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端粒功能障碍的细胞水平决定了体内衰老或凋亡的诱导。

The cellular level of telomere dysfunction determines induction of senescence or apoptosis in vivo.

作者信息

Lechel André, Satyanarayana Ande, Ju Zhenyu, Plentz Ruben R, Schaetzlein Sonja, Rudolph Cornelia, Wilkens Ludwig, Wiemann Stephanie U, Saretzki Gabriele, Malek Nisar P, Manns Michael P, Buer Jan, Rudolph K Lenhard

机构信息

Department of Gastroenterology, Hepatology, and Endocrinology, Medical School Hannover, Carl-Neuberg-Strasse 1, 30625 Hannover, Germany.

出版信息

EMBO Rep. 2005 Mar;6(3):275-81. doi: 10.1038/sj.embor.7400352.

DOI:10.1038/sj.embor.7400352
PMID:15723042
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1299262/
Abstract

Telomere dysfunction induces two types of cellular response: cellular senescence and apoptosis. We analysed the extent to which the cellular level of telomere dysfunction and p53 gene status affect these cellular responses in mouse liver using the experimental system of TRF2 inhibition by a dominant-negative version of the protein (TRF2delta B delta M). We show that the level of telomere dysfunction correlates with the level of TRF2delta B delta M protein expression resulting in chromosomal fusions, aberrant mitotic figures and aneuploidy of liver cells. These alterations provoked p53-independent apoptosis, but a strictly p53-dependent senescence response in distinct populations of mouse liver cells depending on the cellular level of TRF2delta B delta M expression. Apoptosis was associated with higher expression of TRF2delta B delta M, whereas cellular senescence was associated with low levels of TRF2delta B delta M) expression. Our data provide experimental evidence that induction of senescence or apoptosis in vivo depends on the cellular level of telomere dysfunction and differentially on p53 gene function.

摘要

端粒功能障碍会引发两种细胞反应

细胞衰老和凋亡。我们利用显性负性蛋白(TRF2δBδM)抑制TRF2的实验系统,分析了小鼠肝脏中端粒功能障碍的细胞水平和p53基因状态对这些细胞反应的影响程度。我们发现,端粒功能障碍的水平与TRF2δBδM蛋白表达水平相关,导致染色体融合、异常有丝分裂图像以及肝细胞非整倍体。这些改变引发了不依赖p53的凋亡,但在小鼠肝细胞的不同群体中,根据TRF2δBδM表达的细胞水平,引发了严格依赖p53的衰老反应。凋亡与TRF2δBδM的高表达相关,而细胞衰老与TRF2δBδM低水平表达相关。我们的数据提供了实验证据,表明体内衰老或凋亡的诱导取决于端粒功能障碍的细胞水平,并在不同程度上依赖于p53基因功能。

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