Mouse ES cells maintained in different pluripotency-promoting conditions differ in their neural differentiation propensity

Prior to differentiation, embryonic stem (ES) cells in culture are maintained in a so-called “undifferentiated” state, allowing derivation of multiple downstream cell lineages when induced in a directed manner, which in turn grants these cells their “pluripotent” state. The current work is based on a simple observation that the initial culture condition for maintaining mouse ES cells in an “undifferentiated” state does impact on the differentiation propensity of these cells, in this case to a neuronal fate. We point out the importance in judging the “pluripotency” of a given stem cell culture, as this clearly demonstrated that the “undifferentiated” state of these cells is not necessarily a “pluripotent” state, even for a widely used mouse ES cell line. We partly attribute this difference in the initial value of ES cells to the naïve-to-primed status of pluripotency, which in turn may affect early events of the differentiation in vitro.     

Environmental epigenetic modifications and reprogramming-recalcitrant genes

The term “environmental epigenetic modifications” refers to alterations in phenotype triggered by environmental stimuli via epigenetic mechanisms. Epidemiologic and animal model studies show that a subset of such environmental epigenetic marks may affect susceptibility to chronic diseases. A growing body of evidence regarding incompleteness of reprogramming indicates that the potential retention of pathogenic environmental epigenetics in human induced pluripotent stem cells (iPSCs) should be seriously considered. Given this possibility, the optimization of methods for the generation of human induc pluripotent stem cells may require the identification of epigenetically appropriate somatic cell sources. Similarly, techniques for controlling epigenetic modification by environmental factors may also play a critical role in the development of epigenetically stable sources of pluripotent stem cells.     

RNA结合蛋白在多能干细胞命运转变中的研究进展

RNA结合蛋白(RNA binding proteins,RBPs)是一类通过其RNA结合结构域与RNA相互作用的蛋白质,在细胞内发挥着非常重要的作用。RBPs参与从RNA代谢(包括RNA的可变剪接、稳定性、翻译)到表观遗传修饰等多种调控途径。已有大量文献报道转录因子、表观遗传修饰和细胞外信号通路参与调控干细胞的多能性维持、分化和体细胞重编程,但对于RBPs在细胞命运转变中作用的研究报道甚少。该文主要综述了RBPs通过调控RNA的可变剪接、mRNA稳定性、翻译水平、microRNA代谢及组蛋白修饰进而调控干细胞多能性维持和体细胞重编程。     

Highly efficient reprogramming to pluripotency and directed differentiation of human cells with synthetic modified mRNA

Clinical application of induced pluripotent stem cells (iPSCs) is limited by the low efficiency of iPSC derivation and the fact that most protocols modify the genome to effect cellular reprogramming. Moreover, safe and effective means of directing the fate of patient-specific iPSCs toward clinically useful cell types are lacking. Here we describe a simple, nonintegrating strategy for reprogramming cell fate based on administration of synthetic mRNA modified to overcome innate antiviral responses. We show that this approach can reprogram multiple human cell types to pluripotency with efficiencies that greatly surpass established protocols. We further show that the same technology can be used to efficiently direct the differentiation of RNA-induced pluripotent stem cells (RiPSCs) into terminally differentiated myogenic cells. This technology represents a safe, efficient strategy for somatic cell reprogramming and directing cell fate that has broad applicability for basic research, disease modeling, and regenerative medicine.     

Cellular reprogramming of somatic cells

The process of 'cell reprogramming' can be achieved by somatic cell nuclear transfer, cell fusion with embryonic stem cells, exposure to stem cell extracts, or by inducing pluripotentcy mediated by defined factors giving rise to what are termed induced pluripotent stem cells. More recently, the fate of a somatic cell can be directly induced to uptake other cell fates, termed lineage-specific reprogramming, without the need to de-differentiate the cells to a pluripotent state. In this review we will describe the different methods of reprogramming somatic cells.     

Glucose Metabolism, Hyperosmotic Stress, and Reprogramming of Somatic Cells

The availability of glucose and oxygen are important regulatory elements that help directing stem cell fate. In the undifferentiated state, stem cells, and their artificially reprogrammed equivalent-induced pluripotent stem cells (iPS) are characterized by limited oxidative capacity and active anaerobic glycolysis. Recent studies have shown that pluripotency—a characteristic of staminality—is associated with a poorly developed mitochondrial patrimony, while differentiation is accompanied by an activation of mitochondrial biogenesis. Besides being an important energy source in hypoxia, high glucose level results in hyperosmotic stress. The identification of specific metabolic pathways and biophysical factors that regulate stem cell fate, including high glucose in the extracellular medium, may therefore facilitate reprogramming efficiency and control the differentiation and fate of iPS cells, which are increasingly being explored as therapeutic tools. In this article, we review recent knowledge of the role of glucose metabolism and high glucose level as major anaerobic energy source, and a determinant of osmolarity as possible tools for reprogramming therapies in clinical applications. As in the diabetic setting hyperglycemia negatively affect the stem/progenitor cell fate and likely somatic reprogramming, we also discuss the in vivo potential transferability of the available in vitro findings.     

Emerging roles of microRNAs in the control of embryonic stem cells and the generation of induced pluripotent stem cells

MicroRNAs (miRNAs) have emerged as critical regulators of gene expression. These small, non-coding RNAs are believed to regulate more than a third of all protein coding genes, and they have been implicated in the control of virtually all biological processes, including the biology of stem cells. The essential roles of miRNAs in the control of pluripotent stem cells were clearly established by the finding that embryonic stem (ES) cells lacking proteins required for miRNA biogenesis exhibit defects in proliferation and differentiation. Subsequently, the function of numerous miRNAs has been shown to control the fate of ES cells and to directly influence critical gene regulatory networks controlled by pluripotency factors Sox2, Oct4, and Nanog. Moreover, a growing list of tissue-specific miRNAs, which are silenced or not processed fully in ES cells, has been found to promote differentiation upon their expression and proper processing. The importance of miRNAs for ES cells is further indicated by the exciting discovery that specific miRNA mimics or miRNA inhibitors promote the reprogramming of somatic cells into induced pluripotent stem (iPS) cells. Although some progress has been made during the past two years in our understanding of the contribution of specific miRNAs during reprogramming, further progress is needed since it is highly likely that miRNAs play even wider roles in the generation of iPS cells than currently appreciated. This review examines recent developments related to the roles of miRNAs in the biology of pluripotent stem cells. In addition, we posit that more than a dozen additional miRNAs are excellent candidates for influencing the generation of iPS cells as well as for providing new insights into the process of reprogramming.     

体细胞重编程为多能干细胞的研究进展

体细胞通过重编程转变成其他类型的细胞,在再生医学方面具有重要的应用前景。细胞重编程的方法主要有体细胞核移植、细胞融合、细胞提取物诱导、限定因子诱导等,这些方法可以不同程度地改变细胞命运。最近,限定因子诱导的多能干细胞（induced pluripotent stem cell。iPS）为重编程提供了一种崭新的方法,不仅可以避免伦理争议,还提供了一种更为便利的技术,为再生医学开辟了新的天地;同时,iPS技术为研究基因表达调控、蛋白质互作、机体生长发育等提供了一个非常重要的研究手段。本文主要论述了体细胞重编程的方法及iPS细胞的进展、面临的问题和应用前景。     

Direct reprogramming of human astrocytes into neural stem cells and neurons

Generating neural stem cells and neurons from reprogrammed human astrocytes is a potential strategy for neurological repair. Here we show dedifferentiation of human cortical astrocytes into the neural stem/progenitor phenotype to obtain progenitor and mature cells with a neural fate. Ectopic expression of the reprogramming factors OCT4, SOX2, or NANOG into astrocytes in specific cytokine/culture conditions activated the neural stem gene program and induced generation of cells expressing neural stem/precursor markers. Pure CD44+ mature astrocytes also exhibited this lineage commitment change and did not require passing through a pluripotent state. These astrocyte-derived neural stem cells gave rise to neurons, astrocytes, and oligodendrocytes and showed in vivo engraftment properties. ASCL1 expression further promoted neuronal phenotype acquisition in vitro and in vivo. Methylation analysis showed that epigenetic modifications underlie this process. The restoration of multipotency from human astrocytes has potential in cellular reprogramming of endogenous central nervous system cells in neurological disorders.     

细胞命运转变——谱系重编程技术研究进展

体细胞核移植和诱导多能干细胞技术表明已分化的体细胞可以转变命运。最近的研究再一次验证了成熟体细胞可以通过外源转录因子的导入,直接重编程为其他类型的体细胞或祖细胞。这种重编程技术称为谱系重编程(Lineage reprogramming)。这项技术不仅在再生医学领域具有广阔的应用前景,而且在动物生物技术中也应用广泛。它不但避免了伦理争议,还提供了便利的重编程方法,同时也为基因表达调控的研究提供了重要的手段。文章从谱系重编程的方式、谱系重编程的特点及应用前景等3个方面进行了综述,旨在对相关领域的研究人员起到借鉴作用。     

The Path from Skin to Brain: Generation of Functional Neurons from Fibroblasts

Cell fate reprogramming makes possible the generation of new cell types from healthy adult cells to replace those lost or damaged in disease. Additionally, reprogramming patient cells into specific cell types allows for drug screening and the development of new therapeutic tools. Generation of new neurons is of particular interest because of the potential to treat diseases of the nervous system, such as neurodegenerative disorders and spinal cord injuries, with cell replacement therapy. Recent advances in cell fate reprogramming have led to the development of novel methods for the direct conversion of fibroblasts into neurons and neural stem cells. This review will highlight the advantages of these new methods over neuronal induction from embryonic stem cells and induced pluripotent stem cells, as well as outline the limitations and the potential for future applications.     

Cytoskeletal Expression and Remodeling in Pluripotent Stem Cells

Many emerging cell-based therapies are based on pluripotent stem cells, though complete understanding of the properties of these cells is lacking. In these cells, much is still unknown about the cytoskeletal network, which governs the mechanoresponse. The objective of this study was to determine the cytoskeletal state in undifferentiated pluripotent stem cells and remodeling with differentiation. Mouse embryonic stem cells (ESCs) and reprogrammed induced pluripotent stem cells (iPSCs), as well as the original un-reprogrammed embryonic fibroblasts (MEFs), were evaluated for expression of cytoskeletal markers. We found that pluripotent stem cells overall have a less developed cytoskeleton compared to fibroblasts. Gene and protein expression of smooth muscle cell actin, vimentin, lamin A, and nestin were markedly lower for ESCs than MEFs. Whereas, iPSC samples were heterogeneous with most cells expressing patterns of cytoskeletal proteins similar to ESCs with a small subpopulation similar to MEFs. This indicates that dedifferentiation during reprogramming is associated with cytoskeletal remodeling to a less developed state. In differentiation studies, it was found that shear stress-mediated differentiation resulted in an increase in expression of cytoskeletal intermediate filaments in ESCs, but not in iPSC samples. In the embryoid body model of spontaneous differentiation of pluripotent stem cells, however, both ESCs and iPSCs had similar gene expression for cytoskeletal proteins during early differentiation. With further differentiation, however, gene levels were significantly higher for iPSCs compared to ESCs. These results indicate that reprogrammed iPSCs more readily reacquire cytoskeletal proteins compared to the ESCs that need to form the network de novo. The strategic selection of the parental phenotype is thus critical not only in the context of reprogramming but also the ultimate functionality of the iPSC-differentiated cell population. Overall, this increased characterization of the cytoskeleton in pluripotent stem cells will allow for the better understanding and design of stem cell-based therapies.     

Lineage Specifiers： New Players in the Induction of Pluripotency

Pluripotency-associated factors and their rivals,lineage specifers,have long been considered the determining factors for the identity of pluripotent and differentiated cells,respectively.Therefore,factors that are employed for cellular reprogramming in order to induce pluripotency have been identifed mainly from embryonic stem cell(ESC)-enriched and pluripotency-associated factors.Recently,lineage specifers have been identifed to play important roles in orchestrating the process of restoring pluripotency.In this review,we summarize the latest discoveries regarding cell fate conversion using pluripotency-associated factors and lineage specifers.We highlight the value of the‘‘seesaw’’model in defning cellular identity,opening up a novel scenario to consider pluripotency and lineage specifcation.