人类细胞衰老的过程。

Interdisciplinary topics in gerontology Pub Date : 2014-01-01 Epub Date: 2014-05-13 DOI:10.1159/000358896
Robin Holliday
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引用次数: 21

摘要

50年前,伦纳德·海弗利克证明了培养的人类二倍体成纤维细胞的寿命是有限的。从那时起,无数的实验被发表,以发现导致持续增长的“海弗利克极限”的机制。已经获得了许多新的信息,但是这个实验系统的某些特征还没有被完全理解。一个事实是,不同种群的胎儿肺菌株WI-38和MRC-5的分裂潜力范围至少有一百万倍。30多年前发表的细胞衰老承诺理论能够解释这一点,但它一直被忽视。该理论预测,瓶颈是种群规模的短暂减少,可以显著缩短寿命,或增加寿命的可变性。计算机模拟详细说明了瓶颈对寿命的影响,这在两个系列的实验中得到了证实。对衰老的承诺可能是端粒酶的丧失,这会导致端粒的侵蚀和无法无限生长。许多实验都是用来自不同年龄的人类供体的皮肤成纤维细胞进行的,最初认为体外寿命与供体年龄成反比。在这些实验中,一次皮肤活检产生了一群生长到衰老的细胞。然而,没有理由相信皮肤成纤维细胞的体外寿命比胎儿肺株的变化更小,在这种情况下,皮肤细胞的数据点变化如此之大,以至于它们可能完全模糊了培养寿命和供体年龄之间的任何负相关关系。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
The commitment of human cells to senescence.

Fifty years ago, it was demonstrated by Leonard Hayflick that human diploid fibroblasts grown in culture have a finite lifespan. Since that time, innumerable experiments have been published to discover the mechanism(s) that are responsible for this 'Hayflick limit' to continuous growth. Much new information has been gained, but there are certain features of this experimental system which have not been fully understood. One is the fact that different populations of the foetal lung strains WI-38 and MRC-5 have a range in division potential of at least a millionfold. The commitment theory of cellular aging, published more than 30 years ago, is able to explain this, but it has been consistently ignored. The theory predicts that bottlenecks, which are transient reductions in population size, can significantly reduce lifespan, or increase variability of lifespans. Computer simulations specify the effects of bottlenecks on longevity, and these were confirmed in two series of experiments. Commitment to senescence may be the loss of telomerase, which leads to the erosion of telomeres and the inability to grow indefinitely. Many experiments have been done with skin fibroblasts from human donors of different age, and it was originally thought that in vitro lifespan was inversely correlated with donor age. In these experiments, a single skin biopsy produces a population of cells that are grown to senescence. However, there is no reason to believe that skin fibroblasts are less variable in their in vitro lifespan than foetal lung strains, in which case the data points with skin cells are so variable that they may completely obscure any inverse correlation between culture lifespans and donor age.

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