Reprogramming cell fates: reconciling rarity with robustness

The stunning possibility of “reprogramming” differentiated somatic cells to express a pluripotent stem cell phenotype (iPS, induced pluripotent stem cell) and the “ground state” character of pluripotency reveal fundamental features of cell fate regulation that lie beyond existing paradigms. The rarity of reprogramming events appears to contradict the robustness with which the unfathomably complex phenotype of stem cells can reliably be generated. This apparent paradox, however, is naturally explained by the rugged “epigenetic landscape” with valleys representing “preprogrammed” attractor states that emerge from the dynamical constraints of the gene regulatory network. This article provides a pedagogical primer to the fundamental principles of gene regulatory networks as integrated dynamic systems and reviews recent insights in gene expression noise and fate determination, thereby offering a formal framework that may help us to understand why cell fate reprogramming events are inherently rare and yet so robust.     

利用化学小分子实现人胚胎干细胞多能性状态的转化

小鼠胚胎干细胞（Embryonic Stem Cells,ESCs）具有两种不同的多能性状态-原始态多能性（naive pluripotency）和始发态多能性（primed pluripotency）,这两种多能性干细胞在形态、自我更新维持条件、基因表达、表观遗传学特征以及单克隆形成率等方面都存在明显差别。传统条件下分离和培养的人胚胎干细胞（human Embryonic Stem Cells,h ESCs）生物学特征更接近始发态多能性状态,需依赖转基因操作才能获得和维持原始态多能性状态。本研究通过在培养体系中添加化学小分子成功地将已建系的始发态多能性h ESCs转化为原始态多能性干细胞,转化后h ESCs呈紧密、圆形、隆起的三维克隆结构,具有两条活化的X染色体,单克隆形成率提高,基因表达更接近原始态多能性特征。结果提示h ESCs也存在两种多能性状态,不同的体外培养环境可获得具备不同多能性特征的h ESCs。原始态多能性状态的获得使h ESCs在基因治疗、器官再生等领域具有广阔的应用前景,而仅改变培养条件,不依赖基因操作的培养方式大大提高了原始态多能性干细胞应用的安全性。     

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。     

Identification and characterisation of the early differentiating cells in neural differentiation of human embryonic stem cells

One of the challenges in studying early differentiation of human embryonic stem cells (hESCs) is being able to discriminate the initial differentiated cells from the original pluripotent stem cells and their committed progenies. It remains unclear how a pluripotent stem cell becomes a lineage-specific cell type during early development, and how, or if, pluripotent genes, such as Oct4 and Sox2, play a role in this transition. Here, by studying the dynamic changes in the expression of embryonic surface antigens, we identified the sequential loss of Tra-1-81 and SSEA4 during hESC neural differentiation and isolated a transient Tra-1-81(-)/SSEA4(+) (TR-/S4+) cell population in the early stage of neural differentiation. These cells are distinct from both undifferentiated hESCs and their committed neural progenitor cells (NPCs) in their gene expression profiles and response to extracellular signalling; they co-express both the pluripotent gene Oct4 and the neural marker Pax6. Furthermore, these TR-/S4+ cells are able to produce cells of both neural and non-neural lineages, depending on their environmental cues. Our results demonstrate that expression of the pluripotent factor Oct4 is progressively downregulated and is accompanied by the gradual upregulation of neural genes, whereas the pluripotent factor Sox2 is consistently expressed at high levels, indicating that these pluripotent factors may play different roles in the regulation of neural differentiation. The identification of TR-S4+ cells provides a cell model for further elucidation of the molecular mechanisms underlying hESC neural differentiation.     

microRNAs和体细胞重编程

体细胞重编程与microRNAs(miRNAs)均为近年来研究的热点问题。到目前为止,能成功诱导体细胞形成多能性干细胞的体细胞重编程方法有核移植(nuclear transfer,NT)和外源因子诱导形成多能干细胞(induced pluripotent stem cells,iPSc)两种,这两种方法让人们看到了体细胞重编程在细胞治疗方面具有诱人的应用前景。miRNAs是真核生物中存在的一类长度为22nt左右起调控作用的内源性非编码RNA,它在转录后水平调节靶基因的表达,是细胞内基因表达的基本调控机制之一。近年的研究结果表明,miRNAs在干细胞干性维持和分化过程中具有重要的调节作用,从miRNAs角度研究体细胞重编程机理将对体细胞重编程的应用具有重要意义。     

Epigenetic Signatures Associated with Different Levels of Differentiation Potential in Human Stem Cells

Background

The therapeutic use of multipotent stem cells depends on their differentiation potential, which has been shown to be variable for different populations. These differences are likely to be the result of key changes in their epigenetic profiles.

Methodology/Principal Findings

to address this issue, we have investigated the levels of epigenetic regulation in well characterized populations of pluripotent embryonic stem cells (ESC) and multipotent adult stem cells (ASC) at the trancriptome, methylome, histone modification and microRNA levels. Differences in gene expression profiles allowed classification of stem cells into three separate populations including ESC, multipotent adult progenitor cells (MAPC) and mesenchymal stromal cells (MSC). The analysis of the PcG repressive marks, histone modifications and gene promoter methylation of differentiation and pluripotency genes demonstrated that stem cell populations with a wider differentiation potential (ESC and MAPC) showed stronger representation of epigenetic repressive marks in differentiation genes and that this epigenetic signature was progressively lost with restriction of stem cell potential. Our analysis of microRNA established specific microRNA signatures suggesting specific microRNAs involved in regulation of pluripotent and differentiation genes.

Conclusions/Significance

Our study leads us to propose a model where the level of epigenetic regulation, as a combination of DNA methylation and histone modification marks, at differentiation genes defines degrees of differentiation potential from progenitor and multipotent stem cells to pluripotent stem cells.     

Navigating the epigenetic landscape of pluripotent stem cells

Pluripotent stem cells, which include embryonic stem cells and induced pluripotent stem cells, use a complex network of genetic and epigenetic pathways to maintain a delicate balance between self-renewal and multilineage differentiation. Recently developed high-throughput genomic tools greatly facilitate the study of epigenetic regulation in pluripotent stem cells. Increasing evidence suggests the existence of extensive crosstalk among epigenetic pathways that modify DNA, histones and nucleosomes. Novel methods of mapping higher-order chromatin structure and chromatin-nuclear matrix interactions also provide the first insight into the three-dimensional organization of the genome and a framework in which existing genomic data of epigenetic regulation can be integrated to discover new rules of gene regulation.     

植物根尖干细胞的表观遗传调控

干细胞是一类具有特化为不同细胞类型能力的多能性细胞,他为多细胞生物的器官发生、损伤修复和再生源源不断提供新细胞。干细胞的特化和维持需要复杂的基因调控网络来有序调控。此外,表观遗传调控在包括干细胞命运决定在内的许多生物学过程中发挥极其重要的作用。本文归纳了近年来对植物,主要是模式植物拟南芥（Arabidopsis thaliana（L.）Heynh.）根尖干细胞表观遗传调控方面的研究进展,重点论述了表观调控因子与控制干细胞的关键转录因子之间如何互作、调控植物根尖干细胞的自我更新和分化,并对今后研究的突破方向进行了展望。     

Microfluidic single-cell real-time PCR for comparative analysis of gene expression patterns

Single-cell quantitative real-time PCR (qRT-PCR) combined with high-throughput arrays allows the analysis of gene expression profiles at a molecular level in approximately 11 h after cell sample collection. We present here a high-content microfluidic real-time platform as a powerful tool for comparatively investigating the regulation of developmental processes in single cells. This approach overcomes the limitations involving heterogeneous cell populations and sample amounts, and may shed light on differential regulation of gene expression in normal versus disease-related contexts. Furthermore, high-throughput single-cell qRT-PCR provides a standardized, comparative assay for in-depth analysis of the mechanisms underlying human pluripotent stem cell self-renewal and differentiation.     

microRNA在多能干细胞向心肌细胞分化中的作用

microRNAs(miRNAs)是长约22 nt的非编码RNAs,广泛参与细胞的增殖、分化、病变、修复和凋亡等多种生命活动．多能干细胞（pluripotent stem cells）是指体外具有自我更新和多向分化潜能的细胞,在一定条件下可被定向诱导分化为多种细胞类型．miRNAs在多能干细胞中表达丰富,并通过调控基因表达影响其自我更新及分化．由多能干细胞向心肌细胞分化的方法主要有3种,即拟胚体形成法、与内胚层细胞共培养法和特定诱导物添加法．虽然这3种方法均可成功诱导多能干细胞向心肌细胞分化,但重复率很低. 所以,人们把研究的视野逐渐转向miRNAs--这个广泛参与细胞生命活动的小分子物质．大量研究表明,在多能干细胞中,不同的miRNAs可通过打靶不同基因影响其向心肌细胞分化．在间充质干细胞中,miR-1、miR-133 和miR-499可分别打靶Hes-1、SRF和Pdcd4| 而在胚胎干细胞中,miR-1和miR-499分别打靶 Hand2和Pacs2促进其向心肌细胞分化．miRNAs在多能干细胞向心肌分化作用机制的研究必将促进再生医学在心脏疾病治疗上的应用．     

Safeguarding clinical translation of pluripotent stem cells with suicide genes

The generation of human induced pluripotent stem cells (hiPSCs) opens a new avenue in regenerative medicine. However, transplantation of hiPSC-derived cells carries a risk of tumor formation by residual pluripotent stem cells. Numerous adaptive strategies have been developed to prevent or minimize adverse events and control the in vivo behavior of transplanted stem cells and their progeny. Among them, the application of suicide gene modifications, which is conceptually similar to cancer gene therapy, is considered an ideal means to control wayward stem cell progeny in vivo. In this review, the choices of vectors, promoters, and genes for use in suicide gene approaches for improving the safety of hiPSCs-based cell therapy are introduced and possible new strategies for improvements are discussed. Safety-enhancing strategies that can selectively ablate undifferentiated cells without inducing virus infection or insertional mutations may greatly aid in translating human pluripotent stem cells into cell therapies in the future.     

Heterogeneity of pluripotent marker gene expression in colonies generated in human iPS cell induction culture

Induction of pluripotent stem cells from human fibroblasts has been achieved by the ectopic expression of two different sets of four genes. However, the mechanism of the pluripotent stem cell induction has not been elucidated. Here we identified a marked heterogeneity in colonies generated by the four-gene (Oct3/4, Sox2, c-Myc, and Klf4) transduction method in human neonatal skin-derived cells. The four-gene transduction gave a higher probability of induction for archetypal pluripotent stem cell marker genes (Nanog, TDGF, and Dnmt3b) than for marker genes that are less specific for pluripotent stem cells (CYP26A1 and TERT) in primary induction culture. This tendency may reflect the molecular mechanism underlying the induction of human skin-derived cells into pluripotent stem cells. Among the colonies induced by the four-gene transduction, small cells with a high nucleus-to–cytoplasm ratio could be established by repeated cloning. Subsequently established cell lines were similar to human embryonic stem cells as well as human induced pluripotent stem (iPS) cells derived from adult tissue in morphology, gene expression, long-term self-renewal ability, and teratoma formation. Genome-wide single-nucleotide polymorphism array analysis of the human iPS cell line indicates that the induction process did not induce DNA mutation.