Extension of Life-Span by Introduction of Telomerase into Normal Human Cells

Bodnár, Andrea; Ouellette, Michel; Frolkis, Maria; Holt, Shawn E.; Chiu, Choy‐Pik; Morin, Gregg B.; Harley, Calvin B.; Shay, Jerry W.; Lichtsteiner, Serge; Wright, Woodring E.

doi:10.1126/science.279.5349.349

Cited by 4,465 publications

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“…Expression of the hTERT gene and concomitant activation of telomerase has been demonstrated to be su cient for extension of cellular replicative lifespan and bypass of the Hay¯ick limit for three di erent primary human cell lines (Bodnar et al, 1998). If the regulation of TERT expression indeed represents a key gatekeeper for the transition to an immortal phenotype in the mouse, as it appears to be for human cells, then the continued expression of TERT in mouse cells and tissues could be an important permissive factor enabling their cancer-prone phenotype.…”

Section: Mtert and Mtr Expression In Primary Senescent And Immortalmentioning

confidence: 99%

“…Most somatic human tissues and primary cells possess low or undetectable telomerase activity, leading to a steady decline in telomere length with continued organ renewal in vivo and with passage in culture. This progressive telomere shortening has been shown to provide a signal for entry of cells into a state of replicative senescence (Harley et al, 1990;Bodnar et al, 1998;Kim et al, 1994).…”

Section: Introductionmentioning

confidence: 99%

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Expression of mouse telomerase reverse transcriptase during development, differentiation and proliferation

et al. 1998

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We have identi®ed the mouse telomerase reverse transcriptase component (mTERT) and demonstrate both substantial sequence homology to the human ortholog (hTERT), and the presence of reverse transcriptase and telomerase speci®c motifs. Furthermore, we show functional interchangeability with hTERT in in vitro telomerase reconstitution experiments, as mTERT produces strong telomerase activity in combination with the human telomerase RNA component hTR. The mouse TERT is widely expressed at low levels in adult tissues, with greatest abundance during embryogenesis and in adult thymus and intestine. The mTERT component mRNA levels were regulated during both di erentiation and proliferation, while mTR levels remained constant throughout both processes. Comparison of mTERT and mTR levels to telomerase activity indicates that mTERT expression is more tightly linked to the regulation of telomerase activity during these processes than is mTR. In contrast to the situation in human cell cultures, mTERT transcript levels are present at readily detectable levels in primary cultured cells and are not upregulated following crisis. The widespread expression of mTERT in primary cells and mouse tissues could explain the increased frequency of spontaneous immortalization of mouse cells in culture and tumorigenesis in vivo.

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Section: Mtert and Mtr Expression In Primary Senescent And Immortalmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Expression of mouse telomerase reverse transcriptase during development, differentiation and proliferation

et al. 1998

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“…Although some tumor cells maintain telomere length by the alternative lengthening of telomere (ALT) pathway involving recombination processes, >85% of all tumor cells rather do so by inducing telomerase activity through hTERT transcriptional upregulation . Indeed, ectopic expression of hTERT in telomerasenegative cells is sufficient to restore telomerase activity and induce the immortalization of several primary human cell types (Bodnar et al, 1998). However, although hTERT expression alone is sufficient to immortalize for example human fibroblasts in culture, spontaneous immortalization is extremely rare.…”

Section: Introductionmentioning

confidence: 99%

Regulation of telomerase activity by the p53 family member p73

Beitzinger

Oswald

Beinoraviciute-Kellner

et al. 2005

Oncogene

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The terminal ends of eukaryotic chromosomes, termed telomeres, progressively shorten during each round of cell division eventually leading cells into senescence. Tumor cells typically overcome this barrier to unlimited proliferation by activation of the human telomerase reverse transcriptase (hTERT) gene. In contrast, in most human somatic cells hTERT expression is tightly repressed by multiple tumor suppressors. Here, we studied the regulation of hTERT by the p53 family member p73. We show that forced expression of p73 or activation of endogenous p73 by E2F1 results in the downregulation of telomerase activity. Vice versa, siRNA-mediated knockdown of p73 induces hTERT expression. Responsiveness to p73 is conferred by Sp1 binding sites within the hTERT core promoter. In tumor cells, p73 isoforms lacking the transactivation domain (DNp73) are frequently overexpressed and believed to function as oncogenes. We show that DNp73 antagonizes the repressive effect of the proapoptotic p53 family members on hTERT expression and, in addition, induces hTERT expression in telomerase-negative cells by interfering with E2F-RB-mediated repression of the hTERT core promoter. These data provide evidence that the p73 gene functions as an important regulator of telomerase activity with implications for embryonic development, cellular differentiation and tumorigenesis.

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“…A signal generated by telomeres shortened below a threshold value would induce cells, which have passed through a number of genetically determined cell cycles, to reach a quiescent state de®ned as replicative senescence (Harley, 1991). This hypothesis has recently received indirect support from the demonstration that the forced expression of the catalytic subunit of telomerase in normal human cells is su cient to prevent replicative senescence (Bodnar et al, 1998;Vaziri and Benchimol, 1998). Although there are instances in which human and murine cells are capable of unlimited cell doublings in the absence of active telomerase Blasco et al, 1997), telomerase reactivation could represent a crucial advantage for the unrestrained growth of tumor cells.…”

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confidence: 99%

“…Telomerase activity was measured by the telomere repeat ampli®cation protocol (TRAP) (Kim et al, 1994), as modi®ed in Falchetti et al (1998). As shown in Figure Alterations in telomere length have been shown in human cells as consequence of the forced expression of telomerase catalytic subunit (Bodnar et al, 1998). We have used terminal restriction fragment (TRF) length assay (Strahl and Blackburn, 1966) to measure average telomeric lengths and have found no di erence between early passage (P1, equivalent to 3 PD in vitro) chicken NR cells and late passage (P15, equivalent to about 40 PD) cells transformed by either v-Myc or v-Src (not shown).…”

mentioning

confidence: 99%

Induction of telomerase activity in v-myc-transformed avian cells

Falchetti¹,

Falcone²,

D’Ambrosio³

et al. 1999

Oncogene

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Telomerase activity is detectable in the majority of tumors or immortalized cell lines, but is repressed in most normal human somatic cells. It is generally assumed that reactivation of telomerase prevents the erosion of chromosome ends which occurs in cycling cells and, hence, hinders cellular replicative senescence. Here, we show that the expression of v-Myc oncoprotein by retroviral infection of telomerase-negative embryonal quail myoblasts and chicken neuroretina cells is su cient for reactivating telomerase activity, earlier than telomere shortening could occur. Furthermore, the use of a conditional v-Myc-estrogen receptor protein (v-MycER) causes estrogen-dependent expression of detectable levels of telomerase activity in recently infected chick embryo ®broblasts and neuroretina cells. We conclude that the high levels of telomerase activity in v-Myc-expressing avian cells are not the mere consequence of transformation or of a di erentiative block, since v-Src tyrosine kinase, which prevents terminal di erentiation and promotes cell transformation, fails to induce telomerase activity.

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Extension of Life-Span by Introduction of Telomerase into Normal Human Cells

Cited by 4,465 publications

References 50 publications

Expression of mouse telomerase reverse transcriptase during development, differentiation and proliferation

Expression of mouse telomerase reverse transcriptase during development, differentiation and proliferation

Regulation of telomerase activity by the p53 family member p73

Induction of telomerase activity in v-myc-transformed avian cells

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