Ultrafast cooling reveals microsecond-scale biomolecular dynamics

Mark E. Polinkovsky; Yann Gambin; Priya R. Banerjee; Michael J. Erickstad; Alex Groisman; Ashok A. Deniz

doi:10.1038/ncomms6737

Ultrafast cooling reveals microsecond-scale biomolecular dynamics

Mark E. Polinkovsky
, Yann Gambin
, Priya R. Banerjee
, Michael J. Erickstad
, Alex Groisman
, Ashok A. Deniz

Physics

University of California at San Diego
Scripps Research Institute
University of Queensland

Research output: Contribution to journal › Article › peer-review

25 Scopus citations

Abstract

The temperature-jump technique, in which the sample is rapidly heated by a powerful laser pulse, has been widely used to probe the fast dynamics of folding of proteins and nucleic acids. However, the existing temperature-jump setups tend to involve sophisticated and expensive instrumentation, while providing only modest temperature changes of ∼10-15 €‰°C, and the temperature changes are only rapid for heating, but not cooling. Here we present a setup comprising a thermally conductive sapphire substrate with light-absorptive nano-coating, a microfluidic device and a rapidly switched moderate-power infrared laser with the laser beam focused on the nano-coating, enabling heating and cooling of aqueous solutions by ∼50 €‰°C on a 1- 1/4s time scale. The setup is used to probe folding and unfolding dynamics of DNA hairpins after direct and inverse temperature jumps, revealing low-pass filter behaviour during periodic temperature variations.

Original language	English
Article number	5737
Journal	Nature Communications
Volume	5
DOIs	https://doi.org/10.1038/ncomms6737
State	Published - Dec 2014

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10.1038/ncomms6737

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title = "Ultrafast cooling reveals microsecond-scale biomolecular dynamics",

abstract = "The temperature-jump technique, in which the sample is rapidly heated by a powerful laser pulse, has been widely used to probe the fast dynamics of folding of proteins and nucleic acids. However, the existing temperature-jump setups tend to involve sophisticated and expensive instrumentation, while providing only modest temperature changes of ∼10-15 €‰°C, and the temperature changes are only rapid for heating, but not cooling. Here we present a setup comprising a thermally conductive sapphire substrate with light-absorptive nano-coating, a microfluidic device and a rapidly switched moderate-power infrared laser with the laser beam focused on the nano-coating, enabling heating and cooling of aqueous solutions by ∼50 €‰°C on a 1- 1/4s time scale. The setup is used to probe folding and unfolding dynamics of DNA hairpins after direct and inverse temperature jumps, revealing low-pass filter behaviour during periodic temperature variations.",

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AU - Polinkovsky, Mark E.

AU - Gambin, Yann

AU - Banerjee, Priya R.

AU - Erickstad, Michael J.

AU - Groisman, Alex

AU - Deniz, Ashok A.

PY - 2014/12

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Ultrafast cooling reveals microsecond-scale biomolecular dynamics

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