Inhibition of telomerase activity and human telomerase reverse transcriptase gene expression by histone deacetylase inhibitor in human brain cancer cells

The aim of the present study is to investigate the effect of histone deacetylase inhibitor, trichostatin A (TSA) on the cell growth, apoptosis, genomic DNA damage and the expression of telomerase and associated factors in human normal and brain cancer cells. Here, human normal un-transformed fibroblasts (MRC-5), human normal hTERT-immortalised fibroblasts (hTERT-BJ1) and human brain cancer cell lines (glioblastoma cell line, A-172 and medulloblastoma cell line, ONS-76) were treated with 0.5–3.0 μM TSA for 24 h. Exposure to TSA resulted in apoptosis in a dose-dependent manner in the brain cancer cells. Glioblastoma cell line (A-172) displayed higher sensitivity to TSA-induced cell killing effect and apoptosis than the medulloblastoma cell line (ONS-76). The brain cancer cell lines and hTERT-BJ1 cell line displayed significant inhibition in telomerase activity and hTERT mRNA level after 2 μM TSA treatment. Elevated expressions of p53 and p21 with a decrease in cyclin-D level supported the observation on cell cycle arrest following TSA treatment. Upregulation of Bax and cytochrome c correlated with the apoptotic events in TSA-treated cells. This study suggests that telomerase and hTERT might be the primary targets of TSA which may have the potential to be used as a telomerase inhibitor in cancer therapy.     

Ectopic human telomerase catalytic subunit expression maintains telomere length but is not sufficient for CD8+ T lymphocyte immortalization

Like most somatic human cells, T lymphocytes have a limited replicative life span. This phenomenon, called senescence, presents a serious barrier to clinical applications that require large numbers of Ag-specific T cells such as adoptive transfer therapy. Ectopic expression of hTERT, the human catalytic subunit of the enzyme telomerase, permits fibroblasts and endothelial cells to avoid senescence and to become immortal. In an attempt to immortalize normal human CD8(+) T lymphocytes, we infected bulk cultures or clones of these cells with a retrovirus transducing an hTERT cDNA clone. More than 90% of transduced cells expressed the transgene, and the cell populations contained high levels of telomerase activity. Measuring the content of total telomere repeats in individual cells (by flowFISH) we found that ectopic hTERT expression reversed the gradual loss of telomeric DNA observed in control populations during long term culture. Telomere length in transduced cells reached the levels observed in freshly isolated normal CD8(+) lymphocytes. Nevertheless, all hTERT-transduced populations stopped to divide at the same time as nontransduced or vector-transduced control cells. When kept in IL-2 the arrested cells remained alive. Our results indicate that hTERT may be required but is not sufficient to immortalize human T lymphocytes.     

Expression of human telomerase (hTERT) does not prevent stress-induced senescence in normal human fibroblasts but protects the cells from stress-induced apoptosis and necrosis

Cells subjected to sub-lethal doses of stress such as irradiation or oxidative damage enter a state that closely resembles replicative senescence. What triggers stress-induced premature senescence (SIPS) and how similar this mechanism is to replicative senescence are not well understood. It has been suggested that stress-induced senescence is caused by rapid telomere shortening resulting from DNA damage. In order to test this hypothesis directly, we examined whether overexpression of the catalytic subunit of human telomerase (hTERT) can protect cells from SIPS. We therefore analyzed the response of four different lines of normal human fibroblasts with and without hTERT to stress induced by UV, gamma-irradiation, and H(2)O(2). SIPS was induced with the same efficiency in normal and hTERT-immortalized cells. This suggests that SIPS is not triggered by telomere shortening and that nonspecific DNA damage serves as a signal for induction of SIPS. Although telomerase did not protect cells from SIPS, fibroblasts expressing hTERT were more resistant to stress-induced apoptosis and necrosis. We hypothesize that healing of DNA breaks by telomerase inhibits the induction of cell death, but because healing does not provide legitimate DNA repair, it does not protect cells from SIPS.     

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.     

Human fibroblasts expressing hTERT show remarkable karyotype stability even after exposure to ionizing radiation

Ectopic expression of telomerase results in an immortal phenotype in various types of normal cells, including primary human fibroblasts. In addition to its role in telomere lengthening, telomerase has now been found to have various functions, including the control of DNA repair, chromatin modification, and the control of expression of genes involved in cell cycle regulation. The investigations on the long-term effects of telomerase expression in normal human fibroblast highlighted that these cells show low frequencies of chromosomal aberrations. In this paper, we describe the karyotypic stability of human fibroblasts immortalized by expression of hTERT. The ectopic overexpression of telomerase is associated with unusual spontaneous as well as radiation-induced chromosome stability. In addition, we found that irradiation did not enhance plasmid integration in cells expressing hTERT, as has been reported for other cell types. Long-term studies illustrated that human fibroblasts immortalized by telomerase show an unusual stability for chromosomes and for plasmid integration sites, both with and without exposure to ionizing radiation. These results confirm a role for telomerase in genome stabilisation by a telomere-independent mechanism and point to the possibility for utilizing hTERT-immortalized normal human cells for the study of gene targeting.     

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.     

Transient expression of human telomerase extends the life span of normal human fibroblasts

We utilized the Cre/lox recombination system to transiently express the catalytic subunit of telomerase (hTERT) in normal diploid foreskin fibroblasts (BJ cells). A retroviral construct containing an hTERT cDNA, flanked by loxP-sites was introduced into near senescent BJ cells (population doubling 85). At population doubling (PD) 92, which exceeds the typical life span of these cells, we excised the gene via Cre-mediated recombination. All clones lost telomerase activity and showed telomere shortening over an additional 50 PDs. Interestingly, the average telomere length in these cells became shorter than in untreated BJ cells at senescence. This may be due to hTERT preferentially elongating the shortest telomeres, leading to greater length uniformity. In summary, transient telomerase expression and only a very small average telomere elongation by hTERT resulted in a 50% increase in life span of human fibroblasts. This suggests a potentially safe use of hTERT in tissue engineering.     

Evidence that high telomerase activity may induce a senescent-like growth arrest in human fibroblasts

Expression of the catalytic subunit of human telomerase (hTERT), in normal human fibroblasts allows them to escape replicative senescence. However, we have observed that populations of hTERT-immortalized human fibroblasts contain 3-20% cells with a senescent morphology. To determine what causes the appearance of these senescent-like cells, we used flow cytometry to select them from the population and analyzed them for various senescence markers, telomere length, and telomerase activity. This subpopulation of cells had elevated levels of p21 and hypophosphorylated Rb, but telomere length was similar to that of the immortal cells in the culture that was sorted. Surprisingly, telomerase activity in the senescent-like cells was significantly elevated compared with immortal cells from the same population, suggesting that high telomerase activity may induce the senescent phenotype. Furthermore, transfection of normal fibroblasts with a hTERT-expressing plasmid that confers high telomerase activity led to the induction of p21, a higher percentage of SA-beta-galactosidase-positive cells, and a greater number of cells entering growth arrest compared with controls. These results suggest that excessive telomerase activity may act as a hyperproliferative signal in cells and induce a senescent phenotype in a manner similar to that seen following overexpression of oncogenic Ras, Raf, and E2F1. Thus, there must be a critical threshold of telomerase activity that permits cell proliferation.     

Human diploid fibroblasts are refractory to oncogene-mediated transformation

It has long been known that human cells are more refractory than rodent cells against oncogenic transformation in vitro. Recent success to make normal human cells susceptible to oncogene-mediated transformation by the ectopic expression of the telomerase catalytic subunit (hTERT) introduces the possibility that the difference in the regulation of telomerase expression can explain the different susceptibility to transformation between human and rodent cells. In a recent study, however, we demonstrated that normal human fibroblasts are still more resistant than normal rodent fibroblasts to oncogenic transformation even with the ectopic expression of hTERT. Our results clearly indicate that a difference in telomere biology can not fully account for the species difference in transformability, and that normal human cells have still undefined intrinsic mechanisms rendering them resistant to oncogenic transformation.     

Human Diploid Fibroblasts are Refractory to Oncogene-Mediated Transformation

It has long been known that human cells are more refractory than rodent cells against oncogenic transformation in vitro. Recent success to make normal human cells susceptible to oncogene-mediated transformation by the ectopic expression of the telomerase catalytic subunit (hTERT) raises the possibility that the difference in the regulation of telomerase expression can explain the different susceptibility to transformation between human and rodent cells. In the recent study, however, we demonstrated that normal human fibroblasts are still more resistant than normal rodent fibroblasts to oncogenic transformation even with the ectopic expression of hTERT. Our results clearly indicate that a difference in telomere biology can not fully account for the species difference in transformability, and that normal human cells have still undefined intrinsic mechanisms rendering them resistant to oncogenic transformation.