Energy landscape views for interplays among folding, binding, and allostery of calmodulin domains

Wenfei Li; Wei Wang; Shoji Takada

doi:10.1073/pnas.1402768111

New Research In

Edited by José N. Onuchic, Rice University, Houston, TX, and approved June 9, 2014 (received for review February 17, 2014)

Significance

Protein dynamics can conceptually be classified into three factors: folding, conformational transitions, and chemical events. Although couplings between every two of these factors have been well studied, explicit coupling among the three factors has not been examined due to its difficulty in direct experimental measurements. Toward this direction, calmodulin is a suitable model system. Here, constructing a computational model that integrates folding, ligand binding, and allosteric motions based on the energy landscape theory, we studied interplay among the three factors, in detail, for calmodulin domains. The analysis includes three conformational states and three binding states, resulting into nine states in total. We found multiple routes and their intriguing modulation by ligand concentration.

Abstract

Ligand binding modulates the energy landscape of proteins, thus altering their folding and allosteric conformational dynamics. To investigate such interplay, calmodulin has been a model protein. Despite much attention, fully resolved mechanisms of calmodulin folding/binding have not been elucidated. Here, by constructing a computational model that can integrate folding, binding, and allosteric motions, we studied in-depth folding of isolated calmodulin domains coupled with binding of two calcium ions and associated allosteric conformational changes. First, mechanically pulled simulations revealed coexistence of three distinct conformational states: the unfolded, the closed, and the open states, which is in accord with and augments structural understanding of recent single-molecule experiments. Second, near the denaturation temperature, we found the same three conformational states as well as three distinct binding states: zero, one, and two calcium ion bound states, leading to as many as nine states. Third, in terms of the nine-state representation, we found multiroute folding/binding pathways and shifts in their probabilities with the calcium concentration. At a lower calcium concentration, “combined spontaneous folding and induced fit” occurs, whereas at a higher concentration, “binding-induced folding” dominates. Even without calcium binding, we observed that the folding pathway of calmodulin domains can be modulated by the presence of metastable states. Finally, full-length calmodulin also exhibited an intriguing coupling between two domains when applying tension.

Footnotes

↵¹To whom correspondence may be addressed. Email: takada{at}biophys.kyoto-u.ac.jp or wangwei{at}nju.edu.cn.

Author contributions: W.L., W.W., and S.T. designed research; W.L. performed research; W.L. and S.T. contributed new reagents/analytic tools; W.L., W.W., and S.T. analyzed data; and W.L., W.W., and S.T. wrote the paper.
The authors declare no conflict of interest.
This article is a PNAS Direct Submission.
This article contains supporting information online at www.pnas.org/lookup/suppl/doi:10.1073/pnas.1402768111/-/DCSupplemental.

Freely available online through the PNAS open access option.

View Full Text