Membraneless and membrane-bound organelles in an anhydrobiotic cell line are protected from desiccation-induced damage

IF 3.3 3区 生物学 Q3 CELL BIOLOGY
Clinton J. Belott , Oleg A. Gusev , Takahiro Kikawada , Michael A. Menze
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引用次数: 0

Abstract

Anhydrobiotic species can survive virtually complete water loss by entering a reversible ametabolic glassy state that may persist for years in ambient conditions. The Pv11 cell line was derived from the egg mass of the anhydrobiotic midge, Polypedilum vanderplanki, and is currently the only available anhydrobiotic cell line. Our results demonstrate that the necessary preconditioning for Pv11 cells to enter anhydrobiosis causes autophagy and reduces mitochondrial respiration by over 70%. We speculate that reorganizing cellular bioenergetics to create and conserve energy stores may be valuable to successfully recover after rehydration. Furthermore, mitochondria in preconditioned cells lose their membrane potential during desiccation but rapidly restore it within 30 min upon rehydration, demonstrating that the inner mitochondrial membrane integrity is well-preserved. Strikingly, the nucleolus remains visible immediately upon rehydration in preconditioned cells while absent in control cells. In contrast, a preconditioning-induced membraneless organelle reformed after rehydration, demonstrating that membraneless organelles in Pv11 cells can be either stabilized or recovered. Staining the endoplasmic reticulum and the Golgi apparatus revealed that these organelles fragment during preconditioning. We hypothesize that this process reduces sheering stress caused by rapid changes in cellular volume during desiccation and rehydration. Additionally, preconditioning was found to cause the filamentous-actin (F-actin) network to disassemble significantly and reduce the fusion of adjacent plasma membranes. This study offers several exciting avenues for future studies in the animal model and Pv11 cell line that will further our understanding of anhydrobiosis and may lead to advancements in storing sensitive biologics at ambient temperatures for months or years.

水生细胞系中的无膜细胞器和膜结合细胞器免受干燥引起的损伤
无水生生物可通过进入一种可逆的非代谢玻璃态(在环境条件下可持续数年)而在几乎完全失水的情况下存活下来。Pv11 细胞系源自无水生生物蠓虫 Polypedilum vanderplanki 的卵块,是目前唯一可用的无水生生物细胞系。我们的研究结果表明,Pv11 细胞进入无水生生物状态的必要前提条件会导致自噬,并使线粒体呼吸减少 70% 以上。我们推测,重组细胞生物能以创建和保存能量储存可能对在补液后成功恢复很有价值。此外,预处理细胞中的线粒体在干燥过程中失去膜电位,但在补液后 30 分钟内迅速恢复,这表明线粒体内膜的完整性得到了很好的保护。令人震惊的是,预处理细胞中的核仁在复水后立即可见,而对照细胞中的核仁则不可见。相反,预处理诱导的无膜细胞器在复水后重新形成,这表明 Pv11 细胞中的无膜细胞器可以稳定或恢复。对内质网和高尔基体的染色显示,这些细胞器在预处理过程中会破碎。我们推测这一过程可减少干燥和复水过程中细胞体积快速变化造成的剪切应力。此外,我们还发现预处理会导致丝状肌动蛋白(F-actin)网络显著解体,并减少相邻质膜的融合。这项研究为今后在动物模型和 Pv11 细胞系中进行研究提供了几条令人兴奋的途径,这将进一步加深我们对无水生物中毒的理解,并有可能推动将敏感生物制品在环境温度下储存数月或数年。
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来源期刊
Cell Stress & Chaperones
Cell Stress & Chaperones 生物-细胞生物学
CiteScore
7.60
自引率
2.60%
发文量
59
审稿时长
6-12 weeks
期刊介绍: Cell Stress and Chaperones is an integrative journal that bridges the gap between laboratory model systems and natural populations. The journal captures the eclectic spirit of the cellular stress response field in a single, concentrated source of current information. Major emphasis is placed on the effects of climate change on individual species in the natural environment and their capacity to adapt. This emphasis expands our focus on stress biology and medicine by linking climate change effects to research on cellular stress responses of animals, micro-organisms and plants.
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