技术资料

Mesenchymal stem cells (MSCs) are defined as non-hematopoietic,plastic-adherent,self-renewing cells that are capable of tri-lineage differentiation into bone,cartilage or fat in vitro. Thus,MSCs are promising candidates for cell-based medicine. However,classifications of MSCs have been defined retrospectively; moreover,this conventional criterion may be inaccurate due to contamination with other hematopoietic lineage cells. Human MSCs can be enriched by selection for LNGFR and THY-1,and this population may be analogous to murine PDGFR??+Sca-1+ cells,which are developmentally derived from neural crest cells (NCCs). Murine NCCs were labeled by fluorescence,which provided definitive proof of neural crest lineage,however,technical considerations prevent the use of a similar approach to determine the origin of human LNGFR+THY-1+ MSCs. To further clarify the origin of human MSCs,human embryonic stem cells (ESCs) and human induced pluripotent stem cells (iPSCs) were used in this study. Under culture conditions required for the induction of neural crest cells,human ESCs and iPSCs-derived cells highly expressed LNGFR and THY-1. These LNGFR+THY-1+ neural crest-like cells,designated as LT-NCLCs,showed a strong potential to differentiate into both mesenchymal and neural crest lineages. LT-NCLCs proliferated to form colonies and actively migrated in response to serum concentration. Furthermore,we transplanted LT-NCLCs into chick embryos,and traced their potential for survival,migration and differentiation in the host environment. These results suggest that LNGFR+THY-1+ cells identified following NCLC induction from ESCs/iPSCs shared similar potentials with multipotent MSCs. View Publication

Acute monocytic leukemia (AML-M5),a subtype of acute myeloid leukemia (AML),affects mostly young children and has poor prognosis. The mechanisms of treatment failure of AML-M5 are still unclear. In this study,we generated iPSC from THP-1 cells from a patient with AML-M5,using retroviruses encoding the pluripotency-associated genes (OCT3/4,SOX2,KLF4 and c-MYC). These AML-M5-derived iPSC showed features similar with those of human embryonic stem cells in terms of the morphology,gene expression,protein/antigen expression and differentiation capability. Parental-specific markers were down-regulated in these AML-M5-derived iPSCs. Expression of MLL-AF9 fusion gene (previously identified to be associated with pathogenesis of AML-M5) was observed in all iPSC clones as well as parental cells. We conclude that AML-M5-specific iPSC clones have been successfully developed. This disease model may provide a novel approach for future study of pathogenesis and therapeutic intervention of AML-M5. View Publication

The unique mental abilities of humans are rooted in the immensely expanded and folded neocortex,which reflects the expansion of neural progenitors,especially basal progenitors including basal radial glia (bRGs) and intermediate progenitor cells (IPCs). We found that constitutively active Sonic hedgehog (Shh) signaling expanded bRGs and IPCs and induced folding in the otherwise smooth mouse neocortex,whereas the loss of Shh signaling decreased the number of bRGs and IPCs and the size of the neocortex. SHH signaling was strongly active in the human fetal neocortex but Shh signaling was not strongly active in the mouse embryonic neocortex,and blocking SHH signaling in human cerebral organoids decreased the number of bRGs. Mechanistically,Shh signaling increased the initial generation and self-renewal of bRGs and IPC proliferation in mice and the initial generation of bRGs in human cerebral organoids. Thus,robust SHH signaling in the human fetal neocortex may contribute to bRG and IPC expansion and neocortical growth and folding. View Publication

Loss-of-function studies are fundamental for dissecting gene function. Yet,methods to rapidly and effectively perturb genes in mammalian cells,and particularly in stem cells,are scarce. Here we present a system for simultaneous conditional regulation of two different proteins in the same mammalian cell. This system harnesses the plant auxin and jasmonate hormone-induced degradation pathways,and is deliverable with only two lentiviral vectors. It combines RNAi-mediated silencing of two endogenous proteins with the expression of two exogenous proteins whose degradation is induced by external ligands in a rapid,reversible,titratable and independent manner. By engineering molecular tuners for NANOG,CHK1,p53 and NOTCH1 in mammalian stem cells,we have validated the applicability of the system and demonstrated its potential to unravel complex biological processes. View Publication

Directed differentiation of stem cells offers a scalable solution to the need for human cell models recapitulating islet biology and T2D pathogenesis. We profiled mRNA expression at 6 stages of an induced pluripotent stem cell (iPSC) model of endocrine pancreas development from 2 donors,and characterized the distinct transcriptomic profiles associated with each stage. Established regulators of endodermal lineage commitment,such as SOX17 (log2 fold change [FC] compared to iPSCs = 14.2,p-value = 4.9 × 10(-5)) and the pancreatic agenesis gene GATA6 (log2 FC = 12.1,p-value = 8.6 × 10(-5)),showed transcriptional variation consistent with their known developmental roles. However,these analyses highlighted many other genes with stage-specific expression patterns,some of which may be novel drivers or markers of islet development. For example,the leptin receptor gene,LEPR,was most highly expressed in published data from in vivo-matured cells compared to our endocrine pancreas-like cells (log2 FC = 5.5,p-value = 2.0 × 10(-12)),suggesting a role for the leptin pathway in the maturation process. Endocrine pancreas-like cells showed significant stage-selective expression of adult islet genes,including INS,ABCC8,and GLP1R,and enrichment of relevant GO-terms (e.g. insulin secretion"; odds ratio = 4.2� View Publication

Fibrodysplasia ossificans progressiva (FOP) syndrome is caused by mutation of the gene ACVR1,encoding a constitutive active bone morphogenetic protein type I receptor (also called ALK2) to induce heterotopic ossification in the patient. To genetically correct it,we attempted to generate the mutant ALK2-iPSCs (mALK2-iPSCs) from FOP-human dermal fibroblasts. However,the mALK2 leads to inhibitory pluripotency maintenance,or impaired clonogenic potential after single-cell dissociation as an inevitable step,which applies gene-correction tools to induced pluripotent stem cells (iPSCs). Thus,current iPSC-based gene therapy approach reveals a limitation that is not readily applicable to iPSCs with ALK2 mutation. Here we developed a simplified one-step procedure by simultaneously introducing reprogramming and gene-editing components into human fibroblasts derived from patient with FOP syndrome,and genetically treated it. The mixtures of reprogramming and gene-editing components are composed of reprogramming episomal vectors,CRISPR/Cas9-expressing vectors and single-stranded oligodeoxynucleotide harboring normal base to correct ALK2 c.617GtextgreaterA. The one-step-mediated ALK2 gene-corrected iPSCs restored global gene expression pattern,as well as mineralization to the extent of normal iPSCs. This procedure not only helps save time,labor and costs but also opens up a new paradigm that is beyond the current application of gene-editing methodologies,which is hampered by inhibitory pluripotency-maintenance requirements,or vulnerability of single-cell-dissociated iPSCs. View Publication

It has become increasingly clear that proper cellular control of pluripotency and differentiation is related to the regulation of rRNA synthesis. To further our understanding of the role that the regulation of rRNA synthesis has in pluripotency we monitored rRNA synthesis during the directed differentiation of human embryonic stem cells (hESCs). We discovered that the rRNA synthesis rate is reduced ˜50% within 6 hours of ACTIVIN A treatment. This precedes reductions in expression of specific stem cell markers and increases in expression of specific germ layer markers. The reduction in rRNA synthesis is concomitant with dissociation of the Pol I transcription factor,UBTF,from the rRNA gene promoter and precedes any increase to heterochromatin throughout the rRNA gene. To directly investigate the role of rRNA synthesis in pluripotency,hESCs were treated with the Pol I inhibitor,CX-5461. The direct reduction of rRNA synthesis by CX-5461 induces the expression of markers for all three germ layers,reduces the expression of pluripotency markers,and is overall similar to the ACTIVIN A induced changes. This work indicates that the dissociation of UBTF from the rRNA gene,and corresponding reduction in transcription,represent early regulatory events during the directed differentiation of pluripotent stem cells. View Publication

In most human somatic cells,the lack of telomerase activity results in progressive telomere shortening during each cell division. Eventually,DNA damage responses triggered by critically short telomeres induce an irreversible cell cycle arrest termed replicative senescence. However,the cellular responses of human pluripotent stem cells to telomere uncapping remain unknown. We generated telomerase knockout human embryonic stem (ES) cells through gene targeting. Telomerase inactivation in ES cells results in progressive telomere shortening. Telomere DNA damage in ES cells and neural progenitor cells induces rapid apoptosis when telomeres are uncapped,in contrast to fibroblast cells that enter a state of replicative senescence. Significantly,telomerase inactivation limits the proliferation capacity of human ES cells without affecting their pluripotency. By targeting telomerase activity,we can functionally separate the two unique properties of human pluripotent stem cells,namely unlimited self-renewal and pluripotency. We show that the potential of ES cells to form teratomas in vivo is dictated by their telomere length. By controlling telomere length of ES cells through telomerase inactivation,we can inhibit teratoma formation and potentially improve the safety of cell therapies involving terminally differentiated cells as well as specific progenitor cells that do not require sustained cellular proliferation in vivo,and thus sustained telomerase activity. This article is protected by copyright. All rights reserved. View Publication

Human somatic stem cells such as mesenchymal stem cells (hMSCs) have the capacity to differentiate into mesenchymal tissue lineages and to alter immune regulatory functions. As such,they hold promise for use in stem cell-based therapies. However,no method is currently available to evaluate the actual differentiation capacity of hMSCs prior to cell transplantation. Previously,we performed a comprehensive glycan profiling of adipose-derived hMSCs using high-density lectin microarray and demonstrated that $$2-6-sialylation is a marker of the differentiation potential of these cells. Nevertheless,no information was available about the structural details of these of $$2-6-sialylated glycans. Here we used high performance liquid chromatography (HPLC) analysis combined with mass spectrometry (MS) to perform a structural and quantitative glycome analysis targeting both N- and O-glycans derived from early (with differentiation ability) and late (without differentiation ability) passages of adipose tissue-derived hMSCs. Findings in these cells were compared with those from human induced pluripotent stem cells (hiPSCs),human dermal fibroblasts (hFibs) and cartilage tissue-derived chondrocytes. A higher percentage of $$2-6-sialylated N-glycans was detected in early passage cells (24-28 % of sialylated N-glycans) compared with late passage cells (13-15 %). A major $$2-6-sialylated N-glycan structure detected in adipose-derived hMSCs was that of mono-sialylated biantennary N-glycan. Similar results were obtained for the cartilage tissue-derived chondrocytes,Yub621c (28 % for passage 7 and 5 % for passage 28). In contrast,no significant differences were observed between early and late passage hMSCs with respect to $$2-6-sialylated O-glycan percentages. These results demonstrate that levels of $$2-6-sialylated N-glycans,but not O-glycans,could be used as markers of the differential potential of hMSCs. View Publication

Helper-dependent adenoviral vectors (HDAd) that express certain transgene products are impossible to produce because the transgene product is toxic to the producer cells,especially when made in large amounts during vector production. Downregulating transgene expression from the HDAd during vector production is a way to solve this problem. In this report,we show that this can be accomplished by inserting the target sequence for the adenoviral VA RNAI into the 3' untranslated region of the expression cassette in the HDAd. Thus during vector production,when the producer cells are coinfected with both the helper virus (HV) and the HDAd,the VA RNAI produced by the HV will target the transgene mRNA from the HDAd via the endogenous cellular RNAi pathway. Once the HDAd is produced and purified,transduction of the target cells results in unimpeded transgene expression because of the absence of HV. This simple and universal strategy permits for the robust production of otherwise recalcitrant HDAds. View Publication

The epicardium contributes both multi-lineage descendants and paracrine factors to the heart during cardiogenesis and cardiac repair,underscoring its potential for cardiac regenerative medicine. Yet little is known about the cellular and molecular mechanisms that regulate human epicardial development and regeneration. Here,we show that the temporal modulation of canonical Wnt signaling is sufficient for epicardial induction from 6 different human pluripotent stem cell (hPSC) lines,including a WT1-2A-eGFP knock-in reporter line,under chemically-defined,xeno-free conditions. We also show that treatment with transforming growth factor beta (TGF-β)-signalling inhibitors permitted long-term expansion of the hPSC-derived epicardial cells,resulting in a more than 25 population doublings of WT1+ cells in homogenous monolayers. The hPSC-derived epicardial cells were similar to primary epicardial cells both in vitro and in vivo,as determined by morphological and functional assays,including RNA-seq. Our findings have implications for the understanding of self-renewal mechanisms of the epicardium and for epicardial regeneration using cellular or small-molecule therapies. View Publication

Monitoring pluripotent stem cell behaviors (self-renewal and differentiation to specific lineages/phenotypes) is critical for a fundamental understanding of stem cell biology and their translational applications. In this study,a multi-modal stem cell monitoring system was developed to quantitatively characterize physico-electrochemical changes of the cells in real time,in relation to cellular activities during self-renewal or lineage-specific differentiation,in a non-destructive,label-free manner. The system was validated by measuring physical (mass) and electrochemical (impedance) changes in human induced pluripotent stem cells undergoing self-renewal,or subjected to mesendodermal or ectodermal differentiation,and correlating them to morphological (size,shape) and biochemical changes (gene/protein expression). An equivalent circuit model was used to further dissect the electrochemical (resistive and capacitive) contributions of distinctive cellular features. Overall,the combination of the physico-electrochemical measurements and electrical circuit modeling collectively offers a means to longitudinally quantify the states of stem cell self-renewal and differentiation. View Publication