技术资料

A major road-block in stem cell therapy is the poor homing and integration of transplanted stem cells with the targeted host tissue. Human induced pluripotent stem (hiPS) cells are considered an excellent alternative to embryonic stem (ES) cells and we tested the feasibility of using small,physiological electric fields (EFs) to guide hiPS cells to their target. Applied EFs stimulated and guided migration of cultured hiPS cells toward the anode,with a stimulation threshold of textless30 mV/mm; in three-dimensional (3D) culture hiPS cells remained stationary,whereas in an applied EF they migrated directionally. This is of significance as the therapeutic use of hiPS cells occurs in a 3D environment. EF exposure did not alter expression of the pluripotency markers SSEA-4 and Oct-4 in hiPS cells. We compared EF-directed migration (galvanotaxis) of hiPS cells and hES cells and found that hiPS cells showed greater sensitivity and directedness than those of hES cells in an EF,while hES cells migrated toward cathode. Rho-kinase (ROCK) inhibition,a method to aid expansion and survival of stem cells,significantly increased the motility,but reduced directionality of iPS cells in an EF by 70-80%. Thus,our study has revealed that physiological EF is an effective guidance cue for the migration of hiPS cells in either 2D or 3D environments and that will occur in a ROCK-dependent manner. Our current finding may lead to techniques for applying EFs in vivo to guide migration of transplanted stem cells. View Publication

Human embryonic stem cells (hESCs) represent a promising source of tissues of different cell lineages because of their high degree of self-renewal and their unique ability to give rise to most somatic cell lineages. In this article,we report on a new approach to differentiate hESCs into neural stem cells that can be differentiated further into neuronal restricted cells. We have rapidly and efficiently differentiated hESCs into neural stem cells by presenting the cell adhesion molecule,E-cadherin,to undifferentiated hESCs via E-cadherin transfected fibroblast monolayers. The neural restricted progenitor cells rapidly express nestin and beta-III-tubulin,but not glial fibrillary acidic protein (GFAP) during the 1-week E-cadherin induction phase,suggesting that E-cadherin promotes rapid neuronal differentiation. Further,these cells are able to achieve enhanced neuronal differentiation with the addition of exogenous growth factors. Cadherin-induced hESCs show a loss in Oct4 and nestin expression associated with positive staining for vimentin,neurofilament,and neural cell adhesion molecule. Moreover,blocking by functional E-cadherin antibody and failure of paracrine stimulation suggested that direct E-cadherin engagement is necessary to induce neural restriction. By providing hESCs with molecular cues to promote differentiation,we are able to utilize a specific cell-cell adhesion molecule,E-cadherin,to influence the nature and degree of neural specialization. View Publication

Although regulation of histone methylation is believed to contribute to embryonic stem cell (ESC) self-renewal,the mechanisms remain obscure. We show here that the histone H3 trimethyl lysine 4 (H3K4me3) demethylase,KDM5B,is a downstream Nanog target and critical for ESC self-renewal. Although KDM5B is believed to function as a promoter-bound repressor,we find that it paradoxically functions as an activator of a gene network associated with self-renewal. ChIP-Seq reveals that KDM5B is predominantly targeted to intragenic regions and that it is recruited to H3K36me3 via an interaction with the chromodomain protein MRG15. Depletion of KDM5B or MRG15 increases intragenic H3K4me3,increases cryptic intragenic transcription,and inhibits transcriptional elongation of KDM5B target genes. We propose that KDM5B activates self-renewal-associated gene expression by repressing cryptic initiation and maintaining an H3K4me3 gradient important for productive transcriptional elongation. View Publication

Human ESC and iPSC are an attractive source of cells of high quantity and purity to be used to elucidate early human development processes,for drug discovery,and in clinical cell therapy applications. To efficiently differentiate pluripotent cells into a pure population of hematopoietic progenitors we have developed a new 2-dimensional,defined and highly efficient protocol that avoids the use of feeder cells,serum or embryoid body formation. Here we showed that a single matrix protein in combination with growth factors and a hypoxic environment is sufficient to generate from pluripotent cells hematopoietic progenitors capable of differentiating further in mature cell types of different lineages of the blood system. We tested the differentiation method using hESCs and 9 iPSC lines generated from different tissues. These data indicate the robustness of the protocol providing a valuable tool for the generation of clinical-grade hematopoietic cells from pluripotent cells. View Publication

Meticulous characterization of human embryonic stem cells (hESC) is critical to their eventual use in cell-based therapies,particularly in view of the diverse methods for derivation and maintenance of these cell lines. However,characterization methods are generally not standardized and many currently used assays are subjective,making dependable and direct comparison of cell lines difficult. In order to address this problem,we selected 10 molecular-based high-resolution assays as components of a panel for characterization of hESC. The selection of the assays was primarily based on their quantitative or objective (rather than subjective) nature. We demonstrate the efficacy of this panel by characterizing 4 hESC lines,derived in two different laboratories using different derivation techniques,as pathogen free,genetically stable,and able to differentiate into derivatives of all three germ layers. Our panel expands and refines a characterization panel previously proposed by the International Stem Cell Initiative and is another step toward standardized hESC characterization and quality control,a crucial element of successful hESC research and clinical translation. View Publication

Genetic reprogramming of human somatic cells to induced pluripotent stem cells (iPSCs) could offer replenishable cell sources for transplantation therapies. To fulfill their promises,human iPSCs will ideally be free of exogenous DNA (footprint-free),and be derived and cultured in chemically defined media free of feeder cells. Currently,methods are available to enable efficient derivation of footprint-free human iPSCs. However,each of these methods has its limitations. We have previously derived footprint-free human iPSCs by employing episomal vectors for transgene delivery,but the process was inefficient and required feeder cells. Here,we have greatly improved the episomal reprogramming efficiency using a cocktail containing MEK inhibitor PD0325901,GSK3β inhibitor CHIR99021,TGF-β/Activin/Nodal receptor inhibitor A-83-01,ROCK inhibitor HA-100 and human leukemia inhibitory factor. Moreover,we have successfully established a feeder-free reprogramming condition using chemically defined medium with bFGF and N2B27 supplements and chemically defined human ESC medium mTeSR1 for the derivation of footprint-free human iPSCs. These improvements enabled the routine derivation of footprint-free human iPSCs from skin fibroblasts,adipose tissue-derived cells and cord blood cells. This technology will likely be valuable for the production of clinical-grade human iPSCs. View Publication

Induced pluripotent stem cells (iPSCs) offer immense potential for regenerative medicine and studies of disease and development. Somatic cell reprogramming involves epigenomic reconfiguration,conferring iPSCs with characteristics similar to embryonic stem (ES) cells. However,it remains unknown how complete the reestablishment of ES-cell-like DNA methylation patterns is throughout the genome. Here we report the first whole-genome profiles of DNA methylation at single-base resolution in five human iPSC lines,along with methylomes of ES cells,somatic cells,and differentiated iPSCs and ES cells. iPSCs show significant reprogramming variability,including somatic memory and aberrant reprogramming of DNA methylation. iPSCs share megabase-scale differentially methylated regions proximal to centromeres and telomeres that display incomplete reprogramming of non-CG methylation,and differences in CG methylation and histone modifications. Lastly,differentiation of iPSCs into trophoblast cells revealed that errors in reprogramming CG methylation are transmitted at a high frequency,providing an iPSC reprogramming signature that is maintained after differentiation. View Publication

Bromodomain-containing protein 4 (BRD4) is an important epigenetic reader implicated in the pathogenesis of a number of different cancers and other diseases. Brd4-null mouse embryos die shortly after implantation and are compromised in their ability to maintain the inner cell mass,which gives rise to embryonic stem cells (ESCs). Here we report that BRD4 regulates expression of the pluripotency factor Nanog in mouse ESCs and preimplantation embryos,as well as in human ESCs and embryonic cancer stem cells. Inhibition of BRD4 function using a chemical inhibitor,small interfering RNAs,or a dominant-negative approach suppresses Nanog expression,and abolishes the self-renewal ability of ESCs. We also find that BRD4 associates with BRG1 (brahma-related gene 1,aka Smarca4 (SWI/SNF-related,matrix-associated,actin-dependent regulator of chromatin,subfamily a,member 4)),a key regulator of ESC self-renewal and pluripotency,in the Nanog regulatory regions to regulate Nanog expression. Our study identifies Nanog as a novel BRD4 target gene,providing new insights for the biological function of BRD4 in stem cells and mouse embryos. Knowledge gained from these non-cancerous systems will facilitate future investigations of how Brd4 dysfunction leads to cancers.Cell Death and Differentiation advance online publication,22 August 2014; doi:10.1038/cdd.2014.124. View Publication

MED13L is a component subunit of the Mediator complex,an important regulator of transcription that is highly conserved across eukaryotes. Here we report MED13L disruption in a translocation t(12;19) breakpoint of a patient with Pierre-Robin syndrome,moderate intellectual disability (ID),craniofacial anomalies,and muscular defects. The phenotype is similar to previously described patients with MED13L haploinsufficiency. Knockdown of MED13L orthologue in zebrafish,med13b,showed early defective migration of cranial neural crest cells (NCCs) that contributed into cartilage structure deformities in the later stage,recapitulating craniofacial anomalies seen in human patients. Notably,we observed abnormal distribution of developing neurons in different brain regions of med13b morphant embryos,which could be rescued upon introduction of full-length human MED13L mRNA. To compare with mammalian system,we suppressed MED13L expression by short-hairpin RNA in ES-derived human neural progenitors,and differentiated them into neurons. Transcriptome analysis revealed differential expression of components of Wnt and FGF signalling pathways in MED13L-deficient neurons. Our finding provides a novel insight into the mechanism of overlapping phenotypic outcome targeting NCCs derivatives organs in patients with MED13L haploinsufficiency,and emphasizes a clinically recognizable syndromic phenotype in these patients. This article is protected by copyright. All rights reserved. View Publication

Genetic Parkinson disease (PD) has been associated with mutations in PINK1,a gene encoding a mitochondrial kinase implicated in the regulation of mitochondrial degradation. While the studies so far examined PINK1 function in non-neuronal systems or through PINK1 knockdown approaches,there is an imperative to examine the role of endogenous PINK1 in appropriate human-derived and biologically relevant cell models. Here we report the generation of induced pluripotent stem (iPS) cells from skin fibroblasts taken from three PD patients with nonsense (c.1366CtextgreaterT; p.Q456X) or missense (c.509TtextgreaterG; p.V170G) mutations in the PINK1 gene. These cells were differentiated into dopaminergic neurons that upon mitochondrial depolarization showed impaired recruitment of lentivirally expressed Parkin to mitochondria,increased mitochondrial copy number,and upregulation of PGC-1α,an important regulator of mitochondrial biogenesis. Importantly,these alterations were corrected by lentiviral expression of wild-type PINK1 in mutant iPS cell-derived PINK1 neurons. In conclusion,our studies suggest that fibroblasts from genetic PD can be reprogrammed and differentiated into neurons. These neurons exhibit distinct phenotypes that should be amenable to further mechanistic studies in this relevant biological context. View Publication

The role of autophagy,a lysosomal degradation pathway which prevents cellular damage,in the maintenance of adult mouse hematopoietic stem cells (HSCs) remains unknown. Although normal HSCs sustain life-long hematopoiesis,malignant transformation of HSCs leads to leukemia. Therefore,mechanisms protecting HSCs from cellular damage are essential to prevent hematopoietic malignancies. In this study,we crippled autophagy in HSCs by conditionally deleting the essential autophagy gene Atg7 in the hematopoietic system. This resulted in the loss of normal HSC functions,a severe myeloproliferation,and death of the mice within weeks. The hematopoietic stem and progenitor cell compartment displayed an accumulation of mitochondria and reactive oxygen species,as well as increased proliferation and DNA damage. HSCs within the Lin(-)Sca-1(+)c-Kit(+) (LSK) compartment were significantly reduced. Although the overall LSK compartment was expanded,Atg7-deficient LSK cells failed to reconstitute the hematopoietic system of lethally irradiated mice. Consistent with loss of HSC functions,the production of both lymphoid and myeloid progenitors was impaired in the absence of Atg7. Collectively,these data show that Atg7 is an essential regulator of adult HSC maintenance. View Publication