Replication and/or separation of some human telomeres is delayed beyond S-phase in pre-senescent cells.

Cultured primary human cells, which lack telomerase, enter a state of replicative senescence after a characteristic number of population doublings. During this process telomeres shorten to a critical length of approximately 5-7 kb. The mechanistic relationship between advanced cell passage, cellular senescence and telomeric function has yet to be fully elucidated. In the study described here, we investigated the relationship between changes in telomeric replication timing and/or sister chromatid separation at telomeric regions and advanced cell passage. Using fluorescence in situ hybridization, we analyzed the appearance of double hybridization signals (doublets), which indicate that the region of interest has replicated and the replicated products have separated sufficiently to be resolved as two distinct signals. The results showed that the replication and separation of several telomeric regions occurs during the second half of S-phase and that a delay in replication and/or separation of sister chromatids at these regions occurs in pre-senescent human fibroblasts. Surprisingly, in a significant percentage of pre-senescent cells, several telomeric regions did not hybridize as doublets even in metaphase chromosomes. This delay was not associated with extensive changes in methylation levels at subtelomeric regions and was circumvented in human fibroblasts expressing ectopic telomerase. We propose that incomplete replication and/or separation of telomeric regions in metaphase may be associated with proliferative arrest of senescent cells. This cell growth arrest may result from the activation of a mitotic checkpoint, or from chromosomal instability consequent to progression in the cell cycle despite failure to replicate and/or separate these regions completely.

High glucose-induced replicative senescence: point of no return and effect of telomerase.

Primary human cells enter senescence after a characteristic number of population doublings (PDs). In the current study, human skin fibroblasts were propagated in culture under 5.5mM glucose (normoglycemia); addition of 16.5mM D-glucose to a concentration of 22 mM (hyperglycemia); and addition of 16.5mM L-glucose (osmotic control). Hyperglycemia induced premature replicative senescence after 44.42+/-1.5 PDs compared to 57.9+/-3.83 PDs under normoglycemia (p<0.0001). L-Glucose had no effect, suggesting that the effect of hyperglycemia was not attributed to hyperosmolarity. Activated caspase-3 measurement showed a significantly higher percentage of apoptotic cells in high glucose medium. Telomerase overexpression circumvented the effects of hyperglycemia on replicative capacity and apoptosis. The "point of no return," beyond which hyperglycemia resulted in irreversible progression to premature replicative senescence, occurred after exposure to hyperglycemia for as few as 20 PDs. These results may provide a biochemical basis for the relationship between hyperglycemia and those complications of diabetes, which are reminiscent of accelerated senescence.