哺乳动物DNA甲基化及其在体细胞诱导重编程中的作用

诱导多能干细胞(Induced pluripotent stem cell, iPS)技术提供了将终末分化的细胞逆转为多潜能干细胞的可能, 在干细胞基础理论研究和再生医学中具有重要意义。然而, 目前体细胞诱导重编程方法效率极低, 常发生不完全的重编程。研究表明, 在不完全重编程的细胞中存在体细胞的表观遗传记忆, 而DNA甲基化作为相对长期和稳定的表观遗传修饰, 是影响重编程效率和iPS细胞分化能力的重要因素之一。哺乳动物DNA甲基化是指胞嘧啶第五位碳原子上的甲基化修饰, 常发生于CpG位点。DNA甲基化能够调节体细胞特异基因和多能性基因的表达, 因此其在哺乳动物基因调控、胚胎发育和细胞重编程过程中发挥着重要作用。此外, 异常DNA甲基化可能导致iPS细胞基因印记的异常和X染色体的失活。文章重点围绕DNA甲基化的机制、分布特点、及其在体细胞诱导重编程中的作用进行了综述。     

诱导多功能干细胞的影响因素

将体细胞诱导为多功能干细胞为人类的再生医学提供了一个全新的研究手段,从而可以不用损坏胚胎就能获得可用于治疗各种特殊疾病的细胞。本文比较了近年来关于生成诱导性多能干细胞(induced pluripotent stem cells,iPS细胞)的诱导方法及重编程效率,总结了这些方法的共同点;另外通过对每个不同试验过程的影响因素进行比较,归纳了影响iPS细胞重编程过程的几个因素。     

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。     

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．     

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．     

Human parthenogenetic embryonic stem cells: one potential resource for cell therapy

Pluripotent stem cells derived from somatic cells through such processes as nuclear transfer or induced pluripotent stem (iPS) cells present an important model for biomedical research and provide potential resources for cell replacement therapies. However, the overall efficiency of the conversional nuclear transfer is very low and the safety issue remains a major concern for iPS cells. Embryonic stem cells (ESCs) generated from parthenogenetic embryos are one attractive alternative as a source of histocompatible cells and tissues for cell therapy. Recent studies on human parthenogenetic embryonic stem cells (hPG ESCs) have revealed that these ESCs are very similar to the hESCs derived from IVF or in vivo produced blastocysts in gene expression and other characteristics, but full differentiation and development potential of these hPG ESCs have to be further investigated before clinical research and therapeutic interventions. To generate various pluripotent stem cells, diverse reprogramming techniques and approaches will be developed and integrated. This may help elucidate the fundamental mechanisms underlying reprogramming and stem cell biology, and ultimately benefit cell therapy and regenerative medicine. Supported by the National High Technology Research and Development Program of China (Grant No. 2006AA02A101).     

Activation of the Imprinted Dlk1-Dio3 Region Correlates with Pluripotency Levels of Mouse Stem Cells

Low reprogramming efficiency and reduced pluripotency have been the two major obstacles in induced pluripotent stem (iPS) cell research. An effective and quick method to assess the pluripotency levels of iPS cells at early stages would significantly increase the success rate of iPS cell generation and promote its applications. We have identified a conserved imprinted region of the mouse genome, the Dlk1-Dio3 region, which was activated in fully pluripotent mouse stem cells but repressed in partially pluripotent cells. The degree of activation of this region was positively correlated with the pluripotency levels of stem cells. A mammalian conserved cluster of microRNAs encoded by this region exhibited significant expression differences between full and partial pluripotent stem cells. Several microRNAs from this cluster potentially target components of the polycomb repressive complex 2 (PRC2) and may form a feedback regulatory loop resulting in the expression of all genes and non-coding RNAs encoded by this region in full pluripotent stem cells. No other genomic regions were found to exhibit such clear expression changes between cell lines with different pluripotency levels; therefore, the Dlk1-Dio3 region may serve as a marker to identify fully pluripotent iPS or embryonic stem cells from partial pluripotent cells. These findings also provide a step forward toward understanding the operating mechanisms during reprogramming to produce iPS cells and can potentially promote the application of iPS cells in regenerative medicine and cancer therapy.     

诱导多能干细胞技术的优化及其应用前景

诱导多能干细胞(induced pluripotent stem cells, iPSCs)是类似胚胎干细胞的一种细胞类型,可以通过对已分化的体细胞进行诱导重编程获得,具有自我更新能力和多潜能性,在体外疾病模型的建立、移植替代治疗、发育学等方面有广阔的应用前景,但致瘤性、转化率低、疾病模型拟合度差等缺点限制着iPS技术在临床和科研上的推广。对近几年诱导多能干细胞技术优化方面取得的新进展进行综述,重点阐述降低致瘤性和提高转化率的几种方法及iPS在临床和科研上的应用前景。     

Genomic analysis of induced pluripotent stem (iPS) cells: routes to reprogramming

The phenomenal proliferation of scientific studies into the nature of induced pluripotent stem (iPS) cells following publication of the findings of Takahashi and Yamanaka little more than 2 years ago, have significantly expanded our understanding of cellular mechanisms relating to cell lineage, differentiation, and proliferation. While the full potential of iPS cell lineages for both scientific tool and therapeutic applications is as yet unclear, findings from several lines of investigation suggests that multipotential and terminally differentiated cells from an array of cell types are competent to undergo epigenetic reprogramming to a pluripotential state. The nature of this pluripotential state appears to be similar to, but not identical with that previously described for embryonic stem (ES) cells. Understanding the nature of this induced reprogrammed state will be critical to determining the full potential of iPS cells. Recently, this issue has been examined through an integrated analysis of the genome in fully and partially reprogrammed iPS cell lineages. These results provide a window onto the temporal components of reprogramming and suggest mechanisms by which the efficacy of reprogramming can be enhanced.     

Human-Induced Pluripotent Stem Cells: In Quest of Clinical Applications

In the field of regenerative medicine, the development of induced pluripotent stem (iPS) cells may represent a potential strategy to overcome the limitations of human embryonic stem cells (ESCs). iPS cells have the potential to mimic human disease, since they carry the genome of the donor. Hypothetically, with iPS cell technology it is possible to screen patients for a genetic cause of disease (genetic mutation), develop cell lines, reprogram them back to iPS cells, finally differentiate them into one or more cell types that develop the disease. Although the creation of multiple lineages with iPS cells can seem limitless, a number of challenges need to be addressed in order to effectively use these cell lines for disease modeling. These include the low efficiency of iPS cell generation without genetic alterations, the possibility of tumor formation in vivo, the random integration of retroviral-based delivery vectors into the genome, and unregulated growth of the remaining cells that are partially reprogrammed and refractory to differentiation. The establishment of protein or RNA-based reprogramming strategies will help generate human iPS cells without permanent genetic alterations. Finally, direct reprogramming strategies can provide rapid production of models of human ??diseases in a dish??, without first passing the cells through a pluripotent state, so avoiding the challenges of time-consumming and labor-intensive iPS cell line generation. This review will overview methods to develop iPS cells, current strategies for direct reprogramming, and main applications of iPS cells as human disease model, focusing on human cardiovascular diseases, with the aim to be a potential information resource for biomedical scientists and clinicians who exploit or intend to exploit iPS cell technology in a range of applications.     

不同物种诱导性多潜能干细胞研究进展及应用

将特定的转录因子转入细胞并使其重编程后,获得与胚胎干细胞极其相似的多潜能性干细胞,称为诱导性多潜能干细胞(induced Pluripotent Stem Cells,iPS),它是由日本Yamanaka研究小组首次构建并命名。iPS细胞具有极强地自我更新和多项分化潜能,有发育和分化形成机体内几乎所有组织细胞类型的潜能,从而构成机体各种复杂的组织器官,且避免了在伦理、道德、宗教、法律和免疫排斥等诸多问题。随着iPS技术的不断发展,不同物种的iPS细胞相继产生,为细胞代替治疗、疾病模型的建立和药物筛选及再生医学等注入了新的活力。目前,iPS细胞的研究尚处于初级阶段,在临床应用上还存在诸多问题,本文将对近年来不同物种iPS细胞的产生、应用,及我们未来面临的问题和挑战进行综述。     

Induced Pluripotency for Translational Research

The advent of induced pluripotent stem cells （iPSCs） has revolutionized the concept of cellular reprogramming and potentially will solve the immunological compatibility issues that have so far hindered the application of human pluripotent stem cells in regenerative medicine. Recent findings showed that pluripotency is defined by a state of balanced lineage potency, which can be artificially instated through various procedures, including the conventional Yamanaka strategy. As a type of pluripotent stem cell, iPSCs are subject to the usual concerns over purity of differen- tiated derivatives and risks of tumor formation when used for cell-based therapy, though they pro- vide certain advantages in translational research, especially in the areas of personalized medicine, disease modeling and drug screening, iPSC-based technology, human embryonic stem cells （hESCs） and direct lineage conversion each will play distinct roles in specific aspects of translational medi- cine, and continue yielding surprises for scientists and the public.     

Potentialities of induced pluripotent stem (iPS) cells for treatment of diseases

Induced pluripotent stem (iPS) cell research has been growing a new height throughout the world due to its potentialities in medical applications. We can explore several therapeutic applications through the iPS cell research. In this review, we have first discussed the development of iPS cells, reprogramming factors, and effectiveness of iPS cells. Then we have emphasized the potential applications of iPS cells in pharmaceutical and medical sectors, such as, study of cellular mechanisms for spectrum of disease entities, disease-specific iPS cell lines for drugs discovery and development, toxicological studies of drugs development, personalized medicine, and regenerative medicine.