技术资料

Manipulation of genes in human embryonic stem cells (hESCs) is imperative for their highly potential applications; however,the transduction efficiency remains very low. Although existing evidence revealed the type,size,and zeta potential of vector affect gene transfection efficiency in cells,the systematic study in hESCs is scarce. In this study,using poly(amidoamine) (PAMAM) dendrimers ended with amine,hydroxyl,or carboxyl as model,we tested the influences of size and surface group as well as cytotoxicity and endocytosis on hESC gene transfection. We found that in culture medium of mTeSR the particle sizes of G5,G7,G4.5COOH,and G5OH were around 5 nm and G1 had a smaller size of 3.14 nm. G5 and G7 had a slight and significant positive zeta potential,respectively,whereas G1 was slightly negative,and G4.5COOH and G5OH were significantly negative. We demonstrated that only amine-terminated dendrimers accomplished gene transfection in hESCs,which is greater than that from Lipofectamine 2000 transfection. Ten micromolar G5 had the greatest efficiency and was better than 1000 μM G1. Only a low concentration (0.5 and 1 μM) of G7 realized gene delivery. Amine-ended dendrimers,especially with higher generations,were detrimental to the growth and pluripotent maintenance of hESCs. In contrast,similarly sized hydroxyl- and carboxyl-terminated dendrimers exerted much lower cytotoxicity,in which carboxyl-terminated dendrimer maintained pluripotency of hESCs. We also confirmed the endocytosis into and significant exocytosis from hESCs using FITC-labeled G5 dendrimer. These results suggested that careful considerations of size,concentration,and zeta potential,particularly the identity and position of groups,as well as minimized exocytosis in the design of a vector for hESC gene delivery are necessary,which helps to better design an effective vector in hESC gene transduction. View Publication

The combination of induced pluripotent stem cell (iPSC) technology and targeted gene modification by homologous recombination (HR) represents a promising new approach to generate genetically corrected,patient-derived cells that could be used for autologous transplantation therapies. This strategy has several potential advantages over conventional gene therapy including eliminating the need for immunosuppression,avoiding the risk of insertional mutagenesis by therapeutic vectors,and maintaining expression of the corrected gene by endogenous control elements rather than a constitutive promoter. However,gene targeting in human pluripotent cells has remained challenging and inefficient. Recently,engineered zinc finger nucleases (ZFNs) have been shown to substantially increase HR frequencies in human iPSCs,raising the prospect of using this technology to correct disease causing mutations. Here,we describe the generation of iPSC lines from sickle cell anemia patients and in situ correction of the disease causing mutation using three ZFN pairs made by the publicly available oligomerized pool engineering method (OPEN). Gene-corrected cells retained full pluripotency and a normal karyotype following removal of reprogramming factor and drug-resistance genes. By testing various conditions,we also demonstrated that HR events in human iPSCs can occur as far as 82 bps from a ZFN-induced break. Our approach delineates a roadmap for using ZFNs made by an open-source method to achieve efficient,transgene-free correction of monogenic disease mutations in patient-derived iPSCs. Our results provide an important proof of principle that ZFNs can be used to produce gene-corrected human iPSCs that could be used for therapeutic applications. View Publication

Conventional methods for quantification of undifferentiated pluripotent stem cells such as fluorescence-activated cell sorting and real-time PCR analysis have technical limitations in terms of their sensitivity and recyclability. Herein,we designed a real-time in situ label-free monitoring system on the basis of a specific electrochemical signature of human pluripotent stem cells in vitro. The intensity of the signal of hPSCs highly corresponded to the cell number and remained consistent in a mixed population with differentiated cells. The electrical charge used for monitoring did not markedly affect the proliferation rate or molecular characteristics of differentiated human aortic smooth muscle cells. After YM155 treatment to ablate undifferentiated hPSCs,their specific signal was significantly reduced. This suggests that detection of the specific electrochemical signature of hPSCs would be a valid approach to monitor potential contamination of undifferentiated hPSCs,which can assess the risk of teratoma formation efficiently and economically. 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

The purpose of this study was to investigate the chondrogenic features of human induced pluripotent stem cells (hiPSCs) and examine the differences in the chondrogenesis between hiPSCs and human bone marrow-derived MSCs (hBMMSCs). Embryoid bodies (EBs) were formed from undifferentiated hiPSCs. After EBs were dissociated into single cells,chondrogenic culture was performed in pellets and alginate hydrogel. Chondro-induced hiPSCs were implanted in osteochondral defects created on the patellar groove of immunosuppressed rats and evaluated after 12 weeks. The ESC markers NANOG,SSEA4 and OCT3/4 disappeared while the mesodermal marker BMP-4 appeared in chondro-induced hiPSCs. After 21 days of culture,greater glycosaminoglycan contents and better chondrocytic features including lacuna and abundant matrix formation were observed from chondro-induced hiPSCs compared to chondro-induced hBMMSCs. The expression of chondrogenic markers including SOX-9,type II collagen,and aggrecan in chondro-induced hiPSCs was comparable to or greater than chondro-induced hBMMSCs. A remarkably low level of hypertrophic and osteogenic markers including type X collagen,type I collagen and Runx-2 was noted in chondro-induced hiPSCs compared to chondro-induced hBMMSCs. hiPSCs had significantly greater methylation of several CpG sites in COL10A1 promoter than hBMMSCs in either undifferentiated or chondro-induced state,suggesting an epigenetic cause of the difference in hypertrophy. The defects implanted with chondro-induced hiPSCs showed a significantly better quality of cartilage repair than the control defects,and the majority of cells in the regenerated cartilage consisted of implanted hiPSCs. ?? 2014 Elsevier Ltd. View Publication

Human pluripotent stem cells (hPSCs) are a promising cell source with pluripotency and capacity to differentiate into all human somatic cell types. Designing simple and safe biomaterials with an innate ability to induce osteoblastic lineage from hPSCs is desirable to realize their clinical adoption in bone regenerative medicine. To address the issue,here we developed a fully defined synthetic peptides-decorated two dimensional (2D) microenvironment assisted via polydopamine (pDA) chemistry and subsequent carboxymethyl chitosan (CMC) grafting to enhance the culture and osteogenic potential of hPSCs in vitro. The hPSCs including human embryonic stem cells (hESCs) and human induced pluripotent stem cells (hiPSCs) were successfully cultured on the peptides-decorated surface without Matrigel- and ECM protein-coating and underwent promoted osteogenic differentiation in vitro,determined from the alkaline phosphate (ALP) activity,gene expression,and protein production as well as calcium deposit amount. It was found that directed osteogenic differentiation of hPSCs could be achieved through a peptides-decorated niche. This chemical-defined and safe 2D microenvironment which facilitates proliferation and osteo-differentiation of hPSCs,not only helps to accelerate the translational perspectives of hPSCs,but also provides tissue-specific functions such as directing stem cell differentiation commitment,having great potential in bone tissue engineering and presenting new avenues for bone regenerative medicine. View Publication

Magnesium alloys have attracted great interest for medical applications due to their unique biodegradable capability and desirable mechanical properties. When designed for medical applications,these alloys must have suitable degradation properties,i.e.,their degradation rate should not exceed the rate at which the degradation products can be excreted from the body. Cellular responses and tissue integration around the Mg-based implants are critical for clinical success. Four magnesium–zinc–strontium (ZSr41) alloys were developed in this study. The degradation properties of the ZSr41 alloys and their cytocompatibility were studied using an in vitro human embryonic stem cell (hESC) model due to the greater sensitivity of hESCs to known toxicants which allows to potentially detect toxicological effects of new biomaterials at an early stage. Four distinct ZSr41 alloys with 4 wt% zinc and a series of strontium compositions (0.15,0.5,1,and 1.5 wt% Sr) were produced through metallurgical processing. Their degradation was characterized by measuring total mass loss of samples and pH change in the cell culture media. The concentration of Mg ions released from ZSr41 alloy into the cell culture media was analyzed using inductively coupled plasma atomic emission spectroscopy. Surface microstructure and composition before and after culturing with hESCs were characterized using field emission scanning electron microscopy and energy dispersive X-ray spectroscopy. Pure Mg was used as a control during cell culture studies. Results indicated that the Mg–Zn–Sr alloy with 0.15 wt% Sr provided slower degradation and improved cytocompatibility as compared with pure Mg control. View Publication

Embryonic stem cells can be induced in vitro,by coculture with the stromal line RP.0.10 and a mixture of interleukins 3,6,and 7,to differentiate into T (Joro75+) and B (B-220+) lymphocyte progenitors and other (Thy-1+,PgP-1+,c-kit+,Joro75-,B-220-,F4/80-,Mac-1-) hemopoietic precursors. The progeny of in vitro-induced embryonic stem cells can reconstitute the lymphoid compartments of T- and B-lymphocyte-deficient scid mice and generate mature T and B lymphocytes in sublethally irradiated normal mice. Exogenous cytokines can dramatically alter the developmental fate of embryonic stem cells in culture. The in vitro system described here should facilitate the study of molecular events leading to cell-lineage commitment and to the formation of hemopoietic stem cells and their immediate lymphoid progeny. View Publication

Under appropriate conditions in culture,embryonic stem cells will differentiate and form embryoid bodies that have been shown to contain cells of the hematopoietic,endothelial,muscle and neuronal lineages. Many aspects of the lineage-specific differentiation programs observed within the embryoid bodies reflect those found in the embryo,indicating that this model system provides access to early cell populations that develop in a normal fashion. Recent studies involving the differentiation of genetically altered embryonic stem cells highlight the potential of this in vitro differentiation system for defining the function of genes in early development. View Publication

Recent breakthroughs in 3-dimensional (3D) organoid cultures for many organ systems have led to new physiologically complex in vitro models to study human development and disease. Here,we report the step-wise differentiation of human pluripotent stem cells (hPSCs) (embryonic and induced) into lung organoids. By manipulating developmental signaling pathways hPSCs generate ventral-anterior foregut spheroids,which are then expanded into human lung organoids (HLOs). HLOs consist of epithelial and mesenchymal compartments of the lung,organized with structural features similar to the native lung. HLOs possess upper airway-like epithelium with basal cells and immature ciliated cells surrounded by smooth muscle and myofibroblasts as well as an alveolar-like domain with appropriate cell types. Using RNA-sequencing,we show that HLOs are remarkably similar to human fetal lung based on global transcriptional profiles,suggesting that HLOs are an excellent model to study human lung development,maturation and disease. View Publication

We developed a protocol of in vitro differentiation of human embryonic stem cells into three-dimensional structures histologically and molecularly similar to the developing retina. View Publication

Brain-derived microvascular endothelial cells (BMECs),which play a central role in blood brain barrier (BBB),can be used for the evaluation of drug transport into the brain. Although human BMEC cell lines have already been reported,they lack original properties such as barrier integrity. Pluripotent stem cells (PSCs) can be used for various applications such as regenerative therapy,drug screening,and pathological study. In the recent study,an induction method of BMECs from PSCs has been established,making it possible to more precisely study the in vitro human BBB function. Here,using induced pluripotent stem (iPS) cell-derived BMECs,we examined the effects of oxygen-glucose deprivation (OGD) and OGD/reoxygenation (OGD/R) on BBB permeability. OGD disrupted the barrier function,and the dysfunction was rapidly restored by re-supply of the oxygen and glucose. Interestingly,TNF-α,which is known to be secreted from astrocytes and microglia in the cerebral ischemia,prevented the restoration of OGD-induced barrier dysfunction in an apoptosis-independent manner. Thus,we could establish the in vitro BBB disease model that mimics the cerebral ischemia by using iPS cell-derived BMECs. View Publication