15N NMR Relaxation Studies of Backbone Dynamics in Free and Steroid-Bound Δ5-3-Ketosteroid Isomerase from Pseudomonas testosteroni

Yun, Sunggoo; Jang, Dogeun; Kim, Do-Hyung; Choi, Kwan Yong; Lee, Hee Cheon

doi:10.1021/bi0023192

Cited by 31 publications

(34 citation statements)

References 46 publications

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“…Such observations are contrary to the perhaps intuitive expectation that adding a ligand will simply tighten down the protein and produce a global reduction in configurational entropy. However, they are consistent with NMR studies of proteins showing that ligand-binding can tighten the binding site while making other regions of the protein more mobile [10, 11, 14, 64, 65, 66, 67, 68, 69]. In fact, it has been proposed that there is a general “conformational relay” mechanism that balances increased rigidity of some residues against increased flexibility of their neighbors [14].…”

Section: Discussionsupporting

confidence: 81%

Configurational Entropy in Protein–Peptide Binding:

Killian

Kravitz

Somani

et al. 2009

Journal of Molecular Biology

111

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Configurational entropy is thought to influence biomolecular processes, but there are still many open questions about this quantity, including its magnitude, its relationship to molecular structure, and the importance of correlation. The mutual information expansion (MIE) provides a novel and systematic approach to computing configurational entropy changes due to correlated motions from molecular simulations. Here, we present the first application of the MIE method to protein-ligand binding, using multiple molecular dynamics simulations (MMDSs) to study association of the UEV domain of the protein Tsg101 and an HIV-derived nonapeptide. The current investigation utilizes the second-order MIE approximation, which treats correlations between all pairs of degrees of freedom. The computed change in configurational entropy is large and is found to have a major contribution from changes in pairwise correlation. The results also reveal intricate structure-entropy relationships. Thus, the present analysis suggests that, in order for a model of binding to be accurate, it must include a careful accounting of configurational entropy changes.

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Section: Discussionsupporting

confidence: 81%

Configurational Entropy in Protein–Peptide Binding:

Killian

Kravitz

Somani

et al. 2009

Journal of Molecular Biology

111

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“…In these cases, binding is associated with a loss of conformational entropy that is necessarily offset by increases in solvent entropy and/or the formation of favorable enthalpic interactions. Decreases/increases in backbone dynamics that are compensated for by increases/decreases (respectively) in distal regions in the backbone, as we report here, have also been found for protein hydrophobic target interactions (21,41,45,(51)(52)(53)(54)(55). It may be that the observed increase in flexibility in the binding pocket accompanies the release of structured water molecules from the solvent accessible hydrophobic surfaces.…”

Section: The Distribution Of Order Parameters-whereas the Values Of Ssupporting

confidence: 80%

Induction of Flexibility through Protein-Protein Interactions

Fayos

Melacini

Newlon

et al. 2003

Journal of Biological Chemistry

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Protein-protein interactions control many critical functions in biology, ranging from tight binding antibody-antigen recognition events to transient interactions between enzymes in a signaling pathway. These interactions can be complex; there are sometimes a number of diverse proteins that can interact with a particular target molecule (1, 2). Elucidation of key intermolecular contacts between protein partners can aid in the development of small molecule inhibitors and/or promoters of these important interactions, which in turn control function. A particularly interesting area in biology today is the investigation of the molecular mechanisms of the assembly/disassembly of signaling networks in response to a specific cellular signal (3). Indeed, the spatiotemporal compartmentalization of signaling molecules affords biological control by poising interacting partners in close proximity to substrate(s) and/or regulatory elements (4).Targeting of the cyclic AMP-dependent protein kinase (PKA) 1 holoenzyme through interactions with A kinase anchoring proteins (AKAPs) has emerged as an important modulator of PKA activity in diverse tissues (5). The PKA holoenzyme consists of a regulatory subunit (R 2 ) dimer and two catalytic (C) subunits (6). Phosphorylation of target proteins is carried out by the C subunit, whereas the N-terminal 45 residues of the R subunit mediates both dimerization and subcellular localization via AKAP recognition (7,8). Hence, the N-terminal functional domain is termed a D/D motif because it dimerizes and docks to anchoring partners. Solution structural studies revealed that the type II␣ D/D of PKA packs into an antiparallel, dimeric X-type four-helix bundle, with a surface-exposed hydrophobic groove that is the site of anchoring interactions (9, 10). PKA interacts with a diverse family of proteins. Sequence alignment of the identified AKAPs, to date, reveals no specific recognition sequence for the D/D. However, a conserved structure consistent with an amphipathic helix was predicted, and has been demonstrated in recent solution structural studies of a peptide derivative of the prototypic AKAP human thyroid anchoring protein Ht31 (residues 493-515 and designated Ht31 pep ) (7,11,12). This peptide derivative of Ht31 exhibits a nanomolar binding affinity for the type II D/D (12, 13) via hydrophobic-hydrophobic interactions between the surface-accessible hydrophobic groove on the D/D and the hydrophobic face of the AKAP-derived amphipathic helix (10,14).In an effort to gain a better understanding of the physicochemical basis for PKA-AKAP interactions, we initiated hydrogen/deuterium (H/D) exchange and backbone relaxation studies of the D/D free and in complex with Ht31 pep . In contrast to recent work described by Powell et al. (15) using H/D exchange to measure ligand-binding affinities, we observe only modest changes in the H/D protection factors upon complex formation, despite the nanomolar binding affinity of Ht31 for the D/D (11). Unexpectedly, we also find that backbone flexibility in the bi...

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“…There is increasing evidence from dynamics studies involving binding of peptides, proteins, and singlestranded DNA and RNA to proteins, to indicate that binding does not always lead to motional restriction. 14,15,[36][37][38][39][40] In many of the above examples, increased mobility in much of the protein has been reported with complex pattern of motions across the interface. In single-stranded DNA binding to the Cterminal DNA binding domain of Escherichia coli topoisomerase I, a majority of residues show a slight decrease in S 2 and almost all residues have increased R ex following DNA binding.…”

Section: Significance Of Interface Dynamicsmentioning

confidence: 99%