A Small Molecule Chemical Chaperone Optimizes Its Unfolded State Contraction and Denaturant Like Properties

Overview

Journal Sci Rep

Specialty Science

Date 2013 Dec 18

PMID 24342892

Citations 4

Authors

Sunny Sharma

Suparna Sarkar

Simanta Sarani Paul

Syamal Roy

Krishnananda Chattopadhyay

Affiliations

Soon will be listed here.

Abstract

Protein aggregation is believed to occur through the formation of misfolded conformations. It is expected that, in order to minimize aggregation, an effective small molecule chaperone would destabilize these intermediates. To study the mechanism of a chemical chaperone, we have designed a series of mutant proteins in which a tryptophan residue experiences different local environments and solvent exposures. We show that these mutants correspond to a series of conformationally altered proteins with varying degree of misfolding stress and aggregation propensities. Using arginine as a model small molecule, we show that a combination of unfolded state contraction and denaturant like properties results in selective targeting and destabilization of the partially folded proteins. In comparison, the effect of arginine towards the folded like control mutant, which is not aggregation prone, is significantly less. Other small molecules, lacking either of the above two properties, do not offer any specificity towards the misfolded proteins.

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