Comparison of the structural and dynamical properties of holo and apo bovine alpha-lactalbumin by NMR spectroscopy.

In the presence of 0.5 M NaCl at pH 7.1, the Ca(2+)-free apo form of recombinant bovine alpha-lactalbumin (BLA) is sufficiently stabilised in its native state to give well-resolved NMR spectra at 20 degrees C. The (1)H and (15)N NMR resonances of native apo-BLA have been assigned, and the chemical-shifts compared with those of the native holo protein. Large changes observed between the two forms of BLA are mainly limited to the Ca(2+)-binding region of the protein. These data suggest that Na(+) stabilises the native apo state through the screening of repulsive negative charges, at the Ca(2+)-binding site or elsewhere, rather than by a specific interaction at the vacant Ca(2+)-binding site. The hydrogen exchange protection of residues in the Ca(2+)-binding loop and the C-helix is reduced in the apo form compared to that in the holo form. This indicates that the dynamic behaviour of this region of the protein is substantially increased in the absence of the bound Ca(2+). Real-time NMR experiments show that the rearrangements of the structure associated with the conversion of the holo to apo form of the protein do not involve the detectable population of partially unfolded intermediates. Rather, the conversion appears to involve local reorganisations of the structure in the vicinity of the Ca(2+)-binding site that are coupled to the intrinsic fluctuations in the protein structure.

Comparison of the denaturant-induced unfolding of the bovine and human alpha-lactalbumin molten globules.

Residue-specific information on the urea-induced unfolding of the molten globule state of bovine alpha-lactalbumin (BLA) has been obtained using NMR spectroscopy. In agreement with previous studies on human alpha-lactalbumin (HLA) the unfolding process for BLA has been found to be non-cooperative. Both the alpha and beta-domains of the protein are substantially collapsed in the absence of denaturant but in both proteins the majority of the structure in the beta-domain unfolds prior to that in the alpha-domain. However, in BLA the protein unfolds completely in 10 M urea at 50 degrees C, whilst in HLA a stable core region persists even under these extreme conditions. Previous studies on HLA have identified eight residues that are crucial for the stability of the molten globule. Of these residues, only three are conserved in the sequence of BLA. By taking into consideration the differences in inter-residue contacts between the four alpha-helices arising from these substitutions, and the relative hydrophobicity of the helices in the two proteins, we show that it is possible to rationalise the observed differences in the behaviour of the molten globule states of the two proteins. Taken together, these results suggest that there may be a number of ways of stabilising a given protein fold, and the specific manner that this is achieved for a particular protein is determined by details of its sequence.

Probing subtle differences in the hydrogen exchange behavior of variants of the human alpha-lactalbumin molten globule using mass spectrometry.

The hydrogen-exchange behavior of the low-pH molten globule of human alpha-lactalbumin, containing all four disulfides, has been examined and compared with that of a single disulfide variant, [28-111] alpha-lactalbumin, and of a series of proline variants of [28-111] alpha-lactalbumin. The small differences in hydrogen-exchange protection exhibited by these partially folded species were compared by mixing two or more proteins and monitoring their exchange simultaneously using mass spectrometry. The effect of single proline mutations within each alpha-domain helix on hydrogen-exchange protection has been investigated using six proline variants of [28-111] alpha-lactalbumin, L11P, L12P, M30P, I95P, K108P and Q117P. The results show that proline mutations in the A, B, C and D alpha-helices lead to a loss of hydrogen-exchange protection for residues in the local helix without perturbing hydrogen-exchange protection in other regions of the protein. Thus, local unfolding of the A, B, C and D helices does not significantly alter the packing and solvent accessibility of other regions of the molten globule. By contrast, introduction of a proline residue in the C-terminal 3(10) helix produces a larger and more widespread loss of hydrogen-exchange protection, demonstrating that longer-range perturbations of the molten globule have occurred. Thus, residues in this C-terminal region must be involved in contacts that are critical for the stabilisation of the compact molten globule structure.

Structure of hen lysozyme in solution.

The structure of the 129-residue protein hen lysozyme has been determined in solution by two-dimensional 1H nuclear magnetic resonance methods. 1158 NOE distance restraints, and 68 phi and 24 chi 1 dihedral angle restraints were employed in conjunction with distance geometry and simulated annealing procedures. The overall C alpha root-mean-square deviation from the average for 16 calculated structures is 1.8(+/- 0.2) A, but excluding 14 residues in exposed disordered regions, this value reduces to 1.3(+/- 0.2) A. Regions of secondary structure, and the four alpha-helices in particular, are well defined (C alpha root-mean-square deviation 0.8(+/- 0.3) A for helices). The main-chain fold is closely similar to structures of the protein in the crystalline state. Furthermore, many of the internal side-chains are found in well-defined conformational states in the solution structures, and these correspond well with the conformational states found in the crystal. The general high level of definition of mainchain and many internal side-chains in the solution structures is reinforced by the results of an analysis of coupling constants and ring current shifts. Many side-chains on the surface, however, are highly disordered amongst the set of solution structures. In certain cases this disorder has been shown to be dynamic in origin by the examination of 3J alpha beta coupling constants.

Different subdomains are most protected from hydrogen exchange in the molten globule and native states of human alpha-lactalbumin.

alpha-Lactalbumin (alpha-LA) is a two-domain, calcium-binding protein that forms one of the best studied molten globules. We present here amide hydrogen exchange studies of the molten globule formed by human alpha-LA at pH 2 and compare these results with a similar study of the native state at pH 6.3. The most persistent structure in the molten globule is localized in the helical domain, consistent with previous results. However, the helices most protected from hydrogen exchange in the molten globule are, in the native state, less protected from exchange than other regions of the protein. The molten globule appears to contain major elements of the native fold, but formation of the fully native state requires stabilization of structure around the calcium-binding site and domain interface.

Rapid collapse and slow structural reorganisation during the refolding of bovine alpha-lactalbumin.

The refolding of bovine alpha-lactalbumin (BLA) from its chemically denatured state in 6 M GuHCl has been investigated by a variety of complementary biophysical approaches. CD experiments indicate that the species formed in the early stages of refolding of the apo-protein have at least 85 % of the alpha-helical content of the native state, and kinetic NMR experiments show that they possess near-native compactness. Hydrogen exchange measurements using mass spectrometry and NMR indicate that persistent structure in these transient species is located predominantly in the alpha-domain of the native protein and is similar to that present in the partially folded A-state formed by the protein at low pH. The extent of the exchange protection is, however, small, and there is no evidence for the existence of well-defined discrete kinetic intermediates of the type populated in the refolding of the structurally homologous c-type lysozymes. Rather, both mass spectrometric and NMR data indicate that the rate-determining transition from the compact partially structured (molten globule) species to the native state is highly cooperative. The data show that folding in the presence of Ca2+ is similar to that in its absence, although the rate is increased by more than two orders of magnitude. Sequential mixing experiments monitored by fluorescence spectroscopy indicate that this slower folding is not the result of the accumulation of kinetically trapped species. Rather, the data are consistent with a model in which binding of Ca2+ stabilizes native-like contacts in the partially folded species and reduces the barriers for the conversion of the protein to its native state. Taken together the results indicate that folding of BLA, in the presence of its four disulphide bonds, corresponds to one of the limiting cases of protein folding in which rapid collapse to a globule with a native-like fold is followed by a search for native-like side-chain contacts that enable efficient conversion to the close packed native structure.

Analysis of the solution structure of human interleukin-4 determined by heteronuclear three-dimensional nuclear magnetic resonance techniques.

Human interleukin-4 (IL-4) is a member of the family of haemopoietic cytokines that modulate cell proliferation and differentiation within the immune system. It has a four-helix-bundle structure, and possesses a high degree of mobility in certain regions, notably in the two long loops running the length of the bundle in its up-up-down-down topology. Information from a variety of three-dimensional heteronuclear NMR experiments, including chemical shifts, coupling constants and NOE data, is analysed in terms of the solution structure of IL-4. In addition, structure calculations with and without specific restraints such as hydrogen bond location or torsion angle restrictions are compared in the light of the dynamic behaviour of the polypeptide chain. Particular emphasis is placed on defining the lengths and positions of secondary structure elements, and on the likely structural preferences within the less well ordered loop regions. The overall topology of IL-4 is compared with those defined in recent structure determinations of related proteins. This analysis is combined with recent mutagenesis data to propose a possible mode of interaction of IL-4 with its receptor.

A nuclear magnetic resonance study of the hydrogen-exchange behaviour of lysozyme in crystals and solution.

Amide hydrogen/deuterium exchange behaviour has been studied for all of the peptide amides of hen lysozyme by means of two-dimensional n.m.r. spectroscopy. The amides have been grouped into four categories on the basis of their rates of exchange in solution at pH 4.2 and 7.5. The distribution of the amides into the different categories has been examined in the light of the crystallographic structural information, considering the type of secondary structure, the nature of hydrogen bonding and the distance from the protein surface. None of these features was found to determine uniquely the pattern of hydrogen exchange rates within the protein. The exchange behaviour of the individual amides could, however, in general be rationalized by a combination of these features. Hydrogen exchange was also monitored in both tetragonal and triclinic crystals of lysozyme, by allowing exchange to take place in the crystals prior to dissolution and recording of n.m.r. spectra under conditions where further exchange was minimized. This enabled direct comparison to be made of the exchange behaviour in the crystals and solution. A reduction in exchange rate was observed in the crystalline state relative to solution for a substantial number of amides and distinct differences between exchange in the different crystals could be observed. These differences between the solution and the different crystal states do not, however, correlate in a simple manner with proximity to intermolecular contacts in the crystals. However, the existence of these contacts, which are on the surface of the protein molecule, have a profound effect on the exchange of amides in the interior of the protein. The results indicate that the spectrum of fluctuations giving rise to hydrogen exchange may be significantly altered by the intermolecular interactions present within the crystalline state.

NMR analysis of main-chain conformational preferences in an unfolded fibronectin-binding protein.

A 130-residue fragment of the Staphylococcus aureus fibronectin-binding protein has been found to exist in a highly unfolded conformation at neutral pH. Measurement of experimental NMR 3JHNalpha coupling constants provides evidence for individual residues having distinct main-chain conformational preferences that are dependent both on the amino acid concerned and on neighbouring residues in the sequence. Analysis shows that these variations in the populations of individual residues can be explained in detail in terms of statistical distributions of conformational states derived from the protein data base. In particular, when the preceding residue has a beta-branched or aromatic side-chain, a significant increase occurs in the population of the less sterically restricted b region of phi,psi space. The results indicate that the local structure of the fibronectin binding protein in solution, under conditions where it displays full activity, approximates very closely to a statistical random coil structure. This may be an important feature in the biological role of this and other polypeptides involved in protein-protein interactions.

Human interleukin 4. The solution structure of a four-helix bundle protein.

Heteronuclear 13C and 15N three-dimensional nuclear magnetic resonance (n.m.r.) techniques have been used to determine the solution structure of human interleukin 4, a four-helix bundle protein. A dynamical simulated annealing protocol was used to calculate an ensemble of structures from an n.m.r. data set of 1735 distance restraints, 101 phi angle restraints and 27 pairs of hydrogen bond restraints. The protein structure has a left-handed up-up-down-down topology for the four helices with the two long overhand loops in the structure being connected by a short section of irregular antiparallel beta-sheet. Analysis of the side-chains in the protein shows a clustering of hydrophobic residues, particularly leucines, in the core of the bundle with the side-chains of charged residues being located on the protein surface. The solution structure has been compared with a recent structure prediction for human interleukin 4 and with crystal structures of other helix bundle proteins.

Characterization of the structure and dynamics of amyloidogenic variants of human lysozyme by NMR spectroscopy.

The structures and dynamics of the native states of two mutational variants of human lysozyme, I56T and D67H, both associated with non-neuropathic systemic amyloidosis, have been investigated by NMR spectroscopy. The (1)H and (15)N main-chain amide chemical shifts of the I56T variant are very similar to those of the wild-type protein, but those of the D67H variant are greatly altered for 28 residues in the beta-domain. This finding is consistent with the X-ray crystallographic analysis, which shows that the structure of this variant is significantly altered from that of the wild-type protein in this region. The (1)H-(15)N heteronuclear NOE values show that, with the exception of V121, every residue in the wild-type and I56T proteins is located in tightly packed structures characteristic of the native states of most proteins. In contrast, D67H has a region of substantially increased mobility as shown by a dramatic decrease in heteronuclear NOE values of residues near the site of mutation. Despite this unusual flexibility, the D67H variant has no greater propensity to form amyloid fibrils in vivo or in vitro than has I56T. This finding indicates that it is the increased ability of the variants to access partially folded conformations, rather than intrinsic changes in their native state properties, that is the origin of their amyloidogenicity.

The structure and dynamics in solution of Cu(I) pseudoazurin from Paracoccus pantotrophus.

The solution structure and backbone dynamics of Cu(I) pseudoazurin, a 123 amino acid electron transfer protein from Paracoccus pantotrophus, have been determined using NMR methods. The structure was calculated to high precision, with a backbone RMS deviation for secondary structure elements of 0.35+/-0.06 A, using 1,498 distance and 55 torsion angle constraints. The protein has a double-wound Greek-key fold with two alpha-helices toward its C-terminus, similar to that of its oxidized counterpart determined by X-ray crystallography. Comparison of the Cu(I) solution structure with the X-ray structure of the Cu(II) protein shows only small differences in the positions of some of the secondary structure elements. Order parameters S2, measured for amide nitrogens, indicate that the backbone of the protein is rigid on the picosecond to nanosecond timescale.

A refined solution structure of hen lysozyme determined using residual dipolar coupling data.

A high resolution NMR structure of hen lysozyme has been determined using 209 residual 1H-15N dipolar coupling restraints from measurements made in two different dilute liquid crystalline phases (bicelles) in conjunction with a data set of 1632 NOE distance restraints, 110 torsion angle restraints, and 60 hydrogen bond restraints. The ensemble of 50 low-energy calculated structures has an average backbone RMSD of 0.50+/-0.13A to the mean structure and of 1.49+/-0.10A to the crystal structure of hen lysozyme. To assess the importance of the dipolar coupling data in the structure determination, the final structures are compared with an ensemble calculated using an identical protocol but excluding the dipolar coupling restraints. The comparison shows that structures calculated with the dipolar coupling data are more similar to the crystal structure than those calculated without, and have better stereochemical quality. The structures also show improved quality factors when compared with additional dipolar coupling data that were not included in the structure calculations, with orientation-dependent 15N chemical shift changes measured in the bicelle solutions, and with T1/T2 values obtained from 15N relaxation measurements. Analysis of the ensemble of NMR structures and comparisons with crystal structures, 15N relaxation data, and molecular dynamics simulations of hen lysozyme provides a detailed description of the solution structure of this protein and insights into its dynamical behavior.

Identification of glycine spin systems in 1H NMR spectra of proteins using multiple quantum coherences.

Double-quantum filtered COSY and triple-quantum filtered COSY techniques have been compared for the tripeptide Gly-Tyr-Gly and for human lysozyme. The insertion of a triple-quantum filter in the COSY experiment leads to dramatic spectral simplification in the fingerprint region of the spectrum and permits the specific identification of glycine spin systems in the complex 1H NMR spectra of proteins. The assignment of these peaks to glycine H alpha can be confirmed using 2D double-quantum correlated spectroscopy.

Surface accessibility of aromatic residues in human lysozyme using photochemically induced dynamic nuclear polarization NMR spectroscopy.

Resonances in the photo-CIDNP spectrum of human lysozyme have been assigned to specific spin systems despite extensive spectral overlap using the two-dimensional photo-CIDNP COSY experiment. Five of the 12 tyrosine, tryptophan and histidine residues of human lysozyme are found to be accessible to flavin dye in solution. This result is in good agreement with surface accessibility calculations carried out on the human lysozyme crystal structure. When amino acid differences are considered the photo-CIDNP results obtained for human lysozyme are in good agreement with results obtained previously for hen lysozyme.

Sequential 1H NMR assignments and secondary structure of hen egg white lysozyme in solution.

Assignments for 1H NMR resonances of 121 of the 129 residues of hen egg white lysozyme have been obtained by sequence-specific methods. Spin systems were identified with phase-sensitive two-dimensional (2-D) correlated spectroscopy and single and double relayed coherence transfer spectroscopy. For key types of amino acid residues, particularly alanine, threonine, valine, and glycine, complete spin systems were identified. For other residues a less complete definition of the spin system was found to be adequate for the purpose of sequential assignment. Sequence-specific assignments were achieved by phase-sensitive 2-D nuclear Overhauser enhancement spectroscopy (NOESY). Exploitation of the wide range of hydrogen exchange rates found in lysozyme was a useful approach to overcoming the problem of spectral overlap. The sequential assignment was built up from 21 peptide segments ranging in length from 2 to 13 residues. The NOESY spectra were also used to provide information about the secondary structure of the protein in solution. Three helical regions and two regions of beta-sheet were identified from the NOESY data; these regions are identical with those found in the X-ray structure of hen lysozyme. Slowly exchanging amides are generally correlated with hydrogen bonding identified in the X-ray structure; a number of exceptions to this general trend were, however, found. The results presented in this paper indicate that highly detailed information can be obtained from 2-D NMR spectra of a protein that is significantly larger than those studied previously.

1H NMR studies of human lysozyme: spectral assignment and comparison with hen lysozyme.

Complete main-chain (NH and alpha CH) 1H NMR assignments are reported for the 130 residues of human lysozyme, along with extensive assignments for side-chain protons. Analysis of 2-D NOESY experiments shows that the regions of secondary structure for human lysozyme in solution are essentially identical with those found previously in a similar study of hen lysozyme and are in close accord with the structure of the protein reported previously from X-ray diffraction studies in the crystalline state. Comparison of the chemical shifts, spin-spin coupling constants, and hydrogen exchange behavior are also consistent with closely similar structures for the two proteins in solution. In a number of cases specific differences in the NMR parameters between hen and human lysozymes can be correlated with specific differences observed in the crystal structures.