造血干细胞自我更新调控及wnt信号在其中的作用

干细胞生物学最为重要的问题之一就是干细胞自我更新的调控机制.造血干细胞具有自我更新和分化为各血细胞世系的能力,但目前对其自我更新的调控机制尚未明确.大量的研究表明,造血干细胞的自我更新受到来自其所处微环境和自身内在基因的共同调控.经典的发育调控通路——wnt信号通路在造血干细胞自我更新调控中起着至关重要的作用.就造血干细胞自我更新及其调控,特别是wnt信号通路在其中的作用作一综述,并对其应用前景和今后的研究方向作了展望.     

Wnt信号通路调控造血干细胞自我更新的研究进展

造血干细胞是一类具有自我更新能力和分化成所有种类血细胞能力的多潜能干细胞,该类群细胞来源于中胚层细胞,最终定植于骨髓中。造血干细胞的增殖分化由多个信号通路精细调控,其中,Wnt信号通路在调控其自我更新的过程中具有重要作用。该文综述了多年来关于Wnt信号通路在脊椎动物(小鼠)造血干细胞自我更新中的研究,有助于了解Wnt信号通路的作用机制,也有望为改善体外增殖造血干细胞的效果提供理论支持。     

干细胞发育的生物力学调控

生物力学是采用力学方法对生物系统的结构和功能进行的研究,与生物化学信号一起是调节胚胎发育、干细胞发育分化和组织器官形成的重要因素。近年来,随着学科交叉的深入,生物力学因素越来越受到研究者的重视。目前的研究表明：在心血管和造血系统,血流产生的流体剪切力对于血管内皮和造血细胞的发育分化至关重要;此外,对于广泛研究的间充质干细胞,由细胞外基质物理特性诱导的细胞张力对于干细胞功能及其向不同子代细胞的分化也扮演了重要的角色;而在肝脏等上皮组织来源的器官,也有研究提示生物力学因素,如基质弹性等在疾病的发生发展过程中起到了不可忽视的作用。总之,在干细胞发育分化过程中,生物力学调控与生物化学信号通路怎样协同发挥作用将成为今后研究的重点。     

Wnt信号在胚胎干细胞自我更新和分化中的作用

胚胎干细胞分离自胚泡内细胞团,具有无限自我更新和多向分化潜能,有很大的医学应用前景。Wnt家族是一类分泌型的细胞信号传导蛋白,可以通过复杂的信号传递通路调控胚胎的早期发育,对细胞的分化、增殖及生长具有重要的调节作用。该文就Wnt信号通路调节胚胎干细胞的自我更新和分化作一综述。     

Notch信号通路对神经干细胞增殖分化的作用

神经干细胞作为一种具有自我更新能力和多向分化潜能的细胞,它的增殖和分化受到多种源于自身或外在、邻近或远程细胞信号通路的调控,各种细胞因子及胞间通讯在神经干细胞的增殖和分化中发挥着重要的作用。近年来的多种研究表明,Notch信号通路正是这样一种可以通过相邻细胞的配体与受体相互作用,从而传递信号,进一步发挥其生物学功能的重要信号通路。该通路参与了神经干细胞维持自我形态及向多种具有不同功能的神经细胞分化的过程．对于研究神经干细胞的增殖和分化具有巨大的意义。该文将就当前Notch信号通路对神经干细胞增殖分化影响的相关研究进行简要综述。     

microRNA在胚胎干细胞中的表达及作用

摘要: 胚胎干细胞是一类具有自我更新能力和多向分化潜能的细胞, 其自我更新和多向分化过程都在遗传和表观遗传的严格调控下进行的。越来越多的研究表明microRNA 也在这一过程中发挥重要的作用。microRNA是一类内源性的非编码RNA, 能够通过与靶mRNA特异性的结合而导致靶mRNA降解或抑制其翻译, 从而对基因进行转录后调控。文章就microRNA在胚胎干细胞中的表达及其作用的研究进展做一综述。主要讨论一些在胚胎干细胞中特异性表达的microRNA, 以及这些microRNA 对胚胎干细胞自我更新和未分化状态的维持和继续分化增殖的调控作用。     

小分子RNA决定果蝇生殖干细胞命运的分子机制研究

生殖干细胞是具有自我更新能力的一群生殖细胞,充当配子生成的源泉。果蝇生殖干细胞的特征在于通过不对称分裂产生两个子代细胞,一个通过自我更新维持干细胞特性,另一个则进行分化。生殖干细胞的命运受其周围的微环境——"干细胞niche"控制,而"niche"的功能又通过干细胞的外源和内源信号间的相互作用来完成。小分子RNA通过复杂的RNAi途径调控基因的表达。大量证据表明生殖干细胞的维持和分化需要小分子RNA参与,小分子RNA生成的紊乱会导致干细胞的"丢失"或"未分化"。该文综述了小分子RNA对果蝇生殖干细胞命运调控的研究进展,并讨论新发现的小分子RNA在生殖干细胞命运决定中的相关功能。     

力学微环境影响间充质干细胞分化的研究现状

间充质干细胞(mesenchymal stem cells,MSCs)具有很强的自我复制能力和多向分化潜能,是近年来热门研究的种子细胞。MSCs的生长微环境可以影响调控干细胞的生长、分化,力学刺激是MSCs分化的影响因素之一。细胞外基质硬度、机械应力(剪切力、静压力、牵张力)、微重力等因素对MSCs的分化作用是当前研究的热点。就细胞外基质硬度、机械应力以及机械应力作用于三维支架培养对MSCs分化的影响等方面进行综述。     

果蝇生殖腺干细胞和它们的微环境

干细胞微环境是由容纳一个或多个干细胞,并控制干细胞自我更新和子代细胞产生的组织细胞以及细胞外基质组成。干细胞必须在微环境内才能增殖,才能保持自我更新的特性。通过对果蝇生殖腺干细胞微环境的结构及其产生的信号路径（该路径可以调节干细胞自我更新）的研究,发现微环境中支持细胞和它们发出的信号路径在调节干细胞的增殖和分化中起重要的作用。     

表观遗传修饰与干细胞分化调控

干细胞具有自我更新和多种分化潜能的特性。干细胞向分化细胞的转变涉及到基因表达模式的改变,与自我更新有关的基因关闭．与细胞特化有关的基因激活。表观遗传调控机制,包括DNA甲基化、组蛋白修饰和微RNA（microRNA）介导的基因调控,在多个层面上控制发育过程中基因表达。近年研究表明,动态的表观遗传调控机制在干细胞自我更新和分化中起关键作用。     

Inhibition of human embryonic stem cell differentiation by mechanical strain

Mechanical forces have been reported to induce proliferation and/or differentiation in many cell types, but the role of mechanotransduction during embryonic stem cell fate decisions is unknown. To ascertain the role of mechanical strain in human embryonic stem cell (hESC) differentiation, we measured the rate of hESC differentiation in the presence and absence of biaxial cyclic strain. Above a threshold of 10% cyclic strain, applied to a deformable elastic substratum upon which the hESC colonies were cultured, hESC differentiation was reduced and self-renewal was promoted without selecting against survival of differentiated or undifferentiated cells. Frequency of mechanical strain application had little effect on extent of differentiation. hESCs cultured under cyclic strain retained pluripotency, evidenced by their ability to differentiate to cell lineages in all three germ layers. Mechanical inhibition of hESC differentiation could not be traced to secretion of chemical factors into the media suggesting that mechanical forces may directly regulate hESC differentiation. Mechanical strain is not sufficient to inhibit differentiation, however, in unconditioned medium, hESCs grown under strain differentiated at the same rate as cells cultured in the absence of strain. Thus, while mechanical forces play a role in regulating hESC self-renewal and differentiation, they must act synergistically with chemical signals. These findings imply that application of mechanical forces may be useful, in combination with chemical and matrix-encoded signals, towards controlling differentiation of hESCs for therapeutic applications.     

The role of Hippo signaling pathway and mechanotransduction in tuning embryoid body formation and differentiation

Embryoid bodies (EBs) are the three-dimensional aggregates of pluripotent stem cells that are used as a model system for the in vitro differentiation. EBs mimic the early stages of embryogenesis and are considered as a potential biomimetic body in tuning the stem cell fate. Although EBs have a spheroid shape, they are not formed accidentally by the agglomeration of cells; they are formed by the deliberate and programmed aggregation of stem cells in a complex topological and biophysical microstructure instead. EBs could be programmed to promisingly differentiate into the desired germ layers with specific cell lineages, in response to intra- and extra-biochemical and biomechanical signals. Hippo signaling and mechanotransduction are the key pathways in controlling the formation and differentiation of EBs. The activity of the Hippo pathway strongly relies on cell–cell junctions, cell polarity, cellular architecture, cellular metabolism, and mechanical cues in the surrounding microenvironment. Although the Hippo pathway was initially thought to limit the size of the organ by inhibiting the proliferation and the promotion of apoptosis, the evidence suggests that this pathway even regulates stem cell self-renewal and differentiation. Considering the abovementioned explanations, the present study investigated the interplay of the Hippo signaling pathway, mechanotransduction, differentiation, and proliferation pathways to draw the molecular network involved in the control of EBs fate. In addition, this study highlighted several neglected critical parameters regarding EB formation, in the interplay with the Hippo core component involved in the promising differentiation.     

Polycystin-1 may play an important role in mechanical modulation of bone growth and healing

Mechanical stress is known to modulate bone growth and healing. However, the mechanisms underlying the mechanotransduction are not fully understood. Previous studies show that PC1 is a promising candidate among proteins that may play a role in the mechanotransduction process as it has been shown to function as a flow sensor in renal epithelium and it is known to be important for the growth of for skeletal development. We hypothesized that PC1 plays an important role in bone responses to mechanical stress. PC1 is required for the proliferation, differentiation and survival of periosteal osteochondroprogenitor cells upon mechanical stimulation of bone. Using both genetically manipulated animal models and animals undergoing are necessary to test this hypothesis.     

Mechanotransduction of stem cells for tendon repair

Tendon is a mechanosensitive tissue that transmits force from muscle to bone. Physiological loading contributes to maintaining the homeostasis and adaptation of tendon, but aberrant loading may lead to injury or failed repair. It is shown that stem cells respond to mechanical loading and play an essential role in both acute and chronic injuries, as well as in tendon repair. In the process of mechanotransduction, mechanical loading is detected by mechanosensors that regulate cell differentiation and proliferation via several signaling pathways. In order to better understand the stem-cell response to mechanical stimulation and the potential mechanism of the tendon repair process, in this review, we summarize the source and role of endogenous and exogenous stem cells active in tendon repair, describe the mechanical response of stem cells, and finally, highlight the mechanotransduction process and underlying signaling pathways.     

Letter from the Guest Editor

Understanding the mechanisms of stem cell proliferation, self-renewal and differentiation is fundamental for stem cell biology. Stem cells proliferate by either symmetric division or asymmetric division. Through asymmetric division, stem cells self-renew and differentiate to mature cells. Stem cells could also divide symmetrically to give rise to differentiated cells. Besides intrinsic cues, proliferation and self-renewal of most stem cell types also rely on extrinsic signals from niche or surrounding cells. Failure in any of these factors may result in disturbed stem cell proliferation, self-renewal or differentiation and/or generate cancer stem cells that drive cancer development.     

Mechanisms for osteogenic differentiation of human mesenchymal stem cells induced by fluid shear stress

Mechanical stimuli can improve bone function by promoting the proliferation and differentiation of bone cells and osteoblasts. As precursors of osteoblasts, human mesenchymal stem cells (hMSCs) are sensitive to mechanical stimuli. In recent years, fluid shear stress (FSS) has been widely used as a method of mechanical stimulation in bone tissue engineering to induce the osteogenic differentiation of hMSCs. However, the mechanism of this differentiation is not completely clear. Several signaling pathways are involved in the mechanotransduction of hMSCs responding to FSS, such as MAPK, NO/cGMP/PKG and Ca²⁺ signaling pathway. Here, we briefly review how hMSCs respond to fluid flow stimuli and focus on the signal molecules involved in this mechanotransduction.     

Nuclear mechanotransduction in stem cells

In development and in homeostatic maintenance of tissues, stem cells and progenitor cells are constantly subjected to forces. These forces can lead to significant changes in gene expression and function of stem cells, mediating self-renewal, lineage specification, and even loss of function. One of the ways that has been proposed to mediate these functional changes in stem cells is nuclear mechanotransduction — the process by which forces are converted to signals in the nucleus. The purpose of this review is to discuss the means by which mechanical signals are transduced into the nucleus, through the linker of nucleoskeleton and cytoskeleton (LINC) complex and other nuclear envelope transmembrane (NET) proteins, which connect the cytoskeleton to the nucleus. We discuss how LINC/NETs confers tissue-specific mechanosensitivity to cells and further elucidate how LINC/NETs acts as a control center for nuclear mechanical signals, regulating both gene expression and chromatin organization. Throughout, we primarily focus on stem cell–specific examples, notwithstanding that this is a nascent field. We conclude by highlighting open questions and pointing the way to enhanced research efforts to understand the role nuclear mechanotransduction plays in cell fate choice.     

精原干细胞自我更新和分化的调控

精原干细胞（spermatogonial stem cells,SSCs）是体内自然状态下惟一能将遗传信息传至子代的成体干细胞,它们能通过维持自我更新和分化的稳定从而保证雄性生命过程中精子发生的持续进行。了解SSCs自我更新和分化的调节机制有助于阐明精子发生机理,并为探究其他组织中成体干细胞增殖分化的调节机制提供依据。然而目前对于SSCs自我更新和分化的调控机制所知甚少。SSCs的更新与分化遵循特定模式,受以睾丸支持细胞为主要成分的微环境及各种内分泌因素如胶质细胞源神经营养因子（GDNF）、维生素、Ets转录因子ERM/Etv5等的调控。本文评述了SSCs更新与分化的模式以及上述因素对其更新、分化的调控,探讨了其中可能涉及的信号通路,以期为本领域及其他成体干细胞相关研究提供借鉴。     

A New Role of p53 in Maintaining Genetic Stability in Embryonic Stem Cells

Embryonic stem cells (ESCs) are capable of unlimited self-renewal and retain the pluripotency to differentiate into all cell lineages in the body. Since DNA damage occurs during normal cellular proliferation as well as after exposure to DNA damaging agents, it is critical for ESCs to possess stringent mechanisms to maintain genetic stability and prevent the passage of DNA damage to the progeny. Consistent with this notion, the rate of spontaneous mutation in ESCs is several magnitudes lower than that in somatic cells. Our recent findings indicate that tumor suppressor p53 plays an important role in maintaining genetic stability in ESCs by eliminating DNA-damaged ESCs from the replicative ESC pool. In this context, p53 induces the differentiation of DNA-damaged ESCs by directly suppressing the expression of Nanog, which is critical for the self-renewal of ESCs. This newly found role of p53 in cellular differentiation indicates an alternative mechanism for p53 to maintain genetic stability in ESCs and suggests the possibility that p53 might play a similar role in certain tissue stem cells and suppress the development of cancer stem cells.