Anna-Karin Gustavsson, Amin A. Banaeiyan, David D. van Niekerk, Jacky L. Snoep, Caroline B. Adiels, Mattias Goksör
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Abstract
In this unit, we provide a clear exposition of the methodology employed to study dynamic responses in individual cells, using microfluidics for controlling and adjusting the cell environment, optical tweezers for precise cell positioning, and fluorescence microscopy for detecting intracellular responses. This unit focuses on the induction and study of glycolytic oscillations in single yeast cells, but the methodology can easily be adjusted to examine other biological questions and cell types. We present a step-by-step guide for fabrication of the microfluidic device, for alignment of the optical tweezers, for cell preparation, and for time-lapse imaging of glycolytic oscillations in single cells, including a discussion of common pitfalls. A user who follows the protocols should be able to detect clear metabolite time traces over the course of up to an hour that are indicative of dynamics on the second scale in individual cells during fast and reversible environmental adjustments. © 2018 by John Wiley & Sons, Inc.
结合荧光显微镜、微流体和光学镊子研究单个酵母细胞中的糖酵解振荡
在本单元中,我们将清楚地阐述研究单个细胞动态反应的方法,使用微流体控制和调节细胞环境,光学镊子精确定位细胞,荧光显微镜检测细胞内反应。本单元侧重于单个酵母细胞中糖酵解振荡的诱导和研究,但方法可以很容易地调整以检查其他生物学问题和细胞类型。我们介绍了微流控装置的制造,光学镊子的对准,细胞制备,以及单细胞糖酵解振荡的延时成像的一步一步的指南,包括对常见陷阱的讨论。遵循该方案的用户应该能够在长达一小时的过程中检测到清晰的代谢物时间痕迹,这表明在快速和可逆的环境调整过程中单个细胞在第二个尺度上的动态。©2018 by John Wiley &儿子,Inc。
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