HeLa细胞端粒酶最适反应条件及活性重建

端粒是真核细胞染色体末端的重复ＤＮＡ序列 ,其生物学功能是防止染色体ＤＮＡ降解、末端融合、非正常重组和染色体的缺失[1] .由于存在“末端复制问题” ,随着老化人体细胞端粒重复序列长度不断缩短 ,但在生殖细胞中由于端粒酶的存在 ,端粒序列并不缩短 .端粒酶是由蛋白质和ＲＮＡ构成的核蛋白 ,是依赖ＲＮＡ的ＤＮＡ聚合酶 ,在ＤＮＡ3’端合成端粒重复序列[2 ] .研究表明 ,在 85 %～ 95 %的人肿瘤细胞中可以检测到端粒酶的活性[3 ,4 ] ,而在正常体细胞中除生殖细胞和造血干细胞等极少数细胞中存在端粒酶活性外 ,均检测不到端粒酶活性 ,这…     

端粒酶在细胞永生化和癌变中的作用

重点讨论了端粒酶在肿瘤细胞和永生化细胞中的作用和功能,以及它与细胞衰老和永生化的关系.多数真核细胞的端粒酶能将单一重复序列加到端粒DNA的3′末端.端粒酶主要由模板RNA和端粒酶蛋白催化亚基组成,后者以前者为模板起逆转录酶的作用.端粒酶活性存在于肿瘤细胞中,而在良性肿瘤、体细胞中未发现端粒酶.     

端粒、端粒酶与肿瘤的相关研究进展

端粒是真核细胞染色体末端的DNA序列,在维持染色体的稳定中起着重要的作用。快速生长的细胞通过端粒酶来合成端 粒重复序列以弥补其损耗。在人类恶性肿瘤细胞中,85%以上能检测到端粒酶的活性,使其成为一个几乎普遍的癌标志物,而在大 多数正常体细胞中,端粒酶是阴性的。端粒酶与肿瘤之间的最新研究已经在肿瘤生物学领域开辟了新的途径,可能会彻底改变抗 癌疗法。在这篇文章中,我们将会总结端粒和端粒酶在癌细胞中的作用。随着科技的发展,端粒和端粒酶拥有巨大的潜力,必将能 够为肿瘤的治疗带来更多的方法。     

端粒酶和端粒酶抑制剂研究进展

端粒酶是一种将端粒区的重复序列加到染色体末端的逆转录酶。端粒酶核蛋白复合物包含了两个基本组分:一个催化蛋白亚单位(hTERT)和一个模板RNA(hTR)。早期的研究讨论了端粒酶及其抑制剂与癌症的关系,由于绝大多数癌症多发于老年期,通常伴随着衰老,预计受癌症困扰的人数会在未来不断增加,而端粒酶激活在细胞的永生化及癌变过程中发挥重要作用,有可能成为癌症治疗的新靶点。端粒酶在绝大多数肿瘤细胞中都有表达,而大部分正常的体细胞中无端粒酶的活性。     

端锚聚合酶(Tankyrase)和端粒

端粒是真核细胞染色体末端的一个特殊结构 ,由一段具有特定重复序列的ＤＮＡ和端粒结合蛋白组成 ,是维持染色体结构稳定的重要因素。端粒ＤＮＡ的复制不是由ＤＮＡ聚合酶完成的 ,而是由端粒酶 (ｔｅｌｏｍｅｒａｓｅ)催化合成后添加到染色体的末端。正常细胞随着细胞分裂活动的进行 ,端粒ＤＮＡ逐渐缩短 ,当缩短到一定程度时 ,染色体结构被破坏 ,细胞进入衰老期并以死亡而告终。但当细胞发生癌变时 ,由于端粒酶的重新激活 ,这种端粒ＤＮＡ随分裂活动发生渐进性缩短的趋势受到阻遏 ,使正常细胞转化成具有无限分裂能力的永生化恶性细胞。研究…     

端粒、端粒酶在动脉粥样硬化中的研究进展CSCD

端粒是真核生物线性染色体末端的DNA重复序列,维持染色体的稳定性和DNA复制的完整性。DNA复制过程中,端粒逐渐缩短达到临界值时,染色体DNA被破坏而发生复制型衰老。端粒酶是催化端粒合成的酶,但在正常体细胞中活性很低。动脉粥样硬化是一种衰老相关性疾病,为冠心病、脑梗死、外周血管病发生发展的病理基础。新近研究发现,在动脉粥样硬化患者体内存在较短的端粒,并且较短的端粒更容易导致动脉粥样硬化。本文主要综述了参与动脉粥样硬化形成过程中细胞端粒长度和端粒酶活性的变化,以及这些变化对动脉粥样硬化形成的影响,并概括了动脉粥样硬化的危险因素与端粒和端粒酶的关系。     

端粒、端粒酶在动脉粥样硬化中的研究进展

端粒是真核生物线性染色体末端的DNA重复序列,维持染色体的稳定性和DNA复制的完整性。DNA复制过程中,端粒逐渐缩短达到临界值时,染色体DNA被破坏而发生复制型衰老。端粒酶是催化端粒合成的酶,但在正常体细胞中活性很低。动脉粥样硬化是一种衰老相关性疾病,为冠心病、脑梗死、外周血管病发生发展的病理基础。新近研究发现,在动脉粥样硬化患者体内存在较短的端粒,并且较短的端粒更容易导致动脉粥样硬化。本文主要综述了参与动脉粥样硬化形成过程中细胞端粒长度和端粒酶活性的变化,以及这些变化对动脉粥样硬化形成的影响,并概括了动脉粥样硬化的危险因素与端粒和端粒酶的关系。     

端粒生物学与肿瘤治疗

端粒的生物学功能主要是保护染色体末端,避免核酸酶对染色体末端的降解,防止染色体之间发生融合和重排。大多数人类肿瘤细胞通常通过端粒酶活性的重新激活来延长端粒,从而稳定染色体端粒DNA的长度。端粒酶是由端粒酶逆转录酶和端粒酶RNA模板组成的具有特殊逆转录活性的核糖核蛋白复合物。抑制端粒酶阳性细胞中的端粒酶活性会导致细胞凋亡或衰老。目前有多种以端粒和端粒酶为靶点来进行肿瘤治疗的策略。     

端粒酶(Telomerase)PCR ELISA——用于检测端粒酶活性的快速方法

宝灵曼公司最近推出了一种端粒酶PCR ELISA,它能对培养细胞或其他生物样品的细胞提取物中的端粒酶活性作高度灵敏的定性检测。 端粒是真核细胞染色体末端的特殊DNA-蛋白质结构,端粒DNA的特点是含有大量串连重复并富含G的重复序列,这些序列在进化中是高度保守的。端粒被认为可以阻止基因组DNA被降解或发生有害的重组,如:末端融合、重排、染色体易位和染色体缺失。由于DNA聚合酶不能复制线性DNA的最末端,所以在普通的体细胞中,端粒的末端会随周期性的复制被逐渐的缩短;这种现象在体内、体外均已被证实,并看来与高等真核生物中正常体细胞的增生受到限制相关,亦似乎在细胞衰老的过程中扮演一定的角色(“mitotic clock”;参看Greider and Blackburn,     

端粒酶抑制剂在肿瘤治疗中的进展

端粒是真核细胞染色体末端含有ＴＴＡＧＧＧ重复结构的复合体 ,有防止染色体降解丢失 ,端端融合和重组建作用 ,端粒酶是一种逆转录酶 ,以自身ＲＮＡ为模板 ,逆转录维持染色体的稳定。目前肿瘤组织端粒酶检出率约 85 - 90 %,而正常组织或良性肿瘤端粒酶检出率〈5 %,说明端粒酶与恶性肿瘤密切相关。端粒酶抑制剂作为新的抗肿瘤策略正成为肿瘤研究的热点 ,现就端粒酶抑制剂在肿瘤治疗中的研究状况做一简单概述。1、阻断端粒酶ＲＮＡ的模板作用对端粒酶活性的抑制1. 1反义核苷酸、反义肽苷及硫代反义核苷酸对端粒酶活性的抑制端粒酶ＲＮＡ序列中…     

Mammalian telomeres and telomerase

New features of mammalian telomeres and telomerase have been identified. Telomeres form t-loops, which engage the 3' single-stranded DNA overhang in an interaction with double-stranded telomeric repeats. Mammalian telomerases contain an RNA H/ACA motif and associated protein(s) shared with H/ACA family of small nucleolar ribonucleoproteins. Essential roles for telomerase in the sustained viability of cultured tumor cells and in the normal proliferative capacity of human somatic cells have been demonstrated.     

细胞DNA损伤检控系统在维持端粒稳定中的功能

真核生物的DNA损伤检控系统是维持细胞基因组稳定的一个重要机制,该系统能检测细胞在生命活动过程中出现的DNA损伤并引发细胞周期阻滞,对DNA损伤进行修复,以维持细胞遗传的稳定性。端粒是位于真核细胞染色体末端由重复DNA序列和蛋白质组成的复合物,具有保护染色体、介导染色体复制、引导减数分裂时的同源染色体配对和调节细胞衰老等作用。虽然端粒与DNA双链断裂都具有作为线性染色体末端的共同特点,但正常端粒并不像DNA双链断裂那样激活DNA损伤检控系统。另一方面,端粒又与DNA损伤相似,因为多种DNA损伤检控蛋白在端粒长度稳定中起重要作用。因此DNA损伤检控系统既参与了维持正常端粒的完整性,又可对端粒损伤作出应答。现就DNA损伤检控系统在维持端粒稳定中的作用及其对功能缺陷端粒的应答作一简要综述。     

Agents that target telomerase and telomeres

Telomeres are guanine-rich regions that are located at the ends of chromosomes and are essential for preventing aberrant recombination and protecting against exonucleolytic DNA degradation. Telomeres are maintained by telomerase, an RNA-dependent DNA polymerase. Because telomerase is known to be expressed in tumor cells, which concurrently have short telomeres, and not in most somatic cells, which usually have long telomeres, telomerase and telomere structures have been recently proposed as attractive targets for the discovery of new anticancer agents. The most exciting current strategies are aimed at specifically designing new drugs that target telomerase or telomeres and new models have been formulated to study the biological effects of inhibitors of telomerase and telomeres both in vitro and in vivo.     

Telomere dynamics: the means to an end

Telomeres are among the most important structures in eukaryotic cells. Creating the physical ends of linear chromosomes, they play a crucial role in maintaining genome stability, control of cell division, cell growth and senescence. In vertebrates, telomeres consist of G-rich repetitive DNA sequences (TTAGGG)n and specific proteins, creating a specialized structure called the telosome that through mutual interactions with many other factors in the cell give rise to dynamic regulation of chromosome maintenance. In this review, we survey the structural and mechanistic aspects of telomere length regulation and how these processes lead to alterations in normal and immortal cell growth.     

Telomere length alterations in microsatellite stable colorectal cancer and association with the immune response

Telomeres are repetitive sequences (TTAGGG) located at the end of chromosomes. Telomeres progressively shorten with each cell replication cycle, ultimately leading to chromosomal instability and loss of cell viability. Telomere length anomaly appears to be one of the earliest and most prevalent genetic alterations in malignant transformation. Here we aim to estimate telomere length from whole-exome sequencing data in colon tumors and normal colonic mucosa, and to analyze the potential association of telomere length with clinical factors and gene expression in colon cancer.Reads containing at least five repetitions of the telomere sequence (TTAGGG) were extracted from the raw sequences of 42 adjacent normal-tumor paired samples. The number of reads from the tumor sample was normalized to build the Tumor Telomere Length Ratio (TTLR), considered an estimation of telomere length change in the tumor compared to the paired normal tissue. We evaluated the associations between TTLR and clinical factors, gene expression and copy number (CN) aberrations measured in the same tumor samples.Colon tumors showed significantly shorter telomeres than their paired normal samples. No significant association was observed between TTLR and gender, age, tumor location, prognosis, stromal infiltration or molecular subtypes. The functional gene set enrichment analysis showed pathways related to immune response significantly associated with TLLR.By extracting a relative measure of telomere length from whole-exome sequencing data, we have assessed that colon tumor cells predominantly shorten telomeres, and this alteration is associated with expression changes in genes related to immune response and inflammation in tumor cells.     

端粒和端粒酶及其在肝细胞癌中的研究进展

摘要：端粒是位于染色体末端的特殊核蛋白复合物,其高度保守的重复序列和蛋白复合物形成保护环结构,以维持线性染色体的稳定性和完整性。端粒酶通过添加富含鸟嘌呤的重复序列,在维持和调节端粒长度、细胞永生性和衰老中起着重要作用。通过研究病变细胞的端粒长度变化趋势和端粒酶活性,可为选择端粒酶作为治疗癌症的标记物提供理论参考。本文针对端粒、端粒酶的结构和日常作用机理,以及它们在肝细胞癌中的研究进展进行综述,以期有助于恶性肿瘤和代谢性疾病的预防、诊断和治疗。     

Telomeres,telomerase, and stability of the plant genome

Telomeres, the complex nucleoprotein structures at the ends of linear eukaryotic chromosomes, along with telomerase, the enzyme that synthesizes telomeric DNA, are required to maintain a stable genome. Together, the enzyme and substrate perform this essential service by protecting chromosomes from exonucleolytic degradation and end-to-end fusions and by compensating for the inability of conventional DNA replication machinery to completely duplicate the ends of linear chromosomes. Telomeres are also important for chromosome organization within the nucleus, especially during mitosis and meiosis. The contributions of telomeres and telomerases to plant genome stability have been confirmed by analysis of Arabidopsis mutants that lack telomerase activity. These mutants have unstable genomes, but manage to survive up to ten generations with increasingly shortened telomeres and cytogenetic abnormalities. Comparisons between telomerase-deficient Arabidopsis and telomerase-deficient mice reveal distinct differences in the consequences of massive genome damage, probably reflecting the greater developmental and genomic plasticity of plants.     

端粒及端粒酶的研究进展

端粒是真核细胞染色体末端的特有结构,是由端粒结合蛋白和一段重复序列的端粒DNA组成的一个高度精密的复合体,在维持染色体末端稳定性,避免染色体被核酸酶降解等方面起着重要的作用。端粒的长度、结构及组织形式受多种端粒结合因子的调控。由于端粒的重要性,在哺乳动物细胞里,端粒的长度或端粒结构变化与癌症发生及细胞衰老有密切的关系。由于末端复制问题的存在,随着细胞分裂次数的增加,端粒不断缩短,细胞不可避免的走向衰老或凋亡。由于在细胞分裂过程中端粒长度的不断缩短与细胞分裂代数增加具有相关性,即端粒长度反应了细胞的分裂次数,因此有人将端粒形象的比喻为生物时钟。在90%的癌细胞中,端粒酶被重新激活,以此来维持端粒的长度,使细胞走向永生化。简要综述了端粒、端粒酶及端粒酶结合蛋白的最新研究进展。