Photochemically induced dynamic nuclear polarization NMR study of yeast and horse muscle phosphoglycerate kinase

A photochemically induced dynamic nuclear polarization (photo-CIDNP) study of yeast and horse muscle phosphoglycerate kinase with flavin dyes was undertaken to identify the histidine, tryptophan, and tyrosine resonances in the aromatic region of the simplified 1H NMR spectra of these enzymes and to investigate the effect of substrates on the resonances observable by CIDNP. Identification of the CIDNP-enhanced resonances with respect to the type of amino acid residue has been achieved since only tyrosine yields emission peaks and the dye 8-aminoriboflavin enhances tryptophan but not histidine. By use of the known amino acid sequences and structures derived from X-ray crystallographic studies of the enzymes from the two species, assignment of the specific residues in the protein sequences giving rise to the CIDNP spectra was partially achieved. In addition, flavin dye accessibility was used to probe any changes in enzyme structure induced by substrate binding. The nine resonance peaks observed in the CIDNP spectrum of yeast phosphoglycerate kinase have been assigned tentatively to five residues: histidines-53 and -151, tryptophan-310, and tyrosines-48 and -195. The accessibility of a tyrosine to photoexcited flavin is reduced in the presence of MgATP. Since the tyrosine residues are located some distance from the MgATP binding site of the catalytic center, it is proposed either that this change is due to a distant conformational change or that a second metal-ATP site inferred from other studies lies close to one of the tyrosines. Horse muscle phosphoglycerate kinase exhibits seven resonances by CIDNP NMR.(ABSTRACT TRUNCATED AT 250 WORDS)     

A photochemically induced dynamic nuclear polarization study of denatured states of lysozyme

Photochemically induced dynamic nuclear polarization (photo-CIDNP) techniques have been used to examine denatured states of lysozyme produced under a variety of conditions. 1H CIDNP difference spectra of lysozyme denatured thermally, by the addition of 10 M urea, or by the complete reduction of its four disulfide bonds were found to differ substantially not only from the spectrum of the native protein but also from that expected for a completely unstructured polypeptide chain. Specifically, denatured lysozyme showed a much reduced enhancement of tryptophan relative to tyrosine than did a mixture of blocked amino acids with the same composition as the intact protein. By contrast, the CIDNP spectrum of lysozyme denatured in dimethyl sulfoxide solution was found to be similar to that expected for a random coil. It is proposed that nonrandom hydrophobic interactions are present within the denatured states of lysozyme in aqueous solution and that these reduce the reactivity of tryptophan residues relative to tyrosine residues. Characterization of such interactions is likely to be of considerable significance for an understanding of the process of protein folding.     

Refolding of ribonuclease A monitored by real-time photo-CIDNP NMR spectroscopy

Photo-CIDNP NMR spectroscopy is a powerful method for investigating the solvent accessibility of histidine, tyrosine and tryptophan residues in a protein. When coupled to real-time NMR, this technique allows changes in the environments of these residues to be used as a probe of protein folding. In this paper we describe experiments performed to monitor the refolding of ribonuclease A following dilution from a high concentration of chemical denaturant. These experiments provide a good example of the utility of this technique which provides information that is difficult to obtain by other biophysical methods. Real-time photo-CIDNP measurements yield residue-specific kinetic data pertaining to the folding reaction, interpreted in terms of current knowledge of the folding of bovine pancreatic ribonuclease A.     

Understanding how small helical proteins fold: conformational dynamics of Im proteins relevant to their folding landscapes

Understanding the mechanism of folding of small proteins requires characterization of their starting unfolded states and any partially unfolded states populated during folding. Here, we review what is known from NMR about these states of Im7, a 4-helix bundle protein that folds via an on-pathway intermediate, and show that there is an alignment of non-native structure in urea-unfolded Im7 with the helices of native Im7 that is a consequence of hydrophobic helix-promoting residues also promoting cluster-formation in the unfolded protein. We suggest that this kind of alignment is present in other proteins and is relevant to how native state topology determines folding rates.     

Ultraviolet resonance Raman studies reveal the environment of tryptophan and tyrosine residues in the native and partially folded states of the E colicin-binding immunity protein Im7

Understanding the nature of partially folded proteins is a challenging task that is best accomplished when several techniques are applied in combination. Here we present ultraviolet resonance Raman (UVRR) spectroscopy studies of the E colicin-binding immunity proteins, Im7* and Im9*, together with a series of variants of Im7* that are designed to trap a partially folded state at equilibrium. We show that the environments of the tryptophan and tyrosine residues in native wild-type Im7* and Im9* are indistinguishable, in contrast with models for their structures based on X-ray and NMR methods. In addition, we show that there is a general increase in the hydrophobicity in the environment of Trp75 in all of the variants compared with wild-type Im7*. These data suggest that a significant rearrangement of the tryptophan pocket occurs in the variants, which, together with an overall decrease in solvent accessibility of Trp75 as judged by time-resolved fluorescence lifetime measurements and fluorescence quenching experiments, rationalize the unusual fluorescence properties of the variants reported previously. The data highlight the power of UVRR in analyzing the structural properties of different conformational states of the same protein and reveal new information about the structural rearrangements occurring during Im7* folding, not possible using other spectroscopic methods alone. Finally, we describe a previously unreported dependence of the tryptophan Fermi doublet on excitation wavelength in the ultraviolet region revealed by these protein spectra. We corroborated this observation using tryptophan-containing model compounds and conclude that the conventional interpretation of this UVRR feature at these wavelengths is unreliable.     

Exposed tyrosine residues of lambda cro repressor protein evidenced by nitration and photo CIDNP experiments

The tyrosine residues of lambda cro repressor were partially nitrated with tetranitromethane under mild conditions. After digestion by Achromobacter protease I, the extent of nitration was determined by HPLC and amino acid analysis. Tyr 26 was most easily nitrated and Tyr 51 followed it. Tyr 10 was resistant to nitration. By comparison of the proton magnetic resonance spectrum of the partially nitrated cro protein with the above result, the aromatic proton resonances of the tyrosine side chains could be assigned to individual tyrosine residues. The extent of nitration is parallel to the accessibility to a flavin dye as measured by photo CIDNP (chemically induced dynamic nuclear polarization).     

Hydration and packing along the folding pathway of SH3 domains by pressure-dependent NMR

The volumetric properties associated with protein folding transitions reflect changes in protein packing and hydration of the states that participate in the folding reaction. Here, NMR spin relaxation techniques are employed to probe the folding-unfolding kinetics of two SH3 domains as a function of pressure so that the changes in partial molar volumes along the folding pathway can be measured. The two domains fold with rates that differ by approximately 3 orders of magnitude, so their folding dynamics must be probed using different NMR relaxation experiments. In the case of the drkN SH3 domain that folds via a two-state mechanism on a time scale of seconds, nitrogen magnetization exchange spectroscopy is employed, while for the G48M mutant of the Fyn SH3 domain where the folding occurs on the millisecond time scale (three-step reaction), relaxation dispersion experiments are utilized. The NMR methodology is extremely sensitive to even small changes in equilibrium and rate constants, so reliable estimates of partial molar volumes can be obtained using low pressures (1-120 bar), thus minimizing perturbations to any of the states along the folding reaction coordinate. The volumetric data that were obtained are consistent with a similar folding mechanism for both SH3 domains, involving early chain compaction to states that are at least partially hydrated. This work emphasizes the role of NMR spin relaxation in studying dynamic processes over a wide range of time scales.     

Side chain accessibility and dynamics in the molten globule state of alpha-lactalbumin: a (19)F-NMR study

The molten globule state of alpha-lactalbumin (alpha-LA) has been considered a prototype of partially folded proteins. Despite the importance of molten globules in understanding the mechanisms of protein folding and its relevance to some biological phenomena, site-specific information on the structure and dynamics of a molten globule is limited, largely because of the high conformational flexibility and heterogeneity. Here, we use selective isotope labeling and (19)F NMR to investigate the solvent accessibility and side-chain dynamics of aromatic residues in the molten globule of alpha-LA. Comparison of these properties with those of the native and unfolded protein indicates that the alpha-LA molten globule is highly heterogeneous; each residue has its unique solvent accessibility and motional environment. Many aromatic residues normally buried in the interior of native alpha-LA remain significantly buried in the molten globule and the side-chain dynamics of these residues are highly restricted. Our results suggest that hydrophobic and van der Waals interactions mediated by the inaccessible surface area could be sufficient to account for all the stability of the alpha-LA molten globule, which is approximately 50% of the value for the native protein.     

Thermodynamics of a beta-hairpin structure: evidence for cooperative formation of folding nucleus

To elucidate early nucleation stages in protein folding, multi-probed thermodynamic characterization was applied to the beta-hairpin structural formation of G-peptide, which is a C-terminal fragment of the B1 domain of streptococcal protein G. The segment corresponding to the sequence of G-peptide is believed to act as a nucleus during the folding process of the B1 domain. In spite of the broad thermal transition of G-peptide, nuclear magnetic resonance (NMR) melting measurements combined with our original analytical theory enabled us to obtain the thermodynamic properties of the beta-hairpin formation with considerable accuracy. Additionally, all the thermodynamic properties determined by every NMR probe on both the main-chain and the side-chains were quite similar, and also comparable to the values that were independently determined by calorimetric analysis of G-peptide. These results demonstrate that G-peptide folds cooperatively throughout the molecule. In other words, the formation of the beta-hairpin is interpreted as the fashion of a first-order phase transition between two states without any distinguishable intermediates. This cooperative formation of the short linear peptide consisting of only 16 residues provides insight into not only the first folding events of the B1 domain, but also the general principles of proteins in terms of structural hierarchy, stability and folding mechanism.     

NMR identification of local structural preferences in HIV-1 protease tethered heterodimer in 6 M guanidine hydrochloride.

Understanding protein folding requires complete characterization of all the states of the protein present along the folding pathways. For this purpose nuclear magnetic resonance (NMR) has proved to be a very powerful technique because of the great detail it can unravel regarding the structure and dynamics of protein molecules. We report here NMR identification of local structural preferences in human immunodeficiency virus-1 protease in the 'unfolded state'. Analyses of the chemical shifts revealed the presence of local structural preferences many of which are native-like, and there are also some non-native structural elements. Three-bond H(N)-H(alpha) coupling constants that could be measured for some of the N-terminal and C-terminal residues are consistent with the native-like beta-structure. Unusually shifted 15N and amide proton chemical shifts of residues adjacent to some prolines and tryptophans also indicate the presence of some structural elements. These conclusions are supported by amide proton temperature coefficients and nuclear Overhauser enhancement data. The locations of the residues exhibiting preferred structural propensities on the crystal structure of the protein, give useful insights into the folding mechanism of this protein.     

NMR structure of the LCCL domain and implications for DFNA9 deafness disorder

The LCCL domain is a recently discovered, conserved protein module named after its presence in Limulus factor C, cochlear protein Coch-5b2 and late gestation lung protein Lgl1. The LCCL domain plays a key role in the autosomal dominant human deafness disorder DFNA9. Here we report the nuclear magnetic resonance (NMR) structure of the LCCL domain from human Coch-5b2, where dominant mutations leading to DFNA9 deafness disorder have been identified. The fold is novel. Four of the five known DFNA9 mutations are shown to involve at least partially solvent-exposed residues. Except for the Trp91Arg mutant, expression of these four LCCL mutants resulted in misfolded proteins. These results suggest that Trp91 participates in the interaction with a binding partner. The unexpected sensitivity of the fold with respect to mutations of solvent-accessible residues might be attributed to interference with the folding pathway of this disulfide-containing domain.     

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 © 1997 Wiley-Liss Inc.     

Side-chain interactions in the folding pathway of a Fyn SH3 domain mutant studied by relaxation dispersion NMR spectroscopy

A major challenge to the study of protein folding is the fact that intermediate states along the reaction pathway are generally unstable and thus difficult to observe. Recently developed NMR relaxation dispersion experiments present an avenue to accessing such states, providing kinetic, thermodynamic, and structural information for intermediates with small (greater than or equal to approximately 1%) populations at equilibrium. We have employed these techniques to study the three-state folding reaction of the G48M Fyn SH3 domain. Using (13)C-, (1)H-, and (15)N-based methods, we have characterized backbone and side-chain interactions in the folded, unfolded, intermediate, and transition states, thereby mapping the energy landscape of the protein. We find that the intermediate, populated to approximately 1%, contains nativelike structure in a central beta-sheet, and is disordered at the amino and carboxy termini. The intermediate is stabilized by side-chain van der Waals contacts, yet (13)C chemical shifts indicate that methyl-containing residues remain disordered. This state has a partially structured backbone and a collapsed yet mobile hydrophobic core and thus closely resembles a molten globule. Nonpolar side-chain contacts are formed in the unfolded-intermediate transition state; these interactions are disrupted in the intermediate-folded transition state, possibly allowing side chains to rearrange as they adopt the native packing configuration. This work illustrates the power of novel relaxation dispersion experiments in characterizing excited states that are "invisible" in even the most sensitive of NMR experiments.     

Observing a late folding intermediate of Ubiquitin at atomic resolution by NMR

The study of intermediates in the protein folding pathway provides a wealth of information about the energy landscape. The intermediates also frequently initiate pathogenic fibril formations. While observing the intermediates is difficult due to their transient nature, extreme conditions can partially unfold the proteins and provide a glimpse of the intermediate states. Here, we observe the high resolution structure of a hydrophobic core mutant of Ubiquitin at an extreme acidic pH by nuclear magnetic resonance (NMR) spectroscopy. In the structure, the native secondary and tertiary structure is conserved for a major part of the protein. However, a long loop between the beta strands β3 and β5 is partially unfolded. The altered structure is supported by fluorescence data and the difference in free energies between the native state and the intermediate is reflected in the denaturant induced melting curves. The unfolded region includes amino acids that are critical for interaction with cofactors as well as for assembly of poly‐Ubiquitin chains. The structure at acidic pH resembles a late folding intermediate of Ubiquitin and indicates that upon stabilization of the protein's core, the long loop converges on the core in the final step of the folding process.     

NMR elucidation of early folding hierarchy in HIV-1 protease

Folding studies on proteases by the conventional hydrogen exchange experiments are severely hampered because of interference from the autolytic reaction in the interpretation of the exchange data. We report here NMR identification of the hierarchy of early conformational transitions (folding propensities) in HIV-1 protease by systematic monitoring of the changes in the state of the protein as it is subjected to different degrees of denaturation by guanidine hydrochloride. Secondary chemical shifts, HN-Halpha coupling constants, 1H-15N nuclear Overhauser effects, and 15N transverse relaxation parameters have been used to report on the residual structural propensities, motional restrictions, conformational transitions, etc., and the data suggest that even under the strongest denaturing conditions (6 m guanidine) hydrophobic clusters as well as different native and non-native secondary structural elements are transiently formed. These constitute the folding nuclei, which include residues spanning the active site, the hinge region, and the dimerization domain. Interestingly, the proline residues influence the structural propensities, and the small amino acids, Gly and Ala, enhance the flexibility of the protein. On reducing the denaturing conditions, partially folded forms appear. The residues showing high folding propensities are contiguous along the sequence at many locations or are in close proximity on the native protein structure, suggesting a certain degree of local cooperativity in the conformational transitions. The dimerization domain, the flaps, and their hinges seem to exhibit the highest folding propensities. The data suggest that even the early folding events may involve many states near the surface of the folding funnel.     

Approaches for the measurement of solvent exposure in proteins by <Superscript>19</Superscript>F NMR

Fluorine NMR is a useful tool to probe protein folding, conformation and local topology owing to the sensitivity of the chemical shift to the local electrostatic environment. As an example we make use of ¹⁹F NMR and 3-fluorotyrosine to evaluate the conformation and topology of the tyrosine residues (Tyr-99 and Tyr-138) within the EF-hand motif of the C-terminal domain of calmodulin (CaM) in both the calcium-loaded and calcium-free states. We critically compare approaches to assess topology and solvent exposure via solvent isotope shifts, ¹⁹F spin–lattice relaxation rates, ¹H–¹⁹F nuclear Overhauser effects, and paramagnetic shifts and relaxation rates from dissolved oxygen. Both the solvent isotope shifts and paramagnetic shifts from dissolved oxygen sensitively reflect solvent exposed surface areas.     

1H-NMR studies on the gene-5-encoded single-stranded DNA binding protein of the filamentous bacteriophage IKe. General spectral and structural features

Under physiological conditions and at concentrations needed for NMR studies, severe aggregation of the gene-5 protein of the filamentous phage IKe occurs. Conditions are described for which well-resolved 1H-NMR spectra of the protein can be obtained. The aromatic part of the spectrum is analyzed by means of two-dimensional NMR techniques; a complete interpretation is presented. Oligonucleotide binding studies reveal that just one phenylalanyl residue and one tyrosyl residue are influenced by the binding of rAMP, (dA)2, (dA)3, (dA)4, (dA)6, d(pT)3 or (dT)4. Upon binding, the aromatic resonances of these amino acid residues are shifted upfield by about 0.4-0.5 ppm. NMR measurements at different pH values demonstrate that only one of the two histidyl residues is freely titratable. From CIDNP experiments it is concluded that three out of five tyrosyl residues are located at the surface of the protein. Measurements carried out as a function of protein concentration indicate the occurrence of specific protein-protein interactions between dimeric gene-5-protein molecules. The data obtained are compared with those available for the gene-5 protein of M13. It follows from the comparison that these proteins mimic each other in almost every respect.     

Oxidative folding of Amaranthus alpha-amylase inhibitor: disulfide bond formation and conformational folding

Oxidative folding is the fusion of native disulfide bond formation with conformational folding. This complex process is guided by two types of interactions: first, covalent interactions between cysteine residues, which transform into native disulfide bridges, and second, non-covalent interactions giving rise to secondary and tertiary protein structure. The aim of this work is to understand both types of interactions in the oxidative folding of Amaranthus alpha-amylase inhibitor (AAI) by providing information both at the level of individual disulfide species and at the level of amino acid residue conformation. The cystine-knot disulfides of AAI protein are stabilized in an interdependent manner, and the oxidative folding is characterized by a high heterogeneity of one-, two-, and three-disulfide intermediates. The formation of the most abundant species, the main folding intermediate, is favored over other species even in the absence of non-covalent sequential preferences. Time-resolved NMR and photochemically induced dynamic nuclear polarization spectroscopies were used to follow the oxidative folding at the level of amino acid residue conformation. Because this is the first time that a complete oxidative folding process has been monitored with these two techniques, their results were compared with those obtained at the level of an individual disulfide species. The techniques proved to be valuable for the study of conformational developments and aromatic accessibility changes along oxidative folding pathways. A detailed picture of the oxidative folding of AAI provides a model study that combines different biochemical and biophysical techniques for a fuller understanding of a complex process.     

Molecular basis of co-operativity in protein folding. III. Structural identification of cooperative folding units and folding intermediates.

The hierarchical partition function formalism for protein folding developed earlier has been extended through the use of three-dimensional polar and apolar contact plots. For each amino acid residue in the protein, these plots indicate the apolar and polar surfaces that are buried from the solvent, the identity of all amino acid residues that contribute to this shielding, and the magnitude of their contributions. These contact plots are then used to examine the distribution of the free energy of stabilization throughout the protein molecule. Analysis of these data allows identification of co-operative folding units and their hierarchical levels, and the identification of partially folded intermediates with a significant probability of being populated. The overall folding/unfolding thermodynamics of 12 globular proteins, for which crystallographic and experimental thermodynamics are available, is predicted within error. An energetic classification of partially folded intermediates is presented and the results compared to those cases for which structural and thermodynamic experimental information is available. Four different types of partially folded states and their structural energies are considered. (1) Local intermediates, in which only a local region of the protein loses secondary and tertiary interactions, while the rest of the protein remains intact. (2) Global intermediates, corresponding to the standard molten globule definition, in which significant secondary structure is maintained but native-like tertiary structure contacts are disrupted. (3) Extended intermediates characterized by the existence of secondary structure elements (e.g. alpha-helices) exposed to solvent. (4) Folding intermediates in proteins with two structural domains. The structure and energetics of folding intermediates of apo-myoglobin, alpha-lactalbumin, phosphoglycerate kinase and arabinose-binding protein are considered in detail.