The catalytic and the RNA subunits of human telomerase are required to immortalize equid primary fibroblasts

Many human primary somatic cells can be immortalized by inducing telomerase activity through the exogenous expression of the human telomerase catalytic subunit (hTERT). This approach has been extended to the immortalization of cell lines from several mammals. Here, we show that hTERT expression is not sufficient to immortalize primary fibroblasts from three equid species, namely donkey, Burchelli’s zebra and Grevy’s zebra. In vitro analysis of a reconstituted telomerase composed by hTERT and an equid RNA component of telomerase (TERC) revealed a low activity of this enzyme compared to human telomerase, suggesting a low compatibility of equid and human telomerase subunits. This conclusion was also strengthened by comparison of human and equid TERC sequences, which revealed nucleotide differences in key regions for TERC and TERT interaction. We then succeeded in immortalizing equid fibroblasts by expressing hTERT and hTERC concomitantly. Expression of both human telomerase subunits led to telomerase activity and telomere elongation, indicating that human telomerase is compatible with the other equid telomerase subunits and proteins involved in telomere metabolism. The immortalization procedure described herein could be extended to primary cells from other mammals. The availability of immortal cells from endangered species could be particularly useful for obtaining new information on the organization and function of their genomes, which is relevant for their preservation.     

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.     

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.     

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.     

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.     

Telomerase expression prevents replicative senescence but does not fully reset mRNA expression patterns in Werner syndrome cell strains.

Reduced replicative capacity is a consistent characteristic of cells derived from patients with Werner syndrome. This premature senescence is phenotypically similar to replicative senescence observed in normal cell strains and includes altered cell morphology and gene expression patterns. Telomeres shorten with in vitro passaging of both WRN and normal cell strains; however, the rate of shortening has been reported to be faster in WRN cell strains, and the length of telomeres in senescent WRN cells appears to be longer than that observed in normal strains, leading to the suggestion that senescence in WRN cell strains may not be exclusively associated with telomere effects. We report here that the telomere restriction fragment length in senescent WRN fibroblasts cultures is within the size range observed for normal fibroblasts strains and that the expression of a telomerase transgene in WRN cell strains results in lengthened telomeres and replicative immortalization, thus indicating that telomere effects are the predominant trigger of premature senescence in WRN cells. Microarray analyses showed that mRNA expression patterns induced in senescent WRN cells appeared similar to those in normal strains and that hTERT expression could prevent the induction of most of these genes. However, substantial differences in expression were seen in comparisons of early-passage and telomerase-immortalized derivative lines, indicating that telomerase expression does not prevent the phenotypic drift, or destabilized genotype, resulting from the WRN defect.     

Genes involved in differentiation, stem cell renewal, and tumorigenesis are modulated in telomerase-immortalized human urothelial cells

The expression of hTERT, the catalytic subunit of telomerase, immortalizes normal human urothelial cells (NHUC). Expression of a modified hTERT, without the ability to act in telomere maintenance, did not immortalize NHUC, confirming that effects at telomeres are required for urothelial immortalization. Previous studies indicate that inhibition of telomerase has an immediate effect on urothelial carcinoma (UC) cell line viability, before sufficient divisions to account for telomere attrition, implicating non-telomere effects of telomerase in UC. We analyzed the effects of telomerase on gene expression in isogenic mortal and hTERT-transduced NHUC. hTERT expression led to consistent alterations in the expression of genes predicted to be of phenotypic significance in tumorigenesis. A subset of expression changes were detected soon after transduction with hTERT and persisted with continued culture. These genes (NME5, PSCA, TSPYL5, LY75, IGFBP2, IGF2, CEACAM6, XG, NOX5, KAL1, and HPGD) include eight previously identified as polycomb group targets. TERT-NHUC showed overexpression of the polycomb repressor complex (PRC1 and PRC4) components, BMI1 and SIRT1, and down-regulation of multiple PRC targets and genes associated with differentiation. TERT-NHUC at 100 population doublings, but not soon after transduction, showed increased saturation density and an attenuated differentiation response, indicating that these are not acute effects of telomerase expression. Some of the changes in gene expression identified may contribute to tumorigenesis. Expression of NME5 and NDN was down-regulated in UC cell lines and tumors. Our data supports the concept of both telomere-based and non-telomere effects of telomerase and provides further rationale for the use of telomerase inhibitors in UC.     

Mass cultured human fibroblasts overexpressing hTERT encounter a growth crisis following an extended period of proliferation

During the process of immortalization, at least two mortality checkpoints, M1 and M2, must be bypassed. Cells that have bypassed M1 (senescence) have an extended life span, but are not necessarily immortal. Recent studies have shown that ectopic expression of the catalytic subunit of telomerase (hTERT) enables normal human cells to bypass senescence (M1) and oncogene transformed cells to avert crisis (M2) and become immortal. However, it is unclear whether hTERT expression is sufficient for normal human fibroblasts to overcome both M1 and M2 and become immortal. We have investigated the role of telomerase in immortalization by maintaining mass cultures of hTERT-transduced primary human fetal lung fibroblasts (MRC-5 cells) for very long periods of time (more than 2 years). In the present studies, up to 70% of MRC-5 cells were transduced with retroviral vectors that express hTERT. hTERT-transduced cells exhibited high levels of telomerase activity, elongation of telomeres, and proliferation beyond senescence. However, after proliferating for more than 36 population doublings (PDLs) beyond senescence, the overall growth rate of hTERT-expressing cells declined. During theses periods of reduced growth, hTERT-transduced MRC-5 cells exhibited features typical of cells in crisis, including an increased rate of cell death and polyploidy. In some instances, very late passage cells acquired a senescence-like phenotype characterized by arrest in the G1 phase of the cell cycle and greatly reduced DNA synthesis. At the onset of crisis, hTERT-transduced cells expressed high levels of telomerase and had very long telomeres, ranging up to 30 kb. Not all cells succumbed to crisis and, consequently, some cultures have proliferated beyond 240 PDLs, while another culture appears to be permanently arrested at 160 PDLs. Late passage MRC-5 cells, including postcrisis cells, displayed no signs of malignant transformation. Our results are consistent with the model in which telomerase and telomere elongation greatly extends cellular life span without inducing malignant changes. However, these investigations also indicate that hTERT-expressing cells may undergo crisis following an extended life span and that immortality is not the universal outcome of hTERT expression in normal diploid fibroblasts.     

Telomerase can extend the proliferative capacity of human myoblasts,but does not lead to their immortalization

Normal cells in culture display a limited capacity to divide and reach a non-proliferative state called cellular senescence. Spontaneous escape from senescence resulting in an indefinite life span is an exceptionally rare event for normal human cells and viral oncoproteins have been shown to extend the replicative life span but not to immortalize them. Telomere shortening has been proposed as a mitotic clock that regulates cellular senescence. Telomerase is capable of synthesizing telomere repeats onto chromosome ends to block telomere shortening and to maintain human fibroblasts in proliferation beyond their usual life span. However, the consequence of telomerase expression on the life span of human myoblasts and on their differentiation is unknown. In this study, the telomerase gene and the puromycin resistance gene were introduced into human satellite cells, which are the natural muscle precursors (myoblasts) in the adult and therefore, a target for cell-mediated gene therapy. Satellite cells expressing telomerase were selected, and the effects of the expression of the telomerase gene on proliferation, telomere length, and differentiation were investigated. Our results show that the telomerase-expressing cells are able to differentiate and to form multinucleated myotubes expressing mature muscle markers and do not form tumors in vivo. We also demonstrated that the expression of hTERT can extend the replicative life of muscle cells although these failed to undergo immortalization.     

Human keratinocytes that express hTERT and also bypass a p16(INK4a)-enforced mechanism that limits life span become immortal yet retain normal growth and differentiation characteristics

Normal human cells exhibit a limited replicative life span in culture, eventually arresting growth by a process termed senescence. Progressive telomere shortening appears to trigger senescence in normal human fibroblasts and retinal pigment epithelial cells, as ectopic expression of the telomerase catalytic subunit, hTERT, immortalizes these cell types directly. Telomerase expression alone is insufficient to enable certain other cell types to evade senescence, however. Such cells, including keratinocytes and mammary epithelial cells, appear to require loss of the pRB/p16(INK4a) cell cycle control mechanism in addition to hTERT expression to achieve immortality. To investigate the relationships among telomerase activity, cell cycle control, senescence, and differentiation, we expressed hTERT in two epithelial cell types, keratinocytes and mesothelial cells, and determined the effect on proliferation potential and on the function of cell-type-specific growth control and differentiation systems. Ectopic hTERT expression immortalized normal mesothelial cells and a premalignant, p16(INK4a)-negative keratinocyte line. In contrast, when four keratinocyte strains cultured from normal tissue were transduced to express hTERT, they were incompletely rescued from senescence. After reaching the population doubling limit of their parent cell strains, hTERT(+) keratinocytes entered a slow growth phase of indefinite length, from which rare, rapidly dividing immortal cells emerged. These immortal cell lines frequently had sustained deletions of the CDK2NA/INK4A locus or otherwise were deficient in p16(INK4a) expression. They nevertheless typically retained other keratinocyte growth controls and differentiated normally in culture and in xenografts. Thus, keratinocyte replicative potential is limited by a p16(INK4a)-dependent mechanism, the activation of which can occur independent of telomere length. Abrogation of this mechanism together with telomerase expression immortalizes keratinocytes without affecting other major growth control or differentiation systems.