技术资料

Neurogenin3+ (Ngn3+) progenitor cells in the developing pancreas give rise to five endocrine cell types secreting insulin,glucagon,somatostatin,pancreatic polypeptide and ghrelin. Gastrin is a hormone produced primarily by G-cells in the stomach,where it functions to stimulate acid secretion by gastric parietal cells. Gastrin is expressed in the embryonic pancreas and is common in islet cell tumors,but the lineage and regulators of pancreatic gastrin+ cells are not known. We report that gastrin is abundantly expressed in the embryonic pancreas and disappears soon after birth. Some gastrin+ cells in the developing pancreas co-express glucagon,ghrelin or pancreatic polypeptide,but many gastrin+ cells do not express any other islet hormone. Pancreatic gastrin+ cells express the transcription factors Nkx6.1,Nkx2.2 and low levels of Pdx1,and derive from Ngn3+ endocrine progenitor cells as shown by genetic lineage tracing. Using mice deficient for key transcription factors we show that gastrin expression depends on Ngn3,Nkx2.2,NeuroD1 and Arx,but not Pax4 or Pax6. Finally,gastrin expression is induced upon differentiation of human embryonic stem cells to pancreatic endocrine cells expressing insulin. Thus,gastrin+ cells are a distinct endocrine cell type in the pancreas and an alternative fate of Ngn3+ cells. View Publication

The unique ability of Sox2 to cooperate with Oct4 at selective binding sites in the genome is critical for reprogramming somatic cells into induced pluripotent stem cells (iPSCs). We have recently demonstrated that Sox17 can be converted into a reprogramming factor by alteration of a single amino acid (Sox17EK) within its DNA binding HMG domain. Here we expanded this study by introducing analogous mutations to 10 other Sox proteins and interrogated the role of N-and C-termini on the reprogramming efficiency. We found that point-mutated Sox7 and Sox17 can convert human and mouse fibroblasts into iPSCs,but Sox4,Sox5,Sox6,Sox8,Sox9,Sox11,Sox12,Sox13,and Sox18 cannot. Next we studied regions outside the HMG domain and found that the C-terminal transactivation domain of Sox17 and Sox7 enhances the potency of Sox2 in iPSC assays and confers weak reprogramming potential to the otherwise inactive Sox4EK and Sox18EK proteins. These results suggest that the glutamate (E) to lysine (K) mutation in the HMG domain is necessary but insufficient to swap the function of Sox factors. Moreover,the HMG domain alone fused to the VP16 transactivation domain is able to induce reprogramming,albeit at low efficiency. By molecular dissection of the C-terminus of Sox17,we found that the β-catenin interaction region contributes to the enhanced reprogramming efficiency of Sox17EK. To mechanistically understand the enhanced reprogramming potential of Sox17EK,we analyzed ChIP-sequencing and expression data and identified a subset of candidate genes specifically regulated by Sox17EK and not by Sox2. View Publication

With defined culture protocol,human embryonic stem cells (hESCs) are able to generate cardiomyocytes in vitro,therefore providing a great model for human heart development,and holding great potential for cardiac disease therapies. In this study,we successfully generated a highly pure population of human cardiomyocytes (hCMs) (backslashtextgreater95% cTnT+) from hESC line,which enabled us to identify and characterize an hCM-specific signature,at both the gene expression and DNA methylation levels. Gene functional association network and gene-disease network analyses of these hCM-enriched genes provide new insights into the mechanisms of hCM transcriptional regulation,and stand as an informative and rich resource for investigating cardiac gene functions and disease mechanisms. Moreover,we show that cardiac-structural genes and cardiac-transcription factors have distinct epigenetic mechanisms to regulate their gene expression,providing a better understanding of how the epigenetic machinery coordinates to regulate gene expression in different cell types. View Publication

Once set,the inactive status of the X chromosome in female somatic cells is preserved throughout subsequent cell divisions. The inactive status of the X chromosome is characterized by many features,including late replication. In contrast to induced pluripotent stem cells (iPSCs) in mice,the X chromosome in human female iPSCs usually remains inactive after reprogramming of somatic cells to the pluripotent state,although recent studies point to the possibility of reactivation of the X chromosome. Here,we demonstrated that,during reprogramming,the inactive X chromosome switches from late to synchronous replication,with restoration of the transcription of previously silenced genes. This process is accompanied by accumulation of a new epigenetic mark or intermediate of the DNA demethylation pathway,5-hydroxymethylcytosine (5hmC),on the activated X chromosome. Our results indicate that the active status of the X chromosome is better confirmed by early replication and the reappearance of 5hmC,rather than by appearance of histone marks of active chromatin,removal of histone marks of inactive chromatin,or an absence of XIST coating. View Publication

View Publication

Human embryonic stem cells (hESCs) can be maintained in vitro as immortal pluripotent cells but remain responsive to many differentiation-inducing signals. Investigation of the initial critical events involved in differentiation induction would be greatly facilitated if a specific,robust,and quantitative assay for pluripotent hESCs with self-renewal potential were available. Here we describe the results of a series of experiments to determine whether the formation of adherent alkaline phosphatase-positive (AP(+)) colonies under conditions optimized for propagating undifferentiated hESCs would meet this need. The findings can be summarized as follows. (a) Most colonies obtained under these conditions consist of textgreateror=30 AP(+) cells that coexpress OCT4,NANOG,SSEA3,SSEA4,TRA-1-60,and TRA-1-81. (b) Most such colonies are derived from SSEA3(+) cells. (c) Primary colonies contain cells that produce secondary colonies of the same composition,including cells that initiate multilineage differentiation in embryoid bodies (EBs). (d) Colony formation is independent of plating density or the colony-forming cell (CFC) content of the test population over a wide range of cell concentrations. (e) CFC frequencies decrease when differentiation is induced by exposure either to retinoic acid or to conditions that stimulate EB formation. Interestingly,this loss of AP(+) clonogenic potential also occurs more rapidly than the loss of SSEA3 or OCT4 expression. The CFC assay thus provides a simple,reliable,broadly applicable,and highly specific functional assay for quantifying undifferentiated hESCs with self-renewal potential. Its use under standardized assay conditions should enhance future elucidation of the mechanisms that regulate hESC propagation and their early differentiation. View Publication

BACKGROUND: Human embryonic stem cells (hESC) provide a unique model to study early events in human development. The hESC-derived cells can potentially be used to replace or restore different tissues including neuronal that have been damaged by disease or injury.backslashnbackslashnMETHODOLOGY AND PRINCIPAL FINDINGS: The cells of two different hESC lines were converted to neural rosettes using adherent and chemically defined conditions. The progenitor cells were exposed to retinoic acid (RA) or to human recombinant basic fibroblast growth factor (bFGF) in the late phase of the rosette formation. Exposing the progenitor cells to RA suppressed differentiation to rostral forebrain dopamine neural lineage and promoted that of spinal neural tissue including motor neurons. The functional characteristics of these differentiated neuronal precursors under both,rostral (bFGF) and caudalizing (RA) signals were confirmed by patch clamp analysis.backslashnbackslashnCONCLUSIONS/SIGNIFICANCE: These findings suggest that our differentiation protocol has the capacity to generate region-specific and electrophysiologically active neurons under in vitro conditions without embryoid body formation,co-culture with stromal cells and without presence of cells of mesodermal or endodermal lineages. View Publication

Mouse embryonic stem (mES) cells will give rise to all of the cells of the adult mouse,but they failed to rejoin half of the DNA double-strand breaks (dsb) produced by high doses of ionizing radiation. A deficiency in DNA-PK(cs) appears to be responsible since mES cells expressed textless10% of the level of mouse embryo fibroblasts (MEFs) although Ku70/80 protein levels were higher than MEFs. However,the low level of DNA-PK(cs) found in wild-type cells appeared sufficient to allow rejoining of dsb after doses textless20Gy even in G1 phase cells. Inhibition of DNA-PK(cs) with wortmannin and NU7026 still sensitized mES cells to radiation confirming the importance of the residual DNA-PK(cs) at low doses. In contrast to wild-type cells,mES cells lacking H2AX,a histone protein involved in the DNA damage response,were radiosensitive but they rejoined double-strand breaks more rapidly. Consistent with more rapid dsb rejoining,H2AX(-/-) mES cells also expressed 6 times more DNA-PK(cs) than wild-type mES cells. Similar results were obtained for ATM(-/-) mES cells. Differentiation of mES cells led to an increase in DNA-PK(cs),an increase in dsb rejoining rate,and a decrease in Ku70/80. Unlike mouse ES,human ES cells were proficient in rejoining of dsb and expressed high levels of DNA-PK(cs). These results confirm the importance of homologous recombination in the accurate repair of double-strand breaks in mES cells,they help explain the chromosome abnormalities associated with deficiencies in H2AX and ATM,and they add to the growing list of differences in the way rodent and human cells deal with DNA damage. View Publication

Human embryonic stem (hES) cells represent a potential source for cell replacement therapy of many degenerative diseases. Most frequently,hES cell lines are derived from surplus embryos from assisted reproduction cycles,independent of their quality or morphology. Here,we show that hES cell lines can be obtained from poor-quality blastocysts with the same efficiency as that obtained from good- or intermediate-quality blastocysts. Furthermore,we show that the self-renewal,pluripotency,and differentiation ability of hES cell lines derived from either source are comparable. Finally,we present a simple and reproducible embryoid body-based protocol for the differentiation of hES cells into functional cardiomyocytes. The five new hES cell lines derived here should widen the spectrum of available resources for investigating the biology of hES cells and advancing toward efficient strategies of regenerative medicine. View Publication

Large-scale manufacture of human embryonic stem cells (hESCs) is prerequisite to their widespread use in biomedical applications. However,current hESC culture strategies are labor-intensive and employ highly variable processes,presenting challenges for scaled production and commercial development. Here we demonstrate that passaging of the hESC lines,HUES7,and NOTT1,with trypsin in feeder-free conditions,is compatible with complete automation on the CompacT SelecT,a commercially available and industrially relevant robotic platform. Pluripotency was successfully retained,as evidenced by consistent proliferation during serial passage,expression of stem cell markers (OCT4,NANOG,TRA1-81,and SSEA-4),stable karyotype,and multi-germlayer differentiation in vitro,including to pharmacologically responsive cardiomyocytes. Automation of hESC culture will expedite cell-use in clinical,scientific,and industrial applications. View Publication

The discovery of human embryonic stem cells (hESCs) has dramatically increased the tools available to medical scientists interested in regenerative medicine. However,direct injection of hESCs,and cells differentiated from hESCs,into living organisms has thus far been hampered by significant cell death,teratoma formation,and host immune rejection. Understanding the in vivo hESC behavior after transplantation requires novel imaging techniques to longitudinally monitor hESC localization,proliferation,and viability. Molecular imaging has given investigators a high-throughput,inexpensive,and sensitive means for tracking in vivo cell proliferation over days,weeks,and even months. This advancement has significantly increased the understanding of the spatio-temporal kinetics of hESC engraftment,proliferation,and teratoma-formation in living subjects. A major advance in molecular imaging has been the extension of noninvasive reporter gene assays from molecular and cellular biology into in vivo multi-modality imaging platforms. These reporter genes,under control of engineered promoters and enhancers that take advantage of the host cell s transcriptional machinery,are introduced into cells using a variety of vector and non-vector methods. Once in the cell,reporter genes can be transcribed either constitutively or only under specific biological or cellular conditions,depending on the type of promoter used. Transcription and translation of reporter genes into bioactive proteins is then detected with sensitive,noninvasive instrumentation (e.g.,CCD cameras) using signal-generating probes such as D-luciferin. To avoid the need for excitatory light to track stem cells in vivo as is required for fluorescence imaging,bioluminescence reporter gene imaging systems require only an exogenously administered probe to induce light emission. Firefly luciferase,derived from the firefly Photinus pyralis,encodes an enzyme that catalyzes D-luciferin to the optically active metabolite,oxyluciferin. Optical activity can then be monitored with an external CCD camera. Stably transduced cells that carry the reporter construct within their chromosomal DNA will pass the reporter construct DNA to daughter cells,allowing for longitudinal monitoring of hESC survival and proliferation in vivo. Furthermore,because expression of the reporter gene product is required for signal generation,only viable parent and daughter cells will create bioluminescence signal; apoptotic or dead cells will not. In this video,the specific materials and methods needed for tracking stem cell proliferation and teratoma formation with bioluminescence imaging will be described. View Publication

Induced pluripotent stem cells (iPSCs) hold enormous potential for the development of personalized in vitro disease models,genomic health analyses,and autologous cell therapy. Here we describe the generation of T lymphocyte-derived iPSCs from small,clinically advantageous volumes of non-mobilized peripheral blood. These T-cell derived iPSCs (TiPS") retain a normal karyotype and genetic identity to the donor. They share common characteristics with human embryonic stem cells (hESCs) with respect to morphology� View Publication