Abstract
Telomere dysfunction is known to induce growth arrest (senescence) and cell death. However, the regulation of the senescence-death process is poorly understood. Here using a yeast dysfunctional telomere model cdc13-1, which carries a temperature sensitive-mutant telomere binding protein Cdc13p, we demonstrate that inhibition of TOR (Target of Rapamycin), a central regulator of nutrient pathways for cell growth, prevents cell death, but not growth arrest, induced by inactivation of Cdc13-1p. This function of TOR is novel and separable from its G1 inhibition function, and not associated with alterations in the telomere length, the amount of G-tails, and the telomere position effect (TPE) in cdc13-1 cells. Furthermore, antioxidants were also shown to prevent cell death initiated by inactivation of cdc13-1. Moreover, inhibition of TOR was also shown to prevent cell death induced by inactivation of telomerase in an est1 mutant. Interestingly, rapamycin did not prevent cell death induced by DNA damaging agents such as etoposide and UV. In the aggregate, our results suggest that the TOR signaling pathway is specifically involved in the regulation of cell death initiated by telomere dysfunction.
Highlights
Telomere function has been linked to aging
We have previously demonstrated that inactivation of Cdc13p induces cell death that is characterized by apoptotic markers such as caspase activation, PS flipping, and ROS production [20]
We show that inhibition of TOR prevents the cell death induced by inactivation of Cdc13p based on both colony formation assay and measurement of various apoptotic markers
Summary
Telomere function has been linked to aging. In humans, telomere length has been correlated with lifespan [1]. Addition of rapa could not further improve survival of the double mutant (Fig. 1F) These results provide additional support for a role of TOR in regulating cell death induced by inactivation of the telomere binding protein Cdc13p. Neither UV nor etoposide increased the cell population with greater than 2N DNA content (Fig. 4C and 4G) These results suggest that rapa prevents telomere-initiated cell death. The presence of rapa (1 nM) was shown to significantly suppress PS flipping and ROS production (Fig. 6B and 6C) These results suggest that rapa suppresses cell death initiated by dysfunctional telomeres due to inactivation of the essential telomerase subunit Est1p
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