技术资料

Huntington's disease (HD) is a fatal neurodegenerative disease,caused by expansion of polyglutamine repeats in the Huntingtin gene,with longer expansions leading to earlier ages of onset. The HD iPSC Consortium has recently reported a new in vitro model of HD based on the generation of induced pluripotent stem cells (iPSCs) from HD patients and controls. The current study has furthered the disease in a dish model of HD by generating new non-integrating HD and control iPSC lines. Both HD and control iPSC lines can be efficiently differentiated into neurons/glia; however,the HD-derived cells maintained a significantly greater number of nestin-expressing neural progenitor cells compared with control cells. This cell population showed enhanced vulnerability to brain-derived neurotrophic factor (BDNF) withdrawal in the juvenile-onset HD (JHD) lines,which appeared to be CAG repeat-dependent and mediated by the loss of signaling from the TrkB receptor. It was postulated that this increased death following BDNF withdrawal may be due to glutamate toxicity,as the N-methyl-d-aspartate (NMDA) receptor subunit NR2B was up-regulated in the cultures. Indeed,blocking glutamate signaling,not just through the NMDA but also mGlu and AMPA/Kainate receptors,completely reversed the cell death phenotype. This study suggests that the pathogenesis of JHD may involve in part a population of 'persistent' neural progenitors that are selectively vulnerable to BDNF withdrawal. Similar results were seen in adult hippocampal-derived neural progenitors isolated from the BACHD model mouse. Together,these results provide important insight into HD mechanisms at early developmental time points,which may suggest novel approaches to HD therapeutics. View Publication

BACKGROUND: Long noncoding RNAs (lncRNAs) have emerged as critical epigenetic regulators with important functions in development and disease. Here,we sought to identify and functionally characterize novel lncRNAs critical for vertebrate development. METHODS AND RESULTS: By relying on human pluripotent stem cell differentiation models,we investigated lncRNAs differentially regulated at key steps during human cardiovascular development with a special focus on vascular endothelial cells. RNA sequencing led to the generation of large data sets that serve as a gene expression roadmap highlighting gene expression changes during human pluripotent cell differentiation. Stage-specific analyses led to the identification of 3 previously uncharacterized lncRNAs,TERMINATOR,ALIEN,and PUNISHER,specifically expressed in undifferentiated pluripotent stem cells,cardiovascular progenitors,and differentiated endothelial cells,respectively. Functional characterization,including localization studies,dynamic expression analyses,epigenetic modification monitoring,and knockdown experiments in lower vertebrates,as well as murine embryos and human cells,confirmed a critical role for each lncRNA specific for each analyzed developmental stage. CONCLUSIONS: We have identified and functionally characterized 3 novel lncRNAs involved in vertebrate and human cardiovascular development,and we provide a comprehensive transcriptomic roadmap that sheds new light on the molecular mechanisms underlying human embryonic development,mesodermal commitment,and cardiovascular specification. View Publication

Loss of pluripotency is a gradual event whose initiating factors are largely unknown. Here we report the earliest metabolic changes induced during the first hours of differentiation. High-resolution NMR identified 44 metabolites and a distinct metabolic transition occurring during early differentiation. Metabolic and transcriptional analyses showed that pluripotent cells produced acetyl-CoA through glycolysis and rapidly lost this function during differentiation. Importantly,modulation of glycolysis blocked histone deacetylation and differentiation in human and mouse embryonic stem cells. Acetate,a precursor of acetyl-CoA,delayed differentiation and blocked early histone deacetylation in a dose-dependent manner. Inhibitors upstream of acetyl-CoA caused differentiation of pluripotent cells,while those downstream delayed differentiation. Our results show a metabolic switch causing a loss of histone acetylation and pluripotent state during the first hours of differentiation. Our data highlight the important role metabolism plays in pluripotency and suggest that a glycolytic switch controlling histone acetylation can release stem cells from pluripotency. View Publication

Recent studies have suggested that REX1 (reduced expression 1) plays an important role in pluripotency,proliferation,and differentiation. However,the molecular mechanisms involved in REX1-dependent regulation of diverse cellular processes remain unclear. To elucidate the regulatory functions of REX1 in human embryonic stem cells (hESCs),comparative proteomic analysis was performed on REX1 RNAi specifically silenced hESCs. Analysis of the proteome via nano-LC-MS/MS identified 140 differentially expressed proteins (DEPs) displaying a textgreater2-fold difference in expression level between control and REX1 knockdown (KD) hESCs,which were then compared with transcriptome data and validated by quantitative real-time RT-PCR and Western blotting. These DEPs were analyzed by GO,pathway,and functional clustering analyses to determine the molecular functions of the proteins and pathways regulated by REX1. The REX1 KD-mediated DEPs mapped to major biological processes involved in the regulation of ribosome-mediated translation and mitochondrial function. Functional network analysis revealed a highly interconnected network among these DEPs and indicated that these interconnected proteins are predominantly involved in translation and the regulation of mitochondrial organization. These findings regarding REX1-mediated regulatory network have revealed the contributions of REX1 to maintaining the status of hESCs and have improved our understanding of the molecular events that underlie the fundamental properties of hESCs. View Publication

Current protocols for human pluripotent stem cell (hPSC) expansion require feeder cells or matrices from animal sources that have been the major obstacle to obtain clinical grade hPSCs due to safety issues,difficulty in quality control,and high expense. Thus,feeder-free,chemically defined synthetic platforms have been developed,but are mostly confined to typical polystyrene culture plates. Here,we report a chemically defined,material-independent,bio-inspired surface coating allowing for feeder-free expansion and maintenance of self-renewal and pluripotency of hPSCs on various polymer substrates and devices. Polydopamine (pDA)-mediated immobilization of vitronectin (VN) peptides results in surface functionalization of VN-dimer/pDA conjugates. The engineered surfaces facilitate adhesion,proliferation,and colony formation of hPSCs via enhanced focal adhesion,cell-cell interaction,and biophysical signals,providing a chemically defined,xeno-free culture system for clonal expansion and long-term maintenance of hPSCs. This surface engineering enables the application of clinically-relevant hPSCs to a variety of biomedical systems such as tissue-engineering scaffolds and medical devices. View Publication

Heterogeneity in human pluripotent stem cell (PSC) fates is partially caused by mechanical asymmetry arising from spatial polarization of cell-cell and cell-matrix adhesions. Independent studies have shown that integrin and E-cadherin adhesions promote opposing differentiation and pluripotent fates respectively although their crosstalk mechanism in modulating cell fate heterogeneity remains unknown. Here,we demonstrated that spatial polarization of integrin and E-cadherin adhesions in a human PSC colony compete to recruit Rho-ROCK activated myosin II to different localities to pattern pluripotent-differentiation decisions,resulting in spatially heterogeneous colonies. Cell micropatterning was used to modulate the spatial polarization of cell adhesions,which enabled us to prospectively determine localization patterns of activated myosin II and mesoendoderm differentiation. Direct inhibition of Rho-ROCK-myosin II activation phenocopied E-cadherin rather than integrin inhibition to form uniformly differentiated colonies. This indicated that E-cadherin was the primary gatekeeper to differentiation progression. This insight allows for biomaterials to be tailored for human PSC maintenance or differentiation with minimal heterogeneity. View Publication

The development of xeno-free,chemically defined stem cell culture systems has been a primary focus in the field of regenerative medicine to enhance the clinical application of pluripotent stem cells (PSCs). In this regard,various electrospun substrates with diverse physiochemical properties were synthesized utilizing various polymer precursors and surface treatments. Human induced pluripotent stem cells (IPSCs) cultured on these substrates were characterized by their gene and protein expression to determine the effects of the substrate physiochemical properties on the cells' self-renewal,i.e.,proliferation and the maintenance of pluripotency. The results showed that surface chemistry significantly affected cell colony formation via governing the colony edge propagation. More importantly,when surface chemistry of the substrates was uniformly controlled by collagen conjugation,the stiffness of substrate was inversely related to the sphericity,a degree of three dimensionality in colony morphology. The differences in sphericity subsequently affected spontaneous differentiation of IPSCs during a long-term culture,implicating that the colony morphology is a deciding factor in the lineage commitment of PSCs. Overall,we show that the capability of controlling IPSC colony morphology by electrospun substrates provides a means to modulate IPSC self-renewal. View Publication

BACKGROUND: Virus-specific T-cells (VSTs) proliferate exponentially after adoptive transfer into hematopoietic stem cell transplant (HSCT) recipients,eliminate virus infections,then persist and provide long-term protection from viral disease. If VSTs behaved similarly when modified with tumor-specific chimeric antigen receptors (CARs),they should have potent anti-tumor activity. This theory was evaluated by Cruz et al. in a previous clinical trial with CD19.CAR-modified VSTs,but there was little apparent expansion of these cells in patients. In that study,VSTs were gene-modified on day 19 of culture and we hypothesized that by this time,sufficient T-cell differentiation may have occurred to limit the subsequent proliferative capacity of the transduced T-cells. To facilitate the clinical testing of this hypothesis in a project supported by the NHLBI-PACT mechanism,we developed and optimized a good manufacturing practices (GMP) compliant method for the early transduction of VSTs directed to Epstein-Barr virus (EBV),Adenovirus (AdV) and cytomegalovirus (CMV) using a CAR directed to the tumor-associated antigen disialoganglioside (GD2). RESULTS: Ad-CMVpp65-transduced EBV-LCLs effectively stimulated VSTs directed to all three viruses (triVSTs). Transduction efficiency on day three was increased in the presence of cytokines and high-speed centrifugation of retroviral supernatant onto retronectin-coated plates,so that under optimal conditions up to 88% of tetramer-positive VSTs expressed the GD2.CAR. The average transduction efficiency of early-and late transduced VSTs was 55 ± 4% and 22 ± 5% respectively,and early-transduced VSTs maintained higher frequencies of T cells with central memory or intermediate memory phenotypes. Early-transduced VSTs also had higher proliferative capacity and produced higher levels of TH1 cytokines IL-2,TNF-α,IFN-γ,MIP-1α,MIP-1β and other cytokines in vitro. CONCLUSIONS: We developed a rapid and GMP compliant method for the early transduction of multivirus-specific T-cells that allowed stable expression of high levels of a tumor directed CAR. Since a proportion of early-transduced CAR-VSTs had a central memory phenotype,they should expand and persist in vivo,simultaneously protecting against infection and targeting residual malignancy. This manufacturing strategy is currently under clinical investigation in patients receiving allogeneic HSCT for relapsed neuroblastoma and B-cell malignancies (NCT01460901 using a GD2.CAR and NCT00840853 using a CD19.CAR). View Publication

Bipolar disorder (BD) is a common neuropsychiatric disorder characterized by chronic recurrent episodes of depression and mania. Despite evidence for high heritability of BD,little is known about its underlying pathophysiology. To develop new tools for investigating the molecular and cellular basis of BD,we applied a family-based paradigm to derive and characterize a set of 12 induced pluripotent stem cell (iPSC) lines from a quartet consisting of two BD-affected brothers and their two unaffected parents. Initially,no significant phenotypic differences were observed between iPSCs derived from the different family members. However,upon directed neural differentiation,we observed that CXCR4 (CXC chemokine receptor-4) expressing central nervous system (CNS) neural progenitor cells (NPCs) from both BD patients compared with their unaffected parents exhibited multiple phenotypic differences at the level of neurogenesis and expression of genes critical for neuroplasticity,including WNT pathway components and ion channel subunits. Treatment of the CXCR4(+) NPCs with a pharmacological inhibitor of glycogen synthase kinase 3,a known regulator of WNT signaling,was found to rescue a progenitor proliferation deficit in the BD patient NPCs. Taken together,these studies provide new cellular tools for dissecting the pathophysiology of BD and evidence for dysregulation of key pathways involved in neurodevelopment and neuroplasticity. Future generation of additional iPSCs following a family-based paradigm for modeling complex neuropsychiatric disorders in conjunction with in-depth phenotyping holds promise for providing insights into the pathophysiological substrates of BD and is likely to inform the development of targeted therapeutics for its treatment and ideally prevention. View Publication

The RNA-guided nuclease Cas9 can be reengineered as a programmable transcription factor. However,modest levels of gene activation have limited potential applications. We describe an improved transcriptional regulator obtained through the rational design of a tripartite activator,VP64-p65-Rta (VPR),fused to nuclease-null Cas9. We demonstrate its utility in activating endogenous coding and noncoding genes,targeting several genes simultaneously and stimulating neuronal differentiation of human induced pluripotent stem cells (iPSCs). View Publication

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Naïve T cells require B7/CD28 costimulation in order to be fully activated. Attempts to block this pathway have been effective in preventing unwanted immune reactions. As B7 blockade might also affect Treg cells and interfere with negative signaling through membrane CTLA-4 on effector T (Teff) cells,its immune-modulatory effects are potentially more complex. Here,we used the mouse model of multiple sclerosis (MS),EAE,to study the effect of B7 blockade. An effective therapy for MS patients has to interfere with ongoing inflammation,and therefore we injected CTLA-4Ig at day 7 and 9 after immunization,when myelin-reactive T cells have been primed and start migrating toward the CNS. Surprisingly,B7 blockade exacerbated disease signs and resulted in more severe CNS inflammation and demyelination,and was associated with an enhanced production of the inflammatory cytokines IL-17 and IFN-γ. Importantly,CTLA-4Ig treatment resulted in a transient reduction of Ki67 and CTLA-4 expression and function of peripheral Treg cells. Taken together,B7 blockade at a particular stage of the autoimmune response can result in the suppression of Treg cells,leading to a more severe disease. View Publication