Nico A. J. van Nuland

The α-to-β Conformational Transition of Alzheimer’s Aβ-(1–42) Peptide in Aqueous Media is Reversible: A Step by Step Conformational Analysis Suggests the Location of β Conformation Seeding

Current views of the role of β‐amyloid (Aβ) peptide fibrils range from regarding them as the cause of Alzheimers pathology to having a protective function. In the last few years, it has also been suggested that soluble oligomers might be the most important toxic species. In all cases, the study of the conformational properties of Aβ peptides in soluble form constitutes a basic approach to the design of molecules with “antiamyloid” activity. We have experimentally investigated the conformational path that can lead the Aβ‐(1–42) peptide from the native state, which is represented by an α helix embedded in the membrane, to the final state in the amyloid fibrils, which is characterized by β‐sheet structures. The conformational steps were monitored by using CD and NMR spectroscopy in media of varying polarities. This was achieved by changing the composition of water and hexafluoroisopropanol (HFIP). In the presence of HFIP, β conformations can be observed in solutions that have very high water content (up to 99 % water; v/v). These can be turned back to α helices simply by adding the appropriate amount of HFIP. The transition of Aβ‐(1–42) from α to β conformations occurs when the amount of water is higher than 80 % (v/v). The NMR structure solved in HFIP/H2O with high water content showed that, on going from very apolar to polar environments, the long N‐terminal helix is essentially retained, whereas the shorter C‐terminal helix is lost. The complete conformational path was investigated in detail with the aid of molecular‐dynamics simulations in explicit solvent, which led to the localization of residues that might seed β conformations. The structures obtained might help to find regions that are more affected by environmental conditions in vivo. This could in turn aid the design of molecules able to inhibit fibril deposition or revert oligomerization processes.

Protein Folding Monitored at Individual Residues During a Two-Dimensional NMR Experiment

An approach is described to monitor directly at the level of individual residues the formation of structure during protein folding. A two-dimensional heteronuclear nuclear magnetic resonance (NMR) spectrum was recorded after the rapid initiation of the refolding of a protein labeled with nitrogen-15. The intensities and line shapes of the cross peaks in the spectrum reflected the kinetic time course of the folding events that occurred during the spectral accumulation. The method was used to demonstrate the cooperative nature of the acquisition of the native main chain fold of apo bovine α-lactalbumin. The general approach, however, should be applicable to the investigation of a wide range of chemical reactions.

The NMR determination of the IIAmtl binding site on HPr of the Escherichia coli phosphoenol pyruvate-dependent phosphotransferase system

The region of the surface of the histidine‐containing protein (HPr) which interacts with the A domain of the mannitol‐specific Enzyme II (IIAmtl) has been mapped by titrating the A‐domain into a solution of 15N‐labeled HPr and monitoring the effects on the amide proton and nitrogen chemical shifts via heteronuclear single quantum correlation spectroscopy (HSQC). Fourteen of the eighty‐five HPr amino acid residues show large changes in either the 15N or 1H chemical shifts or both as a result of the presence of IIAmtl while a further seventeen residues experience lesser shifts. Most of the residues involved are surface residues accounting for approximately 25% of the surface of HPr. Phosphorylation of HPr with catalytic amounts of Enzyme I (EI), in the absence of IIAmtl resulted in chemical shift changes in a sub‐set of the above residues; these were located more in the vicinity of the active site phospho‐histidine. Phosphorylation of the HPr/IIAmtl complex resulted in a HSQC spectrum which was indistinguishable from the P‐HPr spectrum in the absence of IIAmtl indicating that, as expected, the complex P‐HPr/P‐IIAmtl does not exist even at the high concentrations necessary for NMR.

Isolation and structural characterization of epilancin 15X, a novel lantibiotic from a clinical strain of Staphylococcus epidermidis

The potential application of lantibiotics as food‐preserving agents and more recently as antibiotics has strongly increased the interest in these antibacterial peptides. Here, we report the elucidation of the primary and three‐dimensional structures of the novel lantibiotic epilancin 15X from Staphylococcus epidermidis using high‐resolution nuclear magnetic resonance spectroscopy and tandem mass spectrometry. The molecule contains ten post‐translationally modified amino acids, three lanthionine ring structures and a hydroxy‐propionyl N‐terminal moiety. The primary and tertiary structure and the distribution of positive charges are closely similar to the previously identified lantibiotic epilancin K7, most likely indicative of a common mode of action.

Role of aromatic amino acids in carbohydrate binding of plant lectins: Laser photo chemically induced dynamic nuclear polarization study of hevein domain-containing lectins

Carbohydrate recognition by lectins often involves the side chains of tyrosine, tryptophan, and histidine residues. These moieties are able to produce chemically induced dynamic nuclear polarization (CIDNP) signals after laser irradiation in the presence of a suitable radical pair‐generating dye. Elicitation of such a response in proteins implies accessibility of the respective groups to the light‐absorbing dye. In principle, this technique is suitable to monitor surface properties of a receptor and the effect of ligand binding if CIDNP‐reactive amino acids are affected. The application of this method in glycosciences can provide insights into the protein‐carbohydrate interaction process, as illustrated in this initial study. It focuses on a series of N‐acetylglucosamine‐binding plant lectins of increasing structural complexity (hevein, pseudohevein, Urtica dioica agglutinin and wheat germ agglutinin and its domain B), for which structural NMR‐ or X‐ray crystallographic data permit a decision of the validity of the CIDNP method‐derived conclusions. On the other hand, the CIDNP data presented in this study can be used for a rating of our molecular models of hevein, pseudohevein, and domain B obtained by various modeling techniques. Experimentally, the shape and intensity of CIDNP signals are determined in the absence and in the presence of specific glycoligands. When the carbohydrate ligand is bound, CIDNP signals of side chain protons of tyrosine, tryptophan, or histidine residues are altered, for example, they are broadened and of reduced intensity or disappear completely. In the case of UDA, the appearance of a new tryptophan signal upon ligand binding was interpreted as an indication for a conformational change of the corresponding indole ring. Therefore, CIDNP represents a suitable tool to study protein‐carbohydrate interactions in solution, complementing methods such as X‐ray crystallography, high‐resolution multidimensional nuclear magnetic resonance, transferred nuclear Overhauser effect experiments, and molecular modeling. Proteins 28:268–284, 1997

Rapid Formation of Non-native Contacts During the Folding of HPr Revealed by Real-time Photo-CIDNP NMR and Stopped-flow Fluorescence Experiments

We report the combined use of real-time photo-CIDNP NMR and stopped-flow fluorescence techniques to study the kinetic refolding of a set of mutants of a small globular protein, HPr, in which each of the four phenylalanine residues has in turn been replaced by a tryptophan residue. The results indicate that after refolding is initiated, the protein collapses around at least three, and possibly all four, of the side-chains of these residues, as (i) the observation of transient histidine photo-CIDNP signals during refolding of three of the mutants (F2W, F29W, and F48W) indicates a strong decrease in tryptophan accessibility to the flavin dye; (ii) iodide quenching experiments show that the quenching of the fluorescence of F48W is less efficient for the species formed during the dead-time of the stopped-flow experiment than for the fully native state; and (iii) kinetic fluorescence anisotropy measurements show that the tryptophan side-chain of F48W has lower mobility in the dead-time intermediate state than in both the fully denatured and fully native states. The hydrophobic collapse observed for HPr during the early stages of its folding appears to act primarily to bury hydrophobic residues. This process may be important in preventing the protein from aggregating prior to the acquisition of native-like structure in which hydrophobic residues are exposed in order to play their role in the function of the protein. The phenylalanine residue at position 48 is likely to be of particular interest in this regard as it is involved in the binding to enzymes I and II that mediates the transfer of a phosphoryl group between the two enzymes.

Development of Enzymatic Activity during Protein Folding DETECTION OF A SPECTROSCOPICALLY SILENT NATIVE-LIKE INTERMEDIATE OF MUSCLE ACYLPHOSPHATASE

The recovery of enzymatic activity during the folding of muscle acylphosphatase and two single residue mutants (proline 54 to alanine and proline 71 to alanine) from 7m urea has been monitored and compared with the development of intrinsic fluorescence emission. Fluorescence measurements reveal the presence in the wild-type protein of a major rapid refolding phase followed by a second low amplitude slow phase. The slow phase is absent in the fluorescence trace acquired with the proline 54 to alanine mutant, suggesting the involvement of this proline residue in the fluorescence-detected slow phase of the wild-type protein. The major kinetic phase is associated with a considerable recovery of enzymatic activity, indicating that a large fraction of molecules refolds with effective two-state behavior. The use of time-resolved enzymatic activity as a probe to follow the folding process reveals, however, the presence of another exponential slow phase arising from proline 71. This slow phase is not observable by utilizing optical probes, indicating that, unlike proline 54, thecis to trans isomerization of proline 71 can take place in an intermediate possessing a native-like fold. We suggest that, although spectroscopically silent and structurally insignificant, the cis-trans interconversion of proline residues in native-like intermediates may be crucial for the generation of enzymatic activity of functional enzymes.

The high-resolution NMR structure of the R21A Spc-SH3:P41 complex: Understanding the determinants of binding affinity by comparison with Abl-SH3

BackgroundSH3 domains are small protein modules of 60–85 amino acids that bind to short proline-rich sequences with moderate-to-low affinity and specificity. Interactions with SH3 domains play a crucial role in regulation of many cellular processes (some are related to cancer and AIDS) and have thus been interesting targets in drug design. The decapeptide APSYSPPPPP (p41) binds with relatively high affinity to the SH3 domain of the Abl tyrosine kinase (Abl-SH3), while it has a 100 times lower affinity for the α-spectrin SH3 domain (Spc-SH3).ResultsHere we present the high-resolution structure of the complex between the R21A mutant of Spc-SH3 and p41 derived from NMR data. Thermodynamic parameters of binding of p41 to both WT and R21A Spc-SH3 were measured by a combination of isothermal titration and differential scanning calorimetry. Mutation of arginine 21 to alanine in Spc-SH3 increases 3- to 4-fold the binding affinity for p41 due to elimination at the binding-site interface of the steric clash produced by the longer arginine side chain. Amide hydrogen-deuterium experiments on the free and p41-bound R21A Spc-SH3 domain indicate that binding elicits a strong reduction in the conformational flexibility of the domain. Despite the great differences in the thermodynamic magnitudes of binding, the structure of the R21A Spc-SH3:P41 complex is remarkably similar to that of the Abl-SH3:P41 complex, with only few differences in protein-ligand contacts at the specificity pocket. Using empirical methods for the prediction of binding energetics based on solvent-accessible surface area calculations, the differences in experimental energetics of binding between the two complexes could not be properly explained only on the basis of the structural differences observed between the complexes. We suggest that the experimental differences in binding energetics can be at least partially ascribed to the absence in the R21A Spc-SH3:P41 complex of several buried water molecules, which have been proposed previously to contribute largely to the highly negative enthalpy and entropy of binding in the Abl-SH3:P41 complex.ConclusionBased on a deep structural and thermodynamic analysis of a low and high affinity complex of two different SH3 domains with the same ligand p41, we underline the importance of taking into account in any effective strategy of rational design of ligands, factors different from the direct protein-ligand interactions, such as the mediation of interactions by water molecules or the existence of cooperative conformational effects induced by binding.

Detection and Characterization of Partially Unfolded Oligomers of the SH3 Domain of α-Spectrin

For the purpose of equilibrium and kinetic folding-unfolding studies, the SH3 domain of α-spectrin (spc-SH3) has long been considered a classic two-state folding protein. In this work we have indeed observed that the thermal unfolding curves of spc-SH3 measured at pH 3.0 by differential scanning calorimetry, circular dichroism, and NMR follow apparently the two-state model when each unfolding profile is considered individually. Nevertheless, we have found that protein concentration has a marked effect upon the thermal unfolding profiles. This effect cannot be properly explained in terms of the two-state unfolding model and can only be interpreted in terms of the accumulation of intermediate associated states in equilibrium with the monomeric native and unfolded states. By chemical cross-linking and pulsed-field gradient NMR diffusion experiments we have been able to confirm the existence of associated states formed during spc-SH3 unfolding. A three-state model, in which a dimeric intermediate state is assumed to be significantly populated, provides the simplest interpretation of the whole set of thermal unfolding data and affords a satisfactory explanation for the concentration effects observed. Whereas at low concentrations the population of the associated intermediate state is negligible and the unfolding process consequently takes place in a two-state fashion, at concentrations above ∼0.5 mM the population of the intermediate state becomes significant at temperatures between 45°C and 80°C and reaches up to 50% at the largest concentration investigated. The thermodynamic properties of the intermediate state implied by this analysis fall in between those of the unfolded state and the native ones, indicating a considerably disordered conformation, which appears to be stabilized by oligomerization.

A partially folded intermediate species of the β-sheet protein apo-pseudoazurin is trapped during proline-limited folding

The folding of apo‐pseudoazurin, a 123‐residue, predominantly β‐sheet protein with a complex Greek key topology, has been investigated using several biophysical techniques. Kinetic analysis of refolding using far‐ and near‐ultraviolet circular dichroism (UV CD) shows that the protein folds slowly to the native state with rate constants of 0.04 and 0.03 min−1, respectively, at pH 7.0 and at 15°C. This process has an activation enthalpy of ∼90 kJ/mole and is catalyzed by cyclophilin A, indicating that folding is limited by trans‐cis proline isomerization, presumably around the Xaa‐Pro 20 bond that is in the cis isomer in the native state. Before proline isomerization, an intermediate accumulates during folding. This species has a substantial signal in the far‐UV CD, a nonnative signal in the near‐UV CD, exposed hydrophobic surfaces (judged by 1‐anilino naphthalenesulphonate binding), a noncooperative denaturation transition, and a dynamic structure (revealed by line broadening on the nuclear magnetic resonance time scale). We compare the properties of this intermediate with partially folded states of other proteins and discuss its role in folding of this complex Greek key protein.