Jeffrey W. Peng

[20] Investigation of protein motions via relaxation measurements

Publisher Summary This chapter discusses the 2D pulse sequences applicable for measuring relaxation rates in singly protonated heteronuclear spin systems, such as 15 N- 1 H and 13 C α - l H. This chapter uses the symbols “I” and “S” to denote the operators or expectation values of the proton and heterospin, respectively. Thus far, most of the relaxation measurements of proteins have focused on the 15 N nucleus. This has provided insight into the general flexibility of the protein backbone. For proteins that have the benefit of 15 N enrichment to aid conformational analyses, a set of complementary backbone dynamics experiments will become routine. Future relaxation studies will undoubtedly focus on the dynamics of other parts of the protein structure and different time scales of motion. For example, increased 13 C relaxation studies should permit a more detailed picture of side-chain dynamics. The end goal of all of these research directions is to gain a clearer picture of protein dynamics using NMR and, eventually, to understand their relevance to biological function.

Modeling Conformational Ensembles of Slow Functional Motions in Pin1-WW

Protein-protein interactions are often mediated by flexible loops that experience conformational dynamics on the microsecond to millisecond time scales. NMR relaxation studies can map these dynamics. However, defining the network of inter-converting conformers that underlie the relaxation data remains generally challenging. Here, we combine NMR relaxation experiments with simulation to visualize networks of inter-converting conformers. We demonstrate our approach with the apo Pin1-WW domain, for which NMR has revealed conformational dynamics of a flexible loop in the millisecond range. We sample and cluster the free energy landscape using Markov State Models (MSM) with major and minor exchange states with high correlation with the NMR relaxation data and low NOE violations. These MSM are hierarchical ensembles of slowly interconverting, metastable macrostates and rapidly interconverting microstates. We found a low population state that consists primarily of holo-like conformations and is a “hub” visited by most pathways between macrostates. These results suggest that conformational equilibria between holo-like and alternative conformers pre-exist in the intrinsic dynamics of apo Pin1-WW. Analysis using MutInf, a mutual information method for quantifying correlated motions, reveals that WW dynamics not only play a role in substrate recognition, but also may help couple the substrate binding site on the WW domain to the one on the catalytic domain. Our work represents an important step towards building networks of inter-converting conformational states and is generally applicable.

Stereospecific gating of functional motions in Pin1

Pin1 is a modular enzyme that accelerates the cis-trans isomerization of phosphorylated-Ser/Thr-Pro (pS/T-P) motifs found in numerous signaling proteins regulating cell growth and neuronal survival. We have used NMR to investigate the interaction of Pin1 with three related ligands that include a pS-P substrate peptide, and two pS-P substrate analogue inhibitors locked in the cis and trans conformations. Specifically, we compared the ligand binding modes and binding-induced changes in Pin1 side-chain flexibility. The cis and trans binding modes differ, and produce different mobility in Pin1. The cis-locked inhibitor and substrate produced a loss of side-chain flexibility along an internal conduit of conserved hydrophobic residues, connecting the domain interface with the isomerase active site. The trans-locked inhibitor produces a weaker conduit response. Thus, the conduit response is stereoselective. We further show interactions between the peptidyl-prolyl isomerase and Trp-Trp (WW) domains amplify the conduit response, and alter binding properties at the remote peptidyl-prolyl isomerase active site. These results suggest that specific input conformations can gate dynamic changes that support intraprotein communication. Such gating may help control the propagation of chemical signals by Pin1, and other modular signaling proteins.

Sequence-specific dynamics modulate recognition specificity in WW domains

The current canon attributes the binding specificity of protein-recognition motifs to distinctive chemical moieties in their constituent amino acid sequences. However, we show for a WW domain that the sequence crucial for specificity is an intrinsically flexible loop that partially rigidifies upon ligand docking. A single-residue deletion in this loop simultaneously reduces loop flexibility and ligand binding affinity. These results suggest that sequences of recognition motifs may reflect natural selection of not only chemical properties but also dynamic modes that augment specificity.

Applications of SHAPES screening in drug discovery.

The SHAPES strategy combines nuclear magnetic resonance (NMR) screening of a library of small drug-like molecules with a variety of complementary methods, such as virtual screening, high throughput enzymatic assays, combinatorial chemistry, X-ray crystallography, and molecular modeling, in a directed search for new medicinal chemistry leads. In the past few years, the SHAPES strategy has found widespread utility in pharmaceutical research. To illustrate a variety of different implementations of the method, we will focus in this review on recent applications of the SHAPES strategy in several drug discovery programs at Vertex Pharmaceuticals.

Toward Flexibility−Activity Relationships by NMR Spectroscopy: Dynamics of Pin1 Ligands

Drug design involves iterative ligand modifications. For flexible ligands, these modifications often entail restricting conformational flexibility. However, defining optimal restriction strategies can be challenging if the relationship between ligand flexibility and biological activity is unclear. Here, we describe an approach for ligand flexibility-activity studies using Nuclear Magnetic Resonance (NMR) spin relaxation. Specifically, we use (13)C relaxation dispersion measurements to compare site-specific changes in ligand flexibility for a series of related ligands that bind a common macromolecular receptor. The flexibility changes reflect conformational reorganization resulting from formation of the receptor-ligand complex. We demonstrate this approach on three structurally similar but flexibly differentiated ligands of human Pin1, a peptidyl-prolyl isomerase. The approach is able to map the ligand dynamics relevant for activity and expose changes in those dynamics caused by conformational locking. Thus, NMR flexibility-activity studies can provide information to guide strategic ligand rigidification. As such, they help establish an experimental basis for developing flexibility-activity relationships (FAR) to complement traditional structure-activity relationships (SAR) in molecular design.

Interdomain Interactions Support Interdomain Communication in Human Pin1

Pin1 is an essential mitotic regulator consisting of a peptidyl–prolyl isomerase (PPIase) domain flexibly tethered to a smaller Trp–Trp (WW) binding domain. Communication between these domains is important for Pin1 in vivo activity; however, the atomic basis for this communication has remained elusive. Our previous nuclear magnetic resonance (NMR) studies of Pin1 functional dynamics suggested that weak interdomain contacts within Pin1 enable allosteric communication between the domain interface and the distal active site of the PPIase domain.1,2 A necessary condition for this hypothesis is that the intrinsic properties of the PPIase domain should be sensitive to interdomain contact. Here, we test this sensitivity by generating a Pin1 mutant, I28A, which weakens the wild-type interdomain contact while maintaining the overall folds of the two domains. Using NMR, we show that I28A leads to altered substrate binding affinity and isomerase activity. Moreover, I28A causes long-range perturbations to conformational flexibility in both domains, for both the apo and substrate-complexed states of the protein. These results show that the distribution of conformations sampled by the PPIase domain is sensitive to interdomain contact and strengthen the hypothesis that such contact supports interdomain allosteric communication in Pin1. Other modular systems may exploit interdomain interactions in a similar manner.

Communication breakdown: protein dynamics and drug design.

Mauldin et al. (2009) use NMR to show that drug binding can break up collective protein motions necessary for function. We discuss their findings in the context of drug discovery in pharmaceutical research.

Mapping the dynamics of ligand reorganization via 13CH3 and 13CH2 relaxation dispersion at natural abundance.

Flexible ligands pose challenges to standard structure-activity studies since they frequently reorganize their conformations upon protein binding and catalysis. Here, we demonstrate the utility of side chain 13C relaxation dispersion measurements to identify and quantify the conformational dynamics that drive this reorganization. The dispersion measurements probe methylene 13CH2 and methyl 13CH3 groups; the latter are highly prevalent side chain moieties in known drugs. Combining these side chain studies with existing backbone dispersion studies enables a comprehensive investigation of μs–ms conformational dynamics related to binding and catalysis. We perform these measurements at natural 13C abundance, in congruence with common pharmaceutical research settings. We illustrate these methods through a study of the interaction of a phosphopeptide ligand with the peptidyl-prolyl isomerase, Pin1. The results illuminate the side-chain moieties that undergo conformational readjustments upon complex formation. In particular, we find evidence that multiple exchange processes influence the side chain dispersion profiles. Collectively, our studies illustrate how side-chain relaxation dispersion can shed light on ligand conformational transitions required for activity, and thereby suggest strategies for its optimization.

Lysine Nzeta-decarboxylation switch and activation of the beta-lactam sensor domain of BlaR1 protein of methicillin-resistant Staphylococcus aureus.

The integral membrane protein BlaR1 of methicillin-resistant Staphylococcus aureus senses the presence of β-lactam antibiotics in the milieu and transduces the information to the cytoplasm, where the biochemical events that unleash induction of antibiotic resistance mechanisms take place. We report herein by two-dimensional and three-dimensional NMR experiments of the sensor domain of BlaR1 in solution and by determination of an x-ray structure for the apo protein that Lys-392 of the antibiotic-binding site is posttranslationally modified by Nζ-carboxylation. Additional crystallographic and NMR data reveal that on acylation of Ser-389 by antibiotics, Lys-392 experiences Nζ-decarboxylation. This unique process, termed the lysine Nζ-decarboxylation switch, arrests the sensor domain in the activated (“on”) state, necessary for signal transduction and all the subsequent biochemical processes. We present structural information on how this receptor activation process takes place, imparting longevity to the antibiotic-receptor complex that is needed for the induction of the antibiotic-resistant phenotype in methicillin-resistant S. aureus.