技术资料

Human-pluripotent-stem-cell-derived kidney cells (hPSC-KCs) have important potential for disease modelling and regeneration. Whether the hPSC-KCs can reconstitute tissue-specific phenotypes is currently unknown. Here we show that hPSC-KCs self-organize into kidney organoids that functionally recapitulate tissue-specific epithelial physiology,including disease phenotypes after genome editing. In three-dimensional cultures,epiblast-stage hPSCs form spheroids surrounding hollow,amniotic-like cavities. GSK3β inhibition differentiates spheroids into segmented,nephron-like kidney organoids containing cell populations with characteristics of proximal tubules,podocytes and endothelium. Tubules accumulate dextran and methotrexate transport cargoes,and express kidney injury molecule-1 after nephrotoxic chemical injury. CRISPR/Cas9 knockout of podocalyxin causes junctional organization defects in podocyte-like cells. Knockout of the polycystic kidney disease genes PKD1 or PKD2 induces cyst formation from kidney tubules. All of these functional phenotypes are distinct from effects in epiblast spheroids,indicating that they are tissue specific. Our findings establish a reproducible,versatile three-dimensional framework for human epithelial disease modelling and regenerative medicine applications. View Publication

Targeted nucleases,including zinc-finger nucleases (ZFNs),transcription activator-like (TAL) effector nucleases (TALENs) and clustered regularly interspaced short palindromic repeat (CRISPR)/CRISPR-associated protein 9 (Cas9),have provided researchers with the ability to manipulate nearly any genomic sequence in human cells and model organisms. However,realizing the full potential of these genome-modifying technologies requires their safe and efficient delivery into relevant cell types. Unlike methods that rely on expression from nucleic acids,the direct delivery of nuclease proteins to cells provides rapid action and fast turnover,leading to fewer off-target effects while maintaining high rates of targeted modification. These features make nuclease protein delivery particularly well suited for precision genome engineering. Here we describe procedures for implementing protein-based genome editing in human embryonic stem cells and primary cells. Protocols for the expression,purification and delivery of ZFN proteins,which are intrinsically cell-permeable; TALEN proteins,which can be internalized via conjugation with cell-penetrating peptide moieties; and Cas9 ribonucleoprotein,whose nucleofection into cells facilitates rapid induction of multiplexed modifications,are described,along with procedures for evaluating nuclease protein activity. Once they are constructed,nuclease proteins can be expressed and purified within 6 d,and they can be used to induce genomic modifications in human cells within 2 d. View Publication

BACKGROUND Disruptive mutation in the CHD8 gene is one of the top genetic risk factors in autism spectrum disorders (ASDs). Previous analyses of genome-wide CHD8 occupancy and reduced expression of CHD8 by shRNA knockdown in committed neural cells showed that CHD8 regulates multiple cell processes critical for neural functions,and its targets are enriched with ASD-associated genes. METHODS To further understand the molecular links between CHD8 functions and ASD,we have applied the CRISPR/Cas9 technology to knockout one copy of CHD8 in induced pluripotent stem cells (iPSCs) to better mimic the loss-of-function status that would exist in the developing human embryo prior to neuronal differentiation. We then carried out transcriptomic and bioinformatic analyses of neural progenitors and neurons derived from the CHD8 mutant iPSCs. RESULTS Transcriptome profiling revealed that CHD8 hemizygosity (CHD8 (+/-)) affected the expression of several thousands of genes in neural progenitors and early differentiating neurons. The differentially expressed genes were enriched for functions of neural development,$$-catenin/Wnt signaling,extracellular matrix,and skeletal system development. They also exhibited significant overlap with genes previously associated with autism and schizophrenia,as well as the downstream transcriptional targets of multiple genes implicated in autism. Providing important insight into how CHD8 mutations might give rise to macrocephaly,we found that seven of the twelve genes associated with human brain volume or head size by genome-wide association studies (e.g.,HGMA2) were dysregulated in CHD8 (+/-) neural progenitors or neurons. CONCLUSIONS We have established a renewable source of CHD8 (+/-) iPSC lines that would be valuable for investigating the molecular and cellular functions of CHD8. Transcriptomic profiling showed that CHD8 regulates multiple genes implicated in ASD pathogenesis and genes associated with brain volume. View Publication

Human embryonic stem cells (hESCs) are predicted to be an unlimited source of hepatocytes which can pave the way for applications such as cell replacement therapies or as a model of human development or even to predict the hepatotoxicity of drug compounds. We have optimized a 23-d differentiation protocol to generate hepatocyte-like cells (HLCs) from hESCs,obtaining a relatively pure population which expresses the major hepatic markers and is functional and mature. The stability of the HLCs in terms of hepato-specific marker expression and functionality was found to be intact even after an extended period of in vitro culture and cryopreservation. The hESC-derived HLCs have shown the capability to display sensitivity and an alteration in the level of CYP enzyme upon drug induction. This illustrates the potential of such assays in predicting the hepatotoxicity of a drug compound leading to advancement of pharmacology View Publication

WNT/$\$-CATENIN signaling promotes the hematopoietic/endothelial differentiation of human embryonic stem cells and human induced pluripotent stem cells (hiPSCs). The transient addition of a GSK3$\$ (GSKi) has been found to facilitate in vitro endothelial cell differentiation from hESCs/hiPSCs. Because hematopoietic and endothelial cells are derived from common progenitors (hemogenic endothelial progenitors [HEPs]),we examined the effect of transient GSKi treatment on hematopoietic cell differentiation from hiPSCs. We found that transient GSKi treatment at the start of hiPSC differentiation induction altered the gene expression profile of the cells. Multiple CDX/HOX genes,which are expressed in the posterior mesoderm of developing embryos,were significantly upregulated by GSKi treatment. Further,inclusion of the GSKi in a serum- and stroma-free culture with chemically defined medium efficiently induced HEPs,and the HEPs gave rise to various lineages of hematopoietic and endothelial cells. Therefore,transient WNT/$\$-CATENIN signaling triggers activation of the CDX/HOX pathway,which in turn confers hemogenic posterior mesoderm identity to differentiating hiPSCs. These data enhance our understanding of human embryonic hematopoietic/endothelial cell development and provide a novel in vitro system for inducing the differentiation of hematopoietic cells from hiPSCs. View Publication

Primary dilated cardiomyopathy (DCM) is a non-ischemic heart disease with impaired pumping function of the heart. In this study,we used human induced pluripotent stem cell-derived cardiomyocytes (iPSC-CMs) from a healthy volunteer and a primary DCM patient to investigate the impact of DCM on iPSC-CMs' responses to different types of anisotropic strain. A bioreactor system was established that generates cardiac-mimetic forces of 150 kPa at 5% anisotropic cyclic strain and 1. Hz frequency. After confirming cardiac induction of the iPSCs,it was determined that fibronectin was favorable to other extracellular matrix protein coatings (gelatin,laminin,vitronectin) in terms of viable cell area and density,and was therefore selected as the coating for further study. When iPSC-CMs were exposed to three strain conditions (no strain,5% static strain,and 5% cyclic strain),the static strain elicited significant induction of sarcomere components in comparison to other strain conditions. However,this induction occurred only in iPSC-CMs from a healthy volunteer (control iPSC-CMs")� View Publication

Short bowel syndrome (SBS) is characterized by poor nutrient absorption due to a deficit of healthy intestine. Current treatment practices rely on providing supportive medical therapy with parenteral nutrition; while life saving,such interventions are not curative and are still associated with significant co-morbidities. As approaches to lengthen remaining intestinal tissue have been met with only limited success and intestinal transplants have poor survival outcomes,new approaches to treating SBS are necessary. Human intestine derived from embryonic stem cells (hESCs) or induced pluripotent stem cells (iPSCs),called human intestinal organoids (HIOs),have the potential to offer a personalized and scalable source of intestine for regenerative therapies. However,given that HIOs are small three-dimensional structures grown in vitro,methods to generate usable HIO-derived constructs are needed. We investigated the ability of hESCs or HIOs to populate acellular porcine intestinal matrices and artificial polyglycolic/poly L lactic acid (PGA/PLLA) scaffolds,and examined the ability of matrix/scaffolds to thrive when transplanted in vivo. Our results demonstrate that the acellular matrix alone is not sufficient to instruct hESC differentiation towards an endodermal or intestinal fate. We observed that while HIOs reseed acellular porcine matrices in vitro,the HIO-reseeded matrices do not thrive when transplanted in vivo. In contrast,HIO-seeded PGA/PLLA scaffolds thrive in vivo and develop into tissue that looks nearly identical to adult human intestinal tissue. Our results suggest that HIO-seeded PGA/PLLA scaffolds are a promising avenue for developing the mucosal component of tissue engineered human small intestine,which need to be explored further to develop them into fully functional tissue. View Publication

The generation of liquefied poly-ɛ-caprolactone (PCL) droplets by means of a microfluidic device results in uniform-sized microspheres,which are validated as microcarriers for human embryonic stem cell culture. Formed droplet size and size distribution,as well as the resulting PCL microsphere size,are correlated with the viscosity and flow rate ratio of the dispersed (Q d) and continuous (Q c) phases. PCL in dichloromethane increases its viscosity with concentration and molecular weight. Higher viscosity and Q d/Q c lead to the formation of larger droplets,within two observed formation modes: dripping and jetting. At low viscosity of dispersed phase and Q d/Q c,the microfluidic device is operated in dripping mode,which generates droplets and microspheres with greater size uniformity. Solutions with lower molecular weight PCL have lower viscosity,resulting in a wider concentration range for the dripping mode. When coated with extracellular matrix (ECM) proteins,the fabricated PCL microspheres are demonstrated capable of supporting the expansion of human embryonic stem cells. View Publication

Tools for rapid and efficient transgenesis in safe harbor" loci in an isogenic context remain important to exploit the possibilities of human pluripotent stem cells (hPSCs). We created hPSC master cell lines suitable for FLPe recombinase-mediated cassette exchange (RMCE) in the AAVS1 locus that allow generation of transgenic lines within 15 days with 100% efficiency and without random integrations. Using RMCE� 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

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

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