Aneuploidy and telomere attrition are independent determinants of crisis in SV40-transformed epithelial cells

Replicative immortality is achieved in vitro by overcoming two mortality checkpoints, M1 (senescence) and M2 (crisis). Cancer cells are thought to overcome M2 by activating telomerase, an enzyme believed to confer genomic stability in addition to maintaining telomeric sequences above a critical length. Here we show that a subset of cultured ovarian cystadenoma cells expressing SV40 large T-antigen, which allows bypassing of M1, develop a specific type of genomic instability, characterized by numerical (as opposed to structural) chromosomal alterations, that leads to non-telomere-based premature growth arrest/crisis. Cells recover from this type of growth arrest and stabilize their ploidy status without telomerase expression. In these cases, telomeres continue to shorten until a second, telomere-based growth arrest/crisis event is reached. Transfection of the catalytic subunit of telomerase does not immortalize cells harboring severe abnormalities in their DNA ploidy but results in immortalization of diploid cells. We conclude that changes in DNA ploidy constitute an important determinant of growth arrest that is independent of telomere attrition in a subset of SV40 large T-antigen-expressing cystadenoma cells. Reestablishment or emergence of ploidy stability, which is not always dependent on telomerase activation, is necessary for acquisition of the potential to achieve replicative immortality.     

Telomere dynamics, end-to-end fusions and telomerase activation during the human fibroblast immortalization process.

Loss of telomeric repeats during cell proliferation could play a role in senescence. It has been generally assumed that activation of telomerase prevents further telomere shortening and is essential for cell immortalization. In this study, we performed a detailed cytogenetic and molecular characterization of four SV40 transformed human fibroblastic cell lines by regularly monitoring the size distribution of terminal restriction fragments, telomerase activity and the associated chromosomal instability throughout immortalization. The mean TRF lengths progressively decreased in pre-crisis cells during the lifespan of the cultures. At crisis, telomeres reached a critical size, different among the cell lines, contributing to the peak of dicentric chromosomes, which resulted mostly from telomeric associations. We observed a direct correlation between short telomere length at crisis and chromosomal instability. In two immortal cell lines, although telomerase was detected, mean telomere length still continued to decrease whereas the number of dicentric chromosomes associated was stabilized. Thus telomerase could protect specifically telomeres which have reached a critical size against end-to-end dicentrics, while long telomeres continue to decrease, although at a slower rate as before crisis. This suggests a balance between elongation by telomerase and telomere shortening, towards a stabilized 'optimal' length.     

影响端粒结构和动力学的微演化过程:端粒在癌症中的作用

端粒在基因组稳定、细胞核结构以及减数分裂中染色体配对中发挥关键作用.细胞每分裂一次,端粒会缩短,缩短的端粒可能再延长或不延长,这取决于细胞内是否存在一种专用酶-端粒酶.由于人体的多数体细胞并不表达端粒酶,因此发育和衰老过程中端粒必然缩短.在生理条件下,端粒缩短与延长的细胞增殖相矛盾,因此端粒长度决定了细胞的增殖潜能,并作为细胞无限生长的预防机制.相反,在细胞增殖检查点受破坏的细胞巾,缩短的端粒n『导致染色体融合并启动断裂-融合-桥周期,这极大地促发了基因组不稳定.在体外研究中,转化细胞中由于端粒严重缩短造成的基因组高度不稳定,在这种细胞种蓄积了有害的遗传改变,从而导致细胞最终死亡(危象).同时,随机的遗传或拟遗传学改变可使细胞获得端粒维持机制(以及其它肿瘤表型),从而成为永生细胞.在体内研究中,尽管在早期肿瘤细胞中发现端粒缩短和其它形式的端粒功能障碍可能使基因组不稳定,但端粒功能障碍对于人类肿瘤表型的直接作用有待进一步研究.     

Dysfunctional telomeres promote genomic instability and metastasis in the absence of telomerase activity in oncogene induced mammary cancer

Telomerase is a ribonucleoprotein that maintains the ends of chromosomes (telomeres). In normal cells lacking telomerase activity, telomeres shorten with each cell division because of the inability to completely synthesize the lagging strand. Critically shortened telomeres elicit DNA damage responses and limit cellular division and lifespan, providing an important tumor suppressor function. Most human cancer cells express telomerase which contributes significantly to the tumor phenotype. In human breast cancer, telomerase expression is predictive of clinical outcomes such as lymph node metastasis and survival. In mouse models of mammary cancer, telomerase expression is also upregulated. Telomerase overexpression resulted in spontaneous mammary tumor development in aged female mice. Increased mammary cancer also was observed when telomerase deficient mice were crossed with p53 null mutant animals. However, the effects of telomerase and telomere length on oncogene driven mammary cancer have not been completely characterized. To address these issues we characterized neu proto‐oncogene driven mammary tumor formation in G1 Terc?/? (telomerase deficient with long telomeres), G3 Terc?/? (telomerase deficient with short telomeres), and Terc+/+ mice. Telomerase deficiency reduced the number of mammary tumors and increased tumor latency regardless of telomere length. Decreased tumor formation correlated with increased apoptosis in Terc deficient tumors. Short telomeres dramatically increased lung metastasis which correlated with increased genomic instability, and specific alterations in DNA copy number and gene expression. We concluded that short telomeres promote metastasis in the absence of telomerase activity in neu oncogene driven mammary tumors. © 2011 Wiley Periodicals, Inc.     

Telomere length maintenance in aging and carcinogenesis

Normal somatic cells have a finite number of divisions, a limited capacity to proliferate. Human telomeres, the long DNA TTAGGG repeats at the ends of chromosomes, are considered a molecular clock marker. The gradual and progressive telomere shortening at each replicative cycle is associated, through the activation of pRB and p53 pathways and genomic instability, to the replicative senescence, a non-dividing state and widespread cell death. Activation of telomere maintenance [telomerase; or alternative lengthening of telomeres mechanisms (ALT), or other adaptive responses] can revert this program. Although not completely known, several mechanisms and modulating agents may be able to up and down-regulate telomere length and its maintenance. Chemopreventive therapies for the up-regulation of telomerase activity, able to prolong the life of cell cultures in a phenotypically youthful state, could have important applications in research and medicine. On the contrary the therapeutic down-regulation of telomerase activity may be used in cancer therapy. Telomerase expression per se is not oncogenic, but telomere shortening and maintenance seem to be crucial events in tumor formation. Thus a particular focus has been pointed out relatively to the immortalization of normal or potential pre-cancerous cells. With the extension of life span the probability to get in contact with carcinogens increases, genetic instability, oncogene activation and/or onco-suppressor gene inactivation (i.e. p53, pRB, ras): the cancer transformation can be then induced in predisposed cells, depending on their genetic context, by the activation of telomere maintenance. Pharmacological intervention may be able to modulate the rate of living, by increasing life span of few specific target cells, or decreasing it in proliferating . Because of the unknown state of the enormous cell number of the human organism, is it safe to extend the human life span by therapeutic agents?     

Telomere shortening, telomerase expression, and chromosome instability in rat hepatic epithelial stem-like cells

Telomeres, which are specialized structures consisting of T2AG3 repeats and proteins at the ends of chromosomes, may be essential for genomic stability. To test whether telomere length maintenance preserves genomic stability in rats (Rattus rattus and Fischer 344), we assayed telomerase activity and telomere length in the rat hepatic epithelial stem-like cell line WB-F344 during aging in vitro and in tumor-derived lines. Telomerase activity in the parental WB-F344 line was repressed at low and intermediate passage levels in vitro and reexpressed at high passages. Southern blot hybridization and quantitative fluorescence in situ hybridization analyses demonstrated that telomeres were significantly eroded at intermediate passage levels, when telomerase was repressed, and at high passage levels, when telomerase was expressed. Fluorescence in situ hybridization analysis also revealed interstitial telomeric sequences in rat chromosomes. Tumor-derived WB-F344 cell lines that express telomerase had variably shortened telomeres. Cytogenetic analyses performed on WB-F344 cells at low, intermediate, and high passages demonstrated that chromosome instability was most severe in the intermediate passage cells. These data suggest that telomere shortening during aging of rat hepatic epithelial stem-like WB-F344 cells in vitro and during selection of tumorigenic lines in vivo may destabilize chromosomes. Expression of telomerase in high passage cells appeared to partially stabilize chromosomes.     

Low telomerase activity: possible role in the progression of human medullary thyroid carcinoma

Maintenance of telomere length has been reported to be an absolute requirement for unlimited growth of human tumour cells and in about 85% of cases, this is achieved by reactivation of telomerase, the enzyme that elongates telomeres. Only in rare cases, like in human medullary thyroid carcinomas (MTC), telomerase activity (TA) is low or undetectable; however, this does not limit tumours to become clinically significant. Here, we report that very low TA (below 5% of HEK293) observed in MTC cell strains derived from different patients, although not sufficient for immortalising the cells, is necessary for prolonging their replicative life span. Telomere erosion led to induction of a crisis period after long-term in vitro cultivation, which was reached earlier when treating the cells with MST-312, a telomerase inhibitor at non-toxic concentrations. Crisis was bypassed either by ectopic hTERT introduction or by infrequent spontaneous immortalisation, the latter of which was always associated with telomerase reactivation and changes of the cellular phenotype. While confirming the high importance of telomerase for tumour development, these data draw attention to the relevance of low TA: although insufficient for telomere stabilisation, it allows MTC cells to reach more population doublings, increasing both cell numbers as well as the risk of accumulating mutations and thus might support the development of clinically significant MTC.     

Recent advances in telomere biology: implications for human cancer

PURPOSE OF REVIEW: Research into the basic biology of telomeres continues to reveal details relevant to fundamental aspects of human cancer. The goal of this review is to highlight discoveries made within the last year, with emphasis on their relevance to cancer prevention, diagnosis, prognostics, and treatment. RECENT FINDINGS: Increasing evidence indicates that dysfunctional telomeres likely play a causal role in the process of malignant transformation, in at least a fraction of human cancers, by initiating chromosomal instability. Telomeres form protective capping structures composed of telomeric DNA complexed with a multitude of associated proteins, the loss of which can have profound effects on telomeric stability. Critical telomeric shortening can lead to telomere "uncapping" and may occur at the earliest recognizable stages of malignant transformation in epithelial tissues. The widespread activation of the telomere synthesizing enzyme telomerase in human cancers not only confers unlimited replicative potential but also prevents intolerable levels of chromosomal instability. Several details regarding telomere structure and telomerase regulation have recently been elucidated, providing new targets for therapeutic exploitation. Various therapeutic strategies aimed at either telomerase or its telomeric substrate are showing promise and may synergize with established anti-cancer agents. Further support for anti-telomerase approaches comes from recent studies indicating that telomerase may possess additional functions, beyond telomere maintenance, that support the growth and survival of tumor cells. SUMMARY: Substantial progress has been made in understanding the complex relationships that exist between telomeres and cancer. However, important issues, such as transient activation of telomerase in normal cells and the potential for tumor cell immortalization via telomerase independent means, remain to be clarified.     

The shortest telomeres drive karyotype evolution in transformed cells

Maintenance of telomeres is essential for chromosome stability. In the absence of telomerase, telomeres shorten with cell division until they approach a stability threshold, at which point cells enter senescence. When senescence-signaling pathways are inactive, further telomere shortening leads to chromosome instability characterized by telomeric fusions and breakage-fusion-bridge (BFB) cycles. Since the distribution of telomere lengths among chromosome extremities is heterogeneous, we wondered about the impact of such variability on the stability of particular chromosome arms. We correlated the initial length of individual telomeres in telomerase-negative-transformed cells with the stability of the corresponding chromosome arms during the precrisis period. We show that arms carrying the shortest telomeres are the first to become unstable and this instability affects the chromosome homologues with shorter telomeres almost exclusively. The analysis of several postcrisis cell populations, which had stabilized their telomeres by re-expressing telomerase, showed that the karyotypic outcome is strongly influenced by the initial telomere length heterogeneity. The timing of telomerase re-expression also seems to play a role in limiting the extent of karyotypic changes, probably by reducing the frequency of telomeric fusions and hence BFB. Since the distribution of telomere lengths within somatic cells is proper to every individual, our results predict that the risk for a particular chromosome arm of becoming unstable early in tumorigenesis will differ between individuals and contribute directly to the heterogeneity of chromosome aberrations found in tumors.     

Short telomeres result in chromosomal instability in hematopoietic cells and precede malignant evolution in human aplastic anemia

In cell and animal models, telomere erosion promotes chromosomal instability via breakage-fusion-bridge cycles, contributing to the early stages of tumorigenesis. However, evidence involving short telomeres in cancer development in humans is scarce, epidemiological and indirect. Here we directly implicate telomere shortening as a critical molecular event for malignant evolution in aplastic anemia (AA). Patients' telomere lengths at diagnosis of AA, while comparable to age-matched controls, inversely correlated with the probability of developing a cytogenetically abnormal clone. A significantly increased number of telomere signal-free chromosomal ends and chromosomal numerical and structural abnormalities were observed in bone marrow cells of patients with shorter telomeres in comparison with patients with longer telomeres and healthy subjects. The proportion of monosomy-7 cells in the bone marrow at diagnosis of AA inversely correlated with telomere length, years before the emergence of an autonomous and clinically detectable abnormal clone. Marrow cells of clinically healthy individuals carrying loss-of-function telomerase mutations and with extremely short telomeres also showed chromosomal instability in vitro. These results provide the first clinical direct evidence in humans that short telomeres in hematopoietic cells are dysfunctional, mediate chromosomal instability and predispose to malignant transformation in a human disease.     

Haploinsufficiency of hTERT leads to telomere dysfunction and radiosensitivity in human cancer cells

One of the most consistent differences between cancer cells and normal somatic cells is the continuous expression of telomerase, an enzyme that is important for maintenance of chromosome ends, or telomeres. It is believed that telomerase expression allows cancer cells to maintain their telomeres after many cell divisions and thereby avoid replicative senescence. We have tested this hypothesis by targeting the gene encoding the catalytic subunit of the telomerase holoenzyme, hTERT, in a human cancer cell line. Heterozygous disruption of hTERT led to a reduction in telomerase activity, telomere shortening, activation of DNA damage signaling and the appearance of a subpopulation of cells that displayed features of senescence. Targeted cells were radiosensitive, as compared with parental controls that had two intact hTERT alleles, and expressed a classical marker of senescence after irradiation. These results suggest that telomerase inhibitors might be useful in the sensitization of cancer cells to DNA damaging agents.     

Involvement of WRN helicase in immortalization and tumorigenesis by the telomeric crisis pathway (Review)

The repeated replication of cells shortens telomeres, culminating in their instability, after which most cells cease to replicate and die. However, a small fraction of the cells become immortalized by maintaining telomeres with activated telomerase activity. It has been proposed that WRN helicase encoded by the WRN gene, the causative gene of Werner syndrome (WS), is required for immortalization by the telomeric crisis pathway (TCP) in a system that uses lymphoblastoid cell lines transformed by the Epstein-Barr virus. Taken together, these characteristics indicate that WRN helicase is also required for the immortalization of epithelial cells by TCP and consequent carcinogenesis, suggesting that the tumorigenesis of epithelial cells by TCP is suppressed in WS lacking the WRN helicase function. Notably, in WS the pathway of alternative lengthening of telomeres without activation of telomerase activity has been suggested to be involved in immortalization and tumorigenesis. This factor is consistent with the abundance of non-epithelial cancers in WS in that the ratio of epithelial to non-epithelial cancers is approximately 1:1 in WS patients compared to 10:1 in the general population. A hypothetical scheme showing the role of WRN helicase in immortalization by means of the supposed 'breakage-fusion-bridge cycle' of chromosomes at telomeric crisis is described.     

A telomere-independent senescence mechanism is the sole barrier to Syrian hamster cell immortalization

Reactivation of telomerase and stabilization of telomeres occur simultaneously during human cell immortalization in vitro and the vast majority of human cancers possess high levels of telomerase activity. Telomerase repression in human somatic cells may therefore have evolved as a powerful resistance mechanism against immortalization, clonal evolution and malignant progression. The comparative ease with which rodent cells immortalize in vitro suggests that they have less stringent controls over replicative senescence than human cells. Here, we report that Syrian hamster dermal fibroblasts possess substantial levels of telomerase activity throughout their culture life-span, even after growth arrest in senescence. In our studies, telomerase was also detected in uncultured newborn hamster skin, in several adult tissues, and in cultured fibroblasts induced to enter the post-mitotic state irreversibly by serum withdrawal. Transfection of near-senescent dermal fibroblasts with a selectable plasmid vector expressing the SV40 T-antigen gene resulted in high-frequency single-step immortalization without the crisis typically observed during the immortalization of human cells. Collectively, these data provide an explanation for the increased susceptibility of rodent cells to immortalization (and malignant transformation) compared with their human equivalents, and provide evidence for a novel, growth factor-sensitive, mammalian senescence mechanism unrelated to telomere maintenance.