Telomerase with mutated catalytic motifs has dominant negative effects on telomerase activity and inhibits cell growth

Telomerase catalytic subunit (TERT) seems a key factor controlling telomerase activity, telomere length, and cell growth. To further address this issue, we forced expression of a catalytically inactive mutant human TERT (hTERT) in hTERT-immortalised sheep fibroblasts to examine its effects. Expression of mutant hTERT compromised telomerase activity reconstituted by wild-type hTERT in a manner directly attributable to mutant hTERT expression level. High levels of mutant hTERT expression inhibited cell growth with a subset of cells entering replicative senescence. Furthermore, significant telomere attrition was evident in two of three clones with high levels of mutant hTERT expression. Our findings are consistent with the notion that hTERT homodimers are necessarily required to form a functional telomerase complex at the telomere substrate. We also highlight the requirement of a more thorough understanding of telomerase- and telomere-associated factors to understand fully the interplay that governs telomere homeostasis in vitro and in vivo.     

Stabilization of telomere length and karyotypic stability are directly correlated with the level of hTERT gene expression in primary fibroblasts

Telomere shortening and lack of telomerase activity have been implicated in cellular senescence in human fibroblasts. Expression of the human telomerase (hTERT) gene in sheep fibroblasts reconstitutes telomerase activity and extends their lifespan. However, telomere length is not maintained in all cell lines, even though in vitro telomerase activity is restored in all of them. Cell lines expressing higher levels of hTERT mRNA do not exhibit telomere erosion or genomic instability. By contrast, fibroblasts expressing lower levels of hTERT do exhibit telomere shortening, although the telomeres eventually stabilize at a shorter length. The shorter telomere lengths and the extent of karyotypic abnormalities are both functions of hTERT expression level. We conclude that telomerase activity is required to bypass senescence but is not sufficient to prevent telomere erosion and genomic instability at lower levels of expression.     

端粒酶活性调节的分子机制

人端粒酶由RNA亚基、hTERT催化亚基和hTEP1调节蛋白等组成。端粒酶对端粒结构的稳定起着重要的作用,而端粒结构和端粒结合蛋白也影响着端粒酶活性。某些化疗药物通过破坏端粒结构下调端粒酶活性。端粒酶的激活需要hTERT基因的从头转录和各个蛋白亚基正确装配为端粒酶全酶。端粒酶活性调节的分子机制包括：（1）TERT基因的表达和转录是决定端粒酶活性的重要环节,受多种因素调控;（2）蛋白激酶Cα和蛋白激酶B磷酸化端粒酶蛋白而激活端粒酶,蛋白磷酸酯酶2A（PP2A）可逆转这一过程,下调端粒酶活性;（3）多种癌基因和抑癌基因及其编码的蛋白质也直接或间接与端粒蛋白、端粒酶蛋白反应,参与端粒酶活性的调控。     

Suppression of hPOT1 in diploid human cells results in an hTERT-dependent alteration of telomere length dynamics

POT1 is a 3' telomeric single-stranded overhang binding protein that has been implicated in chromosome end protection, the regulation of telomerase function, and defining the 5' chromosome terminus. In human cancer cells that exhibit constitutive hTERT activity, hPOT1 exerts control over telomere length. Primary human fibroblasts express low levels of catalytically active hTERT in an S-phase-restricted manner that fails to counteract telomere attrition with cell division. Here, we show that diploid human fibroblasts in which hPOT1 expression has been suppressed harbor telomeres that are longer than control cells. This difference in telomere length delays the onset of replicative senescence and is dependent on S-phase-restricted hTERT expression. These findings are consistent with the view that hPOT1 promotes a nonextendable telomere state resistant to extension by S-phase-restricted telomerase. Manipulating this function of hPOT1 may thus hasten the cytotoxic effects of telomerase inhibition.     

Non-telomeric activities of telomerase

Recent results suggest that telomerase is involved in many more cellular processes than merely telomere elongation. These include telomere-independent anti-apoptotic, cytoprotective and pro-proliferative effects of telomerase or protection of mitochondrial DNA against oxidative stress. Telomerase also participates in DNA repair and its essential subunits, hTR and hTERT, are able to modulate independently the cell's response to DNA damage. Recent high throughput analyses of gene expression showed that hTERT expression modulates expression of about 300 genes, including genes involved in the regulation of cell cycle progression, proliferation and differentiation. Besides the well-known telomerase catalytic activity of RNA-dependent DNA polymerase, its RNA-dependent RNA polymerase activity was recently described in association with the RNA subunit of mitochondrial RNA processing endoribonuclease, thus suggesting involvement of telomerase in RNA interference processes. These recent discoveries open novel possibilities and entirely unexpected research perspectives, branching off from the mainstream telomere and telomerase research.     

Catalytically active human telomerase mutants with allele-specific biological properties

Expression of the catalytic subunit of human telomerase, hTERT, extends human primary fibroblast life span. Such life span extension has generally been reported to be accompanied by net telomere lengthening, which led to the hypothesis that it is the telomere lengthening that causes the life span extension. Here we show that hTERT+C and hTERT-FlagC, mutant telomerase proteins with either 10 additional residues or a FLAG epitope added to the hTERT C-terminus, confer significant but limited life span extension to IMR90 human primary lung fibroblasts. However, as the cells continue to grow for >100 population doublings past their normal senescence point, bulk telomere length continues to erode to lengths much shorter than those seen at the senescence of control telomerase-negative cells. Expression of hTERT+C immortalized IMR90 cells transformed by three different oncogenes. Again, bulk telomeres became much shorter than those of the control cells at crisis. Additional hTERT mutants were constructed and analyzed similarly. Enzymatically active hTERT-N125A+T126A, like other previously reported conserved GQ domain mutants and C-terminally HA-tagged hTERT, failed to extend life span. Another GQ domain mutant, hTERT-E79A, was indistinguishable from wild-type hTERT in its cell growth effects, but there was no net telomere lengthening. These results uncover further hTERT allele-specific phenotypes that uncouple telomerase activity, net telomere lengthening and life span extension.     

Metastases suppressor NME2 associates with telomere ends and telomerase and reduces telomerase activity within cells

Analysis of chromatin-immunoprecipitation followed by sequencing (ChIP-seq) usually disregards sequence reads that do not map within binding positions (peaks). Using an unbiased approach, we analysed all reads, both that mapped and ones that were not included as part of peaks. ChIP-seq experiments were performed in human lung adenocarcinoma and fibrosarcoma cells for the metastasis suppressor non-metastatic 2 (NME2). Surprisingly, we identified sequence reads that uniquely represented human telomere ends in both cases. In vivo presence of NME2 at telomere ends was validated using independent methods and as further evidence we found intranuclear association of NME2 and the telomere repeat binding factor 2. Most remarkably, results demonstrate that NME2 associates with telomerase and reduces telomerase activity in vitro and in vivo, and sustained NME2 expression resulted in reduced telomere length in aggressive human cancer cells. Anti-metastatic function of NME2 has been demonstrated in human cancers, however, mechanisms are poorly understood. Together, findings reported here suggest a novel role for NME2 as a telomere binding protein that can alter telomerase function and telomere length. This presents an opportunity to investigate telomere-related interactions in metastasis suppression.     

Coexistence of alternative lengthening of telomeres and telomerase in hTERT-transfected GM847 cells

It has been shown previously that some immortalized human cells maintain their telomeres in the absence of significant levels of telomerase activity by a mechanism referred to as alternative lengthening of telomeres (ALT). Cells utilizing ALT have telomeres of very heterogeneous length, ranging from very short to very long. Here we report the effect of telomerase expression in the ALT cell line GM847. Expression of exogenous hTERT in GM847 (GM847/hTERT) cells resulted in lengthening of the shortest telomeres; this is the first evidence that expression of hTERT in ALT cells can induce telomerase that is active at the telomere. However, rapid fluctuation in telomere length still occurred in the GM847/hTERT cells after more than 100 population doublings. Very long telomeres and ALT-associated promyelocytic leukemia (PML) bodies continued to be generated, indicating that telomerase activity induced by exogenous hTERT did not abolish the ALT mechanism. In contrast, when the GM847 cell line was fused with two different telomerase-positive tumor cell lines, the ALT phenotype was repressed in each case. These hybrid cells were telomerase positive, and the telomeres decreased in length, very rapidly at first and then at the rate seen in telomerase-negative normal cells. Additionally, ALT-associated PML bodies disappeared. After the telomeres had shortened sufficiently, they were maintained at a stable length by telomerase. Together these data indicate that the telomerase-positive cells contain a factor that represses the ALT mechanism but that this factor is unlikely to be telomerase. Further, the transfection data indicate that ALT and telomerase can coexist in the same cells.     

骨肿瘤端粒长度变化与相关蛋白表达的关系

目的:研究骨肿瘤端粒长度变化与端粒结合蛋白即端粒重复结合因子1(TRF1)和端粒保护因子(POT1),端粒酶催化亚单位(hTERT),肿瘤相关基因P53、c-myc表达的关系,以了解骨肿瘤的分子特征。方法:采用免疫组织化学、端粒定量荧光原位杂交(Telo-FISH)和原位杂交检测了20例骨肉瘤、25例软骨肉瘤、14例骨的纤维结构不良中端粒长度、TRF1、POT1、hTERT、P53、c-myc的表达情况,并进行统计分析。结果:20例骨肉瘤平均长度为0.31,25例软骨肉瘤为0.41,14例骨的纤维结构不良为0.52。统计显示三者间端粒长度有显著差异(P<0.05)。骨肉瘤和软骨肉瘤TRF1、POT1阳性率均显著低于骨纤维结构不良(P<0.05)。而骨肉瘤和软骨肉瘤hTERT基因表达显著高于骨纤维结构不良(P<0.05)。骨肉瘤、软骨肉瘤P53、c-myc阳性率高于骨纤维结构不良(P<0.05)。统计分析骨肿瘤端粒长度变化与端粒结合蛋白TRF1、POT1的表达呈负相关性,与端粒酶hTERT基因表达、与P53蛋白核聚积,以及c-myc癌基因表达呈正相关性。结论:骨肿瘤端粒长度与恶性表型有关、端粒短缩与肿瘤基因突变相关。     

Telomerase enzymatic component hTERT shortens long telomeres in human cells

Telomere lengths are tightly regulated within a narrow range in normal human cells. Previous studies have extensively focused on how short telomeres are extended and have demonstrated that telomerase plays a central role in elongating short telomeres. However, much about the molecular mechanisms of regulating excessively long telomeres is unknown. In this report, we demonstrated that the telomerase enzymatic component, hTERT, plays a dual role in the regulation of telomere length. It shortens excessively long telomeres and elongates short telomeres simultaneously in one cell, maintaining the optimal telomere length at each chromosomal end for efficient protection. This novel hTERT-mediated telomere-shortening mechanism not only exists in cancer cells, but also in primary human cells. The hTERT-mediated telomere shortening requires hTERT’s enzymatic activity, but the telomerase RNA component, hTR, is not involved in that process. We found that expression of hTERT increases telomeric circular DNA formation, suggesting that telomere homologous recombination is involved in the telomere-shortening process. We further demonstrated that shelterin protein TPP1 interacts with hTERT and recruits hTERT onto the telomeres, suggesting that TPP1 might be involved in regulation of telomere shortening. This study reveals a novel function of hTERT in telomere length regulation and adds a new element to the current molecular model of telomere length maintenance.