SNL fibroblast feeder layers support derivation and maintenance of human induced pluripotent stem cells

Induced pluripotent stem(iPS) cells can be derived from human somatic cells by cellular reprogramming.This technology provides a potential source of non-controversial therapeutic cells for tissue repair,drug discovery,and opportunities for studying the molecular basis of human disease.Normally,mouse embryonic fibroblasts(MEFs) are used as feeder layers in the initial derivation of iPS lines.The purpose of this study was to determine whether SNL fibroblasts can be used to support the growth of human iPS cell...     

新物种诱导多能干细胞的研究进展

胚胎干细胞（embryonic stem cells,ESC）在人类遗传病学研究、疾病模型建立、器官再生以及动物物种改良和定向变异等方面的地位是其他类型的细胞不可取代的。但是,由于实验技术和体外培养条件的限制,除了小鼠、恒河猴和人之外,大鼠、猪、牛、羊等其他哺乳动物的ES细胞系被证明很难获得。先后有多个研究小组报道了他们利用新兴的诱导多能干细胞（induced pluripotent stem cells,iPS细胞）技术成功建立大鼠和猪的iPS细胞系的研究成果。迄今为止,这两个物种是在未成功建立ES细胞系之前利用iPS技术建立多能干细胞系的成功范例。这些研究对于那些还未建立ES细胞的物种建立多能干细胞系提供了一种新的方案,也将给这些物种的胚胎干细胞的建立、基因修饰动物的产生以及人类医疗事业的促进和发展带来新的希望。     

ES and iPS cell research for cardiovascular regeneration

Embryonic stem (ES) cells and induced pluripotent stem (iPS) cells, which are ES-like stem cells induced from adult tissues, are twin stem cells with currently (with the exception of fertilized eggs) the broadest differentiation potentials. These two stem cells show various similarities in appearance, maintenance methods, growth and differentiation potentials, i.e. theoretically, those cells can give rise to all kinds of cells including germ-line cells. Generation of human ES and iPS cells is further facilitating the researches towards the realization of regenerative medicine. The following three issues are important purposes of ES and iPS cell researches for regenerative medicine: (1) dissection of differentiation mechanisms, (2) application to cell transplantation, and (3) drug discovery. In this review, the current status of cardiovascular regenerative trials using ES and iPS cells is briefly discussed.     

诱导型细胞的研究进展

胚胎干细胞(ES细胞)和诱导型多能干细胞(iPS细胞)的研究进展为生物学基础研究注入了新的活力,然而免疫排斥、致瘤性以及诱导效率低等缺陷制约其进一步快速发展和临床应用．最近,科学家借鉴iPS细胞诱导技术和传统的诱导体系,将终末分化细胞直接诱导为功能性细胞,如心肌细胞、神经细胞和肝脏细胞,称为诱导型细胞．这些研究进展极大地促进了细胞分化、重编程和表观遗传学的研究,也为人类再生医学的研究提供了新的途径．     

SNL fibroblast feeder layers support derivation and maintenance of human induced pluripotent stem cells

Induced pluripotent stem(iPS)cells can be derived from human somatic cells by cellular reprogramming.This technology provides a potential source of non-controversial therapeutic cells for tissue repair,drug discovery,and opportunities for studying the molecular basis of human disease.Normally,mouse embryonic fibroblasts(MEFs)are used as feeder layers in the initial derivation of iPS lines.The purpose of this study was to determine whether SNL fibroblasts can be used to support the growth of human iPS cells reprogrammed from somatic cells using lentivirai expressed reprogramming factors.In our study,iPS cells expressed common pluripotency markers,displayed human embryonic stern cells(hESCs)morphology and unmethylated promoters of NANOG and OCT4.These data demonstrate that SNL feeder cells can support the derivation and maintenance of human iPS cells.     

猪诱导性多能干细胞技术的研究进展及应用前景

猪作为实验材料,具有由于来源方便、基因序列与人类的相近及其在畜牧业中的重要地位等优势,成为国内外研究的热点,但是猪的胚胎干细胞(Embryonic stem cells,ESC)建系方面的研究进展缓慢。诱导性多能干细胞(induced pluripotent stem cells,iPSC)技术的诞生,开创了体细胞重编程的全新方法。猪iPSC体系的建立将为家畜ESC体系的建立奠定基础,同时也对提高猪转基因克隆的效率,高效育种和保种,乃至生物医学领域均产生深远的影响。文章综述了iPSC技术的主要进展,重点阐述了猪iPSC技术的现状及其在生物医学和畜牧业中的应用前景,以期为从事该领域研究的科研人员提供参考。     

诱导性多潜能干细胞(iPS cells)——现状及前景展望

主要从 iPS细胞发展历程、获得 iPS细胞的几个关键步骤 (如基因导入方式、诱导 iPS细胞所需因子组合与小分子化合物运用和体细胞种类选择等)、病人或疾病特异性 iPS细胞、iPS细胞体内外诱导分化与其衍生物的临床应用和制备无遗传修饰的(genetic modification-free) iPS细胞的可行性与前景等方面对 iPS细胞最新研究进展做评述．日本和美国研究小组先后用4种基因将小鼠(2006年8月)和人(2007年11～12月)的体细胞在体外重编程为诱导性多潜能干细胞(induced pluripotent stem cells,iPS cells),此后在短短两年多时间内,iPS 细胞的研究和关注度呈爆炸式增长．体细胞重编程、去分化和多潜能干细胞来源等一系列热点问题再次成为干细胞和发育生物学等研究的热点和焦点．与胚胎干细胞(embryonic stem cells,ES cells)一样,iPS细胞在体内可分化为3个胚层来源的所有细胞,进而参与形成机体所有组织和器官．迄今,在体外已由 iPS细胞定向诱导分化出功能性的多种成熟细胞．因此,iPS细胞研究不仅具有重要理论意义,而且在再生医学、组织工程和药物发现与评价等方面极具应用价值．     

Induced pluripotent stem (iPS) cells from human fetal stem cells (hFSCs)

Introduction

(1) Human embryonic stem (ES) cells are pluripotent but are difficult to be used for therapy because of immunological, oncological and ethical barriers. (2) Pluripotent cells exist in vivo, i.e., germ cells and epiblast cells but cannot be isolated without sacrificing the developing embryo. (3) Reprogramming to pluripotency is possible from adult cells using ectopic expression of OKSM and other integrative and non-integrative techniques. (4) Hurdles to overcome include i.e stability of the phenotype in relation to epigenetic memory.

Sources of data

We reviewed the literature related to reprogramming, pluripotency and fetal stem cells.

Areas of agreement

(1) Fetal stem cells present some advantageous characteristics compared with their neonatal and postnatal counterparts, with regards to cell size, growth kinetics, and differentiation potential, as well as in vivo tissue repair capacity. (2) Amniotic fluid stem cells are more easily reprogrammed to pluripotency than adult fibroblast. (3) The parental population is heterogeneous and present an intermediate phenotype between ES and adult somatic stem cells, expressing markers of both.

Areas of controversy

(1) It is unclear whether induced pluripotent stem (iPS) derived from amniotic fluid stem cells are fully or partially reprogrammed. (2) Optimal protocols to ensure highest efficiency and phenotype stability remains to be determined. (3) The “level” of reprogramming, fully vs partial, of iPS derived from amniotic fluid stem cells remain to be determined.

Growing points

Banking of fully reprogrammed cells may be important both for (1) autologous and allogenic applications in medicine, and (2) disease modeling.     

Derivation and induction of the differentiation of animal ES cells as well as human pluripotent stem cells derived from fetal membrane

We succeeded in the derivation and maintenance of pluripotent embryonic stem (ES) cells from equine and bovine blastocysts. These cells expressed markers that are characteristics of mouse ES cells, namely, alkaline phosphatase, stage-specific embryonic antigen 1, STAT 3 and Oct 4. We confirmed the pluripotential ability of these cells, which were able to undergo somatic differentiation in vitro to neural progenitors and to endothelial or hematopoietic lineages. We were able to use bovine ES cells as a source of nuclei for nuclear transfer and we generated cloned cattle with a higher frequency of pregnancies to term than has been achieved with somatic cells. On the other hand, we established human fetal membrane derived stem cell lines by the colonial cloning techniques using MEMalpha culture medium containing 10 ng/ml of EGF, 10 ng/ml of LIF and 10% fetal bovine serum (FBS). These cells appeared to maintain normal karyotype in vitro and expressed markers characteristics of stem cells. Furthermore, these cells contributed to the formation of chimeric murine embryoid bodies and gave rise to all three germ layers in vitro. Results from animal ES cells and human fetal membrane derived stem cells clearly demonstrate that these cells might be used for providing different types of cells for regenerative medicine as well as used for targeted genetic manipulation of the genome.     

利用piggyBac转座子制备牛成体多能干细胞诱导技术研究

通过逆转录病毒等媒介表达核转录因子Oct4、Sox2、Klf4、c-Myc可将体细胞重编程为诱导多能干细胞(induced pluripotent stem cells, iPSc)。时至今日,已经报道了小鼠、人、大鼠、猪、羊、马、牛的iPS细胞,但大动物iPS的多能性特别是嵌合体形成和生殖细胞传代还没有得到确认。与逆转录病毒等不同的是,piggyBac转座子转染效率高且无病毒源性、操作简单,可以在转座酶的存在下被安全切除。首次尝试了采用piggyBac转座子携带鼠源Oct4、Sox2、Klf4、c-Myc、Rarg和Lrh16个核转录因子诱导胎牛成纤维细胞,成功获得牛类iPS细胞,其形态与小鼠胚胎干细胞相似,克隆边界清晰、呈丘状、克隆内细胞致密、核大。RT-PCR与免疫组织化学染色分析均显示牛类iPS细胞表达多能性基因。该类细胞体外诱导分化可形成类胚体EB,且表达3个胚层的基因;体内诱导分化可形成畸胎瘤,苏木精、伊红染色显示瘤体有三胚层的分化。上述结果显示利用piggyBac转座子制备牛多潜能干细胞诱导技术可行,产生的牛类iPS细胞具有潜在多能性。     

Human hair follicle pluripotent stem (hfPS) cells promote regeneration of peripheral‐nerve injury: An advantageous alternative to ES and iPS cells

The optimal source of stem cells for regenerative medicine is a major question. Embryonic stem (ES) cells have shown promise for pluripotency but have ethical issues and potential to form teratomas. Pluripotent stem cells have been produced from skin cells by either viral‐, plasmid‐ or transposon‐mediated gene transfer. These stem cells have been termed induced pluripotent stem cells or iPS cells. iPS cells may also have malignant potential and are inefficiently produced. Embryonic stem cells may not be suited for individualized therapy, since they can undergo immunologic rejection. To address these fundamental problems, our group is developing hair follicle pluripotent stem (hfPS) cells. Our previous studies have shown that mouse hfPS cells can differentiate to neurons, glial cells in vitro, and other cell types, and can promote nerve and spinal cord regeneration in vivo. hfPS cells are located above the hair follicle bulge in what we have termed the hfPS cell area (hfPSA) and are nestin positive and keratin 15 (K‐15) negative. Human hfPS cells can also differentiate into neurons, glia, keratinocytes, smooth muscle cells, and melanocytes in vitro. In the present study, human hfPS cells were transplanted in the severed sciatic nerve of the mouse where they differentiated into glial fibrillary‐acidic‐protein (GFAP)‐positive Schwann cells and promoted the recovery of pre‐existing axons, leading to nerve generation. The regenerated nerve recovered function and, upon electrical stimulation, contracted the gastrocnemius muscle. The hfPS cells can be readily isolated from the human scalp, thereby providing an accessible, autologous and safe source of stem cells for regenerative medicine that have important advantages over ES or iPS cells. J. Cell. Biochem. 107: 1016–1020, 2009. © 2009 Wiley‐Liss, Inc.     

A new genetic tool to improve immune‐compromised mouse models: Derivation and CRISPR/Cas9‐mediated targeting of NRG embryonic stem cell lines

Development of human hematopoietic stem cells and differentiation of embryonic stem (ES) cells/induced pluripotent stem (iPS) cells to hematopoietic stem cells are poorly understood. NOD (Non‐obese diabetic)‐derived mouse strains, such as NSG (NOD‐Scid‐il2Rg) or NRG (NOD‐Rag1‐il2Rg), are the best available models for studying the function of fetal and adult human hematopoietic cells as well as ES/iPS cell‐derived hematopoietic stem cells. Unfortunately, engraftment of human hematopoietic stem cells is very variable in these models. Introduction of additional permissive mutations into these complex genetic backgrounds of the NRG/NSG mice by natural breeding is a very demanding task in terms of time and resources. Specifically, since the genetic elements defining the NSG/NRG phenotypes have not yet been fully characterized, intense backcrossing is required to ensure transmission of the full phenotype. Here we describe the derivation of embryonic stem cell (ESC) lines from NRG pre‐implantation embryos generated by in vitro fertilization followed by the CRISPR/CAS9 targeting of the Gata‐2 locus. After injection into morula stage embryos, cells from three tested lines gave rise to chimeric adult mice showing high contribution of the ESCs (70%–100%), assessed by coat color. Moreover, these lines have been successfully targeted using Cas9/CRISPR technology, and the mutant cells have been shown to remain germ line competent. Therefore, these new NRG ESC lines combined with genome editing nucleases bring a powerful genetic tool that facilitates the generation of new NOD‐based mouse models with the aim to improve the existing xenograft models.     

Prospects for pluripotent stem cell‐derived cardiomyocytes in cardiac cell therapy and as disease models

The derivation of embryonic stem cells (hESC) from human embryos a decade ago started a new era in perspectives for cell therapy as well as understanding human development and disease. More recently, reprogramming of somatic cells to an embryonic stem cell‐like state (induced pluripotent stem cells, iPS) presented a new milestone in this area, making it possible to derive all cells types from any patients bearing specific genetic mutations. With the development of efficient differentiation protocols we are now able to use the derivatives of pluripotent stem cells to study mechanisms of disease and as human models for drug and toxicology testing. In addition derivatives of pluripotent stem cells are now close to be used in clinical practice although for the heart, specific additional challenges have been identified that preclude short‐term application in cell therapy. Here we review techniques presently used to induce differentiation of pluripotent stem cells into cardiomyocytes and the potential these cells have as disease models and for therapy. J. Cell. Biochem. 107: 592–599, 2009. © 2009 Wiley‐Liss, Inc.     

Embryoid body formation from embryonic and induced pluripotent stem cells: Benefits of bioreactors

Embryonic stem (ES) cells have the ability to differentiate into all germ layers, holding great promise not only for a model of early embryonic development but also for a robust cell source for cell-replacement therapies and for drug screening. Embryoid body (EB) formation from ES cells is a common method for producing different cell lineages for further applications. However, conventional techniques such as hanging drop or static suspension culture are either inherently incapable of large scale production or exhibit limited control over cell aggregation during EB formation and subsequent EB aggregation. For standardized mass EB production, a well defined scale-up platform is necessary. Recently, novel scenario methods of EB formation in hydrodynamic conditions created by bioreactor culture systems using stirred suspension systems (spinner flasks), rotating cell culture system and rotary orbital culture have allowed large-scale EB formation. Their use allows for continuous monitoring and control of the physical and chemical environment which is difficult to achieve by traditional methods. This review summarizes the current state of production of EBs derived from pluripotent cells in various culture systems. Furthermore, an overview of high quality EB formation strategies coupled with systems for in vitro differentiation into various cell types to be applied in cell replacement therapy is provided in this review. Recently, new insights in induced pluripotent stem (iPS) cell technology showed that differentiation and lineage commitment are not irreversible processes and this has opened new avenues in stem cell research. These cells are equivalent to ES cells in terms of both self-renewal and differentiation capacity. Hence, culture systems for expansion and differentiation of iPS cells can also apply methodologies developed with ES cells, although direct evidence of their use for iPS cells is still limited.     

Human ES- and iPS-derived myogenic progenitors restore DYSTROPHIN and improve contractility upon transplantation in dystrophic mice

A major obstacle in the application of cell-based therapies for the treatment of neuromuscular disorders is obtaining the appropriate number of stem/progenitor cells to produce effective engraftment. The use of embryonic stem (ES) or induced pluripotent stem (iPS) cells could overcome this hurdle. However, to date, derivation of engraftable skeletal muscle precursors that can restore muscle function from human pluripotent cells has not been achieved. Here we applied conditional expression of PAX7 in human ES/iPS cells to successfully derive large quantities of myogenic precursors, which, upon transplantation into dystrophic muscle, are able to engraft efficiently, producing abundant human-derived DYSTROPHIN-positive myofibers that exhibit superior strength. Importantly, transplanted cells also seed the muscle satellite cell compartment, and engraftment is present over 11 months posttransplant. This study provides the proof of principle for the derivation of functional skeletal myogenic progenitors from human ES/iPS cells and highlights their potential for future therapeutic application in muscular dystrophies.     

Mouse induced pluripotent stem cells

The recent discovery that it is possible to directly reprogramme somatic cells to an embryonic stem (ES) cell-like pluripotent state, by retroviral transduction of just four genes (Oct3/4, Sox2, c-Myc and Klf4), represents a major breakthrough in stem cell research. The reprogrammed cells, known as induced pluripotent stem (iPS) cells, possess many of the properties of ES cells, and represent one of the most promising sources of patient-specific cells for use in regenerative medicine. While the ultimate goal is the use of iPS cells in the treatment of human disease, much of the research to date has been carried out with murine cells, and improved mouse iPS cells have been shown to contribute to live chimeric mice that are germ-line competent. Very recently, it has been reported that iPS cells can be generated by three factors without c-Myc, and these cells give rise to chimeric mice with a reduced risk of tumour development.     

The applications of induced pluripotent stem (iPS) cells in drug development

The introduction of induced pluripotent stem (iPS) cells has been a milestone in the field of regenerative medicine and drug discovery. iPS cells can provide a continuous and individualized source of stem cells and are considered to hold great potential for economically feasible personalized stem cell therapy. Various diseases might potentially be cured by iPS cell-based therapy including Parkinson’s disease, Alzheimer’s disease, Huntington disease, ischemic heart disease, diabetes and so on. Moreover, iPS cells derived from patients suffering from unique incurable diseases can be developed into patient- and disease-specific cell lines. These cells can be used as an effective approach to study the mechanisms of diseases, providing useful tools for drug discovery, development and evaluation. The development of suitable methods for the culture and expansion of iPS cells and their differentiated progenies make feasible modern drug discovery techniques such as high-throughput screening. Furthermore, iPS cells can be applied in the field of toxicological and pharmacokinetics tests. This review focuses on the applications of iPS cells in the field of pharmaceutical industry.     

Germline competence of mouse ES and iPS cell lines: Chimera technologies and genetic background

In mice, gene targeting by homologous recombination continues to play an essential role in the understanding of functional genomics. This strategy allows precise location of the site of transgene integration and is most commonly used to ablate gene expression ("knock-out"), or to introduce mutant or modified alleles at the locus of interest ("knock-in"). The efficacy of producing live, transgenic mice challenges our understanding of this complex process, and of the factors which influence germline competence of embryonic stem cell lines. Increasingly, evidence indicates that culture conditions and in vitro manipulation can affect the germline-competence of Embryonic Stem cell (ES cell) lines by accumulation of chromosome abnormalities and/or epigenetic alterations of the ES cell genome. The effectiveness of ES cell derivation is greatly strain-dependent and it may also influence the germline transmission capability. Recent technical improvements in the production of germline chimeras have been focused on means of generating ES cells lines with a higher germline potential. There are a number of options for generating chimeras from ES cells (ES chimera mice); however, each method has its advantages and disadvantages. Recent developments in induced pluripotent stem (iPS) cell technology have opened new avenues for generation of animals from genetically modified somatic cells by means of chimera technologies. The aim of this review is to give a brief account of how the factors mentioned above are influencing the germline transmission capacity and the developmental potential of mouse pluripotent stem cell lines. The most recent methods for generating specifically ES and iPS chimera mice, including the advantages and disadvantages of each method are also discussed.