Induced pluripotent stem cells from patients with Huntington's disease show CAG-repeat-expansion-associated phenotypes

Huntington's disease (HD) is an inherited neurodegenerative disorder caused by an expanded stretch of CAG trinucleotide repeats that results in neuronal dysfunction and death. Here, The HD Consortium reports the generation and characterization of 14 induced pluripotent stem cell (iPSC) lines from HD patients and controls. Microarray profiling revealed CAG-repeat-expansion-associated gene expression patterns that distinguish patient lines from controls, and early onset versus late onset HD. Differentiated HD neural cells showed disease-associated changes in electrophysiology, metabolism, cell adhesion, and ultimately cell death for lines with both medium and longer CAG repeat expansions. The longer repeat lines were however the most vulnerable to cellular stressors and BDNF withdrawal, as assessed using a range of assays across consortium laboratories. The HD iPSC collection represents a unique and well-characterized resource to elucidate disease mechanisms in HD and provides a human stem cell platform for screening new candidate therapeutics.     

Application of induced pluripotent stem cells to hematologic disease

Induced pluripotent stem cells (iPSC) were first generated from somatic cells via the transduction of four ‘Yamanaka’ factors, Oct4, Sox2, Klf4 and c-Myc. Because iPSC are similar to embryonic stem cells (ESC) and can be differentiated into any cell type of choice, iPSC have the potential to become a platform for personalized medicine by allowing a patient's own cells to become a source of therapeutic tissue. This review describes the main challenges in iPSC technology by focusing on its application to hematologic diseases. The explosive interest in improving iPSC technology has generated numerous genetic and chemical methods for iPSC derivation, but these methods must be evaluated comparatively for their safety and efficacy because there are risks of genetic abnormalities and oncogenesis. Competent iPSC will need to be selected carefully based on physical, genetic and functional criteria, and differentiated efficiently into hematopoietic stem cells via modulation of several signaling pathways before they prove valuable in the clinic.     

Disease-specific induced pluripotent stem cells

Tissue culture of immortal cell strains from diseased patients is an invaluable resource for medical research but is largely limited to tumor cell lines or transformed derivatives of native tissues. Here we describe the generation of induced pluripotent stem (iPS) cells from patients with a variety of genetic diseases with either Mendelian or complex inheritance; these diseases include adenosine deaminase deficiency-related severe combined immunodeficiency (ADA-SCID), Shwachman-Bodian-Diamond syndrome (SBDS), Gaucher disease (GD) type III, Duchenne (DMD) and Becker muscular dystrophy (BMD), Parkinson disease (PD), Huntington disease (HD), juvenile-onset, type 1 diabetes mellitus (JDM), Down syndrome (DS)/trisomy 21, and the carrier state of Lesch-Nyhan syndrome. Such disease-specific stem cells offer an unprecedented opportunity to recapitulate both normal and pathologic human tissue formation in vitro, thereby enabling disease investigation and drug development.     

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.     

Methods to produce induced pluripotent stem cell-derived mesenchymal stem cells: Mesenchymal stem cells from induced pluripotent stem cells

Mesenchymal stem cells (MSCs) have received significant attention in recent years due to their large potential for cell therapy. Indeed, they secrete a wide variety of immunomodulatory factors of interest for the treatment of immune-related disorders and inflammatory diseases. MSCs can be extracted from multiple tissues of the human body. However, several factors may restrict their use for clinical applications: the requirement of invasive procedures for their isolation, their limited numbers, and their heterogeneity according to the tissue of origin or donor. In addition, MSCs often present early signs of replicative senescence limiting their expansion in vitro, and their therapeutic capacity in vivo. Due to the clinical potential of MSCs, a considerable number of methods to differentiate induced pluripotent stem cells (iPSCs) into MSCs have emerged. iPSCs represent a new reliable, unlimited source to generate MSCs (MSCs derived from iPSC, iMSCs) from homogeneous and well-characterized cell lines, which would relieve many of the above mentioned technical and biological limitations. Additionally, the use of iPSCs prevents some of the ethical concerns surrounding the use of human embryonic stem cells. In this review, we analyze the main current protocols used to differentiate human iPSCs into MSCs, which we classify into five different categories: MSC Switch, Embryoid Body Formation, Specific Differentiation, Pathway Inhibitor, and Platelet Lysate. We also evaluate common and method-specific culture components and provide a list of positive and negative markers for MSC characterization. Further guidance on material requirements to produce iMSCs with these methods and on the phenotypic features of the iMSCs obtained is added. The information may help researchers identify protocol options to design and/or refine standardized procedures for large-scale production of iMSCs fitting clinical demands.     

Modeling of Menkes disease via human induced pluripotent stem cells

Menkes disease (MD) is a copper-deficient neurodegenerative disorder that manifests severe neurologic symptoms such as seizures, lethargic states, and hypotonia. Menkes disease is due to a dysfunction of ATP7A, but the pathophysiology of neurologic manifestation is poorly understood during embryonic development. To understand the pathophysiology of neurologic symptoms, molecular and cellular phenotypes were investigated in Menkes disease-derived induced pluripotent stem cells (MD-iPSCs). MD-iPSCs were generated from fibroblasts of a Menkes disease patient. Abnormal reticular distribution of ATP7A was observed in MD-fibroblasts and MD-iPSCs, respectively. MD-iPSCs showed abnormal morphology in appearance during embryoid body (EB) formation as compared with wild type (WT)-iPSCs. Intriguingly, aberrant switch of E-cadherin (E-cad) to N-cadherin (N-cad) and impaired neural rosette formation were shown in MD-iPSCs during early differentiation. When extracellular copper was chelated in WT-iPSCs by treatment with bathocuprione sulfate, aberrant switch of E-cad to N-cad and impaired neuronal differentiation were observed, like in MD-iPSCs. Our results suggest that neurological defects in Menkes disease patients may be responsible for aberrant cadherin transition and impaired neuronal differentiation during early developmental stage.     

体细胞诱导为多能干细胞的最新进展

2007年11-12月,Cell、Science和Nature发表一系列体外诱导人类体细胞转变为多能干细胞的论文。来自日本和美国的研究小组利用慢病毒载体分别将Oct-4、Sox2、C-Myc、Klf4和Oct-4、Sox2、Nanog、Lin28两套基因转入人成纤维细胞,均获得类似ES细胞的克隆。小鼠诱导性多能干细胞已初步用于镰刀细胞性贫血的基因治疗。短短一年半,诱导性多能干细胞的研究和关注度呈现了爆炸式成长;体细胞重编程、去分化、多能干细胞来源等一系列热点问题再次成为大众瞩目的中心。     

Modelling mitochondrial dysfunction in Alzheimer's disease using human induced pluripotent stem cells

Alzheimer's disease(AD) is the most common form of dementia. To date, only five pharmacological agents have been approved by the Food and Drug Administration for clinical use in AD, all of which target the symptoms of the disease rather than the cause. Increasing our understanding of the underlying pathophysiology of AD will facilitate the development of new therapeutic strategies. Over the years, the major hypotheses of AD etiology have focused on deposition of amyloid beta and mitochondrial dysfunction. In this review we highlight the potential of experimental model systems based on human induced pluripotent stem cells(iPSCs) to provide novel insights into the cellular pathophysiology underlying neurodegeneration in AD. Whilst Down syndrome and familial AD iPSC models faithfully reproduce features of AD such as accumulation of Aβ and tau, oxidative stress and mitochondrial dysfunction,sporadic AD is much more difficult to model in this way due to its complex etiology. Nevertheless, iPSC-based modelling of AD has provided invaluable insights into the underlying pathophysiology of the disease, and has a huge potential for use as a platform for drug discovery.     

诱导性多潜能干细胞技术进展

诱导性多潜能干细胞(induced pluripotent stem cells,iPSCs)可以通过在分化的成纤维细胞中导入特定的转录因子获得。IPS细胞与胚胎干细胞(embryonic stem cell,ESCs)在形态,增殖能力,基因表达谱和畸胎瘤形成上没有区别,因此在研究疾病机制,药物筛选和毒理学上有重要的应用价值。一旦解决了安全性和效率问题,iPS细胞将在再生医学上有重要的应用价值。主要从提高转化效率、制备无遗传修饰的iPS细胞和疾病特异性的iPS细胞这3个近来在iPS领域飞速进展的方向做一综述。     

Tumorigenesis in cells derived from induced pluripotent stem cells

Induced pluripotent stem (iPS) cells are an attractive source for potential cell-replacement therapy. However, transplantation of differentiated products harbors the risk of teratoma formation, presenting a serious health risk. Thus, we characterized Nanog-expressing (undifferentiated) cells remaining after induction of differentiation by cytological examination. To induce differentiation of iPS cells, we generated embryoid bodies (EBs) derived from iPS cells carrying a Nanog–green fluorescent protein (GFP) reporter and then injected GFP-positive and GFP-negative EBs into nude mice. GFP-positive EB transplantation resulted in the formation of immature teratoma grade 3, but no tumors were induced by GFP-negative EB. GFP-positive cells revealed significantly lower cytoplasmic area and higher nucleus/cytoplasm ratio than those of GFP-negative cells. Our results suggest that morphological analysis might be a useful method for distinguishing between tumorigenic and nontumorigenic iPS cells.     

诱导多能干细胞研究进展

人类诱导多能干细胞（induced pluripotent stem cells,iPS细胞）的建立被公认为目前最重要的科技进展之一。iPS细胞在动物疾病模型上的成功治疗,病患特异性iPS细胞的研究及iPS细胞的定向分化研究将有可能使人们避开治疗性克隆的伦理和技术障碍,给人类疾病的干细胞治疗带来光明的前景。本文从iPS细胞的诱导策略和方法,来源细胞及筛选、重编程机制的研究现状、应用前景以及研究中存在的问题等方面对其作一综述和讨论。