Issue 20, 2022

Connecting conformational stiffness of the protein with energy landscape by a single experiment

Abstract

The structure–function dynamics of a protein as a flexible polymer is essential to describe its biological functions. Here, using single-molecule magnetic tweezers, we have studied the effect of ionic strength on the folding mechanics of protein L, and probed its folding-associated physical properties by re-measuring the same protein in a range of ammonium sulfate concentrations from 150 mM to 650 mM. We observed an electrolyte-dependent conformational dynamics and folding landscape of the protein in a single experiment. Salt increases the refolding kinetics, while decreasing the unfolding kinetics under force, which in turn modifies the barrier heights towards the folded state. Additionally, salt enhances the molecular compaction by decreasing the Kuhn length of the protein polymer from 1.18 nm to 0.58 nm, which we have explained by modifying the freely jointed chain model. Finally, we correlated polymer chain physics to the folding dynamics, and thus provided an analytical framework for understanding compaction-induced folding mechanics across a range of ionic strengths from a single experiment.

Graphical abstract: Connecting conformational stiffness of the protein with energy landscape by a single experiment

Supplementary files

Article information

Article type
Paper
Submitted
06 Dec 2021
Accepted
16 Apr 2022
First published
20 Apr 2022

Nanoscale, 2022,14, 7659-7673

Connecting conformational stiffness of the protein with energy landscape by a single experiment

S. Chakraborty, D. Chaudhuri, D. Chaudhuri, V. Singh, S. Banerjee, D. Chowdhury and S. Haldar, Nanoscale, 2022, 14, 7659 DOI: 10.1039/D1NR07582A

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