Telomerase primer specificity and chromosome healing

Chromosome healing by de novo telomere addition at nontelomeric sites has been well characterized in several organisms. The Tetrahymena telomerase ribonucleoprotein uses an internal RNA template to catalyse d(TTGGGG)n telomere addition to the 3' end of telomeric sequence in vitro and in vivo. Studies of telomerase RNA indicated that hybridization of the RNA template region, 5'-CAACCCCAA-3', to the 3' end of single-stranded telomeric oligonucleotides might be important for primer recognition and utilization. The apparent requirement of telomerase for pre-existing telomeric sequence has raised questions regarding its role in chromosome healing. We report here that Tetrahymena telomerase can specifically elongate single-stranded DNA oligonucleotides whose termini are not complementary to the RNA template sequence 5'-CAACCCCAA-3'. These data suggest that telomerase may be able to heal chromosomes directly in vivo.     

端粒酶核酶抑制肿瘤细胞生长的研究

已证明有84.7%的人类恶性肿瘤组织细胞中端粒酶表达异常增高.端粒酶的作用是合成染色体末端端粒重复序列维持染色体稳定及细胞永生化的关键因素.因此,端粒酶在肿瘤发生发展中起重要作用,是目前最广泛的肿瘤标志物.核酶是一种具有内切酶活性的RNA分子,只要满足一定的空间结构就能定点切割RNA底物.切割端粒酶的核酶(简称为端粒酶核酶)主要针对端粒酶的两个亚单位hTR和hTERT抑制两基因的表达,降低端粒酶的活性,抑制肿瘤细胞的生长.     

关于端粒酶研究:结果与问题

端粒酶是一种由RNA和蛋白质构成的复合结构，在活性状态下端粒酶可以其自身的RNA中的内设模板区为模板，以逆转录方式为染色体末端“加尾”。端粒酶活性的恢复是动物克隆成功的关键因素之一。但是，端粒酶活性恢复机制、端粒酶基因表达调控信号及端粒酶活性与衰老体细胞中染色体端粒恢复的关系等问题还有待研究解决。     

A telomerase component is defective in the human disease dyskeratosis congenita

The X-linked form of the human disease dyskeratosis congenita (DKC) is caused by mutations in the gene encoding dyskerin. Sufferers have defects in highly regenerative tissues such as skin and bone marrow, chromosome instability and a predisposition to develop certain types of malignancy. Dyskerin is a putative pseudouridine synthase, and it has been suggested that DKC may be caused by a defect in ribosomal RNA processing. Here we show that dyskerin is associated not only with H/ACA small nucleolar RNAs, but also with human telomerase RNA, which contains an H/ACA RNA motif. Telomerase adds simple sequence repeats to chromosome ends using an internal region of its RNA as a template, and is required for the indefinite proliferation of primary human cells. We find that primary fibroblasts and lymphoblasts from DKC-affected males are not detectably deficient in conventional H/ACA small nucleolar RNA accumulation or function; however, DKC cells have a lower level of telomerase RNA, produce lower levels of telomerase activity and have shorter telomeres than matched normal cells. The pathology of DKC is consistent with compromised telomerase function leading to a defect in telomere maintenance, which may limit the proliferative capacity of human somatic cells in epithelia and blood.     

Inhibition of telomerase by G-quartet DNA structures

The ends or telomeres of the linear chromosomes of eukaryotes are composed of tandem repeats of short DNA sequences, one strand being rich in guanine (G strand) and the complementary strand in cytosine. Telomere synthesis involves the addition of telomeric repeats to the G strand by telomere terminal transferase (telomerase). Telomeric G-strand DNAs from a variety of organisms adopt compact structures, the most stable of which is explained by the formation of G-quartets. Here we investigate the capacity of the different folded forms of telomeric DNA to serve as primers for the Oxytricha nova telomerase in vitro. Formation of the K(+)-stabilized G-quartet structure in a primer inhibits its use by telomerase. Furthermore, the octanucleotide T4G4, which does not fold, is a better primer than (T4G4)2, which can form a foldback structure. We conclude that telomerase does not require any folding of its DNA primer. Folding of telomeric DNA into G-quartet structures seems to influence the extent of telomere elongation in vitro and might therefore act as a negative regulator of elongation in vivo.     

The human CST complex is a terminator of telomerase activity

The lengths of human telomeres, which protect chromosome ends from degradation and end fusions, are crucial determinants of cell lifespan. During embryogenesis and in cancer, the telomerase enzyme counteracts telomeric DNA shortening. As shown in cancer cells, human telomerase binds the shelterin component TPP1 at telomeres during the S phase of the cell cycle, and adds ~60 nucleotides in a single round of extension, after which telomerase is turned off by unknown mechanisms. Here we show that the human CST (CTC1, STN1 and TEN1) complex, previously implicated in telomere protection and DNA metabolism, inhibits telomerase activity through primer sequestration and physical interaction with the protection of telomeres 1 (POT1)–TPP1 telomerase processivity factor. CST competes with POT1–TPP1 for telomeric DNA, and CST–telomeric-DNA binding increases during late S/G2 phase only on telomerase action, coinciding with telomerase shut-off. Depletion of CST allows excessive telomerase activity, promoting telomere elongation. We propose that through binding of the telomerase-extended telomere, CST limits telomerase action at individual telomeres to approximately one binding and extension event per cell cycle. Our findings define the sequence of events that occur to first enable and then terminate telomerase-mediated telomere elongation.     

Recognition of a chromosome truncation site associated with alpha-thalassaemia by human telomerase

Telomeres define the ends of chromosomes; they consist of short tandemly repeated DNA sequences loosely conserved in eukaryotes (G1-8(T/A)1-4). Telomerase is a ribonucleoprotein which, in vitro, recognizes a single-stranded G-rich telomere primer and adds multiple telomeric repeats to its 3' end by using a template in the RNA moiety. In conjunction with other components, telomerase may balance the loss of telomeric repeats due to DNA replication. Another role of telomerase may be the de novo formation of telomeres. In eukaryotes like Tetrahymena, this process is an integral part of the formation of macronuclear chromosomes. In other eukaryotes this process stabilizes broken chromosomes. A case of human alpha-thalassaemia is caused by a truncation of chromosome 16 that has been healed by the addition of telomeric repeats (TTAGGG)n. Using an in vitro assay, I show here that human telomerase correctly recognizes the chromosome 16 breakpoint sequence and adds (TTAGGG)n repeats. The DNA sequence requirements are minimal and seem to define two modes of DNA recognition by telomerase.     

A telomeric sequence in the RNA of Tetrahymena telomerase required for telomere repeat synthesis

The telomerase enzyme of Tetrahymena synthesizes repeats of the telomeric DNA sequence TTGGGG de novo in the absence of added template. The essential RNA component of this ribonucleoprotein enzyme has now been cloned and found to contain the sequence CAACCCCAA, which seems to be the template for the synthesis of TTGGGG repeats.     

Conditional telomerase induction causes proliferation of hair follicle stem cells

TERT, the protein component of telomerase, serves to maintain telomere function through the de novo addition of telomere repeats to chromosome ends, and is reactivated in 90% of human cancers. In normal tissues, TERT is expressed in stem cells and in progenitor cells, but its role in these compartments is not fully understood. Here we show that conditional transgenic induction of TERT in mouse skin epithelium causes a rapid transition from telogen (the resting phase of the hair follicle cycle) to anagen (the active phase), thereby facilitating robust hair growth. TERT overexpression promotes this developmental transition by causing proliferation of quiescent, multipotent stem cells in the hair follicle bulge region. This new function for TERT does not require the telomerase RNA component, which encodes the template for telomere addition, and therefore operates through a mechanism independent of its activity in synthesizing telomere repeats. These data indicate that, in addition to its established role in extending telomeres, TERT can promote proliferation of resting stem cells through a non-canonical pathway.     

端粒、端粒酶与细胞衰老及肿瘤的研究进展(综述)

端粒是真核生物线形染色体末端的一种特殊的异质化结构,在稳定染色体及防止染色体在复制时缩短方面有重要作用。其行为的异常被认为同细胞衰老及肿瘤的发生发展有密切关系。端粒酶是一个特殊的具有反转录活性的核糖核蛋白。近来的研究表明,端粒酶已不仅仅能维持端粒的长度,它更有助于肿瘤的形成。笔者综述了端粒的缩短所扮演的双重角色,以及端粒酶的激活与肿瘤之间的关系。     

TPP1 is a homologue of ciliate TEBP-beta and interacts with POT1 to recruit telomerase

Telomere dysfunction may result in chromosomal abnormalities, DNA damage responses, and even cancer. Early studies in lower organisms have helped to establish the crucial role of telomerase and telomeric proteins in maintaining telomere length and protecting telomere ends. In Oxytricha nova, telomere G-overhangs are protected by the TEBP-alpha/beta heterodimer. Human telomeres contain duplex telomeric repeats with 3' single-stranded G-overhangs, and may fold into a t-loop structure that helps to shield them from being recognized as DNA breaks. Additionally, the TEBP-alpha homologue, POT1, which binds telomeric single-stranded DNA (ssDNA), associates with multiple telomeric proteins (for example, TPP1, TIN2, TRF1, TRF2 and RAP1) to form the six-protein telosome/shelterin and other subcomplexes. These telomeric protein complexes in turn interact with diverse pathways to form the telomere interactome for telomere maintenance. However, the mechanisms by which the POT1-containing telosome communicates with telomerase to regulate telomeres remain to be elucidated. Here we demonstrate that TPP1 is a putative mammalian homologue of TEBP-beta and contains a predicted amino-terminal oligonucleotide/oligosaccharide binding (OB) fold. TPP1-POT1 association enhanced POT1 affinity for telomeric ssDNA. In addition, the TPP1 OB fold, as well as POT1-TPP1 binding, seemed critical for POT1-mediated telomere-length control and telomere-end protection in human cells. Disruption of POT1-TPP1 interaction by dominant negative TPP1 expression or RNA interference (RNAi) resulted in telomere-length alteration and DNA damage responses. Furthermore, we offer evidence that TPP1 associates with the telomerase in a TPP1-OB-fold-dependent manner, providing a physical link between telomerase and the telosome/shelterin complex. Our findings highlight the critical role of TPP1 in telomere maintenance, and support a yin-yang model in which TPP1 and POT1 function as a unit to protect human telomeres, by both positively and negatively regulating telomerase access to telomere DNA.     

Defects in mismatch repair promote telomerase-independent proliferation

Mismatch repair has a central role in maintaining genomic stability by repairing DNA replication errors and inhibiting recombination between non-identical (homeologous) sequences. Defects in mismatch repair have been linked to certain human cancers, including hereditary non-polyposis colorectal cancer (HNPCC) and sporadic tumours. A crucial requirement for tumour cell proliferation is the maintenance of telomere length, and most tumours achieve this by reactivating telomerase. In both yeast and human cells, however, telomerase-independent telomere maintenance can occur as a result of recombination-dependent exchanges between often imperfectly matched telomeric sequences. Here we show that loss of mismatch-repair function promotes cellular proliferation in the absence of telomerase. Defects in mismatch repair, including mutations that correspond to the same amino-acid changes recovered from HNPCC tumours, enhance telomerase-independent survival in both Saccharomyces cerevisiae and a related budding yeast with a degree of telomere sequence homology that is similar to human telomeres. These results indicate that enhanced telomeric recombination in human cells with mismatch-repair defects may contribute to cell immortalization and hence tumorigenesis.     

The changes in telomerase activity and telomere length in HeLa cells undergoing apoptosis induced by sodium butyrate

The changes in telomerase activity and telomere length during apoptosis in HeLa cells as induced by sodium butyrate (SB) have been studied. After a 48 h SB treatment, HeLa cells demonstrated characteristic apoptotic hallmarks including chromatin condensation, formation of apoptotic bodies and DNA Laddering which were caused by the cleavage and degradation of DNA between nucleosomes. There were no significant changes in telomerase activity of apoptotic cells, while the telomere length shortened markedly. In the meanwhile, cells became more susceptible to apoptotic stimuli and telomere became more vulnerable to degradation after telomerase activity was inhibited. All the results suggest that the apoptosis induced by SB is closely related to telomere shortening, while telomerase enhances resistance of HeLa cells to apoptotic stimuli by protecting telomere.