技术资料

How BMP signaling integrates into and destabilizes the pluripotency circuitry of human pluripotent stem cells (hPSCs) to initiate differentiation into individual germ layers is a long-standing puzzle. Here we report muscle segment homeobox 2 (MSX2),a homeobox transcription factor of msh family,as a direct target gene of BMP signaling and a master mediator of hPSCs' differentiation to mesendoderm. Enforced expression of MSX2 suffices to abolish pluripotency and induce directed mesendoderm differentiation of hPSCs,while MSX2 depletion impairs mesendoderm induction. MSX2 is a direct target gene of the BMP pathway in hPSCs,and can be synergistically activated by Wnt signals via LEF1 during mesendoderm induction. Furthermore,MSX2 destabilizes the pluripotency circuitry through direct binding to the SOX2 promoter and repression of SOX2 transcription,while MSX2 controls mesendoderm lineage commitment by simultaneous suppression of SOX2 and induction of NODAL expression through direct binding and activation of the Nodal promoter. Interestingly,SOX2 can promote the degradation of MSX2 protein,suggesting a mutual antagonism between the two lineage-specifying factors in the control of stem cell fate. Together,our findings reveal crucial new mechanisms of destabilizing pluripotency and directing lineage commitment in hPSCs. View Publication

Rett syndrome (RTT) is a severe neurodevelopmental disorder associated with mutations in either MECP2,CDKL5 or FOXG1. The precise molecular mechanisms that lead to the pathogenesis of RTT have yet to be elucidated. We recently reported that expression of GluD1 (orphan glutamate receptor $\$-1 subunit) is increased in iPSC-derived neurons obtained from patients with mutations in either MECP2 or CDKL5. GluD1 controls synaptic differentiation and shifts the balance between excitatory and inhibitory synapses toward the latter. Thus,an increase in GluD1 might be a critical factor in the etiology of RTT by affecting the excitatory/inhibitory balance in the developing brain. To test this hypothesis,we generated iPSC-derived neurons from FOXG1(+/-) patients. We analyzed mRNA and protein levels of GluD1 together with key markers of excitatory and inhibitory synapses in these iPSC-derived neurons and in Foxg1(+/-) mouse fetal (E11.5) and adult (P70) brains. We found strong correlation between iPSC-derived neurons and fetal mouse brains,where GluD1 and inhibitory synaptic markers (GAD67 and GABA AR-$\$1) were increased,whereas the levels of a number of excitatory synaptic markers (VGLUT1,GluA1,GluN1 and PSD-95) were decreased. In adult mice,GluD1 was decreased along with all GABAergic and glutamatergic markers. Our findings further the understanding of the etiology of RTT by introducing a new pathological event occurring in the brain of FOXG1(+/-) patients during embryonic development and its time-dependent shift toward a general decrease in brain synapses. View Publication

Oncogenic transformation in Ewing sarcoma tumors is driven by the fusion oncogene EWS-FLI1. However,despite the well-established role of EWS-FLI1 in tumor initiation,the development of models of Ewing sarcoma in human cells with defined genetic elements has been challenging. Here,we report a novel approach to model the initiation of Ewing sarcoma tumorigenesis that exploits the developmental and pluripotent potential of human embryonic stem cells. The inducible expression of EWS-FLI1 in embryoid bodies,or collections of differentiating stem cells,generates cells with properties of Ewing sarcoma tumors,including characteristics of transformation. These cell lines exhibit anchorage-independent growth,a lack of contact inhibition and a strong Ewing sarcoma gene expression signature. Furthermore,these cells also demonstrate a requirement for the persistent expression of EWS-FLI1 for cell survival and growth,which is a hallmark of Ewing sarcoma tumors.Oncogene advance online publication,12 October 2015; doi:10.1038/onc.2015.368. View Publication

Replication stress causes DNA damage at fragile sites in the genome. DNA damage at telomeres can initiate breakage-fusion-bridge cycles and chromosome instability,which can result in replicative senescence or tumor formation. Little is known about the extent of replication stress or telomere dysfunction in human embryonic stem cells (hESCs). hESCs are grown in culture with the expectation of being used therapeutically in humans,making it important to minimize the levels of replication stress and telomere dysfunction. Here,the hESC line UCSF4 was cultured in a defined medium with growth factor Activin A,exogenous nucleosides,or DNA polymerase inhibitor aphidicolin. We used quantitative fluorescence in situ hybridization to analyze individual telomeres for dysfunction and observed that it can be increased by aphidicolin or Activin A. In contrast,adding exogenous nucleosides relieved dysfunction,suggesting that telomere dysfunction results from replication stress. Whether these findings can be applied to other hESC lines remains to be determined. However,because the loss of telomeres can lead to chromosome instability and cancer,we conclude that hESCs grown in culture for future therapeutic purposes should be routinely checked for replication stress and telomere dysfunction. View Publication

Fibroblasts from patients with Type I bipolar disorder (BPD) and their unaffected siblings were obtained from an Old Order Amish pedigree with a high incidence of BPD and reprogrammed to induced pluripotent stem cells (iPSCs). Established iPSCs were subsequently differentiated into neuroprogenitors (NPs) and then to neurons. Transcriptomic microarray analysis was conducted on RNA samples from iPSCs,NPs and neurons matured in culture for either 2 weeks (termed early neurons,E) or 4 weeks (termed late neurons,L). Global RNA profiling indicated that BPD and control iPSCs differentiated into NPs and neurons at a similar rate,enabling studies of differentially expressed genes in neurons from controls and BPD cases. Significant disease-associated differences in gene expression were observed only in L neurons. Specifically,328 genes were differentially expressed between BPD and control L neurons including GAD1,glutamate decarboxylase 1 (2.5 fold) and SCN4B,the voltage gated type IV sodium channel beta subunit (-14.6 fold). Quantitative RT-PCR confirmed the up-regulation of GAD1 in BPD compared to control L neurons. Gene Ontology,GeneGo and Ingenuity Pathway Analysis of differentially regulated genes in L neurons suggest that alterations in RNA biosynthesis and metabolism,protein trafficking as well as receptor signaling pathways may play an important role in the pathophysiology of BPD. View Publication

Diploidy is a fundamental genetic feature in mammals,in which haploid cells normally arise only as post-meiotic germ cells that serve to ensure a diploid genome upon fertilization. Gamete manipulation has yielded haploid embryonic stem (ES) cells from several mammalian species,but haploid human ES cells have yet to be reported. Here we generated and analysed a collection of human parthenogenetic ES cell lines originating from haploid oocytes,leading to the successful isolation and maintenance of human ES cell lines with a normal haploid karyotype. Haploid human ES cells exhibited typical pluripotent stem cell characteristics,such as self-renewal capacity and a pluripotency-specific molecular signature. Moreover,we demonstrated the utility of these cells as a platform for loss-of-function genetic screening. Although haploid human ES cells resembled their diploid counterparts,they also displayed distinct properties including differential regulation of X chromosome inactivation and of genes involved in oxidative phosphorylation,alongside reduction in absolute gene expression levels and cell size. Surprisingly,we found that a haploid human genome is compatible not only with the undifferentiated pluripotent state,but also with differentiated somatic fates representing all three embryonic germ layers both in vitro and in vivo,despite a persistent dosage imbalance between the autosomes and X chromosome. We expect that haploid human ES cells will provide novel means for studying human functional genomics and development. View Publication

Modeling tissues and organs using conventional 2D cell cultures is problematic as the cells rapidly lose their in vivo phenotype. In microfluidic bioreactors the cells reside in microstructures that are continuously perfused with cell culture medium to provide a dynamic environment mimicking the cells natural habitat. These micro scale bioreactors are sometimes referred to as organs-on-chips and are developed in order to improve and extend cell culture experiments. Here,we describe the two manufacturing techniques photolithography and soft lithography that are used in order to easily produce microfluidic bioreactors. The use of these bioreactors is exemplified by a toxicity assessment on 3D clustered human pluripotent stem cells (hPSC)-derived cardiomyocytes by beating frequency imaging. View Publication

Hyperfunction of the mTORC1 pathway has been associated with idiopathic and syndromic forms of autism spectrum disorder (ASD),including tuberous sclerosis,caused by loss of either TSC1 or TSC2. It remains largely unknown how developmental processes and biochemical signaling affected by mTORC1 dysregulation contribute to human neuronal dysfunction. Here,we have characterized multiple stages of neurogenesis and synapse formation in human neurons derived from TSC2-deleted pluripotent stem cells. Homozygous TSC2 deletion causes severe developmental abnormalities that recapitulate pathological hallmarks of cortical malformations in patients. Both TSC2(+/-) and TSC2(-/-) neurons display altered synaptic transmission paralleled by molecular changes in pathways associated with autism,suggesting the convergence of pathological mechanisms in ASD. Pharmacological inhibition of mTORC1 corrects developmental abnormalities and synaptic dysfunction during independent developmental stages. Our results uncouple stage-specific roles of mTORC1 in human neuronal development and contribute to a better understanding of the onset of neuronal pathophysiology in tuberous sclerosis. View Publication

Human pluripotent stem cells (hPSCs),including both embryonic and induced pluripotent stem cells,possess the unique ability to readily differentiate into any cell type of the body,including cells of the retina. Although previous studies have demonstrated the ability to differentiate hPSCs to a retinal lineage,the ability to derive retinal ganglion cells (RGCs) from hPSCs has been complicated by the lack of specific markers with which to identify these cells from a pluripotent source. In the current study,the definitive identification of hPSC-derived RGCs was accomplished by their directed,stepwise differentiation through an enriched retinal progenitor intermediary,with resultant RGCs expressing a full complement of associated features and proper functional characteristics. These results served as the basis for the establishment of induced pluripotent stem cells (iPSCs) from a patient with a genetically inherited form of glaucoma,which results in damage and loss of RGCs. Patient-derived RGCs specifically exhibited a dramatic increase in apoptosis,similar to the targeted loss of RGCs in glaucoma,which was significantly rescued by the addition of candidate neuroprotective factors. Thus,the current study serves to establish a method by which to definitively acquire and identify RGCs from hPSCs and demonstrates the ability of hPSCs to serve as an effective in vitro model of disease progression. Moreover,iPSC-derived RGCs can be utilized for future drug screening approaches to identify targets for the treatment of glaucoma and other optic neuropathies. Stem Cells 2016. View Publication

Genome instability is a potential limitation to the research and therapeutic application of induced pluripotent stem cells (iPSCs). Observed genomic variations reflect the combined activities of DNA damage,cellular DNA damage response (DDR),and selection pressure in culture. To understand the contribution of DDR on the distribution of copy number variations (CNVs) in iPSCs,we mapped CNVs of iPSCs with mutations in the central DDR gene ATM onto genome organization landscapes defined by genome-wide replication timing profiles. We show that following reprogramming the early and late replicating genome is differentially affected by CNVs in ATM deficient iPSCs relative to wild type iPSCs. Specifically,the early replicating regions had increased CNV losses during retroviral reprogramming. This differential CNV distribution was not present after later passage or after episomal reprogramming. Comparison of different reprogramming methods in the setting of defective DNA damage response reveals unique vulnerability of early replicating open chromatin to retroviral vectors. View Publication

Human urine cells (HUCs) can be reprogrammed into neural progenitor cells (NPCs) or induced pluripotent stem cells (iPSCs) with defined factors and a small molecule cocktail,but the underlying fate choice remains unresolved. Here,through sequential removal of individual compound from small molecule cocktail,we showed that A8301,a TGF$$ signaling inhibitor,is sufficient to switch the cell fate from iPSCs into NPCs in OSKM-mediated HUCs reprogramming. However,TGF$$ exposure at early stage inhibits HUCs reprogramming by promoting EMT. Base on these data,we developed an optimized approach for generation of NPCs or iPSCs from HUCs with significantly improved efficiency by regulating TGF$$ activity at different reprogramming stages. This approach provides a simplified and improved way for HUCs reprogramming,thus would be valuable for banking human iPSCs or NPCs from people with different genetic background. View Publication

Background: Huntington's disease (HD) is an incurable hereditary neurodegenerative disorder,which manifests itself as a loss of GABAergic medium spiny (GABA MS) neurons in the striatum and caused by an expansion of the CAG repeat in exon 1 of the huntingtin gene. There is no cure for HD,existing pharmaceutical can only relieve its symptoms. Results: Here,induced pluripotent stem cells were established from patients with low CAG repeat expansion in the huntingtin gene,and were then efficiently differentiated into GABA MS-like neurons (GMSLNs) under defined culture conditions. The generated HD GMSLNs recapitulated disease pathology in vitro,as evidenced by mutant huntingtin protein aggregation,increased number of lysosomes/autophagosomes,nuclear indentations,and enhanced neuronal death during cell aging. Moreover,store-operated channel (SOC) currents were detected in the differentiated neurons,and enhanced calcium entry was reproducibly demonstrated in all HD GMSLNs genotypes. Additionally,the quinazoline derivative,EVP4593,reduced the number of lysosomes/autophagosomes and SOC currents in HD GMSLNs and exerted neuroprotective effects during cell aging. Conclusions: Our data is the first to demonstrate the direct link of nuclear morphology and SOC calcium deregulation to mutant huntingtin protein expression in iPSCs-derived neurons with disease-mimetic hallmarks,providing a valuable tool for identification of candidate anti-HD drugs. Our experiments demonstrated that EVP4593 may be a promising anti-HD drug. [ABSTRACT FROM AUTHOR] View Publication