技术资料

Ligation of erythropoietin (EPO) receptor (EPOR) JAK2 kinase complexes propagates signals within erythroid progenitor cells (EPCs) that are essential for red blood cell production. To reveal hypothesized novel EPOR/JAK2 targets,a phosphotyrosine (PY) phosphoproteomics approach was applied. Beyond known signal transduction factors,32 new targets of EPO-modulated tyrosine phosphorylation were defined. Molecular adaptors comprised one major set including growth factor receptor-bound protein 2 (GRB2)-associated binding proteins 1-3 (GAB1-3),insulin receptor substrate 2 (IRS2),docking protein 1 (DOK1),Src homology 2 domain containing transforming protein 1 (SHC1),and sprouty homologue 1 (SPRY1) as validating targets,and SPRY2,SH2 domain containing 2A (SH2D2A),and signal transducing adaptor molecule 2 (STAM2) as novel candidate adaptors together with an ORF factor designated as regulator of human erythroid cell expansion (RHEX). RHEX is well conserved in Homo sapiens and primates but absent from mouse,rat,and lower vertebrate genomes. Among tissues and lineages,RHEX was elevated in EPCs,occurred as a plasma membrane protein,was rapidly PY-phosphorylated textgreater20-fold upon EPO exposure,and coimmunoprecipitated with the EPOR. In UT7epo cells,knockdown of RHEX inhibited EPO-dependent growth. This was associated with extracellular signal-regulated kinase 1,2 (ERK1,2) modulation,and RHEX coupling to GRB2. In primary human EPCs,shRNA knockdown studies confirmed RHEX regulation of erythroid progenitor expansion and further revealed roles in promoting the formation of hemoglobinizing erythroblasts. RHEX therefore comprises a new EPO/EPOR target and regulator of human erythroid cell expansion that additionally acts to support late-stage erythroblast development. View Publication

Mesenchymal stem cells (MSCs) may be used as powerful tools for the repair and regeneration of damaged tissues. However,isolating tissue specific-derived MSCs may cause pain and increased infection rates in patients,and repetitive isolations may be required. To overcome these difficulties,we have examined alternative methods for MSC production. Here,we show that induced pluripotent stem cells (iPSCs) may be differentiated into mesenchymal stem cells (iMSCs) following exposure to SB431542. Purified iMSCs were administered to mdx mice to study skeletal muscle regeneration in a murine model of muscular dystrophy. Purified iMSCs displayed fibroblast-like morphology,formed three-dimensional spheroid structures,and expressed characteristic mesenchymal stem cell surface markers such as CD29,CD33,CD73,CD90,and CD105. Moreover,iMSCs were capable of differentiating into adipogenic,osteogenic,and chondrogenic lineages. Transplanting iMSC cells to tibialis anterior skeletal muscle tissue in mdx mice lowered oxidative damage as evidenced by a reduction in nitrotyrosine levels,and normal dystrophin expression levels were restored. This study demonstrates the therapeutic potential of purified iMSCs in skeletal muscle regeneration in mdx mice,and suggests that iPSCs are a viable alternate source for deriving MSCs as needed. textcopyright 2014 Elsevier Inc. View Publication

Optimization of pluripotent stem cell expansion and differentiation is facilitated by biological tools that permit non-invasive and dynamic monitoring of pluripotency,and the ability to select for an undifferentiated input cell population. Here we report on the generation and characterisation of clonal human embryonic stem (HES3,H9) and human induced pluripotent stem cell lines (UQEW01i-epifibC11) that have been stably modified with an artificial EOS(C3+) promoter driving expression of EGFP and puromycin resistance-conferring proteins. We show that EGFP expression faithfully reports on the pluripotency status of the cells in these lines and that antibiotic selection allows for an efficient elimination of differentiated cells from the cultures. We demonstrate that the extinction of the expression of the pluripotency reporter during differentiation closely correlates with the decrease in expression of conventional pluripotency markers,such as OCT4 (POU5F1),TRA-1-60 and SSEA4 when screening across conditions with various levels of pluripotency-maintaining or differentiation-inducing signals. We further illustrate the utility of these lines for real-time monitoring of pluripotency in embryoid bodies and microfluidic bioreactors. View Publication

Nature Neuroscience 17,1180 (2014). doi:10.1038/nn.3787 View Publication

Differentiation of neural lineages from human pluripotent stem cells (hPSCs) raises the hope of generating functional cells for the treatment of neural diseases. However,current protocols for differentiating hPSCs into neural lineages remain inefficient and largely variable between different hPSC lines. We report that microRNA 376c (miR-376c) significantly enhanced neural differentiation of hPSCs in a defined condition by suppressing SMAD4,the co-SMAD for TGF-β signaling. Downstream,SMAD4 directly bound and suppressed PAX6,the critical neural lineage specification factor. Interestingly,we also found that SMAD4 binds and suppresses miR-376c clusters in undifferentiated hESCs. In summary,our findings revealed a reciprocal antagonism between miR-376c and SMAD signaling that regulates cell fate during human neural differentiation.-Liu,J.,Wang,L.,Su,Z.,Wu,W.,Cai,X.,Li,D.,Hou,J.,Pei,D.,Pan,G. A reciprocal antagonism between miR-376c and TGF-β signaling regulates neural differentiation of hPSCs. View Publication

The complement activation product,C5a,is a pivotal member of the innate immune response; however,a diverse number of nonimmune functions are now being ascribed to C5a signaling,including roles during embryonic development. Here,we identify the expression of the C5a precursor protein,C5,as well as the C5a receptors,C5aR and C5L2,in both human embryonic stem cells and human-induced pluripotent stem cells. We show that administration of a physiologically relevant dose of purified human C5a (1 nM) stimulates activation of ERK1/2 and AKT signaling pathways,and is able to promote maintenance of the pluripotent state in the absence of FGF2. C5a also reduced cell loss following dissociation of human pluripotent stem cells. Our results reveal that complement C5a signaling supports human stem cell pluripotency and survival,and thus may play a key role in shaping early human embryonic development. Stem Cells 2014;32:3278-3284. View Publication

Dysregulated neurodevelopment with altered structural and functional connectivity is believed to underlie many neuropsychiatric disorders,and /`a disease of synapses/' is the major hypothesis for the biological basis of schizophrenia. Although this hypothesis has gained indirect support from human post-mortem brain analyses and genetic studies,little is known about the pathophysiology of synapses in patient neurons and how susceptibility genes for mental disorders could lead to synaptic deficits in humans. Genetics of most psychiatric disorders are extremely complex due to multiple susceptibility variants with low penetrance and variable phenotypes. Rare,multiply affected,large families in which a single genetic locus is probably responsible for conferring susceptibility have proven invaluable for the study of complex disorders. Here we generated induced pluripotent stem (iPS) cells from four members of a family in which a frameshift mutation of disrupted in schizophrenia 1 (DISC1) co-segregated with major psychiatric disorders and we further produced different isogenic iPS cell lines via gene editing. We showed that mutant DISC1 causes synaptic vesicle release deficits in iPS-cell-derived forebrain neurons. Mutant DISC1 depletes wild-type DISC1 protein and,furthermore,dysregulates expression of many genes related to synapses and psychiatric disorders in human forebrain neurons. Our study reveals that a psychiatric disorder relevant mutation causes synapse deficits and transcriptional dysregulation in human neurons and our findings provide new insight into the molecular and synaptic etiopathology of psychiatric disorders. View Publication

Trisomy 21 is the most common chromosomal abnormality and is associated primarily with cardiovascular,hematological,and neurological complications. A robust patient-derived cellular model is necessary to investigate the pathophysiology of the syndrome because current animal models are limited and access to tissues from affected individuals is ethically challenging. We aimed to derive induced pluripotent stem cells (iPSCs) from trisomy 21 human mid-trimester amniotic fluid stem cells (AFSCs) and describe their hematopoietic and neurological characteristics. Human AFSCs collected from women undergoing prenatal diagnosis were selected for c-KIT(+) and transduced with a Cre-lox-inducible polycistronic lentiviral vector encoding SOX2,OCT4,KLF-4,and c-MYC (50,000 cells at a multiplicity of infection (MOI) 1-5 for 72 h). The embryonic stem cell (ESC)-like properties of the AFSC-derived iPSCs were established in vitro by embryoid body formation and in vivo by teratoma formation in RAG2(-/-),$\$-chain(-/-),C2(-/-) immunodeficient mice. Reprogrammed cells retained their cytogenetic signatures and differentiated into specialized hematopoietic and neural precursors detected by morphological assessment,immunostaining,and RT-PCR. Additionally,the iPSCs expressed all pluripotency markers upon multiple rounds of freeze-thawing. These findings are important in establishing a patient-specific cellular platform of trisomy 21 to study the pathophysiology of the aneuploidy and for future drug discovery. View Publication

Current human pluripotent stem cells lack the transcription factor circuitry that governs the ground state of mouse embryonic stem cells (ESC). Here,we report that short-term expression of two components,NANOG and KLF2,is sufficient to ignite other elements of the network and reset the human pluripotent state. Inhibition of ERK and protein kinase C sustains a transgene-independent rewired state. Reset cells self-renew continuously without ERK signaling,are phenotypically stable,and are karyotypically intact. They differentiate in vitro and form teratomas in vivo. Metabolism is reprogrammed with activation of mitochondrial respiration as in ESC. DNA methylation is dramatically reduced and transcriptome state is globally realigned across multiple cell lines. Depletion of ground-state transcription factors,TFCP2L1 or KLF4,has marginal impact on conventional human pluripotent stem cells but collapses the reset state. These findings demonstrate feasibility of installing and propagating functional control circuitry for ground-state pluripotency in human cells. View Publication

Differentiation of human stem cells to hepatocytes is crucial for industrial applications as well as to develop new therapeutic strategies for liver disease. The protocol described here,using sequentially growth factors known to play a role in liver embryonic development,efficiently differentiates human embryonic stem cells (hESC) as well as human-induced pluripotent stem cells (hiPSC) to hepatocytes by directing them through defined embryonic intermediates,namely,mesendoderm/definitive endoderm and hepatoblast and hepatocyte phenotype. After 28 days,the final differentiated progeny is a mixture of cells,comprising cells with characteristics of hepatoblasts and a smaller cell fraction with morphological and phenotypical features of mature hepatocytes. An extensive functional characterization of the stem cell progeny should be used to confirm that differentiated cells display functional characteristics of mature hepatocytes including albumin secretion,glycogen storage,and several detoxifying functions such as urea production,bilirubin conjugation,glutathione S-transferase activity,cytochrome activity and drug transporter activity. View Publication

Molecular beacons (MBs) are dual-labeled oligonucleotides that fluoresce only in the presence of complementary mRNA. The use of MBs to target specific mRNAs allows sorting of specific cells from a mixed cell population. In contrast to existing approaches that are limited by available surface markers or selectable metabolic characteristics,the MB-based method enables the isolation of a wide variety of cells. For example,the ability to purify specific cell types derived from pluripotent stem cells (PSCs) is important for basic research and therapeutics. In addition to providing a general protocol for MB design,validation and nucleofection into cells,we describe how to isolate a specific cell population from differentiating PSCs. By using this protocol,we have successfully isolated cardiomyocytes differentiated from mouse or human PSCs (hPSCs) with ∼ 97% purity,as confirmed by electrophysiology and immunocytochemistry. After designing MBs,their ordering and validation requires 2 weeks,and the isolation process requires 3 h. View Publication

Standardization of mesenchymal stromal cells (MSCs) remains a major obstacle in regenerative medicine. Starting material and culture expansion affect cell preparations and render comparison between studies difficult. In contrast,induced pluripotent stem cells (iPSCs) assimilate toward a ground state and may therefore give rise to more standardized cell preparations. We reprogrammed MSCs into iPSCs,which were subsequently redifferentiated toward MSCs. These iPS-MSCs revealed similar morphology,immunophenotype,in vitro differentiation potential,and gene expression profiles as primary MSCs. However,iPS-MSCs were impaired in suppressing T cell proliferation. DNA methylation (DNAm) profiles of iPSCs maintained donor-specific characteristics,whereas tissue-specific,senescence-associated,and age-related DNAm patterns were erased during reprogramming. iPS-MSCs reacquired senescence-associated DNAm during culture expansion,but they remained rejuvenated with regard to age-related DNAm. Overall,iPS-MSCs are similar to MSCs,but they reveal incomplete reacquisition of immunomodulatory function and MSC-specific DNAm patterns - particularly of DNAm patterns associated with tissue type and aging. View Publication