技术资料

Human induced pluripotent stem cells (iPSC) can be used to understand the pathological mechanisms of human disease. These cells are a promising source for cell-replacement therapy. However,such studies require genetically defined conditions. Such genetic manipulations can be performed using the novel Transcription Activator-Like Effector Nucleases (TALENs),which generate site-specific double-strand DNA breaks (DSBs) with high efficiency and precision. Combining the TALEN and iPSC methods,we developed two iPS cell lines by generating the point mutation A5768G in the SCN1A gene,which encodes the voltage-gated sodium channel Nav1.1 α subunit. The engineered iPSC maintained pluripotency and successfully differentiated into neurons with normal functional characteristics. The two cell lines differ exclusively at the epilepsy-susceptibility variant. The ability to robustly introduce disease-causing point mutations in normal hiPS cell lines can be used to generate a human cell model for studying epileptic mechanisms and for drug screening. View Publication

Many forms of blindness result from the dysfunction or loss of retinal photoreceptors. Induced pluripotent stem cells (iPSCs) hold great potential for the modelling of these diseases or as potential therapeutic agents. However,to fulfill this promise,a remaining challenge is to induce human iPSC to recreate in vitro key structural and functional features of the native retina,in particular the presence of photoreceptors with outer-segment discs and light sensitivity. Here we report that hiPSC can,in a highly autonomous manner,recapitulate spatiotemporally each of the main steps of retinal development observed in vivo and form three-dimensional retinal cups that contain all major retinal cell types arranged in their proper layers. Moreover,the photoreceptors in our hiPSC-derived retinal tissue achieve advanced maturation,showing the beginning of outer-segment disc formation and photosensitivity. This success brings us one step closer to the anticipated use of hiPSC for disease modelling and open possibilities for future therapies. 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

Despite the high incidence of trophoblast-related diseases,the molecular mechanism of inadequate early trophoblast development is still unclear due to the lack of an appropriate cellular model in vitro. In the present study,we reprogrammed the amniotic cells to be induced pluripotent stem cells (iPSCs) via a non-virus and non-integrated method and subsequently differentiated them into trophoblast-like cells by a modified BMP4 strategy in E6 medium. Compared with the previously studied trophoblast-like cells from ESCs,the iPSCs derived trophoblast-like cells behave similarly in terms of gene expression profiles and biofunctions. Also we confirmed the differentiating tendency from iPSCs to be syncytiotrophoblasts-like cells might be caused by inappropriate differentiating oxygen condition. Additionally,we preliminarily indicated in vitro artificial" differentiation of iPSCs also undergoing a possible trophoblastic stem cell stage as witnessed in vivo. In conclusion we provided an in vitro cellular model to study early trophoblast development for specific individual by using the feasible amnion. View Publication

Human endothelial cells (ECs) and pericytes are of great interest for research on vascular development and disease,as well as for future therapy. This protocol describes the efficient generation of ECs and pericytes from human pluripotent stem cells (hPSCs) under defined conditions. Essential steps for hPSC culture,differentiation,isolation and functional characterization of ECs and pericytes are described. Substantial numbers of both cell types can be derived in only 2-3 weeks: this involves differentiation (10 d),isolation (1 d) and 4 or 10 d of expansion of ECs and pericytes,respectively. We also describe two assays for functional evaluation of hPSC-derived ECs: (i) primary vascular plexus formation upon coculture with hPSC-derived pericytes and (ii) incorporation in the vasculature of zebrafish xenografts in vivo. These assays can be used to test the quality and drug sensitivity of hPSC-derived ECs and model vascular diseases with patient-derived hPSCs. View Publication

Cardiovascular progenitor cells (CVPCs) derived from human embryonic stem cells and human induced pluripotent stem cells represent an invaluable potential source for the study of early embryonic cardiovascular development and stem cell-based therapies for congenital and acquired heart diseases. To fully realize their values,it is essential to establish an efficient and stable differentiation system for the induction of these pluripotent stem cells (PSCs) into the CVPCs and robustly expand them in culture,and then further differentiate these CVPCs into multiple cardiovascular cell types. Here we describe the protocols for efficient derivation,expansion,and differentiation of CVPCs from hPSCs in a chemically defined medium under feeder- and serum-free culture conditions. View Publication

Human pluripotent stem cell (hPSC)-derived neural progenitor cells (NPCs),a multipotent cell population that is capable of near indefinite expansion and subsequent differentiation into the various cell types that comprise the central nervous system (CNS),could provide an unlimited source of cells for neural-related cell-based therapies and disease modeling. However,the use of NPCs for the study and treatment of a variety of debilitating neurological diseases requires the development of scalable and reproducible protocols for their generation,expansion,characterization,and neuronal differentiation. Here,we describe a serum-free method for the stepwise generation of NPCs from hPSCs through the sequential formation of embryoid bodies (EBs) and neuro-epithelial-like rosettes. NPCs isolated from neural rosette cultures can be homogenously expanded while maintaining high expression of pan-neural markers such as SOX1,SOX2,and Nestin. Finally,this protocol allows for the robust differentiation of NPCs into microtubule-associated protein 2 (MAP2) and β-Tubulin-III (β3T) positive neurons. View Publication

Hematopoietic stem cells (HSCs) have the capacity to self-renew and continuously differentiate into all blood cell lineages throughout life. At each branching point during differentiation,interactions with the environment are key in the generation of daughter cells with distinct fates. Here,we examined the role of the cell adhesion molecule JAM-C,a protein known to mediate cellular polarity during spermatogenesis,in hematopoiesis. We show that murine JAM-C is highly expressed on HSCs in the bone marrow (BM). Expression correlates with self-renewal,the highest being on long-term repopulating HSCs,and decreases with differentiation,which is maintained longest among myeloid committed progenitors. Inclusion of JAM-C as a sole marker on lineage-negative BM cells yields HSC enrichments and long-term multilineage reconstitution when transferred to lethally irradiated mice. Analysis of Jam-C-deficient mice showed that two-thirds die within 48 hours after birth. In the surviving animals,loss of Jam-C leads to an increase in myeloid progenitors and granulocytes in the BM. Stem cells and myeloid cells from fetal liver are normal in number and homing to the BM. These results provide evidence that JAM-C defines HSCs in the BM and that JAM-C plays a role in controlling myeloid progenitor generation in the BM. View Publication

Insulin resistance is central to diabetes and metabolic syndrome. To define the consequences of genetic insulin resistance distinct from those secondary to cellular differentiation or in vivo regulation,we generated induced pluripotent stem cells (iPSCs) from individuals with insulin receptor mutations and age-appropriate control subjects and studied insulin signaling and gene expression compared with the fibroblasts from which they were derived. iPSCs from patients with genetic insulin resistance exhibited altered insulin signaling,paralleling that seen in the original fibroblasts. Insulin-stimulated expression of immediate early genes and proliferation were also potently reduced in insulin resistant iPSCs. Global gene expression analysis revealed marked differences in both insulin-resistant iPSCs and corresponding fibroblasts compared with control iPSCs and fibroblasts. Patterns of gene expression in patients with genetic insulin resistance were particularly distinct in the two cell types,indicating dependence on not only receptor activity but also the cellular context of the mutant insulin receptor. Thus,iPSCs provide a novel approach to define effects of genetically determined insulin resistance. This study demonstrates that effects of insulin resistance on gene expression are modified by cellular context and differentiation state. Moreover,altered insulin receptor signaling and insulin resistance can modify proliferation and function of pluripotent stem cell populations. View Publication

Interactions between developmental signaling pathways govern the formation and function of stem cells. Prostaglandin (PG) E2 regulates vertebrate hematopoietic stem cells (HSC). Similarly,the Wnt signaling pathway controls HSC self-renewal and bone marrow repopulation. Here,we show that wnt reporter activity in zebrafish HSCs is responsive to PGE2 modulation,demonstrating a direct interaction in vivo. Inhibition of PGE2 synthesis blocked wnt-induced alterations in HSC formation. PGE2 modified the wnt signaling cascade at the level of beta-catenin degradation through cAMP/PKA-mediated stabilizing phosphorylation events. The PGE2/Wnt interaction regulated murine stem and progenitor populations in vitro in hematopoietic ES cell assays and in vivo following transplantation. The relationship between PGE2 and Wnt was also conserved during regeneration of other organ systems. Our work provides in vivo evidence that Wnt activation in stem cells requires PGE2,and suggests the PGE2/Wnt interaction is a master regulator of vertebrate regeneration and recovery. View Publication

Human induced pluripotent stem cells (HIPSC) have tremendous value as a source of autologous cells for cellular transplantation in the treatment of degenerative diseases. The protocols described here address methods for large-scale genetic modification of HIPSCs. The first is an optimized method for transfecting HIPSCs cultured in feeder-free conditions. The second method allows nucleofection of trypsinized HIPSCs at an optimal cell density. Both methods enable robust generation of stable HIPSC transfectants within two weeks. Our protocols are highly reproducible and do not require optimization for individual HIPSC and human embryonic stem cell (HESC) lines. View Publication

The promise of genetic reprogramming has prompted initiatives to develop banks of induced pluripotent stem cells (iPSCs) from diverse sources. Sentinel assays for pluripotency could maximize available resources for generating iPSCs. Neural rosettes represent a primitive neural tissue that is unique to differentiating PSCs and commonly used to identify derivative neural/stem progenitors. Here,neural rosettes were used as a sentinel assay for pluripotency in selection of candidates to advance to validation assays. Candidate iPSCs were generated from independent populations of amniotic cells with episomal vectors. Phase imaging of living back up cultures showed neural rosettes in 2 of the 5 candidate populations. Rosettes were immunopositive for the Sox1,Sox2,Pax6 and Pax7 transcription factors that govern neural development in the earliest stage of development and for the Isl1/2 and Otx2 transcription factors that are expressed in the dorsal and ventral domains,respectively,of the neural tube in vivo. Dissociation of rosettes produced cultures of differentiation competent neural/stem progenitors that generated immature neurons that were immunopositive for βIII-tubulin and glia that were immunopositive for GFAP. Subsequent validation assays of selected candidates showed induced expression of endogenous pluripotency genes,epigenetic modification of chromatin and formation of teratomas in immunodeficient mice that contained derivatives of the 3 embryonic germ layers. Validated lines were vector-free and maintained a normal karyotype for more than 60 passages. The credibility of rosette assembly as a sentinel assay for PSCs is supported by coordinate loss of nuclear-localized pluripotency factors Oct4 and Nanog in neural rosettes that emerge spontaneously in cultures of self-renewing validated lines. Taken together,these findings demonstrate value in neural rosettes as sentinels for pluripotency and selection of promising candidates for advance to validation assays. View Publication