精原干细胞与睾丸生殖衰老的研究进展

雄性睾丸内精子的生成及其质量随年龄增长逐渐降低。精原干细胞是精子生成的起点,其数量和质量决定了精子的生成,而精原干细胞niche是调节精原干细胞自我更新与分化的重要因素。在衰老过程中,干细胞微环境退化,精原干细胞自我更新和分化失衡,被认为是衰老导致睾丸生殖功能衰退的的主要因素。本文将综述衰老引起的精原干细胞与niche变化及其对生殖的影响相关研究进展。     

小分子物质对维持胚胎干细胞未分化状态的调控作用

胚胎干细胞作为一种具有多潜能和高度自我更新能力的种子细胞,己被广泛地应用于医学研究领域。在体外培养条件下,胚胎干细胞可被诱导分化为三个胚层来源的组织细胞,故被看作为最具有应用前景的种子细胞。近年来,对于在体外培养条件下如何维持胚胎干细胞的多能性即使其较长时期的处于未分化状态成为研究热点,其中一些天然存在或人工合成的小分子物质可通过作用于某些特定的靶信号通路,调控胚胎干细胞的分化命运。本文概述了几种小分子物质的最新研究进展,并对小分子物质在成体多分化潜能胚胎样干细胞分化调控方面的应用前景进行评述。     

干细胞研究的新途径:miRNAs

微小RNA(microRNAs,miRNAs)是一类内源性的非编码单链RNA,能够通过与靶mRNA特异性的碱基配对而导致靶mRNA降解或抑制其翻译,从而对基因进行转录后调控。干细胞的自我更新和多向分化过程依赖于广泛而多样的调控机制,miRNAs正是这些调控机制中非常重要的一类分子。研究发现,干细胞的自我更新功能需要多种miRNAs的参与来维持;干细胞的分化也是多种miRNAs参与调控的结果。miRNAs可以作为干细胞研究的一个新的切入点。     

精原干细胞niche的研究进展

精原干细胞(spermatogonial stem cells,SSCs)是指睾丸内位于曲精细管基膜上既能自我更新维持自身适量恒定,又能定向分化产生精母细胞的一类原始精原细胞。随着干细胞深入的研究,人们发现了一种控制着干细胞可塑性与命运的微环境,此微环境被称为干细胞niche,干细胞niche由niche细胞、细胞外基质、细胞因子等构成。精原干细胞niche是由黏附因子、生长因子、支持细胞、间质细胞以及小管周肌肉细胞组成。大量的研究表明支持细胞在睾丸中是主要的成体细胞,通过分泌可溶性的因子来影响精原干细胞niche的结构与功能,同时支持细胞还能够间接的影响其他的成体细胞。随着年龄的增长使得精原干细胞niche的功能下降。精原干细胞数量以及精原干细胞niche为我们研究组织特异性干细胞生物学以及保持再生组织平衡提供了很宝贵的线索,精原干细胞对于保持组织的自我更新具有很重要的作用,并且受到人们大量的关注,然而精原干细胞niche也起到很重要的作用,它为治疗一些疾病提供新途径.本文将综述精原干细胞niche及其变化对精原干细胞功能调节的相关研究进展。     

MicroRNA在果蝇原始生殖细胞命运调控中的功能研究

果蝇原始生殖细胞(primordial germ cells,PGCs)是生殖干细胞的前体。该群细胞在果蝇幼虫期经历特征性的发育过程,这一过程涉及程序化的细胞命运及行为改变。为系统探讨mi RNA在上述PGCs命运调控中的作用,对雌蝇幼虫发育中的性腺组织进行了mi RNA表达谱分析,发现一组mi RNA分子持续在性腺组织细胞中表达。应用GAL4/UAS遗传操作系统验证了部分候选mi RNAs的功能,获得了mi R-33和mi R-278参与调控果蝇幼虫PGCs有序分化的实验证据。该文为发育过程中功能性mi RNA研究工作的开展提供了有益的借鉴。     

Piwi家族:干细胞分裂中的重要调控基因

Piwi是果蝇卵巢中发现的一个对干细胞的分裂有调控作用的基因。Piwi家族蛋白的表达在各种生物中具有广泛的保守性,而且大多参与干细胞自我更新的调控。在果蝇卵巢中,Piwi对生殖干细胞的调控方式包括外源调控和内源调控两种,而高等动物中的同源物Hiwi只以自调控的方式控制干细胞的分裂和分化。Piwi家族蛋白含有保守结构域Piwi box和PAZ。在果蝇中Yb是Piwi信号途径的上游。     

piRNA和PIWI蛋白的功能机制研究进展

piRNA是2006年7月在动物生殖细胞中发现的一类新小分子非编码RNA。piRNA特异地与PIWI家族蛋白相互作用,因此,被命名为PIWI-interacting RNA,简称piRNA。这类长度在26～32核苷酸的小分子非编码RNA代表了一个生殖细胞转座子沉默的独特小RNA通路。它们可能通过与PIWI家族蛋白质相互作用,在表观遗传学水平和转录后水平沉默转座子等基因组自私性遗传元件,参与生殖干细胞自我维持和分化命运决定、减数分裂、精子形成等生殖相关事件。在piRNA发现后短短数年的时间,对其生物发生、功能及作用机制的研究都取得了诸多重大突破。该文就piRNA研究的最新研究进展作一简述。     

MicroRNA调控造血干细胞发育

造血干细胞是目前研究最为深入的成体干细胞,是极富应用前景的研究领域,然而其维持自我更新以及多向分化潜能的分子机制尚不明.MicroRNA (miRNA)是一类崭新的调控性非编码小分子RNA,在监控生物体个体发育和细胞增殖、分化进程中起着重要作用.miRNA参与包括胚胎干细胞和多种成体干细胞的发育进程,人类造血干细胞及其发育过程中也存在特征性miRNA表达谱,参与调控造血干细胞发育进程,以miRNA为分子靶点的防治造血功能低下疾患的研究具有广阔的应用前景.     

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。     

Osa在果蝇卵巢生殖干细胞分化中的功能研究

果蝇卵巢生殖干细胞(Germline stem cell,GSC)是在活体(in vivo)研究干细胞命运调控的理想平台。表观遗传机制在果蝇卵巢GSC命运调控中发挥重要作用,其机理的探明需要研究并发现更多参与此过程的表观调控因子。为探究果蝇染色质重塑复合物BAP中特有的亚基Osa在果蝇卵巢GSC分化调控中的功能及其分子机理,利用GAL4/UAS二元表达系统结合RNAi技术在干细胞微环境组分护卫细胞(Escort cells,ECs)中特异性下调osa的表达,并通过免疫荧光染色法对相关指标进行检测。结果显示,敲减ECs中osa可致卵巢组织卵原区中未分化生殖细胞数目(Undifferentiated germ cells,UGCs)显著增多,同时BMP信号通路激活标志p Mad、Dad-lacZ阳性细胞数目显著增多,并观察到EC细胞形态异常,不能有效包裹生殖系细胞。推论Osa以BMP信号通路依赖方式参与果蝇卵巢GSC的分化调控,其作用机理还可能涉及EC细胞特定的形态学过程。     

Centrosome misorientation mediates slowing of the cell cycle under limited nutrient conditions in Drosophila male germline stem cells

Drosophila male germline stem cells (GSCs) divide asymmetrically, balancing self-renewal and differentiation. Although asymmetric stem cell division balances between self-renewal and differentiation, it does not dictate how frequently differentiating cells must be produced. In male GSCs, asymmetric GSC division is achieved by stereotyped positioning of the centrosome with respect to the stem cell niche. Recently we showed that the centrosome orientation checkpoint monitors the correct centrosome orientation to ensure an asymmetric outcome of the GSC division. When GSC centrosomes are not correctly oriented with respect to the niche, GSC cell cycle is arrested/delayed until the correct centrosome orientation is reacquired. Here we show that induction of centrosome misorientation upon culture in poor nutrient conditions mediates slowing of GSC cell proliferation via activation of the centrosome orientation checkpoint. Consistently, inactivation of the centrosome orientation checkpoint leads to lack of cell cycle slowdown even under poor nutrient conditions. We propose that centrosome misorientation serves as a mediator that transduces nutrient information into stem cell proliferation, providing a previously unappreciated mechanism of stem cell regulation in response to nutrient conditions.     

Germline stem cells

Sperm and egg production requires a robust stem cell system that balances self-renewal with differentiation. Self-renewal at the expense of differentiation can cause tumorigenesis, whereas differentiation at the expense of self-renewal can cause germ cell depletion and infertility. In most organisms, and sometimes in both sexes, germline stem cells (GSCs) often reside in a defined anatomical niche. Factors within the niche regulate a balance between GSC self-renewal and differentiation. Asymmetric division of the germline stem cell to form daughter cells with alternative fates is common. The exception to both these tendencies is the mammalian testis where there does not appear to be an obvious anatomical niche and where GSC homeostasis is likely accomplished by a stochastic balance of self-renewal and differentiation and not by regulated asymmetric cell division. Despite these apparent differences, GSCs in all organisms share many common mechanisms, although not necessarily molecules, to guarantee survival of the germline.     

Balancing self-renewal and differentiation by asymmetric division: insights from brain tumor suppressors in Drosophila neural stem cells

Balancing self-renewal and differentiation of stem cells is an important issue in stem cell and cancer biology. Recently, the Drosophila neuroblast (NB), neural stem cell has emerged as an excellent model for stem cell self-renewal and tumorigenesis. It is of great interest to understand how defects in the asymmetric division of neural stem cells lead to tumor formation. Here, we review recent advances in asymmetric division and the self-renewal control of Drosophila NBs. We summarize molecular mechanisms of asymmetric cell division and discuss how the defects in asymmetric division lead to tumor formation. Gain-of-function or loss-of-function of various proteins in the asymmetric machinery can drive NB overgrowth and tumor formation. These proteins control either the asymmetric protein localization or mitotic spindle orientation of NBs. We also discuss other mechanisms of brain tumor suppression that are beyond the control of asymmetric division.     

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.     

Heparan sulfate regulates the number and centrosome positioning of Drosophila male germline stem cells

Stem cell division is tightly controlled via secreted signaling factors and cell adhesion molecules provided from local niche structures. Molecular mechanisms by which each niche component regulates stem cell behaviors remain to be elucidated. Here we show that heparan sulfate (HS), a class of glycosaminoglycan chains, regulates the number and asymmetric division of germline stem cells (GSCs) in the Drosophila testis. We found that GSC number is sensitive to the levels of 6-O sulfate groups on HS. Loss of 6-O sulfation also disrupted normal positioning of centrosomes, a process required for asymmetric division of GSCs. Blocking HS sulfation specifically in the niche, termed the hub, led to increased GSC numbers and mispositioning of centrosomes. The same treatment also perturbed the enrichment of Apc2, a component of the centrosome-anchoring machinery, at the hub–GSC interface. This perturbation of the centrosome-anchoring process ultimately led to an increase in the rate of spindle misorientation and symmetric GSC division. This study shows that specific HS modifications provide a novel regulatory mechanism for stem cell asymmetric division. The results also suggest that HS-mediated niche signaling acts upstream of GSC division orientation control.     

The Nuclear Matrix Protein Megator Regulates Stem Cell Asymmetric Division through the Mitotic Checkpoint Complex in Drosophila Testes

In adult Drosophila testis, asymmetric division of germline stem cells (GSCs) is specified by an oriented spindle and cortically localized adenomatous coli tumor suppressor homolog 2 (Apc2). However, the molecular mechanism underlying these events remains unclear. Here we identified Megator (Mtor), a nuclear matrix protein, which regulates GSC maintenance and asymmetric division through the spindle assembly checkpoint (SAC) complex. Loss of Mtor function results in Apc2 mis-localization, incorrect centrosome orientation, defective mitotic spindle formation, and abnormal chromosome segregation that lead to the eventual GSC loss. Expression of mitotic arrest-deficient-2 (Mad2) and monopolar spindle 1 (Mps1) of the SAC complex effectively rescued the GSC loss phenotype associated with loss of Mtor function. Collectively our results define a new role of the nuclear matrix-SAC axis in regulating stem cell maintenance and asymmetric division.     

Rab11 maintains connections between germline stem cells and niche cells in the Drosophila ovary

All stem cells have the ability to balance their production of self-renewing and differentiating daughter cells. The germline stem cells (GSCs) of the Drosophila ovary maintain such balance through physical attachment to anterior niche cap cells and stereotypic cell division, whereby only one daughter remains attached to the niche. GSCs are attached to cap cells via adherens junctions, which also appear to orient GSC division through capture of the fusome, a germline-specific organizer of mitotic spindles. Here we show that the Rab11 GTPase is required in the ovary to maintain GSC-cap cell junctions and to anchor the fusome to the anterior cortex of the GSC. Thus, rab11-null GSCs detach from niche cap cells, contain displaced fusomes and undergo abnormal cell division, leading to an early arrest of GSC differentiation. Such defects are likely to reflect a role for Rab11 in E-cadherin trafficking as E-cadherin accumulates in Rab11-positive recycling endosomes (REs) and E-cadherin and Armadillo (beta-catenin) are both found in reduced amounts on the surface of rab11-null GSCs. The Rab11-positive REs through which E-cadherin transits are tightly associated with the fusome. We propose that this association polarizes the trafficking by Rab11 of E-cadherin and other cargoes toward the anterior cortex of the GSC, thus simultaneously fortifying GSC-niche junctions, fusome localization and asymmetric cell division. These studies bring into focus the important role of membrane trafficking in stem cell biology.     

The Drosophila ovary: an active stem cell community

Only a small number of cells in adult tissues (the stem cells) possess the ability to self-renew at every cell division,while producing differentiating daughter cells to maintain tissue homeostasis for an organism's lifetime.The Drosophilaovary harbors three different types of stem cell populations (germline stem cell (GSC),somatic stem cell (SSC) andescort stem cell (ESC)) located in a simple anatomical structure known as germarium,rendering it one of the best modelsystems for studying stem cell biology due to reliable stem cell identification and available sophisticated genetic toolsfor manipulating gene functions.Particularly,the niche for the GSC is among the first and best studied ones,and studieson the GSC and its niche have made many unique contributions to a better understanding of relationships between stemcells and their niche.So far,both the GSC and the SSC have been shown to be regulated by extrinsic factors originatingfrom their niche and intrinsic factors functioning within.Multiple signaling pathways are required for controlling GSCand SSC self-renewal and differentiation,which provide unique opportunities to investigate how multiple signals fromthe niche are interpreted in the stem cell.Since the Drosophila ovary contains three types of stem cells,it also providesoutstanding opportunities to study how multiple stem cells in a given tissue work collaboratively to contribute to tissuefunction and maintenance.This review highlights recent major advances in studying Drosophila ovarian stem cells andalso discusses future directions and challenges.