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。     

依赖端粒酶的端粒维持机制

端粒是真核生物染色体的末端重要结构复合物,对维持染色体稳定性起着重要作用。端粒酶的主要功能是复制端粒末端DNA,维持端粒长度。端粒酶活性调节与肿瘤发生和细胞衰老有着密切关系。本简要综述近年来依赖端粒酶的端粒维持机理的研究进展。     

端粒和端粒酶的发现及意义

端粒是真核生物染色体末端的一种特殊结构,对于维持染色体稳定性具有十分重要的意义,端粒长度的维持则需要端粒酶催化完成,端粒的长短和端粒酶的功能异常与细胞衰老和癌变有密切关联。回顾了端粒与端粒酶的发现历程及研究意义。     

端粒、端粒酶结构功能研究进展

端粒是真核生物线性染色体末端由重复DNA序列和蛋白质结合形成的复合结构,其特殊的环形结构与多种结合蛋白形成了端粒的多重功能的基础。端粒的功能包括染色体末端的保护、引导减数分裂的同源染色体配对、参与DNA修复过程等;端粒酶具有逆转录酶特性和维持端粒长度的功能,其活性与恶性肿瘤的发生密切相关,调控因子错综复杂。     

氧化应激与端粒、端粒酶的关系

端粒是真核生物染色体末端的DNA与特殊蛋白质结合的复合体。端粒酶是一种由蛋白质和RNA组成的核糖核蛋白复合物,具有逆转录酶的活性。除末端复制问题是端粒DNA缩短的原因之外,氧化应激也能加速端粒缩短,而抗氧化剂则能延缓端粒缩短率。氧化应激对端粒酶活性的影响仍不确定。研究表明氧化应激是端粒缩短及其所致细胞衰老的重要调节因子。     

端粒与端粒酶

端粒与端粒酶任波（湖北医学院生物教研室武汉４３００７１）染色体在细胞世代中保持其稳定性应起码具备３个结构要素,即ＤＮＡ复制起点,着丝粒以及端粒（ｔｄｏｍｅｒｅ）。端粒是真核生物染色体末端的特殊结构,由蛋白质与ＤＮＡ构成。其中的ＤＮＡ在结构与功能上与其...     

端粒和端粒酶在癌症中的研究进展及意义

端粒是位于染色体末端的DNA串联重复序列,对基因组稳定性和完整性起保护作用。端粒的长度与细胞周期密切相关。其长度变化机制分为依赖端粒酶活性和端粒重组两类,氧化应激和铅(Pb)与端粒酶的功能蛋白相结合抑制其活性,致使端粒缩短,硒(Se)与二者具有拮抗作用,延缓衰老。相关数据表明85%肿瘤细胞与端粒酶活性成正相关,以端粒酶活性作为肿瘤治疗靶标称为当代热点之一。主要对肺癌、乳腺癌等恶性肿瘤与端粒的相关性进行了综述,以期为端粒和端粒酶在癌症治疗研究提供参考依据。     

哺乳动物早期胚胎端粒和端粒酶重编程

端粒位于真核染色体末端,是稳定染色体末端的重要元件。端粒酶(TER)是一种特殊的细胞核糖核蛋白(RNP)反转录酶(RT),其核心酶包括蛋白亚基和RNA元件。在DNA复制过程中的端粒丢失可以被有活性的端粒酶修复回来。哺乳动物端粒酶在发育中受调控,端粒的重编程可能是由于早期胚胎不同时期的端粒酶活性而造成的。因此,研究端粒和端粒酶重编程在早期胚胎发育中是非常重要的。该文综述了端粒和端粒酶的结构和功能,及其与哺乳动物早期胚胎发育的关系,并在此基础上展望了端粒和端粒酶在克隆动物胚胎发育的基础研究。     

端粒与端粒酶研究进展

细胞分裂中染色体因其末端（端粒）的DNA不能完全复制而短缩,使细胞逐渐失去增殖能力而衰老．端粒酶可延长染色体末端DNA,端粒酶的活化使细胞无限增殖．85％左右的恶性肿瘤端粒酶表达阳性,生殖细胞和无限繁殖的细胞系中端粒酶表达也呈阳性．文章综述了端粒的构成和功能、端粒酶在端粒合成中的作用,介绍了端粒酶活性的测定方法、细胞恶变与端粒酶激活的关系,并论及通过抑制端粒酶活性来治疗癌症的可能性．     

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。     

Telomere configuration influences the choice of telomere maintenance pathways

Telomere maintenance is required for chromosome stability, and telomeres are typically replicated by the action of telomerase. In yeast cells that lack telomerase, telomeres are maintained by alternative type I and type II recombination mechanisms. Previous studies identified several proteins to control the choice between two types of recombinations. Here, we demonstrate that configuration of telomeres also plays a role to determine the fate of telomere replication in progeny. When diploid yeasts from mating equip with a specific type of telomeric structure in their genomes, they prefer to maintain this type of telomere replication in their descendants. While inherited telomere structure is easier to be utilized in progeny at the beginning stage, the telomeres in type I diploids can gradually switch to the type II cells in liquid culture. Importantly, the TLC1/tlc1 yeast cells develop type II survivors suggesting that haploid insufficiency of telomerase RNA component, which is similar to a type of dyskeratosis congenital in human. Altogether, our results suggest that both protein factors and substrate availability contribute to the choice among telomere replication pathways in yeast.     

Telomere higher-order structure and genomic instability

Telomeres, nucleoprotein complexes at the end of eukaryotic chromosomes, have vital roles in chromosome integrity. Telomere chromatin structure is both intricate and dynamic allowing for a variety of responses to several stimuli. A critical determinant in telomere structure is the G-strand overhang. Facilitated by telomeric proteins, the G-strand overhang stabilizes telomere higher-order assemblies most likely by adopting unusual DNA structures. These structures influence activities that occur at the chromosome end. Dysfunctional telomeres induce signals resulting in cell growth arrest or death. To overcome telomere dysfunction, cancer cells activate the DNA polymerase, telomerase. The presence of telomerase at the telomere may establish a particular telomeric state. If the chromosome ends of cancer and normal cells exist in different states, cancer-specific telomere structures would offer a unique chemotherapeutic target.     

Diet, nutrition and telomere length

The ends of human chromosomes are protected by DNA–protein complexes termed telomeres, which prevent the chromosomes from fusing with each other and from being recognized as a double-strand break by DNA repair proteins. Due to the incomplete replication of linear chromosomes by DNA polymerase, telomeric DNA shortens with repeated cell divisions until the telomeres reach a critical length, at which point the cells enter senescence. Telomere length is an indicator of biological aging, and dysfunction of telomeres is linked to age-related pathologies like cardiovascular disease, Parkinson disease, Alzheimer disease and cancer. Telomere length has been shown to be positively associated with nutritional status in human and animal studies. Various nutrients influence telomere length potentially through mechanisms that reflect their role in cellular functions including inflammation, oxidative stress, DNA integrity, DNA methylation and activity of telomerase, the enzyme that adds the telomeric repeats to the ends of the newly synthesized DNA.     

Telomeric recombination induced by dysfunctional telomeres

Telomere maintenance is essential for cellular immortality, and most cancer cells maintain their telomeres through the enzyme telomerase. Telomeres and telomerase represent promising anticancer targets. However, 15% of cancer cells maintain their telomeres through alternative recombination-based mechanisms, and previous analyses showed that recombination-based telomere maintenance can be activated after telomerase inhibition. We determined whether telomeric recombination can also be promoted by telomere dysfunction. We report for the first time that telomeric recombination can be induced in human telomerase-positive cancer cells with dysfunctional telomeres.     

Telomeres and human disease: ageing, cancer and beyond

Telomere length and telomerase activity are important factors in the pathobiology of human disease. Age-related diseases and premature ageing syndromes are characterized by short telomeres, which can compromise cell viability, whereas tumour cells can prevent telomere loss by aberrantly upregulating telomerase. Altered functioning of both telomerase and telomere-interacting proteins is present in some human premature ageing syndromes and in cancer, and recent findings indicate that alterations that affect telomeres at the level of chromatin structure might also have a role in human disease. These findings have inspired a number of potential therapeutic strategies that are based on telomerase and telomeres.     

Telomere length mediates the effects of telomerase on the cellular response to genotoxic stress

Telomerase inhibition may be a novel anti-cancer strategy that can be used in combination with conventional therapies, such as DNA damaging agents. There are conflicting reports as to whether and to what extent telomerase and telomere length influence the sensitivity of cells to genotoxins. To understand the relationship between telomere length, telomerase expression, and sensitivity to genotoxic stress, we expressed the catalytic subunit of telomerase, hTERT, in human fibroblasts having different telomere lengths. We show that telomerase confers resistance to ionizing radiation, bleomycin, hydrogen peroxide, and etoposide only in cells with short, presumably near-dysfunctional, telomeres. This resistance depended on the ability of telomerase to elongate the short telomeres, and telomerase did not protect cells with long telomeres. Interestingly, although long telomeres had no effect on sensitivity to etoposide and bleomycin, they exacerbated sensitivity to hydrogen peroxide, supporting the idea that, compared to other types of DNA damage, telomeres are particularly vulnerable to oxidative damage. Our findings identify a mechanism and conditions under which telomerase and telomeres affect the response of human cells to genotoxic agents and may have important implications for anti-cancer interventions.     

The Werner Syndrome Protein Suppresses Telomeric Instability Caused by Chromium (VI) Induced DNA Replication Stress

Telomeres protect the chromosome ends and consist of guanine-rich repeats coated by specialized proteins. Critically short telomeres are associated with disease, aging and cancer. Defects in telomere replication can lead to telomere loss, which can be prevented by telomerase-mediated telomere elongation or activities of the Werner syndrome helicase/exonuclease protein (WRN). Both telomerase and WRN attenuate cytotoxicity induced by the environmental carcinogen hexavalent chromium (Cr(VI)), which promotes replication stress and DNA polymerase arrest. However, it is not known whether Cr(VI)-induced replication stress impacts telomere integrity. Here we report that Cr(VI) exposure of human fibroblasts induced telomeric damage as indicated by phosphorylated H2AX (γH2AX) at telomeric foci. The induced γH2AX foci occurred in S-phase cells, which is indicative of replication fork stalling or collapse. Telomere fluorescence in situ hybridization (FISH) of metaphase chromosomes revealed that Cr(VI) exposure induced an increase in telomere loss and sister chromatid fusions that were rescued by telomerase activity. Human cells depleted for WRN protein exhibited a delayed reduction in telomeric and non-telomeric damage, indicated by γH2AX foci, during recovery from Cr(VI) exposure, consistent with WRN roles in repairing damaged replication forks. Telomere FISH of chromosome spreads revealed that WRN protects against Cr(VI)-induced telomere loss and downstream chromosome fusions, but does not prevent chromosome fusions that retain telomere sequence at the fusion point. Our studies indicate that environmentally induced replication stress leads to telomere loss and aberrations that are suppressed by telomerase-mediated telomere elongation or WRN functions in replication fork restoration.     

Short telomeres in short‐lived males: what are the molecular and evolutionary causes?

Telomere length regulation is an important aspect of cell maintenance in eukaryotes, since shortened telomeres can lead to a number of defects, including impaired cell division. Although telomere length is correlated with lifespan in some bird species, its possible role in aging and lifespan determination is still poorly understood. Here we investigate telomere dynamics (changes in telomere length and attrition rate) and telomerase activity in the ant Lasius niger, a species in which different groups of individuals have evolved extraordinarily different lifespans. We found that somatic tissues of the short-lived males had dramatically shorter telomeres than those of the much longer-lived queens and workers. These differences were established early during larval development, most likely through faster telomere shortening in males compared with females. Workers did not, however, have shorter telomeres than the longer-lived queens. We discuss various molecular mechanisms that are likely to cause the observed sex-specific telomere dynamics in ants, including cell division, oxidative stress and telomerase activity. In addition, we discuss the evolutionary causes of such patterns in ants and in other species.