Inactive C-terminal telomerase reverse transcriptase insertion splicing variants are dominant-negative inhibitors of telomerase.

Maintenance of telomere length and structure is essential for cell survival. Telomere synthesis is mediated by the ribonucleoprotein telomerase in 90% of cancer cells, and is regulated mainly by transcription of the human telomerase reverse transcriptase subunit, hTERT. However, transcriptome analysis reveals complex splicing patterns and to date, twenty-two alternatively-spliced hTERT mRNAs have been reported, yet their functions have not been fully elucidated. The best characterized hTERT spliced variants encode for inactive proteins that possess specific deletions within the hTERT catalytic domains. We studied two less well characterized hTERT splice variants (termed INS3 and 4) that encode proteins with intact reverse transcriptase motifs, but alternative C-domains due to insertion of intronic sequences. We determined the prevalence of these mRNA variants in primary cells, telomerase-positive cells and in alternative lengthening of telomere (ALT) cells and found the transcripts to be expressed mainly in telomerase-positive cell lines and to be translated into proteins as illustrated by their association with polysomes. These variants were inactive when expressed in vitro or in cells, retained DNA substrate binding in vitro but were impaired in binding the telomerase RNA component when expressed in, and immunoprecipitated from either telomerase-positive or telomerase-negative ALT cells coexpressing the telomerase RNA component. Stable expression of INS3 and INS4 variants in a hepatocarcinoma cell line inhibited telomerase activity, shortened telomeres and slowed cell growth suggesting a potential dominant-negative function.

Regulation of telomere length and homeostasis by telomerase enzyme processivity.

Telomerase is a ribonucleoprotein consisting of a catalytic subunit, the telomerase reverse transcriptase (TERT), and an integrally associated RNA that contains a template for the synthesis of short repetitive G-rich DNA sequences at the ends of telomeres. Telomerase can repetitively reverse transcribe its short RNA template, acting processively to add multiple telomeric repeats onto the same DNA substrate. The contribution of enzyme processivity to telomere length regulation in human cells is not well characterized. In cancer cells, under homeostatic telomere length-maintenance conditions, telomerase acts processively, whereas under nonequilibrium conditions, telomerase acts distributively on the shortest telomeres. To investigate the role of increased telomerase processivity on telomere length regulation in human cells with limited lifespan that are dependent on human TERT for lifespan extension and immortalization, we mutated the leucine at position 866 in the reverse transcriptase C motif of human TERT to a tyrosine (L866Y), which is the amino acid found at the equivalent position in HIV-1 reverse transcriptase. We report that, similar to the previously reported gain-of-function Tetrahymena telomerase mutant (L813Y), the human telomerase variant displays increased processivity. Human TERT-L866Y, like wild-type human TERT, can immortalize and extend the lifespan of limited-lifespan cells. Moreover, cells expressing human TERT-L866Y display heterogenous telomere lengths, telomere elongation, multiple telomeric signals indicative of fragile sites and replicative stress, and an increase in short telomeres, which is accompanied by telomere trimming events. Our results suggest that telomere length and homeostasis in human cells may be regulated by telomerase enzyme processivity.