Sarah Lecinski, Jamieson A L Howard, Chris MacDonald, Mark C Leake
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引用次数: 0
Abstract
Background: Cells employ myriad regulatory mechanisms to maintain protein homeostasis, termed proteostasis, to ensure correct cellular function. Dysregulation of proteostasis, which is often induced by physiological stress and ageing, often results in protein aggregation in cells. These aggregated structures can perturb normal physiological function, compromising cell integrity and viability, a prime example being early onset of several neurodegenerative diseases. Understanding aggregate dynamics in vivo is therefore of strong interest for biomedicine and pharmacology. However, factors involved in formation, distribution and clearance of intracellular aggregates are not fully understood.
Methods: Here, we report an improved methodology for production of fluorescent aggregates in model budding yeast which can be detected, tracked and quantified using fluorescence microscopy in live cells. This new openly-available technology, iPAR (inducible Protein Aggregation Reporter), involves monomeric fluorescent protein reporters fused to a ∆ssCPY* aggregation biomarker, with expression controlled under the copper-regulated CUP1 promoter.
Results: Monomeric tags overcome challenges associated with non-physiological reporter aggregation, whilst CUP1 provides more precise control of protein production. We show that iPAR and the associated bioimaging methodology enables quantitative study of cytoplasmic aggregate kinetics and inheritance features in vivo. We demonstrate that iPAR can be used with traditional epifluorescence and confocal microscopy as well as single-molecule precise Slimfield millisecond microscopy. Our results indicate that cytoplasmic aggregates are mobile and contain a broad range of number of iPAR molecules, from tens to several hundred per aggregate, whose mean value increases with extracellular hyperosmotic stress.
Discussion: Time lapse imaging shows that although larger iPAR aggregates associate with nuclear and vacuolar compartments, we show directly, for the first time, that these proteotoxic accumulations are not inherited by daughter cells, unlike nuclei and vacuoles. If suitably adapted, iPAR offers new potential for studying diseases relating to protein oligomerization processes in other model cellular systems.
Supplementary information: The online version contains supplementary material available at 10.1186/s44330-025-00023-w.
背景:细胞采用多种调节机制来维持蛋白质稳态,称为蛋白质稳态,以确保正确的细胞功能。蛋白质平衡失调通常由生理应激和衰老引起,通常导致细胞内蛋白质聚集。这些聚集的结构可以扰乱正常的生理功能,损害细胞的完整性和活力,一个主要的例子是一些神经退行性疾病的早期发病。因此,生物医学和药理学对体内聚合动力学有着浓厚的兴趣。然而,与细胞内聚集体的形成、分布和清除有关的因素尚不完全清楚。方法:在这里,我们报告了一种改进的方法,用于在模型出芽酵母中生产荧光聚集体,可以在活细胞中使用荧光显微镜检测,跟踪和定量。这项新技术名为iPAR (inducible Protein Aggregation Reporter,诱导型蛋白聚集报告因子),将单体荧光蛋白报告因子融合到一个∆ssCPY*聚集的生物标志物上,在铜调控的CUP1启动子下控制其表达。结果:单体标签克服了与非生理性报告聚集相关的挑战,而CUP1提供了更精确的蛋白质生产控制。我们表明iPAR和相关的生物成像方法能够定量研究体内细胞质聚集动力学和遗传特征。我们证明了iPAR可以与传统的会聚荧光和共聚焦显微镜以及单分子精确细场毫秒显微镜一起使用。我们的研究结果表明,细胞质聚集体是可移动的,并且含有广泛数量的iPAR分子,每个聚集体从几十到几百个,其平均值随着细胞外高渗胁迫而增加。讨论:延时成像显示,尽管较大的iPAR聚集体与细胞核和液泡室有关,但我们首次直接显示,这些蛋白质毒性聚集体不像细胞核和液泡那样由子细胞遗传。如果适当调整,iPAR为研究其他模型细胞系统中与蛋白质寡聚化过程相关的疾病提供了新的潜力。补充信息:在线版本包含补充信息,获取地址:10.1186/s44330-025-00023-w。
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