Exploring one-state downhill protein folding in single molecules

A one-state downhill protein folding process is barrierless at all conditions, resulting in gradual melting of native structure that permits resolving folding mechanisms step-by-step at atomic resolution. Experimental studies of one-state downhill folding have typically focused on the thermal denatu...

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Bibliographic Details
Published in:Proceedings of the National Academy of Sciences - PNAS 2012-01, Vol.109 (1), p.179-184
Main Authors: Liu, Jianwei, Campos, Luis A, Cerminara, Michele, Wang, Xiang, Ramanathan, Ravishankar, English, Douglas S, Muñoz, Victor
Format: Article
Language:English
Subjects:
Biological Sciences
denaturation
Dyes
Escherichia coli - metabolism
Escherichia coli Proteins - chemistry
Escherichia coli Proteins - metabolism
Fluorescence Resonance Energy Transfer - methods
Histograms
Kinetics
melting
Modeling
Molecules
Photons
photostability
Protein Denaturation
Protein Folding
Protein Structure, Tertiary
proteins
quantitative analysis
Shot noise
Statistical variance
Temperature
Trajectories
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Summary:A one-state downhill protein folding process is barrierless at all conditions, resulting in gradual melting of native structure that permits resolving folding mechanisms step-by-step at atomic resolution. Experimental studies of one-state downhill folding have typically focused on the thermal denaturation of proteins that fold near the speed limit (ca. 106 s-1) at their unfolding temperature, thus being several orders of magnitude too fast for current single-molecule methods, such as single-molecule FRET. An important open question is whether one-state downhill folding kinetics can be slowed down to make them accessible to single-molecule approaches without turning the protein into a conventional activated folder. Here we address this question on the small helical protein BBL, a paradigm of one-state downhill thermal (un)folding. We decreased 200-fold the BBL folding-unfolding rate by combining chemical denaturation and low temperature, and carried out free-diffusion single-molecule FRET experiments with 50-μs resolution and maximal photoprotection using a recently developed Trolox-cysteamine cocktail. These experiments revealed a single conformational ensemble at all denaturing conditions. The chemical unfolding of BBL was then manifested by the gradual change of this unique ensemble, which shifts from high to low FRET efficiency and becomes broader at increasing denaturant. Furthermore, using detailed quantitative analysis, we could rule out the possibility that the BBL single-molecule data are produced by partly overlapping folded and unfolded peaks. Thus, our results demonstrate the one-state downhill folding regime at the single-molecule level and highlight that this folding scenario is not necessarily associated with ultrafast kinetics.
ISSN:0027-8424
1091-6490
DOI:10.1073/pnas.1111164109