# Observation of protein thermodynamics in ice by passive millimeter-wave   microscopy

**Authors:** Manabu Ishino, Akio Kishigami, Hiroyuki Kudo, Jongsuck Bae, Tatsuo, Nozokido

arXiv: 1904.00524 · 2019-05-01

## TL;DR

This paper introduces a passive millimeter-wave microscopy technique for noninvasive, high-resolution thermal imaging of proteins in frozen aqueous solutions, enabling new insights into protein conformational states at low temperatures.

## Contribution

The study presents a novel passive millimeter-wave microscope capable of imaging protein thermodynamics in ice, allowing analysis at low temperatures where traditional methods are ineffective.

## Key findings

- Displacement between protein conformations observed at 190 K.
- Microscope enables noninvasive thermal imaging in frozen conditions.
- Potential for high-throughput calorimetry in protein analysis.

## Abstract

The study of protein functions attributed to the conformation and fluctuation that are ruled by both the amino acid sequence and thermodynamics, requires thermodynamic quantities given by calorimetry using thermometric techniques. The increased need for protein function in different applications requires improvements of measurement systems assessing protein thermodynamics to handle many kinds of samples quickly. We have developed a passive millimeter-wave microscope that allows near-field imaging of thermal radiation, even in the low temperature range under room temperature where passive infrared imaging systems are ineffective. This advantage of our microscope system in combination with low thermal emission property of water ice in the millimeter-wave region enables the characterization of the thermal radiation from the proteins themselves in aqueous solution at a temperature range low enough to freeze water and to trap conformation intermediates in the proteins. Experiments performed at a millimeter-wave frequency of 50 GHz in a temperature range from 130 K to 270 K for a 20 % bovine serum albumin (BSA) aqueous solution showed a displacement between two conformational states of BSA at a temperature of approximately 190 K as a boundary. Our microscope system using this freeze-trapping method is expected to provide noninvasive thermal images to enable novel high-throughput calorimetry useful for the analysis of protein functions.

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Source: https://tomesphere.com/paper/1904.00524