Т. В. Поспелова scite author profile

When the cell cycle is arrested but cellular growth is not, then cells senesce, permanently losing proliferative potential. Here we demonstrated that the duration of cell cycle arrest determines a progressive loss of proliferative capacity. In human and rodent cell lines, rapamycin (an inhibitor of mTOR) dramatically decelerated loss of proliferative potential caused by ectopic p21, p16 and sodium butyrate-induced p21. Thus, when the cell cycle was arrested by these factors in the presence of rapamycin, cells retained the capacity to resume proliferation, once p21, p16 or sodium butyrate were removed. While rapamycin prevented the permanent loss of proliferative potential in arrested cells, it did not force the arrested cells into proliferation. During cell cycle arrest, rapamycin transformed the irreversible arrest into a reversible condition. Our data demonstrate that senescence can be pharmacologically suppressed.

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Pseudo-DNA damage response in senescent cells

Поспелова

Demidenko²,

Bukreeva³

et al. 2009

Cell Cycle

196

169

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Cellular senescence is currently viewed as a response to DNA damage. In this report, we showed that non-damaging agents such as sodium butyrate-induced p21 and ectopic expression of either p21 or p16 cause cellular senescence without detectable DNA breaks. Nevertheless, senescent cells displayed components of DNA damage response (DDR) such as γH2AX foci and uniform nuclear staining for p-ATM. Importantly, there was no accumulation of 53BP1 in γH2AX foci of senescent cells. Consistently, comet assay failed to detect DNA damage. Rapamycin, an inhibitor of mTOR, which was shown to suppress cellular senescence, decreased γH2AX foci formation. Thus, cellular senescence leads to activation of atypical DDR without detectable DNA damage. Pseudo-DDR may be a marker of general over-activation of senescent cells.

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Cyclin-dependent kinase inhibitor p21Waf1: Contemporary view on its role in senescence and oncogenesis

Romanov

Поспелов

Поспелова

2012

Biochemistry Moscow

108

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p21(Waf1) was identified as a protein suppressing cyclin E/A-CDK2 activity and was originally considered as a negative regulator of the cell cycle and a tumor suppressor. It is now considered that p21(Waf1) has alternative functions, and the view of its role in cellular processes has begun to change. At present, p21(Waf1) is known to be involved in regulation of fundamental cellular programs: cell proliferation, differentiation, migration, senescence, and apoptosis. In fact, it not only exhibits antioncogenic, but also oncogenic properties. This review provides a contemporary understanding of the functions of p21(Waf1) depending on its intracellular localization. On one hand, when in the nucleus, it serves as a negative cell cycle regulator and tumor suppressor, in particular by participating in the launch of a senescence program. On the other hand, when p21(Waf1) is localized in the cytoplasm, it acts as an oncogene by regulating migration, apoptosis, and proliferation.

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Activation of DNA damage response signaling in mouse embryonic stem cells

Chuykin¹,

Lianguzova²,

Поспелова³

et al. 2008

Cell Cycle

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Mouse embryonic stem cells (mESC) are characterized by high proliferation activity. mESC are highly sensitive to genotoxic stresses and do not undergo G 1 /S checkpoint upon DNA-damage. mESC are supposed to develop sensitive mechanisms to maintain genomic integrity provided by either DNA damage repair or elimination of defected cells by apoptosis. The issue of how mESC recognize the damages and execute DNA repair remains to be studied. We analyzed the kinetics of DNA repair foci marked by antibodies to phosphorylated ATM kinase and histone H2AX (γH2AX). We showed that mESC display non-induced DNA single-strand breaks (SSBs), as revealed by comet-assay, and a noticeable background of γH2AX staining. Exposure of mESC to γ-irradiation induced the accumulation of phosphorylated ATM-kinase in the nucleus as well as the formation of additional γH2AX foci, which disappeared thereafter. To decrease the background of γH2AX staining in control non-irradiated cells, we pre-synchronized mESC at the G 2 /M by low concentration of nocodazol for a short time (6 h). The cells were then irradiated and stained for γH2AX. Irradiation induced the formation of γH2AX foci both in G 2 -phase and mitotic cells, which evidenced for the active state of DNA-damage signaling at these stages of the cell cycle in mESC. Due to the G 1 /S checkpoint is compromised in mESCs, we checked, whether wild-type p53, a target for ATM kinase, was phosphorylated in response to γ-irradiation. The p53 was barely phosphorylated in response to irradiation, which correlated with a very low expression of p53-target p21/Waf1 gene. Thus, in spite of the dysfunction of the p53/Waf1 pathway and the lack of cell cycle checkpoints, the mESC are capable of activating ATM and inducing γH2AX foci formation, which are necessary for the activation of DNA damage response.

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