Multiplexed dynamic control of temperature to probe and observe mammalian cells.

IF 7.7 Cell systems Pub Date : 2025-03-19 Epub Date: 2025-03-12 DOI:10.1016/j.cels.2025.101234

William Benman, Pavan Iyengar, Thomas R Mumford, Zikang Huang, Manya Kapoor, Grace Liu, Lukasz J Bugaj

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Abstract

Temperature is an important biological stimulus, yet there is a lack of approaches to modulate the temperature of biological samples in a dynamic and high-throughput manner. The thermoPlate is a device for programmable control of temperature in a 96-well plate, compatible with cell culture and microscopy. The thermoPlate maintains feedback control of temperature independently in each well, with minutes-scale heating and cooling through ΔT = 15-20°C. We first used the thermoPlate to characterize the rapid temperature-dependent phase separation of a synthetic elastin-like polypeptide (ELP₅₃). We then examined stress granule (SG) formation in response to dynamic heat stress, revealing adaptation of SGs to persistent heat and formation of a memory of stress that prevented SG formation in response to subsequent heat shocks. The capabilities and open-source nature of the thermoPlate will empower the study and engineering of a wide range of thermoresponsive phenomena. A record of this paper's transparent peer review process is included in the Supplemental information.

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对温度进行多重动态控制，以探测和观察哺乳动物细胞。

温度是一种重要的生物刺激，但目前还缺乏动态、高通量调节生物样品温度的方法。热板是一种可编程控制96孔板温度的设备，与细胞培养和显微镜兼容。thermoPlate在每口井中保持独立的温度反馈控制，通过ΔT = 15-20°C进行分钟尺度的加热和冷却。我们首先使用热板来表征合成弹性蛋白样多肽（ELP53）的快速温度依赖相分离。然后，我们研究了应力颗粒（SG）在动态热应激下的形成，揭示了SGs对持续高温的适应，以及在随后的热冲击下防止SG形成的应激记忆的形成。热板的功能和开源特性将使广泛的热响应现象的研究和工程成为可能。本文的透明同行评议过程记录包含在补充信息中。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Cell systems

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