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Understanding the heterogeneity intrinsic to protein folding

Relating the native fold of a protein to its amino acid sequence remains a fundamental problem in biology. While computer algorithms have demonstrated recently their prowess in predicting what structure a particular amino acid sequence will fold to, an understanding of how and why a specific protein...

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Published in:	Current opinion in structural biology 2024-02, Vol.84, p.102738-102738, Article 102738
Main Authors:	Bhatia, Sandhya, Udgaonkar, Jayant B.
Format:	Article
Language:	English
Subjects:	Amino Acid Sequence Computer Simulation Conformational heterogeneity Entropy Folding pathways Intermediate ensemble Protein Conformation Protein Folding Proteins - chemistry Proteins - genetics Time-resolved FRET
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description	Relating the native fold of a protein to its amino acid sequence remains a fundamental problem in biology. While computer algorithms have demonstrated recently their prowess in predicting what structure a particular amino acid sequence will fold to, an understanding of how and why a specific protein fold is achieved remains elusive. A major challenge is to define the role of conformational heterogeneity during protein folding. Recent experimental studies, utilizing time-resolved FRET, hydrogen-exchange coupled to mass spectrometry, and single-molecule force spectroscopy, often in conjunction with simulation, have begun to reveal how conformational heterogeneity evolves during folding, and whether an intermediate ensemble of defined free energy consists of different sub-populations of molecules that may differ significantly in conformation, energy and entropy.
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subjects	Amino Acid Sequence Computer Simulation Conformational heterogeneity Entropy Folding pathways Intermediate ensemble Protein Conformation Protein Folding Proteins - chemistry Proteins - genetics Time-resolved FRET
title	Understanding the heterogeneity intrinsic to protein folding
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