Mapping protein-protein interactions in solution by NMR spectroscopy.

NMR is very well suited to the study of especially weak protein-protein interactions, as no crystallization is required. The available NMR methods to this end are reviewed and illustrated with applications from the recent biochemical literature: intermolecular NOEs, cross-saturation, chemical shift perturbation, dynamics and exchange perturbation, paramagnetic methods, and dipolar orientation. Most of these methods are now routinely applied for complexes with total molecular mass of 60 kDa and can likely be applied to systems up to 1000 kDa. A substantial fraction of complexes studied show distinct effects of induced fit affecting structural and dynamical properties beyond the contact interface.     

Weak protein-protein interactions as probed by NMR spectroscopy

Weak protein-protein interactions (PPIs) are fundamental to many cellular processes, such as reversible cell-cell contact, rapid enzyme turnover and transient assembly and/or reassembly of large signaling complexes. However, structural and functional characterizations of weak PPIs have been technically challenging and lagged behind those for strong PPIs. Here, we describe nuclear magnetic resonance (NMR) spectroscopy as a highly effective tool for unraveling the atomic details of weak PPIs. We highlight the recent advances of how NMR can be used to rapidly detect and structurally determine extremely weak PPIs (K(d)>10(-4)M). Coupled with functional approaches, NMR has the potential to look into a wide variety of biologically important weak PPIs at the detailed molecular level, thereby facilitating a thorough view of how proteins function in living cells.     

Structural characterization of peptide hormone/receptor interactions by NMR spectroscopy.

The structural characterization of peptide hormones and their interaction with G-protein (guanine nucleotide-binding regulatory protein) coupled receptors by high-resolution nmr is described. The general approaches utilized can be categorized into three different classes based on their target: the ligand, the receptor, and the ligand/receptor complex. Examples of these different approaches, aimed at facilitating the rational design of peptides and peptidomimetics with improved pharmacological profiles, based on work carried out in our own laboratory, are given. In the ligand-based approach, the high-resolution structures of bradykinin analogues allowing for the development of a structure-activity relationship for activation of the B1 receptor are described. Studies targeting the receptor are to a large extent theoretical, based on computational molecular modeling. However, experimentally based structural features provided by high-resolution nmr can be used to great advantage, providing insight into the mechanism of receptor function, as illustrated here with results from parathyroid hormone. A similar combination of theoretical methods, supplemented by high-resolution structures from nmr has been utilized to probe the formation and stabilization of the ligand/receptor complex both for parathyroid hormone and cholecystokinin. In each of these three approaches, the importance of well-designed peptide mimetics and accurate structural analysis by high-resolution nmr, will be highlighted.     

Facile detection of protein-protein interactions by one-dimensional NMR spectroscopy

Two methods for detecting protein-protein interactions in solution using one-dimensional (1D) NMR spectroscopy are described. Both methods rely on measurement of the intensity of the strongest methyl resonance (SMR), which for most proteins is observed at 0.8-0.9 ppm. The severe resonance overlap in this region facilitates detection of the SMR at low micromolar and even sub-micromolar protein concentrations. A decreased SMR intensity in the 1H NMR spectrum of a protein mixture compared to the added SMR intensities of the isolated proteins reports that the proteins interact (SMR method). Decreased SMR intensities in 1D 13C-edited 1H NMR spectra of 13C-labeled proteins upon addition of unlabeled proteins or macromolecules also demonstrate binding (SMRC method). Analysis of the interaction between XIAP and Smac, two proteins involved in apoptosis, illustrates both methods. A study showing that phospholipids compete with the neuronal core complex for Ca2+-dependent binding to the presynaptic Ca2+-sensor synaptotagmin 1 illustrates the usefulness of the SMRC method in studying multicomponent systems.     

An NMR spectroscopy study of bendaline-albumin interactions

The complete assignment of the 1H and 13C NMR spectra of bendaline (BNDL) was performed by mono-dimensional and homo- and hetero-correlated two-dimensional NMR experiments. The interaction between bendaline and albumin was also studied by the analysis of the motional parameters spin-lattice relaxation times, allowing the motional state of the BNDL free and bound with albumin to be defined. In absence of albumin the indazolacetic and benzylic moieties are characterized by roughly the same mobility and by positive sigma (cross-relaxation rates) values. In the presence of the macromolecule, the indazolacetic and benzylic moieties and the lysine change their motional behaviour to different extents, as indicated by correlation times. Data obtained in absence and in presence of the protein show that the molecular moiety of the bendaline most involved in the binding with albumin is the fragment H-4 H-5. The binding constant was evaluated at 2.4x10(3)M(-1).     

The membrane interactions of antimicrobial peptides revealed by solid-state NMR spectroscopy

Solid-state NMR spectroscopic techniques provide valuable information about the structure, dynamics and topology of membrane-inserted polypeptides. In particular antimicrobial peptides (or 'host defence peptides') have early on been investigated by solid-state NMR spectroscopy and many technical innovations in this domain have been developed with the help of these compounds when reconstituted into oriented phospholipid bilayers. Using solid-state NMR spectroscopy it could be shown for the first time that magainins or derivatives thereof exhibit potent antimicrobial activities when their cationic amphipathic helix is oriented parallel to the bilayer surface, a configuration found in later years for many other linear cationic amphipathic peptides. In contrast transmembrane alignments or lipid-dependent tilt angles have been found for more hydrophobic sequences such as alamethicin or β-hairpin antimicrobials. This review presents various solid-state NMR approaches and develops the basic underlying concept how angular information can be obtained from oriented samples. It is demonstrated how this information is used to calculate structures and topologies of peptides in their native liquid-disordered phospholipid bilayer environment. Special emphasis is given to discuss which NMR parameters provide the most complementary information, the minimal number of restraints needed and the effect of motions on the analysis of the NMR spectra. Furthermore, recent (31)P and (2)H solid-state NMR measurements of lipids are presented including some unpublished data which aim at investigating the morphological and structural changes of oriented or non-oriented phospholipids. Finally the structural models that have been proposed for the mechanisms of action of these peptides will be presented and discussed in view of the solid-state NMR and other biophysical experiments.     

Kinetics of drug release from a hyaluronan-steroid conjugate investigated by NMR spectroscopy

The methylprednisolone steroid ester of hyaluronan was hydrolyzed under physiological conditions in vitro, and the kinetics of drug release was investigated by NMR spectroscopy. Transverse relaxation times are correlated with the molecular rotational freedom, which undergoes large changes for methylprednisolone when released. Multi-exponential decays were observed, which together with the corresponding population gave valuable insights into the conformational changes that occur in the biopolymer during hydrolysis. The biomaterial exists in aqueous solution in two conformations, ‘collapsed’ and ‘water-exposed’, in equilibrium. Under physiological conditions, the methylprednisolone is completely released within 48 h. Transverse relaxation times proved to be an appropriate tool for monitoring the drug release in vitro.     

The structural analysis of protein–protein interactions by NMR spectroscopy

A comprehensive understanding of protein–protein interactions is an important next step in our quest to understand how the information contained in a genome is put into action. Although a number of experimental techniques can report on the existence of a protein– protein interaction, very few can provide detailed structural information. NMR spectroscopy is one of these, and in recent years several complementary NMR approaches, including residual dipolar couplings and the use of paramagnetic effects, have been developed that can provide insight into the structure of protein–protein complexes. In this article, we review these approaches and comment on their strengths and weaknesses.     

Ca modulating α-synuclein membrane transient interactions revealed by solution NMR spectroscopy

α-Synuclein is involved in Parkinson's disease and its interaction with cell membrane is crucial to its pathological and physiological functions. Membrane properties, such as curvature and lipid composition, have been shown to affect the interactions by various techniques, but ion effects on α-synuclein membrane interactions remain elusive. Ca^2 + dynamic fluctuation in neurons plays important roles in the onset of Parkinson's disease and its influx is considered as one of the reasons to cause cell death. Using solution Nuclear Magnetic Resonance (NMR) spectroscopy, here we show that Ca^2 + can modulate α-synuclein membrane interactions through competitive binding to anionic lipids, resulting in dissociation of α-synuclein from membranes. These results suggest a negative modulatory effect of Ca^2 + on membrane mediated normal function of α-synuclein, which may provide a clue, to their dysfunction in neurodegenerative disease.     

Nature of lysozyme-water interactions by proton NMR.

Proton spin-lattice relaxation measurements were performed in 10 mM lysozyme solution as a function of temperature and degree of substitution of solvent H2O with D2O. The results show that in the temperature range from 274 to 323 K, the intermolecular lysozyme proton water proton coupling contributes appreciably to the observed water proton relaxation rate. In this system exchange between water protons and labile protein protons does not dominate the behaviour with temperature of the water-lysozyme intermolecular contribution to the spin-lattice relaxation.     

Ligand interactions with the kringle 5 domain of plasminogen. A study by 1H NMR spectroscopy

The binding of small molecules to the kringle 5 domain fragment of human plasminogen has been investigated by 1H NMR spectroscopy at 300 MHz. The compounds tested as potential ligands include L-arginine, L-lysine, and a number of aliphatic and aromatic analogs of similar size but different ionic charge configurations. Ligand/kringle 5 association constant (Ka) values were obtained from ligand titration experiments at 22 degrees C, pH 7.2. Neither L-arginine nor N alpha-acetyl-L-arginine and N alpha-acetyl-L-arginine methyl ester bind measurably to kringle 5 (Ka approximately less than 0.05 mM-1). In contrast, binding of hexylamine or epsilon-aminocaproic acid (epsilon ACA) is favored (Ka approximately 2.9 and 10.5 mM-1, respectively). Benzamidine and p-benzylaminesulfonic acid associate with kringle 5 with similar affinities (Ka approximately 3.4 and 2.2 mM-1, respectively) while benzylamine binds about twice as tightly (Ka approximately 6.3 mM-1). The higher affinities toward both benzylamine and epsilon ACA indicate that a free carboxylate group is not, by itself, a main determinant of ligand-binding to kringle 5. The experiments also reveal a definite affinity for L-arginine methyl ester, L-lysine, and N alpha-acetyl-L-lysine methyl ester. It is suggested that, although weak (0.1 approximately less than Ka approximately less than 0.6 mM-1), these interactions could be of physiological relevance in the context of plasminogen binding to the fibrin clot. Ligand-induced shifts of kringle 5 proton resonances indicate that the Trp25, His33, Tyr50, Trp62, and Tyr72 (kringle numbering convention) side chains form or neighbor the kringle 5-binding site. Benzamidine-kringle 5 magnetization transfer (Overhauser) experiments verify a close proximity of the bound ligand to these aromatic groups. A model of the binding site is proposed in which the above residues interact closely with each other and define a lipophilic surface which is accessible to the free ligand.     

Solid-state NMR spectroscopy to study protein–lipid interactions

The appropriate lipid environment is crucial for the proper function of membrane proteins. There is a tremendous variety of lipid molecules in the membrane and so far it is often unclear which component of the lipid matrix is essential for the function of a respective protein. Lipid molecules and proteins mutually influence each other; parameters such as acyl chain order, membrane thickness, membrane elasticity, permeability, lipid-domain and annulus formation are strongly modulated by proteins. More recent data also indicates that the influence of proteins goes beyond a single annulus of next-neighbor boundary lipids. Therefore, a mesoscopic approach to membrane lipid–protein interactions in terms of elastic membrane deformations has been developed. Solid-state NMR has greatly contributed to the understanding of lipid–protein interactions and the modern view of biological membranes. Methods that detect the influence of proteins on the membrane as well as direct lipid–protein interactions have been developed and are reviewed here. Examples for solid-state NMR studies on the interaction of Ras proteins, the antimicrobial peptide protegrin-1, the G protein-coupled receptor rhodopsin, and the K⁺ channel KcsA are discussed. This article is part of a Special Issue entitled Tools to study lipid functions.     

New structural insights into carbohydrate-protein interactions from NMR spectroscopy

Recently developed NMR methods have been applied to discover carbohydrate ligands for proteins and to identify their binding epitopes. The structural details of carbohydrate-protein complexes have also been examined by NMR, providing site-specific information on the architecture, binding selectivity and plasticity of the carbohydrate-binding sites of the proteins. New insights into the conformational behaviour of free and protein-bound glycomimetics pave the way for the design of carbohydrate-based therapeutics. Finally, recent progress towards elucidating the influence of glycosylation on peptide conformation will be of key importance to fully understanding the role of carbohydrates in the function of glycopeptides.     

In-cell NMR spectroscopy.

The recent development of "in-cell NMR" techniques by two independent groups has demonstrated that NMR spectroscopy can be used to characterize the conformation and dynamics of biological macromolecules inside living cells. In this article, we describe different methods and discuss current and future applications as well as critical parameters of this new technique. We show experimental results, compare them with traditional in vitro experiments, and demonstrate that differences between the in vitro and the in vivo state of a macromolecule exist and can be detected and characterized.     

Peptide structural analysis by solid-state NMR spectroscopy.

Solid-state nmr spectroscopy provides a robust method for investigating polypeptides that have been prepared by chemical synthesis and that are immobilized by strong interactions with solid surfaces or large macroscopic complexes. Solid-state nmr spectroscopy has been widely used to investigate membrane polypeptides or peptide aggregates such as amyloid fibrils. Whereas magic angle spinning solid-state nmr spectroscopy allows one to measure distances and dihedral angles with high accuracy, static membrane samples that are aligned with respect to the magnetic field direction allow one to determine the secondary structure of bound polypeptides and their orientation with respect to the bilayer normal. Peptide dynamics and the effect of polypeptides on the macroscopic phase preference of phospholipid membranes have been investigated in nonoriented samples. Investigations of the structure and topology of membrane channels, peptide antibiotics, signal sequences as well as model systems that allow one to dissect the interaction contributions in phospholipid membranes will be presented in greater detail.     

Plastocyanin-cytochrome f interactions: the influence of hydrophobic patch mutations studied by NMR spectroscopy

Transient complex formation between plastocyanin from Prochlorothrix hollandica and cytochrome f from Phormidium laminosum was investigated using nuclear magnetic resonance (NMR) spectroscopy. Binding curves derived from NMR titrations at 10 mM ionic strength reveal a 1:1 stoichiometry and a binding constant of 6 (+/-2) x 10(3) M(-1) for complex formation, 1 order of magnitude larger than that for the physiological plastocyanin-cytochrome f complex from Ph. laminosum. Chemical-shift perturbation mapping indicates that the hydrophobic patch of plastocyanin is involved in the complex interface. When the unusual hydrophobic patch residues of P. hollandica plastocyanin were reverted to the conserved residues found in most other plastocyanins (Y12G/P14L), the binding constant for the interaction with cytochrome f was unaffected. However, the chemical shift perturbation map was considerably different, and the size of the average perturbation decreased by 40%. The complexes of both the wild-type and double mutant plastocyanin with cytochrome f were sensitive to ionic strength, contrary to the physiological complex. The possible implications of these findings for the mechanism of transient complex formation are discussed.     

Kinetics of monensin complexation with sodium ions by 23Na NMR spectroscopy

The kinetics of the sodium binding to the ionophore monensin (Mon) in methanol has been studied by ²³Na NMR spectroscopy. Fast quadrupole relaxation of the bound sodium affected the relaxation rate of the free sodium through an exchange process between these two species. The exchange was found to be dominated by the reaction: Na⁺ + Mon^? ? MonNa. The dissociation rate constant at 25°C is 63 s^?1, with an activation enthalpy of 10.3 $\text{kcal}\text{mol}$ and activation entropy of ?15.8 $\text{cal}\text{mol}$ deg. These results indicate that the specificity of the binding of sodium ions to monensin is reflected in the relatively slow dissociation process. The entropy changes indicate that the activated monensin-sodium complex undergoes a conformational change, but the existence of a conformational change in monensin anion prior to complexation is excluded.     

Structure determination of membrane proteins by NMR spectroscopy.

Current strategies for determining the structures of membrane proteins in lipid environments by NMR spectroscopy rely on the anisotropy of nuclear spin interactions, which are experimentally accessible through experiments performed on weakly and completely aligned samples. Importantly, the anisotropy of nuclear spin interactions results in a mapping of structure to the resonance frequencies and splittings observed in NMR spectra. Distinctive wheel-like patterns are observed in two-dimensional 1H-15N heteronuclear dipolar/15N chemical shift PISEMA (polarization inversion spin-exchange at the magic angle) spectra of helical membrane proteins in highly aligned lipid bilayer samples. One-dimensional dipolar waves are an extension of two-dimensional PISA (polarity index slant angle) wheels that map protein structures in NMR spectra of both weakly and completely aligned samples. Dipolar waves describe the periodic wave-like variations of the magnitudes of the heteronuclear dipolar couplings as a function of residue number in the absence of chemical shift effects. Since weakly aligned samples of proteins display these same effects, primarily as residual dipolar couplings, in solution NMR spectra, this represents a convergence of solid-state and solution NMR approaches to structure determination.