综述: 干细胞衰老的表观遗传调控

干细胞衰老理论认为,组织器官特异的成体干细胞随着衰老出现功能性衰退,从而导致组织器官生理功能的衰退甚至衰老相关疾病的发生.表观遗传机制通过精密调控基因表达,在成体干细胞的衰老过程中发挥着重要作用.近年来,机体衰老过程中成体干细胞的表观遗传调控已经成为衰老研究的热点.本综述主要总结了衰老过程中成体干细胞命运的表观遗传调控,并详细介绍了DNA甲基化与组蛋白共价修饰在成体干细胞衰老中的作用,以期为深入认识衰老本质、实现健康长寿提供启示.     

干细胞衰老的表观遗传调控

干细胞衰老理论认为,组织器官特异的成体干细胞随着衰老出现功能性衰退,从而导致组织器官生理功能的衰退甚至衰老相关疾病的发生.表观遗传机制通过精密调控基因表达,在成体干细胞的衰老过程中发挥着重要作用.近年来,机体衰老过程中成体干细胞的表观遗传调控已经成为衰老研究的热点.本综述主要总结了衰老过程中成体干细胞命运的表观遗传调控,并详细介绍了DNA甲基化与组蛋白共价修饰在成体干细胞衰老中的作用,以期为深入认识衰老本质、实现健康长寿提供启示.     

脑细胞的基因及其表达与衰老

概述了脑与衰老在神经分子生物学方面的研究进展 ,包括 :细胞衰老分子机制的主要进展 ,衰老脑在基因及其表达水平的研究进展 ;阿尔茨海默病 (AlzheimerDisease ,AD)相关基因研究进展 ,帕金森病 (porkinsondisease ,PD)相关基因研究进展[7] 。这些研究成果对脑与衰老的关系、对脑在基因及其表达水平上衰老机制认识的加深乃至对衰老脑的基因治疗均具有理论意义和应用价值。     

人参皂苷Rg1拮抗D-半乳糖致睾丸间质细胞雄激素分泌障碍的机制研究

该文重点探讨人参皂苷Rg1拮抗D-半乳糖(D-gal)致小鼠睾丸间质细胞分泌雄激素障碍的机制。采用D-gal构建小鼠衰老模型,体内注射Rg1干预衰老过程,观察睾丸组织细胞衰老的病理学改变;体外构建D-gal致睾丸间质细胞(TM3细胞株)衰老模型,在培养体系加入Rg1拮抗D-gal的致衰老作用。衰老相关半乳糖苷酶(SA-β-Gal)染色观察小鼠睾丸组织细胞和体外培养TM3细胞的衰老情况;ELISA法检测TM3细胞分泌睾酮水平和细胞氧化应激损伤水平;荧光探针DCFH-DA检测细胞活性氧(ROS)水平;Western blot检测TM3细胞合成睾酮的关键酶和Nrf2/ARE抗氧化通路相关蛋白表达;qRT-PCR法检测相关炎症因子及睾酮合成关键酶基因的mRNA表达。结果显示,注射Rg1拮抗D-gal致小鼠衰老过程,衰老的睾丸间质细胞数量明显减少。Rg1体外拮抗D-gal致TM3细胞衰老作用后,细胞分泌睾酮水平无显著降低;IL-1、IL-6、IL-8等炎症因子的基因表达受到抑制;细胞内GSH-Px和CAT表达活性提高同时细胞产生丙二醛(MDA)与活性氧(ROS)能力受到抑制;StAR、3β-HSD及P450scc等睾酮合成关键酶基因及蛋白表达上调;Nrf2、HO-1等抗氧化蛋白表达上调,Keap1蛋白表达下调。研究提示,Rg1可能通过激活Nrf2/ARE抗氧化信号通路,拮抗D-gal对睾丸间质细胞的氧化应激损伤,进而调控睾丸雄激素的分泌功能。     

Wnt/β-catenin信号通路与干细胞衰老

Wnt/β-catenin信号通路作为一条进化保守的信号通路,有着广泛的生物学作用。研究发现,Wnt/β-catenin信号通路与干细胞衰老之间存在联系。激活Wnt/β-catenin信号通路可导致干细胞发生衰老变化,而抑制Wnt/β-catenin信号通路可延缓干细胞的衰老。本文对Wnt/β-catenin信号通路与干细胞衰老之间的关系及其作用机制作一综述。     

衰老相关新基因CSIG的cDNA克隆和功能

为了获得 2BS细胞衰老过程中表达下降的差异基因片段Y6 2的编码序列 ,以cDNA末端快速扩增法获得细胞衰老相关新基因CSIG(cellularsenescenceinhibitedgene ,细胞衰老抑制基因 )的cDNA全长 .CSIGcDNA长 196 1bp ,编码 4 90个氨基酸 ,在多种重要组织中都有不同程度的表达 ;蛋白产物位于细胞核内特定位点 ,可能在核仁中聚集 .细胞转染表明 :CSIG可抑制细胞衰老并延长细胞寿限 ,可能通过核糖体生物合成过程或基因转录调节来调控细胞衰老过程     

miR-223促进小鼠胚胎成纤维细胞复制性衰老北大核心CSCD

微小RNA(miRNAs)作为强大的基因表达调控子,广泛参与多种生命过程,在细胞衰老进程中的作用也日益受到关注。miR-223是一个典型的抑癌基因,可显著抑制细胞增殖能力。miR-223与阿尔茨海默症、心血管疾病以及类风湿性关节炎等衰老相关疾病的发生发展密切相关。尽管如此,miR-223在细胞衰老进程中的作用及其分子机制尚未见报道。本研究通过连续传代建立了小鼠胚胎成纤维细胞(MEF细胞)的复制性衰老模型,并利用荧光定量qRT-PCR检测发现,miR-223在衰老MEF细胞中的表达水平显著上调。随后,通过转染miR-223模拟物Agomir-223在MEF细胞中过表达miR-223。结果显示,过表达miR-223可显著促进MEF细胞的衰老表型并抑制其增殖能力,而抑制miR-223的表达可延缓MEF细胞的复制性衰老进程。进一步利用生物信息学方法预测,获得多个miR-223的候选衰老相关靶基因,包括Rasa1、Ddit4和Smad1等。然而,双萤光素酶报告系统结果显示,miR-223并不显著影响其萤光强度,表明它们很可能并不是miR-223的下游靶基因。综上所述,miR-223可显著促进MEF细胞复制性衰老,然而其调节细胞衰老进程的分子机制依然有待深入研究。     

miR-223促进小鼠胚胎成纤维细胞复制性衰老

微小RNA（MicroRNAs（或miRNAs）是作为强大的基因表达调控子,广泛参与多种生命过程,在细胞衰老进程中的作用也日益受到关注。miR-223是一个典型的抑癌基因,可显著抑制细胞增殖能力。此外,miR-223与阿尔茨海默症、心血管疾病以及类风湿性关节炎等衰老相关疾病的发生发展密切相关。尽管如此,miR-223在细胞衰老进程中的作用及其分子机制尚未见报道。本研究通过连续传代建立了小鼠胚胎成纤维细胞（MEF细胞）的复制性衰老模型,并利用荧光定量qRT-PCR检测发现,miR-223在衰老MEF细胞中的表达水平显著上调。随后,通过转染miR-223模拟物Agomir-223在MEF细胞中过表达miR-223,结果显示过表达miR-223可显著促进MEF细胞的衰老表型并抑制其增殖能力,而抑制miR-223的表达可延缓MEF细胞的复制性衰老进程。进一步利用生物信息学方法预测获得多个miR-223的候选衰老相关靶基因,包括Rasa1、Ddit4和Smad1等。然而双萤光素酶报告系统结果显示,miR-223并不显著影响其萤光强度,表明它们很可能并不是miR-223的下游靶基因。综上所述,miR-223可显著促进MEF细胞复制性衰老,然而其调节细胞衰老进程的分子机制依然有待深入研究。     

消减杂交筛选2BS细胞衰老过程中差异表达基因

细胞的复制性衰老最终导致不可逆的G1 期阻滞 ,研究此过程中差异表达基因对于阐明衰老发生机制有重要意义 .分别构建年轻和衰老 2BS细胞高表达基因的消减文库 ,经点杂交筛选后共得5 3个差异表达基因 .对其中部分基因的VirtualNorthern印迹分析证实差异表达确实存在 .选择Y1 1 4和S1 1 1片段 ,以Northern印迹分析确证其表达变化 ;并通过对新生儿和老年人白细胞中二者的表达分析 ,显示二者在体内也存在与体外衰老过程相一致的随增龄表达变化 .结果在一定程度上体现了 2BS细胞衰老过程中基因表达谱的变化 ;首次报道了TSSC3(tumorsuppressingsubtransferablecandidate 3)、hnRNPK (heterogeneousnuclearribonucleoproteinK)等基因在成纤维细胞衰老时发生差异表达 ;通过对Y1 1 4和S1 1 1在体内衰老时的表达分析 ,显示体内和体外衰老有一定的相关性     

人类胚胎干细胞分化过程中DPPA2基因的表达情况分析(英文)

DPPA2(Developmental Pluripotency-Associated gene2)是近年来发现的在多能性细胞中特异表达的一个基因,它被认为参与维持干细胞的"干性".但目前为止,并没有关于该基因在人类胚胎干细胞(human embryonic stem cells,hESCs)分化过程中的表达情况的报道,其功能也尚不清楚.通过Real-time PCR对DPPA2基因在hESCs分化过程中的表达情况进行分析,此外还对其在异常核型hESCs,人类胚胎癌细胞(human embryonic carcinoma cells,hECCs)NTERA-2以及其它5种癌细胞中的表达情况进行检测.结果表明DPPA2基因在hESCs中特异表达,其表达水平随着hESCs的分化而显著下调.该基因在异常核型hESCs和NTERA-2细胞中也有表达,但在其它肿瘤细胞中未检测到该基因的表达.此外,以EGFP-N1系统为基础的亚细胞信号定位结果表明,DPPA2是一个核蛋白.这些结果提示,DPPA2基因可能在维持hESCs特性的过程中发挥着重要的作用.     

Dynamics of the male germline stem cell population during aging of Drosophila melanogaster

Drosophila melanogaster has emerged as an important model system for the study of both stem cell biology and aging. Much is known about how molecular signals from the somatic niche regulate adult stem cells in the germline, and a variety of environmental factors as well as single point mutations have been shown to affect lifespan. Relatively little is known, however, about how aging affects specific populations of cells, particularly adult stem cells that may be susceptible to aging-related damage. Here we show that male germline stem cells (GSCs) are lost from the stem cell niche during aging, but are efficiently replaced to maintain overall stem cell number. We also find that the division rate of GSCs slows significantly during aging, and that this slowing correlates with a reduction in the number of somatic hub cells that contribute to the stem cell niche. Interestingly, slowing of stem cell division rate was not observed in long-lived methuselah mutant flies. We finally investigated whether two mechanisms that are thought to be used in other adult stem cell types to minimize the effects of aging were operative in this system. First, in many adult tissues stem cells exhibit markedly fewer cell cycles relative to transit-amplifying cells, presumably protecting the stem cell pool from replication-associated damage. Second, at any given time not all stem cells actively cycle, leading to 'clonal succession' from the reserve pool of initially quiescent stem cells. We find that neither of these mechanisms is used in Drosophila male GSCs.     

Stem cell depletion in Hutchinson-Gilford progeria syndrome

Hutchinson-Gilford progeria syndrome (HGPS or progeria) is a very rare genetic disorder with clinical features suggestive of premature aging. Here, we show that induced expression of the most common HGPS mutation (LMNA c.1824C>T, p.G608G) results in a decreased epidermal population of adult stem cells and impaired wound healing in mice. Isolation and growth of primary keratinocytes from these mice demonstrated a reduced proliferative potential and ability to form colonies. Downregulation of the epidermal stem cell maintenance protein p63 with accompanying activation of DNA repair and premature senescence was the probable cause of this loss of adult stem cells. Additionally, upregulation of multiple genes in major inflammatory pathways indicated an activated inflammatory response. This response has also been associated with normal aging, emphasizing the importance of studying progeria to increase the understanding of the normal aging process.     

The Janus face of pluripotent stem cells--connection between pluripotency and tumourigenicity

Pluripotent stem cells have gained special attraction because of their almost unlimited proliferation and differentiation capacity in vitro. These properties substantiate the potential of pluripotent stem cells in basic research and regenerative medicine. Here three types of in vitro cultured pluripotent stem cells (embryonic carcinoma, embryonic stem and induced pluripotent stem cells) are compared in their historical context with respect to their different origin and properties. It became evident that tumourigenicity is an inherent property of pluripotent cells based on p53 down-regulation, expression of tumour-related genes and high telomerase activity that allow unlimited proliferation. In addition, culture-adapted genetic and epigenetic changes may induce tumourigenicity of pluripotent cells. The use of stem cells in regenerative medicine, however, requires non-malignant cell types and strategies that circumvent stages of malignancy.Reprogramming strategies of adult somatic cells that avoid the tumourigenic state of pluripotency may offer alternatives for future biomedical application.     

Mechanical strain modulates age-related changes in the proliferation and differentiation of mouse adipose-derived stromal cells

Background  

Previous studies on the effects of aging in human and mouse mesenchymal stem cells suggest that a decline in the number and differentiation potential of stem cells may contribute to aging and aging-related diseases. In this report, we used stromal cells isolated from adipose tissue (ADSCs) of young (8-10 weeks), adult (5 months), and old (21 months) mice to test the hypothesis that mechanical loading modifies aging-related changes in the self-renewal and osteogenic and adipogenic differentiation potential of these cells.     

Taurine represses age‐associated gut hyperplasia in Drosophila via counteracting endoplasmic reticulum stress

As they age, adult stem cells become more prone to functional decline, which is responsible for aging‐associated tissue degeneration and diseases. One goal of aging research is to identify drugs that can repair age‐associated tissue degeneration. Multiple organ development‐related signaling pathways have recently been demonstrated to have functions in tissue homeostasis and aging process. Therefore, in this study, we tested several chemicals that are essential for organ development to assess their ability to delay intestinal stem cell (ISC) aging and promote gut function in adult Drosophila. We found that taurine, a free amino acid that supports neurological development and tissue metabolism in humans, represses ISC hyperproliferation and restrains the intestinal functional decline seen in aged animals. We found that taurine represses age‐associated ISC hyperproliferation through a mechanism that eliminated endoplasmic reticulum (ER) stress by upregulation of the target genes of unfolded protein response in the ER (UPR^ER) and inhibiting the c‐Jun N‐terminal kinase (JNK) signaling. Our findings show that taurine plays a critical role in delaying the aging process in stem cells and suggest that it may be used as a natural compound for the treatment of age‐associated, or damage‐induced intestinal dysfunction in humans.     

Comparison of glioma stem cells to neural stem cells from the adult human brain identifies dysregulated Wnt- signaling and a fingerprint associated with clinical outcome

Glioblastoma is the most common brain tumor. Median survival in unselected patients is <10 months. The tumor harbors stem-like cells that self-renew and propagate upon serial transplantation in mice, although the clinical relevance of these cells has not been well documented. We have performed the first genome-wide analysis that directly relates the gene expression profile of nine enriched populations of glioblastoma stem cells (GSCs) to five identically isolated and cultivated populations of stem cells from the normal adult human brain. Although the two cell types share common stem- and lineage-related markers, GSCs show a more heterogeneous gene expression. We identified a number of pathways that are dysregulated in GSCs. A subset of these pathways has previously been identified in leukemic stem cells, suggesting that cancer stem cells of different origin may have common features. Genes upregulated in GSCs were also highly expressed in embryonic and induced pluripotent stem cells. We found that canonical Wnt-signaling plays an important role in GSCs, but not in adult human neural stem cells. As well we identified a 30-gene signature highly overexpressed in GSCs. The expression of these signature genes correlates with clinical outcome and demonstrates the clinical relevance of GSCs.