Abstract
Proteins fold up by coordinating the different segments of their polypeptide chain through a network of weak cooperative interactions. Such cooperativity results in unfolding curves that are typically sigmoidal. However, we still do not know what factors modulate folding cooperativity or the minimal amount that ensures folding into specific three-dimensional structures. Here, we address these issues on BBL, a small helical protein that folds in microseconds via a marginally cooperative downhill process (Li, P., Oliva, F. Y., Naganathan, A. N., and Muñoz, V. (2009) Proc. Natl. Acad. Sci. USA. 106, 103-108). Particularly, we explore the effects of salt-induced screening of the electrostatic interactions in BBL at neutral pH and in acid-denatured BBL. Our results show that electrostatic screening stabilizes the native state of the neutral and protonated forms, inducing complete refolding of acid-denatured BBL. Furthermore, without net electrostatic interactions, the unfolding process becomes much less cooperative, as judged by the broadness of the equilibrium unfolding curve and the relaxation rate. Our experiments show that the marginally cooperative unfolding of BBL can still be made twice as broad while the protein retains its ability to fold into the native three-dimensional structure in microseconds. This result demonstrates experimentally that efficient folding does not require cooperativity, confirming predictions from theory and computer simulations and challenging the conventional biochemical paradigm. Furthermore, we conclude that electrostatic interactions are an important factor in determining folding cooperativity. Thus, electrostatic modulation by pH-salt and/or mutagenesis of charged residues emerges as an attractive tool for tuning folding cooperativity.
Highlights
Of the various stabilizing interactions that make proteinsfold in a concerted fashion and result in sigmoidal equilibrium unfolding curves [3]
We focus on the role of electrostatic interactions
The analysis of the effects of salt and protonation on the folding relaxation kinetics of BBL offers two additional advantages: 1) the comparison between the folding relaxation rates of BBL at pH 7 and 3 under conditions where thermal stability and solution viscosity are matched (e.g. 4 M LiCl) provides an independent test of whether BBL folds through the same mechanism when is protonated and at neutral pH; and 2) with these experiments, we can investigate the kinetic manifestations of the less cooperative equilibrium unfolding induced by salt screening of electrostatic interactions
Summary
Of the various stabilizing interactions that make proteins (un)fold in a concerted fashion and result in sigmoidal equilibrium unfolding curves [3]. To investigate the electrostatic effects on the folding cooperativity of BBL (i.e. determined from the broadness of the unfolding curve and the changes in folding kinetics), we revisited the combination of acid denaturation plus salt addition.
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