Issue 15, 2024

An integrative temperature-controlled microfluidic system for budding yeast heat shock response analysis at the single-cell level

Abstract

Cells can respond and adapt to complex forms of environmental change. Budding yeast is widely used as a model system for these stress response studies. In these studies, the precise control of the environment with high temporal resolution is most important. However, there is a lack of single-cell research platforms that enable precise control of the temperature and form of cell growth. This has hindered our understanding of cellular coping strategies in the face of diverse forms of temperature change. Here, we developed a novel temperature-controlled microfluidic platform that integrates a microheater (using liquid metal) and a thermocouple (liquid metal vs. conductive PDMS) on a chip. Three forms of temperature changes (step, gradient, and periodical oscillations) were realized by automated equipment. The platform has the advantages of low cost and a simple fabrication process. Moreover, we investigated the nuclear entry and exit behaviors of the transcription factor Msn2 in yeast in response to heat stress (37 °C) with different heating modes. The feasibility of this temperature-controlled platform for studying the protein dynamic behavior of yeast cells was demonstrated.

Graphical abstract: An integrative temperature-controlled microfluidic system for budding yeast heat shock response analysis at the single-cell level

Supplementary files

Article information

Article type
Paper
Submitted
11 Apr 2024
Accepted
17 Jun 2024
First published
18 Jun 2024

Lab Chip, 2024,24, 3658-3667

An integrative temperature-controlled microfluidic system for budding yeast heat shock response analysis at the single-cell level

J. Hong, H. He, Y. Xu, S. Wang and C. Luo, Lab Chip, 2024, 24, 3658 DOI: 10.1039/D4LC00313F

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