Folding and assembly of the large molecular machine Hsp90 studied in single-molecule experiments

Folding and assembly of the large molecular machine Hsp90 studied in single-molecule experiments

Folding of small proteins often occurs in a two-state manner and is well understood both experimentally and theoretically. However, many proteins are much larger and often populate misfolded states, complicating their folding process significantly. Here we study the complete folding and assembly pro...

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Bibliographic Details
Published in:Proceedings of the National Academy of Sciences - PNAS 2016-02, Vol.113 (5), p.1232-1237
Main Authors: Jahn, Markus, Buchner, Johannes, Hugel, Thorsten, Rief, Matthias
Format: Article
Language:eng
Subjects:
Amino acids
Biological Sciences
Dimerization
Experiments
Heat shock proteins
HSP90 Heat-Shock Proteins - chemistry
Kinetics
Protein Folding
Reaction kinetics
Ribonucleic acid
RNA
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Summary:Folding of small proteins often occurs in a two-state manner and is well understood both experimentally and theoretically. However, many proteins are much larger and often populate misfolded states, complicating their folding process significantly. Here we study the complete folding and assembly process of the 1,418 amino acid, dimeric chaperone Hsp90 using single-molecule optical tweezers. Although the isolated C-terminal domain shows two-state folding, we find that the isolated N-terminal as well as the middle domain populate ensembles of fast-forming, misfolded states. These intradomain misfolds slowdown folding by an order of magnitude. Modeling folding as a competition between productive and misfolding pathways allows us to fully describe the folding kinetics. Beyond intradomain misfolding, folding of the full-length protein is further slowed by the formation of interdomain misfolds, suggesting that with growing chain lengths, such misfolds will dominate folding kinetics. Interestingly, we find that small stretching forces applied to the chain can accelerate folding by preventing the formation of cross-domain misfolding intermediates by leading the protein along productive pathways to the native state. The same effect is achieved by cotranslational folding at the ribosome in vivo.
ISSN:0027-8424
1091-6490