Zinc-finger Nuclease Enhanced Gene Targeting in Human Embryonic Stem Cells

One major limitation with current human embryonic stem cell (ESC) differentiation protocols is the generation of heterogeneous cell populations. These cultures contain the cells of interest, but are also contaminated with undifferentiated ESCs, non-neural derivatives and other neuronal subtypes.  This limits their use in in vitro and in vivo applications, such as in vitro modeling for drug discovery or cell replacement therapy. To help overcome this, reporter cell lines, which offer a means to visualize, track and isolate cells of interest, can be engineered. However, to achieve this in human embryonic stem cells via conventional homologous recombination is extremely inefficient. This protocol describes targeting of the Pituitary homeobox 3 (PITX3) locus in human embryonic stem cells using custom designed zinc-finger nucleases, which introduce site-specific double-strand DNA breaks, together with a PITX3-EGFP-specific DNA donor vector. Following the generation of the PITX3 reporter cell line, it can then be differentiated using published protocols for use in studies such as in vitro Parkinson’s disease modeling or cell replacement therapy.     

PiggyBac Mediated Multiplex Gene Transfer in Mouse Embryonic Stem Cell

PiggyBac system has been shown to have a high efficiency to mediate gene transfer. However, there are no reports on its efficiency to mediate multiplex transgenes in mouse embryonic stem cells. Here we first established an immortalized feeder cell line by introducing four antibiotic resistance genes simultaneously into the original SNL 76/7 feeder cell line utilizing the PiggyBac system. This is the feeder cell line with the most diverse types of antibiotic resistance genes reported so far, which will enable researchers to perform simultaneous multiplex gene transfer or gene targeting experiments in ES cells. With such feeder cell line, we were able to quantitatively characterize the transposition efficiency of PiggyBac system in mouse ES cells using five transposons carrying different inducible fluorescence proteins and antibiotic resistance genes, and the efficiency ranged from about 2% for one transposon to 0.5% for five transposons. The highly efficient multiplex gene transfer mediated by PiggyBac will no doubt provide researchers with more choices in biomedical research and development.     

In Vitro Germ Cell Differentiation from Cynomolgus Monkey Embryonic Stem Cells

Background

Mouse embryonic stem (ES) cells can differentiate into female and male germ cells in vitro. Primate ES cells can also differentiate into immature germ cells in vitro. However, little is known about the differentiation markers and culture conditions for in vitro germ cell differentiation from ES cells in primates. Monkey ES cells are thus considered to be a useful model to study primate gametogenesis in vitro. Therefore, in order to obtain further information on germ cell differentiation from primate ES cells, this study examined the ability of cynomolgus monkey ES cells to differentiate into germ cells in vitro.

Methods and Findings

To explore the differentiation markers for detecting germ cells differentiated from ES cells, the expression of various germ cell marker genes was examined in tissues and ES cells of the cynomolgus monkey (Macaca fascicularis). VASA is a valuable gene for the detection of germ cells differentiated from ES cells. An increase of VASA expression was observed when differentiation was induced in ES cells via embryoid body (EB) formation. In addition, the expression of other germ cell markers, such as NANOS and PIWIL1 genes, was also up-regulated as the EB differentiation progressed. Immunocytochemistry identified the cells expressing stage-specific embryonic antigen (SSEA) 1, OCT-4, and VASA proteins in the EBs. These cells were detected in the peripheral region of the EBs as specific cell populations, such as SSEA1-positive, OCT-4-positive cells, OCT-4-positive, VASA-positive cells, and OCT-4-negative, VASA-positive cells. Thereafter, the effect of mouse gonadal cell-conditioned medium and growth factors on germ cell differentiation from monkey ES cells was examined, and this revealed that the addition of BMP4 to differentiating ES cells increased the expression of SCP1, a meiotic marker gene.

Conclusion

VASA is a valuable gene for the detection of germ cells differentiated from ES cells in monkeys, and the identification and characterization of germ cells derived from ES cells are possible by using reported germ cell markers in vivo, including SSEA1, OCT-4, and VASA, in vitro as well as in vivo. These findings are thus considered to help elucidate the germ cell developmental process in primates.     

在小鼠胚胎干细胞进行基因打靶的策略

基因打靶技术是一种通过同源重组按预期方式改变生物活体的遗传信息的实验手段,与小鼠胚胎干细胞培养系统相结合,使得人们可以方便地将各种突变引入小鼠体内,得以从生物整体水平上研究高等真核生物基因的表达、调控及其生理功能.扼要介绍了近年来在小鼠胚胎干细胞进行基因打靶的研究进展.     

人胚胎干细胞培养建系及其应用

简要概述了自1998年首次建立hES细胞系以来近6－7年国内外的现况、分离培养建系、鉴定标准和冻存技术发展、定向诱导分化及其应用等方面的研究进展。     

Induction of Cancerous Stem Cells during Embryonic Stem Cell Differentiation

Stem cell maintenance depends on their surrounding microenvironment, and aberrancies in the environment have been associated with tumorigenesis. However, it remains to be elucidated whether an environmental aberrancy can act as a carcinogenic stress for cellular transformation of differentiating stem cells into cancer stem cells. Here, utilizing mouse embryonic stem cells as a model, it was illustrated that environmental aberrancy during differentiation leads to the emergence of pluripotent cells showing cancerous characteristics. Analogous to precancerous stages, DNA lesions were spontaneously accumulated during embryonic stem cell differentiation under aberrational environments, which activates barrier responses such as senescence and apoptosis. However, overwhelming such barrier responses, piled-up spheres were subsequently induced from the previously senescent cells. The sphere cells exhibit aneuploidy and dysfunction of the Arf-p53 module as well as enhanced tumorigenicity and a strong self-renewal capacity, suggesting development of cancerous stem cells. Our current study suggests that stem cells differentiating in an aberrational environment are at risk of cellular transformation into malignant counterparts.     

Diverse Epigenetic Profile of Novel Human Embryonic Stem Cell Lines

Human embryonic stem cells (hESCs) are a promising model for studying mechanisms ofregulation of early development and differentiation. OCT4, NANOG, OCT4-related genes andsome others were recently described to be important in pluripotency maintenance. Lesser isknown about molecular mechanisms involved in their regulation. Apart from genetic regulationof gene expression epigenetic events, particularly methylation, play an important role in earlydevelopment. Using RT-PCR we studied the expression of pluripotency-related genes OCT4,NANOG, DPPA3, and DPPA5 during hESCs differentiation to embryoid bodies. Analysis ofmethylation profiles of promoter or putative regulatory regions of the indicated genesdemonstrated that expression of the pluripotency-maintaining genes correlated with theirmethylation status, whereas methylation of DPPA3 and DPPA5 varied between cell lines. Wepropose that DNA methylation underlies the developmental stage-specific mechanisms ofpluripotency-related genes expression and reactivation and may have an impact ondifferentiation potential of hESC lines.     

The Generation of Six Clinical-Grade Human Embryonic Stem Cell Lines

The edict for producing clinically compliant human embryonic stem cells (hESCs) necessitates adherence to global ethical standards for egg procurement and embryo donation, conformity to regulations controlling clinical-grade cell and tissue product development, and compliance with current good tissue and manufacturing practices (cGTPs and cGMPs, respectively). For example, the U.S. FDA Center for Biologics Evaluation and Research recently promulgated regulations regarding human cells and cellular-based products (HCT/Ps) intended for tissue repair or replacement. Issued under Code of Federal Regulations parts 1270 and 1271 (Code of Federal Regulations, 2006a, 2006b), the rules are broadened by requirements for donor selection and cGMPs for HCT/Ps. By adhering to regulations and in anticipation of future standards, we have generated six clinical-grade hESC lines. Here we describe their manufacture, from embryo procurement to line characterization, including sterility and pathogen testing (Figure 1). To our knowledge, the lines represent the first to have been produced in compliance with international regulatory requirements, suitable for therapeutic use.     

人诱导多能干细胞与人胚胎干细胞分化过程中Oct4/Nanog 基因 表达的比较

目的:比较通过慢病毒方法获得的人诱导多能性干细胞(iPSCs)与人胚胎干细胞(hESCs)分化过程中全能性基因Oct4、Nanog的表达变化。方法:收集分化不同时间点的拟胚体(EBs),检测三胚层分化基因以及全能性基因Oct4/Nanog的表达,并通过畸胎瘤组织切片的荧光染色分析Oct4的表达。结果:iPSCs获得的EB中内外三胚层分化基因表达的出现明显晚于hESCs来源的EB。不同于hESCs,iPSCs悬浮培养获得的EBs在体外培养18天未见内源性Oct4、Nanog基因表达的下调。未分化的iPSCs注射严重联合免疫缺陷(SCID)小鼠培养10周后获得的畸胎瘤中仍存在Oct4阳性的细胞,但iPS-#2中明显少于iPS-#5。结论:通过慢病毒方法获得的iPSCs虽然具有向三胚层分化的能力,但在分化过程中仍维持较高水平的全能性基因Oct4、Nanog的表达。     

人诱导多能干细胞与人胚胎干细胞分化过程中Oct4/Nanog基因表达的比较

目的：比较通过慢病毒方法获得的人诱导多能性干细胞（iPSCs）与人胚胎干细胞（hESCs）分化过程中全能性基因Oct4、Nanog的表达变化。方法：收集分化不同时间点的拟胚体（EBs）,检测三胚层分化基因以及全能性基因Oct4/Nanog的表达,并通过畸胎瘤组织切片的荧光染色分析Oct4的表达。结果：iPSCs获得的EB中内外三胚层分化基因表达的出现明显晚于hESCs来源的EB。不同于hESCs,iPSCs悬浮培养获得的EBs在体外培养18天未见内源性Oct4、Nanog基因表达的下调。未分化的iPSCs注射严重联合免疫缺陷（SCID）小鼠培养10周后获得的畸胎瘤中仍存在Oct4阳性的细胞,但iPS-#2中明显少于iPS-#5。结论：通过慢病毒方法获得的iPSCs虽然具有向三胚层分化的能力,但在分化过程中仍维持较高水平的全能性基因Oct4、Nanog的表达。     

Targeting of Embryonic Stem Cells by Peptide-Conjugated Quantum Dots

Background

Targeting stem cells holds great potential for studying the embryonic stem cell and development of stem cell-based regenerative medicine. Previous studies demonstrated that nanoparticles can serve as a robust platform for gene delivery, non-invasive cell imaging, and manipulation of stem cell differentiation. However specific targeting of embryonic stem cells by peptide-linked nanoparticles has not been reported.

Methodology/Principal Findings

Here, we developed a method for screening peptides that specifically recognize rhesus macaque embryonic stem cells by phage display and used the peptides to facilitate quantum dot targeting of embryonic stem cells. Through a phage display screen, we found phages that displayed an APWHLSSQYSRT peptide showed high affinity and specificity to undifferentiated primate embryonic stem cells in an enzyme-linked immunoabsorbent assay. These results were subsequently confirmed by immunofluoresence microscopy. Additionally, this binding could be completed by the chemically synthesized APWHLSSQYSRT peptide, indicating that the binding capability was specific and conferred by the peptide sequence. Through the ligation of the peptide to CdSe-ZnS core-shell nanocrystals, we were able to, for the first time, target embryonic stem cells through peptide-conjugated quantum dots.

Conclusions/Significance

These data demonstrate that our established method of screening for embryonic stem cell specific binding peptides by phage display is feasible. Moreover, the peptide-conjugated quantum dots may be applicable for embryonic stem cell study and utilization.     

Targeted Genomic Integration of a Selectable Floxed Dual Fluorescence Reporter in Human Embryonic Stem Cells

The differentiation of pluripotent stem cells involves transition through a series of specific cell states. To understand these cell fate decisions, the field needs improved genetic tools for the labeling, lineage tracing and selection of specific cell types from heterogeneous differentiating populations, particularly in the human embryonic stem cell (hESC) system. We used zinc finger nuclease technology to stably insert a unique, selectable, floxed dual-fluorescence reporter transgene into the AAVS1 locus of RUES2 hESCs. This “stoplight” transgene, mTmG-2a-Puro, strongly expresses membrane-localized tdTomato red fluorescent protein until Cre-dependent recombination causes a switch to expression of membrane-localized enhanced green fluorescent protein (eGFP) and puromycin resistance. First, to validate this system in undifferentiated cells, we transduced transgenic hESCs with a lentiviral vector driving constitutive expression of Cre and observed the expected phenotypic switch. Next, to demonstrate its utility in lineage-specific selection, we transduced differentiated cultures with a lentiviral vector in which the striated muscle-specific CK7 promoter drives Cre expression. This yielded near-homogenous populations of eGFP⁺ hESC-derived cardiomyocytes. The mTmg-2a-Puro hESC line described here represents a useful new tool for both in vitro fate mapping studies and the selection of useful differentiated cell types.     

从植入前遗传学诊断异常的胚胎中分离人胚胎干细胞系

在体外受精过程中,通过胚胎植入前遗传性诊断（PGD）对有遗传风险患者的胚胎进行植入前活检和遗传学分析,选择无遗传性疾病的胚胎植入子宫,而PGD诊断异常的胚胎则会被丢弃。本研究尝试将PGD异常胚胎用于分离人胚胎干细胞,以获得携带遗传缺陷的人胚胎干细胞系。利用荧光原位杂交技术对第3-5天胚胎进行PGD检测,结果异常的胚胎进一步用于分离获取胚胎干细胞系,然后对h ES细胞系进行核型及干细胞表面标记、多能性基因表达、端粒酶活性以及分化能力等特征性鉴定。总共从13个PGD异常胚胎中分离获得8个人胚胎干细胞系,建系效率为61.5%,其中1个核型正常,5个核型异常。说明利用PGD异常胚胎可以获得携带遗传缺陷的人胚胎干细胞系,不仅为评估PGD技术临床结论的准确性提供了一种新方法,更重要的是为研究各种遗传性疾病的发病机理提供了有效的细胞模型。     

Human Antigen-Specific Regulatory T Cells Generated by T Cell Receptor Gene Transfer

Background

Therapies directed at augmenting regulatory T cell (Treg) activities in vivo as a systemic treatment for autoimmune disorders and transplantation may be associated with significant off-target effects, including a generalized immunosuppression that may compromise beneficial immune responses to infections and cancer cells. Adoptive cellular therapies using purified expanded Tregs represents an attractive alternative to systemic treatments, with results from animal studies noting increased therapeutic potency of antigen-specific Tregs over polyclonal populations. However, current methodologies are limited in terms of the capacity to isolate and expand a sufficient quantity of endogenous antigen-specific Tregs for therapeutic intervention. Moreover, FOXP3+ Tregs fall largely within the CD4+ T cell subset and are thus routinely MHC class II-specific, whereas class I-specific Tregs may function optimally in vivo by facilitating direct tissue recognition.

Methodology/Principal Findings

To overcome these limitations, we have developed a novel means for generating large numbers of antigen-specific Tregs involving lentiviral T cell receptor (TCR) gene transfer into in vitro expanded polyclonal natural Treg populations. Tregs redirected with a high-avidity class I-specific TCR were capable of recognizing the melanoma antigen tyrosinase in the context of HLA-A*0201 and could be further enriched during the expansion process by antigen-specific reactivation with peptide loaded artificial antigen presenting cells. These in vitro expanded Tregs continued to express FOXP3 and functional TCRs, and maintained the capacity to suppress conventional T cell responses directed against tyrosinase, as well as bystander T cell responses. Using this methodology in a model tumor system, murine Tregs designed to express the tyrosinase TCR effectively blocked antigen-specific effector T cell (Teff) activity as determined by tumor cell growth and luciferase reporter-based imaging.

Conclusions/Significance

These results support the feasibility of class I-restricted TCR transfer as a promising strategy to redirect the functional properties of Tregs and provide for a more efficacious adoptive cell therapy.     

Human Embryonic Stem Cell Lines with Lesions in FOXP3 and NF1

Human embryonic stem cells (hESCs) are derived from the inner cell mass (ICM) of blastocyst staged embryos. Spare blastocyst staged embryos were obtained by in vitro fertilization (IVF) and donated for research purposes. hESCs carrying specific mutations can be used as a powerful cell system in modeling human genetic disorders. We obtained preimplantation genetic diagnosed (PGD) blastocyst staged embryos with genetic mutations that cause human disorders and derived hESCs from these embryos. We applied laser assisted micromanipulation to isolate the inner cell mass from the blastocysts and plated the ICM onto the mouse embryonic fibroblast cells. Two hESC lines with lesions in FOXP3 and NF1 were established. Both lines maintain a typical undifferentiated hESCs phenotype and present a normal karyotype. The two lines express a panel of pluripotency markers and have the potential to differentiate to the three germ layers in vitro and in vivo. The hESC lines with lesions in FOXP3 and NF1 are available for the scientific community and may serve as an important resource for research into these disease states.