Abstract
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.
| Original language | English |
|---|---|
| Pages (from-to) | 147-155 |
| Number of pages | 9 |
| Journal | Chromosoma |
| Volume | 111 |
| Issue number | 3 |
| DOIs | |
| State | Published - Sep 2002 |
| Externally published | Yes |
Bibliographical note
Funding Information:Acknowledgements We thank Zipora Kra-Oz (Rambam Medical Center) for providing us with SR foreskin fibroblasts, and Wood-ring Wright for providing us with the BJ, and BJ-pBABEpuro-hTERT cell lines, and for helpful comments on the manuscript. We are grateful to Graham Brock for providing the p1A12 plasmid, to Karine Monier for providing us with her protocol for combined immunofluorescence and FISH, and to Ofer Shenker for help in image analysis. We thank Arie Drugan for the cord blood samples and Avi Lightman for the sperm samples. We thank Daniel Kornitzer and Maty Tzukerman for comments on the manuscript. This research was supported in part by grants from the Israel Science Foundation (S.S.), the Binational Science Foundation (K.L.S.), and the Rambam Research and Development Foundation (S.S.). The experiments described in this paper comply with current laws in Israel.
Funding
Acknowledgements We thank Zipora Kra-Oz (Rambam Medical Center) for providing us with SR foreskin fibroblasts, and Wood-ring Wright for providing us with the BJ, and BJ-pBABEpuro-hTERT cell lines, and for helpful comments on the manuscript. We are grateful to Graham Brock for providing the p1A12 plasmid, to Karine Monier for providing us with her protocol for combined immunofluorescence and FISH, and to Ofer Shenker for help in image analysis. We thank Arie Drugan for the cord blood samples and Avi Lightman for the sperm samples. We thank Daniel Kornitzer and Maty Tzukerman for comments on the manuscript. This research was supported in part by grants from the Israel Science Foundation (S.S.), the Binational Science Foundation (K.L.S.), and the Rambam Research and Development Foundation (S.S.). The experiments described in this paper comply with current laws in Israel.
| Funders | Funder number |
|---|---|
| Rambam Research and Development Foundation | |
| United States-Israel Binational Science Foundation | |
| Israel Science Foundation |