propose that this potentially unique humanized neuronal chimeric mouse model will provide profound opportunities to define the structure,function,and plasticity of neural networks containing human neurons derived from a broad variety of neurological disorders. View Publication

The advent of human induced pluripotent stem cell (hiPSC) technology has produced patient-specific hiPSC derived cardiomyocytes (hiPSC-CMs) that can be used as a platform to study cardiac diseases and to explore new therapies.The ability to genetically manipulate hiPSC-CMs not only is essential for identifying the structural and/or functional role of a protein but can also provide valuable information regarding therapeutic applications. In this chapter,we describe protocols for culture,maintenance,and cardiac differentiation of hiPSCs. Then,we provide a basic procedure to transduce hiPSC-CMs. View Publication