Abstract
Allostery is a fundamental process by which ligand binding to a protein alters its activity at a distant site. Both experimental and theoretical evidence demonstrate that allostery can be communicated through altered slow relaxation protein dynamics without conformational change. The catabolite activator protein (CAP) of Escherichia coli is an exemplar for the analysis of such entropically driven allostery. Negative allostery in CAP occurs between identical cAMP binding sites. Changes to the cAMP-binding pocket can therefore impact the allosteric properties of CAP. Here we demonstrate, through a combination of coarse-grained modeling, isothermal calorimetry, and structural analysis, that decreasing the affinity of CAP for cAMP enhances negative cooperativity through an entropic penalty for ligand binding. The use of variant cAMP ligands indicates the data are not explained by structural heterogeneity between protein mutants. We observe computationally that altered interaction strength between CAP and cAMP variously modifies the change in allosteric cooperativity due to second site CAP mutations. As the degree of correlated motion between the cAMP-contacting site and a second site on CAP increases, there is a tendency for computed double mutations at these sites to drive CAP toward noncooperativity. Naturally occurring pairs of covarying residues in CAP do not display this tendency, suggesting a selection pressure to fine tune allostery on changes to the CAP ligand-binding pocket without a drive to a noncooperative state. In general, we hypothesize an evolutionary selection pressure to retain slow relaxation dynamics-induced allostery in proteins in which evolution of the ligand-binding site is occurring.
Highlights
Protein allostery can be communicated purely through altered entropy
Knowledge of how the interactions between cAMP and catabolite activator protein (CAP) contribute to allostery through alteration in global slow relaxation motion can assist in interpreting selection pressures on protein evolution
Free energies, ⌬G, were calculated using the full harmonic solution summed over the first 100 normal modes, and the negatively allosteric binding of cAMP to wild type full-length CAP confirmed in the modified elastic network model (ENM) by calculating a positive value for ⌬⌬G ϭ (⌬Gholo2 Ϫ ⌬Gholo1) Ϫ (⌬Gholo1 Ϫ ⌬Gapo) ϭ 93.5 cal molϪ1
Summary
Protein allostery can be communicated purely through altered entropy. Results: Altered cAMP binding strength in CAP results in changes to entropy-driven allostery. Analysis of the two major ligand binding domains of the CAP homodimer demonstrated a homotropic negative allosteric interaction between cAMP binding sites and the absence of structural change within this domain [12] This finding supports the theory that allostery can occur through predominantly entropic processes. Seven of eight CAP mutants previously examined showed a direct correlation between ⌬⌬G and the adiabatic compressibility (s°): proteins with a higher s° (reflecting increased structural flexibility in solution) demonstrated enhanced negative cooperativity [33] These experimental findings support the idea that altered correlations in global motion play a role in the regulation of allostery in CAP. These residues from naturally occurring CAP variants form a distinct population that does not show the same pattern of reduced cooperativity when mutated on simulation This suggests an evolutionary selection pressure to retain fluctuation-induced allostery when evolution of the ligand-binding site is occurring
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