10 Aging in Mammalian Stem Cells and Other Self-renewing Compartments

Cold Spring Harbor Monograph Archive Pub Date : 2008-01-01 DOI:10.1101/087969824.51.237

Derrick J. Rossi, N. Sharpless

{"title":"10 Aging in Mammalian Stem Cells and Other Self-renewing Compartments","authors":"Derrick J. Rossi, N. Sharpless","doi":"10.1101/087969824.51.237","DOIUrl":null,"url":null,"abstract":"Long-lived metazoans must replace a variety of lost or consumed cells at a furious pace. For example, an adult human replaces about 1% of their 20 trillion red blood cells every day through de novo synthesis. Similarly staggering rates of cell division are at work to produce new cells in the gut, skin, and bone marrow throughout life. Additionally, certain tissues (e.g., memory lymphocytes and pancreatic β cells) possess a potential for facultative growth in the adult organism; i.e., under certain circumstances (e.g., viral infection and pregnancy), these normally quiescent cells can reenter the cell cycle to increase the mass of a given tissue through regulated proliferation. To offset the high cellular turnover rate in such tissues and avoid the onset of tissue-specific hypoplasia and atrophy, many mammalian tissues contain reservoirs of stem cells capable of generating terminally differentiated effector cell types. The unique cellular property that enables stem cells to maintain such function throughout is their ability to produce large numbers of differentiated cell types while also self-renewing themselves so that their reserves do not become depleted over time. Several lines of evidence—foremost of which is evidence indicating that aged tissues characteristically exhibit a diminished capacity to maintain homeostasis or return to homeostasis after exposure to stress—has implicated stem cell decline in the aging process. In this chapter, we review some of the evidence to support the notion that certain aspects of mammalian aging result from an age-dependent decline in the function of self-renewing stem cells, and...","PeriodicalId":10493,"journal":{"name":"Cold Spring Harbor Monograph Archive","volume":"29 1","pages":"237-265"},"PeriodicalIF":0.0000,"publicationDate":"2008-01-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"4","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Cold Spring Harbor Monograph Archive","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.1101/087969824.51.237","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}

引用次数: 4

Abstract

Long-lived metazoans must replace a variety of lost or consumed cells at a furious pace. For example, an adult human replaces about 1% of their 20 trillion red blood cells every day through de novo synthesis. Similarly staggering rates of cell division are at work to produce new cells in the gut, skin, and bone marrow throughout life. Additionally, certain tissues (e.g., memory lymphocytes and pancreatic β cells) possess a potential for facultative growth in the adult organism; i.e., under certain circumstances (e.g., viral infection and pregnancy), these normally quiescent cells can reenter the cell cycle to increase the mass of a given tissue through regulated proliferation. To offset the high cellular turnover rate in such tissues and avoid the onset of tissue-specific hypoplasia and atrophy, many mammalian tissues contain reservoirs of stem cells capable of generating terminally differentiated effector cell types. The unique cellular property that enables stem cells to maintain such function throughout is their ability to produce large numbers of differentiated cell types while also self-renewing themselves so that their reserves do not become depleted over time. Several lines of evidence—foremost of which is evidence indicating that aged tissues characteristically exhibit a diminished capacity to maintain homeostasis or return to homeostasis after exposure to stress—has implicated stem cell decline in the aging process. In this chapter, we review some of the evidence to support the notion that certain aspects of mammalian aging result from an age-dependent decline in the function of self-renewing stem cells, and...

查看原文本刊更多论文

哺乳动物干细胞和其他自我更新区室的衰老

长寿的后生动物必须以极快的速度替换各种丢失或消耗的细胞。例如，一个成年人每天通过从头合成来替换20万亿红细胞中的1%。在人的一生中，肠道、皮肤和骨髓中也有同样惊人的细胞分裂速度产生新细胞。此外，某些组织(例如，记忆淋巴细胞和胰腺β细胞)在成年生物体中具有兼性生长的潜力;也就是说，在某些情况下(例如，病毒感染和怀孕)，这些通常静止的细胞可以重新进入细胞周期，通过调节增殖来增加给定组织的质量。为了抵消这些组织中的高细胞更新率，避免组织特异性发育不良和萎缩的发生，许多哺乳动物组织中含有能够产生终分化效应细胞类型的干细胞库。使干细胞能够始终保持这种功能的独特细胞特性是它们能够产生大量分化的细胞类型，同时也能自我更新，这样它们的储备就不会随着时间的推移而耗尽。有几条线索的证据——其中最重要的证据表明，衰老组织在暴露于压力后表现出维持体内平衡或恢复体内平衡的能力下降的特征，这与衰老过程中干细胞的下降有关。在本章中，我们回顾了一些证据来支持这一观点，即哺乳动物衰老的某些方面是由于自我更新干细胞功能的年龄依赖性下降造成的，并且……

本文章由计算机程序翻译，如有差异，请以英文原文为准。

求助全文

约1分钟内获得全文求助全文

来源期刊

Cold Spring Harbor Monograph Archive

自引率

0.00%

发文量