技术资料

Regeneration of human cartilage is inherently inefficient; an abundant autologous source,such as human induced pluripotent stem cells (hiPSCs),is therefore attractive for engineering cartilage. We report a growth factor-based protocol for differentiating hiPSCs into articular-like chondrocytes (hiChondrocytes) within 2 weeks,with an overall efficiency textgreater90%. The hiChondrocytes are stable and comparable to adult articular chondrocytes in global gene expression,extracellular matrix production,and ability to generate cartilage tissue in vitro and in immune-deficient mice. Molecular characterization identified an early SRY (sex-determining region Y) box (Sox)9(low) cluster of differentiation (CD)44(low)CD140(low) prechondrogenic population during hiPSC differentiation. In addition,2 distinct Sox9-regulated gene networks were identified in the Sox9(low) and Sox9(high) populations providing novel molecular insights into chondrogenic fate commitment and differentiation. Our findings present a favorable method for generating hiPSC-derived articular-like chondrocytes. The hiChondrocytes are an attractive cell source for cartilage engineering because of their abundance,autologous nature,and potential to generate articular-like cartilage rather than fibrocartilage. In addition,hiChondrocytes can be excellent tools for modeling human musculoskeletal diseases in a dish and for rapid drug screening. View Publication

Induced pluripotent stem (iPS) cells have an enormous potential for physiological studies. A novel protocol was developed combining the derivation of iPS from peripheral blood with an optimized directed differentiation to cardiomyocytes and a subsequent metabolic selection. The human iPS cells were retrovirally dedifferentiated from activated T cells. The subsequent optimized directed differentiation protocol yielded 30-45% cardiomyocytes at day 16 of differentiation. The derived cardiomyocytes expressed appropriate structural markers like cardiac troponin T,$\$-actinin and myosin light chain 2 (MLC2V). In a subsequent metabolic selection with lactate,the cardiomyocytes content could be increased to more than 90%. Loss of cardiomyocytes during metabolic selection were less than 50%,whereas alternative surface antibody-based selection procedures resulted in loss of up to 80% of cardiomyocytes. Electrophysiological characterization confirmed the typical cardiac features and the presence of ventricular,atrial and nodal-like action potentials within the derived cardiomyocyte population. Our combined and optimized protocol is highly robust and applicable for scalable cardiac differentiation. It provides a simple and cost-efficient method without expensive equipment for generating large numbers of highly purified,functional cardiomyocytes. It will further enhance the applicability of iPS cell-derived cardiomyocytes for disease modeling,drug discovery,and regenerative medicine. View Publication

Despite major advances in the pathophysiological understanding of peripheral nerve damage,the treatment of nerve injuries still remains an unmet medical need. Nerve guidance conduits present a promising treatment option by providing a growth-permissive environment that 1) promotes neuronal cell survival and axon growth and 2) directs axonal extension. To this end,we designed an electrospun nerve guidance conduit using a blend of polyurea and poly-caprolactone with both biochemical and topographical cues. Biochemical cues were integrated into the conduit by functionalizing the polyurea with RGD to improve cell attachment. Topographical cues that resemble natural nerve tissue were incorporated by introducing intraluminal microchannels aligned with nanofibers. We determined that electrospinning the polymer solution across a two electrode system with dissolvable sucrose fibers produced a polymer conduit with the appropriate biomimetic properties. Human neural stem cells were cultured on the conduit to evaluate its ability to promote neuronal growth and axonal extension. The nerve guidance conduit was shown to enhance cell survival,migration,and guide neurite extension. View Publication

Transcription factor-mediated reprograming is a powerful method to study cell fate changes. In this study,we demonstrate that the transcription factor Gata6 can initiate reprograming of multiple cell types to induced extraembryonic endoderm stem (iXEN) cells. Intriguingly,Gata6 is sufficient to drive iXEN cells from mouse pluripotent cells and differentiated neural cells. Furthermore,GATA6 induction in human embryonic stem (hES) cells also down-regulates pluripotency gene expression and up-regulates extraembryonic endoderm (ExEn) genes,revealing a conserved function in mediating this cell fate switch. Profiling transcriptional changes following Gata6 induction in mES cells reveals step-wise pluripotency factor disengagement,with initial repression of Nanog and Esrrb,then Sox2,and finally Oct4,alongside step-wise activation of ExEn genes. Chromatin immunoprecipitation and subsequent high-throughput sequencing analysis shows Gata6 enrichment near pluripotency and endoderm genes,suggesting that Gata6 functions as both a direct repressor and activator. Together,this demonstrates that Gata6 is a versatile and potent reprograming factor that can act alone to drive a cell fate switch from diverse cell types. View Publication

Advances in differentiation of cardiomyocytes from human induced pluripotent stem cell (hiPSC) were emerged as a tool for modeling of cardiovascular disease that recapitulates the phenotype for the purpose of drug screening,biomarker discovery,and testing of single-nucleotide polymorphism (SNP) as a modifier for disease stratification. Here,we describe the (1) retroviral reprogramming strategies in the generation of human iPSC,(2) methodology in characterization of iPSC in order to identify the stem cell clones with the best quality,and (3) protocol of cardiac differentiation by modulation of Wnt signaling and $\$-catenin pathway. View Publication

Tissue engineering strategies,based on solid/porous scaffolds,suffer from several limitations,such as ineffective vascularization,poor cell distribution and organization within scaffold,in addition to low final cell density,among others. Therefore,the search for other tissue engineering approaches constitutes an active area of investigation. Decellularized matrices (DM) present major advantages compared to solid scaffolds,such as ideal chemical composition,the preservation of vascularization structure and perfect three-dimensional structure. In the present study,we aimed to characterize and investigate murine heart decellularized matrices as biomaterials for regular and whole organ tissue engineering. Heart decellularized matrices were characterized according to: 1. DNA content,through DNA quantificationo and PCR of isolated genomic DNA; 2. Histological structure,assessed after Hematoxylin and Eosin,as well as Masson's Trichrome stainings; 3. Surface nanostructure analysis,performed,using SEM. Those essays allowed us to conclude that DM was indeed decellularized,with preserved extracellular matrix structure. Following characterization,decellularized heart slices were seeded with induced Pluripotent Stem cells (iPS). As expected,but - to the best of our knowledge - never shown before,decellularization of murine heart matrices maintained matrix biocompatibility,as iPS cells rapidly attached to the surface of the material and proliferated. Strikingly though,heart DM presented a differentiation induction effect over those cells,which lost their pluripotency markers after 7 days of culture in the DM. Such loss of differentiation markers was observed,even though bFGF containing media mTSR was used during such period. Gene expression of iPS cells cultured on DM will be further analyzed,in order to assess the effects of culturing pluripotent stem cells in decellularized heart matrices. View Publication

Human pluripotent stem cells (hPSCs) are sensitive to DNA damage and undergo rapid apoptosis compared to their differentiated progeny cells. Here,we explore the underlying mechanisms for the increased apoptotic sensitivity of hPSCs that helps to determine pluripotent stem cell fate. Apoptosis was induced by exposure to actinomycin D,etoposide,or tunicamycin,with each agent triggering a distinct apoptotic pathway. We show that hPSCs are more sensitive to all three types of apoptosis induction than are lineage-non-specific,retinoic-acid-differentiated hPSCs. Also,Bax activation and pro-apoptotic mitochondrial intermembrane space protein release,which are required to initiate the mitochondria-mediated apoptosis pathway,are more rapid in hPSCs than in retinoic-acid-differentiated hPSCs. Surprisingly,Bak and not Bax is essential for actinomycin-D-induced apoptosis in human embryonic stem cells. Finally,P53 is degraded rapidly in an ubiquitin-proteasome-dependent pathway in hPSCs at steady state but quickly accumulates and induces apoptosis when Mdm2 function is impaired. Rapid degradation of P53 ensures the survival of healthy hPSCs but avails these cells for immediate apoptosis upon cellular damage by P53 stabilization. Altogether,we provide an underlying,interconnected molecular mechanism that primes hPSCs for quick clearance by apoptosis to eliminate hPSCs with unrepaired genome alterations and preserves organismal genomic integrity during the early critical stages of human embryonic development. View Publication

BACKGROUND: Many retinal degenerative diseases are caused by the loss of retinal ganglion cells (RGCs). Autosomal dominant optic atrophy is the most common hereditary optic atrophy disease and is characterized by central vision loss and degeneration of RGCs. Currently,there is no effective treatment for this group of diseases. However,stem cell therapy holds great potential for replacing lost RGCs of patients. Compared with embryonic stem cells,induced pluripotent stem cells (iPSCs) can be derived from adult somatic cells,and they are associated with fewer ethical concerns and are less prone to immune rejection. In addition,patient-derived iPSCs may provide us with a cellular model for studying the pathogenesis and potential therapeutic agents for optic atrophy.backslashnbackslashnMETHODS: In this study,iPSCs were obtained from patients carrying an OPA1 mutation (OPA1 (+/-) -iPSC) that were diagnosed with optic atrophy. These iPSCs were differentiated into putative RGCs,which were subsequently characterized by using RGC-specific expression markers BRN3a and ISLET-1.backslashnbackslashnRESULTS: Mutant OPA1 (+/-) -iPSCs exhibited significantly more apoptosis and were unable to efficiently differentiate into RGCs. However,with the addition of neural induction medium,Noggin,or estrogen,OPA1 (+/-) -iPSC differentiation into RGCs was promoted.backslashnbackslashnCONCLUSIONS: Our results suggest that apoptosis mediated by OPA1 mutations plays an important role in the pathogenesis of optic atrophy,and both noggin and β-estrogen may represent potential therapeutic agents for OPA1-related optic atrophy. View Publication

RNA functions at enhancers remain mysterious. Here we show that the 7SK small nuclear RNA (snRNA) inhibits enhancer transcription by modulating nucleosome position. 7SK occupies enhancers and super enhancers genome wide in mouse and human cells,and it is required to limit enhancer-RNA initiation and synthesis in a manner distinct from promoter pausing. Clustered elements at super enhancers uniquely require 7SK to prevent convergent transcription and DNA-damage signaling. 7SK physically interacts with the BAF chromatin-remodeling complex,recruits BAF to enhancers and inhibits enhancer transcription by modulating chromatin structure. In turn,7SK occupancy at enhancers coincides with that of Brd4 and is exquisitely sensitive to the bromodomain inhibitor JQ1. Thus,7SK uses distinct mechanisms to counteract the diverse consequences of pervasive transcription that distinguish super enhancers,enhancers and promoters. View Publication

X-linked dystonia-parkinsonism (XDP) is a hereditary neurodegenerative disorder involving a progressive loss of striatal medium spiny neurons. The mechanisms underlying neurodegeneration are not known,in part because there have been few cellular models available for studying the disease. The XDP haplotype consists of multiple sequence variations in a region of the X chromosome containingTAF1,a large gene with at least 38 exons,and a multiple transcript system (MTS) composed of five unconventional exons. A previous study identified an XDP-specific insertion of a SINE-VNTR-Alu (SVA)-type retrotransposon in intron 32 ofTAF1,as well as a neural-specific TAF1 isoform,N-TAF1,which showed decreased expression in post-mortem XDP brain compared with control tissue. Here,we generated XDP patient and control fibroblasts and induced pluripotent stem cells (iPSCs) in order to further probe cellular defects associated with this disease. As initial validation of the model,we compared expression ofTAF1and MTS transcripts in XDP versus control fibroblasts and iPSC-derived neural stem cells (NSCs). Compared with control cells,XDP fibroblasts exhibited decreased expression ofTAF1transcript fragments derived from exons 32-36,a region spanning the SVA insertion site. N-TAF1,which incorporates an alternative exon (exon 34'),was not expressed in fibroblasts,but was detectable in iPSC-differentiated NSCs at levels that were ∼threefold lower in XDP cells than in controls. These results support the previous findings that N-TAF1 expression is impaired in XDP,but additionally indicate that this aberrant transcription might occur in neural cells at relatively early stages of development that precede neurodegeneration. View Publication

Induced pluripotent stem cell (iPSC)-derived cortical neurons potentially present a powerful new model to understand corticogenesis and neurological disease. Previous work has established that differentiation protocols can produce cortical neurons,but little has been done to characterize these at cellular resolution. In particular,it is unclear to what extent in vitro two-dimensional,relatively disordered culture conditions recapitulate the development of in vivo cortical layer identity. Single-cell multiplex reverse transcriptase-quantitative polymerase chain reaction (RT-qPCR) was used to interrogate the expression of genes previously implicated in cortical layer or phenotypic identity in individual cells. Totally,93.6% of single cells derived from iPSCs expressed genes indicative of neuronal identity. High proportions of single neurons derived from iPSCs expressed glutamatergic receptors and synaptic genes. And,68.4% of iPSC-derived neurons expressing at least one layer marker could be assigned to a laminar identity using canonical cortical layer marker genes. We compared single-cell RNA-seq of our iPSC-derived neurons to available single-cell RNA-seq data from human fetal and adult brain and found that iPSC-derived cortical neurons closely resembled primary fetal brain cells. Unexpectedly,a subpopulation of iPSC-derived neurons co-expressed canonical fetal deep and upper cortical layer markers. However,this appeared to be concordant with data from primary cells. Our results therefore provide reassurance that iPSC-derived cortical neurons are highly similar to primary cortical neurons at the level of single cells but suggest that current layer markers,although effective,may not be able to disambiguate cortical layer identity in all cells. View Publication

Alzheimer's disease and frontotemporal dementia are amongst the most common forms of dementia characterized by the formation and deposition of abnormal TAU in the brain. In order to develop a translational human TAU aggregation model suitable for screening,we transduced TAU harboring the pro-aggregating P301L mutation into control hiPSC-derived neural progenitor cells followed by differentiation into cortical neurons. TAU aggregation and phosphorylation was quantified using AlphaLISA technology. Although no spontaneous aggregation was observed upon expressing TAU-P301L in neurons,seeding with preformed aggregates consisting of the TAU-microtubule binding repeat domain triggered robust TAU aggregation and hyperphosphorylation already after 2 weeks,without affecting general cell health. To validate our model,activity of two autophagy inducers was tested. Both rapamycin and trehalose significantly reduced TAU aggregation levels suggesting that iPSC-derived neurons allow for the generation of a biologically relevant human Tauopathy model,highly suitable to screen for compounds that modulate TAU aggregation. View Publication