Diverse conditions support near-zero growth in yeast: Implications for the study of cell lifespan

IF 4.1 3区 生物学 Q2 CELL BIOLOGY
Jordan Gulli, E. Cook, Eugene Kroll, Adam P. Rosebrock, A. Caudy, Frank Rosenzweig
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引用次数: 6

Abstract

Baker's yeast has a finite lifespan and ages in two ways: a mother cell can only divide so many times (its replicative lifespan), and a non-dividing cell can only live so long (its chronological lifespan). Wild and laboratory yeast strains exhibit natural variation for each type of lifespan, and the genetic basis for this variation has been generalized to other eukaryotes, including metazoans. To date, yeast chronological lifespan has chiefly been studied in relation to the rate and mode of functional decline among non-dividing cells in nutrient-depleted batch culture. However, this culture method does not accurately capture two major classes of long-lived metazoan cells: cells that are terminally differentiated and metabolically active for periods that approximate animal lifespan (e.g. cardiac myocytes), and cells that are pluripotent and metabolically quiescent (e.g. stem cells). Here, we consider alternative ways of cultivating Saccharomyces cerevisiae so that these different metabolic states can be explored in non-dividing cells: (i) yeast cultured as giant colonies on semi-solid agar, (ii) yeast cultured in retentostats and provided sufficient nutrients to meet minimal energy requirements, and (iii) yeast encapsulated in a semisolid matrix and fed ad libitum in bioreactors. We review the physiology of yeast cultured under each of these conditions, and explore their potential to provide unique insights into determinants of chronological lifespan in the cells of higher eukaryotes.
多种条件支持酵母近乎零生长:对细胞寿命研究的启示
贝克酵母的寿命有限,衰老有两种方式:母细胞只能分裂这么多次(其复制寿命),非分裂细胞只能存活这么长(其按时间顺序排列的寿命)。野生和实验室酵母菌株在每种类型的寿命中都表现出自然变异,这种变异的遗传基础已经推广到其他真核生物,包括后生动物。到目前为止,酵母的实际寿命主要与营养耗尽的分批培养中未分裂细胞的功能下降速度和模式有关。然而,这种培养方法并不能准确捕获两类主要的长寿后生动物细胞:在接近动物寿命的时期内最终分化并具有代谢活性的细胞(例如心肌细胞),以及多能干且代谢静止的细胞(如干细胞)。在这里,我们考虑了培养酿酒酵母的替代方法,以便在非分裂细胞中探索这些不同的代谢状态:(i)在半固体琼脂上培养为巨大菌落的酵母,(ii)在保持物中培养并提供足够营养以满足最低能量需求的酵母,和(iii)包封在半固体基质中并在生物反应器中随意喂养的酵母。我们回顾了在每种条件下培养的酵母的生理学,并探索了它们为高等真核生物细胞按时间顺序寿命的决定因素提供独特见解的潜力。
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来源期刊
Microbial Cell
Microbial Cell Multiple-
CiteScore
6.40
自引率
0.00%
发文量
32
审稿时长
12 weeks
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