Abstract
Dynamic properties are functionally important in many proteins, including the enzyme adenylate kinase (AK), for which the open/closed transition limits the rate of catalytic turnover. Here, we compare our previously published coarse-grained (double-well Gō) simulation of mesophilic AK from E. coli (AKmeso) to simulations of thermophilic AK from Aquifex aeolicus (AKthermo). In AKthermo, as with AKmeso, the LID domain prefers to close before the NMP domain in the presence of ligand, but LID rigid-body flexibility in the open (O) ensemble decreases significantly. Backbone foldedness in O and/or transition state (TS) ensembles increases significantly relative to AKmeso in some interdomain backbone hinges and within LID. In contact space, the TS of AKthermo has fewer contacts at the CORE-LID interface but a stronger contact network surrounding the CORE-NMP interface than the TS of AKmeso. A “heated” simulation of AKthermo at 375K slightly increases LID rigid-body flexibility in accordance with the “corresponding states” hypothesis. Furthermore, while computational mutation of 7 prolines in AKthermo to their AKmeso counterparts produces similar small perturbations, mutation of these sites, especially positions 8 and 155, to glycine is required to achieve LID rigid-body flexibility and hinge flexibilities comparable to AKmeso. Mutating the 7 sites to proline in AKmeso reduces some hinges' flexibilities, especially hinge 2, but does not reduce LID rigid-body flexibility, suggesting that these two types of motion are decoupled in AKmeso. In conclusion, our results suggest that hinge flexibility and global functional motions alike are correlated with but not exclusively determined by the hinge residues. This mutational framework can inform the rational design of functionally important flexibility and allostery in other proteins toward engineering novel biochemical pathways.
Highlights
Many recent works have provided evidence that not just the average structure, and motions or ‘‘dynamics’’ around this structure, are important to protein functions including catalytic rate control [1,2,3,4], macromolecular recognition [5], and/or allosteric regulation [6,7,8,9]
Unique prolines may be important for modulating functional motions
While AKmeso and AKthermo share a LID-first closure pathway in the presence of ligand, LID rigid-body flexibility is considerably less in the O ensemble of AKthermo than in that of AKmeso
Summary
Many recent works have provided evidence that not just the average structure, and motions or ‘‘dynamics’’ around this structure, are important to protein functions including catalytic rate control [1,2,3,4], macromolecular recognition [5], and/or allosteric regulation [6,7,8,9]. Recent studies have been building evidence to support the hypothesis that evolution has selected well-defined motions in allosteric proteins. Motions in apo-proteins tend to parallel closure pathways associated with ligand binding [11,12,13]. Transition path sampling and free energy calculations for CheY have revealed a mechanism intermediate between the conformational selection and induced fit extremes [15,16]. In enzymes with lid-gated active sites, the closure transition is likely to follow a different pathway in the absence vs the presence of ligand [17,18,19]
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