技术资料

OBJECTIVES Kidney disease is emerging as a critical medical problem worldwide. Because of limited treatment options for the damaged kidney,stem cell treatment is becoming an alternative therapeutic approach. Of many possible human stem cell sources,pluripotent stem cells are most attractive due to their self-renewal and pluripotent capacity. However,little is known about the derivation of renal lineage cells from human pluripotent stem cells (hPSCs). In this study,we developed a novel protocol for differentiation of nephron progenitor cells (NPCs) from hPSCs in a serum- and feeder-free system. MATERIALS AND METHODS We designed step-wise protocols for differentiation of human pluripotent stem cells toward primitive streak,intermediate mesoderm and NPCs by recapitulating normal nephrogenesis. Expression of key marker genes was examined by RT-PCR,real time RT-PCR and immunocytochemistry. Each experiment was independently performed three times to confirm its reproducibility. RESULTS After modification of culture period and concentration of exogenous factors,hPSCs can differentiate into NPCs that markedly express specific marker genes such as SIX2,GDNF,HOXD11,WT1 and CITED1 in addition to OSR1,PAX2,SALL1 and EYA1. Moreover,NPCs possess the potential of bidirectional differentiation into both renal tubular epithelial cells and glomerular podocytes in defined culture conditions. In particular,approximately 70% of SYN-positive cells were obtained from hPSC-derived NPCs after podocytes induction. NPCs can also form in vitro tubule-like structures in three dimensional culture systems. CONCLUSIONS Our novel protocol for hPSCs differentiation into NPCs can be useful for producing alternative sources of cell replacement therapy and disease modeling for human kidney diseases. View Publication

We recently reported that chronic lymphocytic leukemia (CLL) subgroups with distinct clonotypic BCRs present discrete patterns of TLR expression,function,and/or tolerance. In this study,to explore whether specific types of BCR/TLR collaboration exist in CLL,we studied the effect of single versus concomitant BCR and/or TLR stimulation on CLL cells from mutated (M-CLL) and unmutated CLL (U-CLL) cases. We stimulated negatively isolated CLL cells by using anti-IgM,imiquimod,and CpG oligodeoxynucleotide for BCR,TLR7,and TLR9,respectively,alone or in combination for different time points. After in vitro culture in the absence of stimulation,differences in p-ERK were identified at any time point,with higher p-ERK levels in U-CLL versus M-CLL. Pronounced p-ERK induction was seen by single stimulation in U-CLL,whereas BCR/TLR synergism was required in View Publication

Data suggest that clinical applications of human induced pluripotent stem cells (hiPSCs) will be realized. Nonetheless,clinical applications will require hiPSCs that are free of exogenous DNA and that can be manufactured through Good Manufacturing Practice (GMP). Optimally,derivation of hiPSCs should be rapid and efficient in order to minimize manipulations,reduce potential for accumulation of mutations and minimize financial costs. Previous studies reported the use of modified synthetic mRNAs to reprogram fibroblasts to a pluripotent state. Here,we provide an optimized,fully chemically defined and feeder-free protocol for the derivation of hiPSCs using synthetic mRNAs. The protocol results in derivation of fully reprogrammed hiPSC lines from adult dermal fibroblasts in less than two weeks. The hiPSC lines were successfully tested for their identity,purity,stability and safety at a GMP facility and cryopreserved. To our knowledge,as a proof of principle,these are the first integration-free iPSCs lines that were reproducibly generated through synthetic mRNA reprogramming that could be putatively used for clinical purposes. View Publication

Human embryonic stem cells (hESC) and induced pluripotent stem cells (hiPSC) can differentiate into many cell types and are important for regenerative medicine; however,further work is needed to reliably differentiate hESC and hiPSC into neural-restricted multipotent derivatives or specialized cell types under conditions that are free from animal products. Toward this goal,we tested the transition of hESC and hiPSC lines onto xeno-free (XF) / feeder-free conditions and evaluated XF substrate preference,pluripotency,and karyotype. Critically,XF transitioned H9 hESC,Shef4 hESC,and iPS6-9 retained pluripotency (Oct-4 and NANOG),proliferation (MKI67 and PCNA),and normal karyotype. Subsequently,XF transitioned hESC and hiPSC were induced with epidermal growth factor (EGF) and basic fibroblast growth factor (bFGF) to generate neuralized spheres containing primitive neural precursors,which could differentiate into astrocytes and neurons,but not oligoprogenitors. Further neuralization of spheres via LIF supplementation and attachment selection on CELLstart substrate generated adherent human neural stem cells (hNSC) with normal karyotype and high proliferation potential under XF conditions. Interestingly,adherent hNSC derived from H9,Shef4,and iPS6-9 differentiated into significant numbers of O4+ oligoprogenitors (∼20-30%) with robust proliferation; however,very few GalC+ cells were observed (∼2-4%),indicative of early oligodendrocytic lineage commitment. Overall,these data demonstrate the transition of multiple hESC and hiPSC lines onto XF substrate and media conditions,and a reproducible neuralization method that generated neural derivatives with multipotent cell fate potential and normal karyotype. View Publication

Integrating viruses represent robust tools for cellular reprogramming; however,the presence of viral transgenes in induced pluripotent stem cells (iPSCs) is deleterious because it holds the risk of insertional mutagenesis leading to malignant transformation. Here,we combine the robustness of lentiviral reprogramming with the efficacy of Cre recombinase protein transduction to derive iPSCs devoid of transgenes. By genome-wide analysis and targeted differentiation towards the cardiomyocyte lineage,we show that transgene-free iPSCs are superior to iPSCs before Cre transduction. Our study provides a simple,rapid and robust protocol for the generation of clinical-grade iPSCs suitable for disease modeling,tissue engineering and cell replacement therapies. View Publication

Embryonic stem (ES) and induced-pluripotent stem (iPS) cells can be grown indefinitely under appropriate conditions whilst retaining the ability to differentiate to cells representative of the three primary germ layers. Such cells have the potential to revolutionize medicine by offering treatment options for a wide range of diseases and disorders as well as providing a model system for elucidating mechanisms involved in development and disease. In recent years,evidence for the function of E-cadherin in regulating pluripotent and self-renewal signaling pathways in ES and iPS cells has emerged. In this review,we discuss the function of E-cadherin and its interacting partners in the context of development and disease. We then describe relevant literature highlighting the function of E-cadherin in establishing and maintaining pluripotent and self-renewal properties of ES and iPS cells. In addition,we present experimental data demonstrating that exposure of human ES cells to the E-cadherin neutralizing antibody SHE78.7 allows culture of these cells in the absence of FGF2-supplemented medium. View Publication

Transcription factors NANOG,OCT4,and SOX2 regulate self-renewal and pluripotency in human embryonic stem (hES) cells; however,their expression profiles during early differentiation of hES cells are unclear. In this study,we used multiparameter flow cytometric assay to detect all three transcription factors (NANOG,OCT4,and SOX2) simultaneously at single cell level and monitored the changes in their expression during early differentiation towards endodermal lineage (induced by sodium butyrate). We observed at least four distinct populations of hES cells,characterized by specific expression patterns of NANOG,OCT4,and SOX2 and differentiation markers. Our results show that a single cell can express both differentiation and pluripotency markers at the same time,indicating a gradual mode of developmental transition in these cells. Notably,distinct regulation of SOX2 during early differentiation events was detected,highlighting the potential importance of this transcription factor for self-renewal of hES cells during differentiation. View Publication

Post-translational modification of histones is fundamental to the regulation of basic nuclear processes and subsequent cellular events,including differentiation. In this study,we analyzed acetylated forms of histones H2A,H2B,and H4 during induced differentiation in mouse (mESCs) and human (hESCs) embryonic stem cells and during induced enterocytic differentiation of colon cancer cells in vitro. Endoderm-like differentiation of mESCs induced by retinoic acid and enterocytic differentiation induced by histone deacetylase inhibitor sodium butyrate were accompanied by increased mono-,di-,and tri-acetylation of histone H2B and a pronounced increase in di- and tri-acetylation of histone H4. In enterocytes,mono-acetylation of histone H2A also increased and tetra-acetylation of histone H4 appeared only after induction of this differentiation pathway. During differentiation of hESCs,we observed increased mono-acetylation and decreased tri-acetylation of H2B. Mono-,di-,and tri-acetylation of H4 were reduced,manifested by a significant increase in nonacetylated H4 histones. Levels of acetylated histones increased during induced differentiation in mESCs and during histone deacetylase (HDAC) inhibitor-induced enterocytic differentiation,whereas differentiation of human ESCs was associated with reduced acetylation of histones H2B and H4. View Publication

GANT61 is a small-molecule inhibitor of glioma-associated oncogene 1 (GLI1)- and GLI2-mediated transcription at the nuclear level that exerts its effect by preventing DNA binding. It has been demonstrated to induce cell death against Ewing's sarcoma family tumor (ESFT) cell lines in a dose-dependent manner. The most sensitive cell line was SK-N-LO,which expresses the EWS-FLI1 fusion gene. SK-N-LO cells treated with GANT61 showed cellular and nuclear morphological changes,including cell shrinkage,chromatin condensation and nuclear fragmentation,in a concentration-dependent manner,as visualized by Hoechst 33342 staining. Furthermore,annexin V-propidium iodide (PI) double-staining revealed a significant increase in the number of late apoptotic cells. GANT61 induced a significant decrease in the proportion of cells in the S phase. Significant decrease of the protein levels of GLI2,survivin,cyclin A and claspin,and significant increase of p21 expression was also observed in the cells treated with GANT61. Moreover,poly (ADP-ribose) polymerase (PARP) cleavage was observed,but no cleavage of caspase-3 or -7,or any change in the expressions of Bcl-2 or p53 were observed. These findings suggest that GANT61 induces cell death of SK-N-LO cells in a caspase-independent manner,by inhibiting DNA replication in the S phase. View Publication

As a critical tumor suppressor,p53 is inactivated in human cancer cells by somatic gene mutation or disruption of pathways required for its activation. Therefore,it is critical to elucidate the mechanism underlying p53 activation after genotoxic and cellular stresses. Accumulating evidence has indicated the importance of posttranslational modifications such as acetylation in regulating p53 stability and activity. However,the physiological roles of the eight identified acetylation events in regulating p53 responses remain to be fully understood. By employing homologous recombination,we introduced various combinations of missense mutations (lysine to arginine) into eight acetylation sites of the endogenous p53 gene in human embryonic stem cells (hESCs). By determining the p53 responses to DNA damage in the p53 knock-in mutant hESCs and their derivatives,we demonstrate physiological importance of the acetylation events within the core domain (K120 and K164) and at the C-terminus (K370/372/373/381/382/386) in regulating human p53 responses to DNA damage. View Publication

The development of human embryonic stem cells (ESCs) and induced pluripotent stem cells (iPSCs) facilitates in vitro studies of human disease mechanisms,speeds up the process of drug screening,and raises the feasibility of using cell replacement therapy in clinics. However,the study of genotype-phenotype relationships in ESCs or iPSCs is hampered by the low efficiency of site-specific gene editing. Transcription activator-like effector nucleases (TALENs) spurred interest due to the ease of assembly,high efficiency and faithful gene targeting. In this study,we optimized the TALEN design to maximize its genomic cutting efficiency. We showed that using optimized TALENs in conjunction with single-strand oligodeoxynucleotide (ssODN) allowed efficient gene editing in human cells. Gene mutations and gene deletions for up to 7.8 kb can be accomplished at high efficiencies. We established human tumor cell lines and H9 ESC lines with homozygous deletion of the microRNA-21 (miR-21) gene and miR-9-2 gene. These cell lines provide a robust platform to dissect the roles these genes play during cell differentiation and tumorigenesis. We also observed that the endogenous homologous chromosome can serve as a donor template for gene editing. Overall,our studies demonstrate the versatility of using ssODN and TALEN to establish genetically modified cells for research and therapeutic application. View Publication

Targeted genome editing with engineered nucleases has transformed the ability to introduce precise sequence modifications at almost any site within the genome. A major obstacle to probing the efficiency and consequences of genome editing is that no existing method enables the frequency of different editing events to be simultaneously measured across a cell population at any endogenous genomic locus.We have developed a method for quantifying individual genome-editing outcomes at any site of interest with single-molecule real-time (SMRT) DNA sequencing. We show that this approach can be applied at various loci using multiple engineered nuclease platforms,including transcription-activator-like effector nucleases (TALENs),RNA-guided endonucleases (CRISPR/Cas9),and zinc finger nucleases (ZFNs),and in different cell lines to identify conditions and strategies in which the desired engineering outcome has occurred. This approach offers a technique for studying double-strand break repair,facilitates the evaluation of gene-editing technologies,and permits sensitive quantification of editing outcomes in almost every experimental system used. ?? 2014 The Authors. View Publication