An investigation of the dissociation and denaturation of legumin by salts using laser light scattering and circular dichroism spectroscopy

The dissociation of legumin, a 12 S seed storage globulin from Pisum sativum, has been studied by laser light scattering and circular dichroism spectroscopy. Salts from the Hofmeister series, in particular sodium perchlorate, were used as dissociating agents. The Mr 360,000 hexameric protein was found to dissociate first to trimers and further to monomers and the number of amino acids involved in the trimer-trimer interaction estimated to be 23(+/-4). Native legumin appears to be more strongly bound together than some analogous seed storage globulins from other plant species such as Arachis hypogaea or Sesamum indicum and the dissociation process was accompanied by some changes in conformation.     

Studies of synthetic helical peptides using circular dichroism and nuclear magnetic resonance

We have designed a set of 17-residue synthetic peptides to be monomeric helices in aqueous solution. Circular dichrosim experiments indicate the presence of helical structure in aqueous solution at low temperature and low pH. The two-dimensional nuclear magnetic resonance results for one of the peptides show a segment of ten residues which clearly meets all of the criteria for the existence of helical structure at both 5 degrees C and 15 degrees C. The first four residues of the peptide are in a largely extended conformation. Calculations suggest that residues 5 through 14 are significantly helical at 5 degrees C. When the temperature is increased, circular dichroism spectra indicate that the helical content decreases. At 15 degrees C, the 3JN alpha coupling constants increase in the helical region, indicating an increase in motion or conformational averaging in the helical segment. None of the peptides has pH titration behavior consistent with salt bridge stabilization of helical conformation. Our data lend themselves to interpretation with the helix dipole model and specific side-chain interactions. When the N and C termini charges are removed the helical content of the peptides increases. The amount of helicity increases as the pH is lowered, due to the ionization of His16. Much of the helical stabilization appears to be due to a specific side-chain interaction between His16 and Tyr12.     

Flavodoxin-cytochrome c interactions: circular dichroism and nuclear magnetic resonance studies

Circular dichroism and 1H and 31P nuclear magnetic resonance spectroscopy have been used to investigate complex formation between cytochrome c and the flavodoxins from Azotobacter vinelandii and Clostridium pasteurianum. Such complexes are known to be involved in the mechanism of electron transfer between these two redox proteins. A large increase in ellipticity in the Soret band of the cytochrome heme was observed upon formation of the Clostridium flavodoxin complex, whereas much smaller changes were found for the complexes with either Azotobacter flavodoxin or an 8 alpha-imidazolyl-FMN-substituted Clostridium flavodoxin analogue. Similarly, the magnitudes of the perturbations of the contact-shifted heme proton resonances obtained upon complexation of cytochrome c by Azotobacter flavodoxin were much smaller than those previously shown for Clostridium flavodoxin [Hazzard, J. T., & Tollin, G. (1985) Biochem. Biophys. Res. Commun. 130, 1281-1286]. 31P nuclear magnetic resonance measurements were also consistent with differences in the interactions between the components in the complexes of the two flavodoxins with cytochrome c. It is suggested that these spectral changes are due to a loosening or opening of the heme crevice upon Clostridium flavodoxin binding, which allows closer contact between the heme and flavin prosthetic groups and results in a faster rate of electron transfer. The implications of these observations for biological oxidation-reduction processes are considered.     

Solution structure of human growth hormone releasing factor. Combined use of circular dichroism and nuclear magnetic resonance spectroscopy

The solution structures of two human growth hormone releasing factor analogues, 27Leu45Gly-hGHRF(1-45)OH and 27Nle-hGHRF(1-29)NH2, are investigated by means of circular dichroism and nuclear magnetic resonance spectroscopy. Using circular dichroism spectroscopy, it is shown that both peptides adopt ordered structures at low concentrations of trifluoroethanol (approximately 30%). Quantitative analysis of the circular dichroism spectra indicates that the same number of residues, approximately 23 to 25, are in a helical state in both peptides. Using two-dimensional nuclear magnetic resonance methods all proton resonances of the 27Nle-hGHRF(1-29)NH2 fragment are assigned and its secondary structure is determined from a qualitative interpretation of the nuclear Overhauser enhancement data. Two distinctive regions of alpha-helix are present extending from residues 6 to 13 and 16 to 29.     

The domain organization of streptokinase: nuclear magnetic resonance, circular dichroism, and functional characterization of proteolytic fragments.

Streptococcus equisimilis streptokinase (SK) is a bacterial protein of unknown tertiary structure and domain organization that is used extensively to treat acute myocardial infarction following coronary thrombosis. Six fragments of SK were generated by limited proteolysis with chymotrypsin and purified. NMR and CD experiments have shown that the secondary and tertiary structure present in the native molecule is preserved within all fragments, except the N-terminal fragment SK7. NMR spectra demonstrate the presence in SK of three structurally autonomous domains and a less structured C-terminal "tail." Cleavage within the N-terminal domain generates an N-terminal fragment, SK7, which remains noncovalently associated with the remainder of the molecule; in isolation, SK7 adopts an unfolded conformation. The abilities of these fragments to induce active site formation within human plasminogen upon formation of their heterodimeric complex were assayed. The lowest mass SK fragment exhibiting Plg-dependent activator activity was shown to be SK27 (mass 27,000, residues 147-380), which contains both central and C-terminal domains, although this activity was reduced approximately 6,000-fold relative to that of full-length SK. The activity of a 36,000 mass fragment, SK36 (residues 64-380), which differs from SK27 in possessing a portion of the N-terminal domain, was reduced to 0.1-1.0% of that of SK. Other fragments (masses 7,000, 11,000, 16,000, 17,000, 25,000, and 26,000), representing either single domains or single domains extended by portions of other domains, were inactive. However, SK7 (residues 1-63), at a 100-fold molar excess concentration, greatly potentiated the activities of SK27 and SK36, by up to 50- and > 130-fold, respectively. These findings demonstrate that all of SK's three domains are essential for native-like SK activity. The central and C-terminal domains mediate plasminogen-binding and active site-generating functions, whereas the N-terminal domain mediates an activity-potentiating function.     

The structure of Escherichia coli heat-stable enterotoxin b by nuclear magnetic resonance and circular dichroism.

The heat-stable enterotoxin b (STb) is secreted by enterotoxigenic Escherichia coli that cause secretory diarrhea in animals and humans. It is a 48-amino acid peptide containing two disulfide bridges, between residues 10 and 48 and 21 and 36, which are crucial for its biological activity. Here, we report the solution structure of STb determined by two- and three-dimensional NMR methods. Approximate interproton distances derived from NOE data were used to construct structures of STb using distance-geometry and simulated annealing procedures. The NMR-derived structure shows that STb is helical between residues 10 and 22 and residues 38 and 44. The helical structure in the region 10-22 is amphipathic and exposes several polar residues to the solvent, some of which have been shown to be important in determining the toxicity of STb. The hydrophobic residues on the opposite face of this helix make contacts with the hydrophobic residues of the C-terminal helix. The loop region between residues 21 and 36 has another cluster of hydrophobic residues and exposes Arg 29 and Asp 30, which have been shown to be important for intestinal secretory activity. CD studies show that reduction of disulfide bridges results in a dramatic loss of structure, which correlates with loss of function. Reduced STb adopts a predominantly random-coil conformation. Chromatographic measurements of concentrations of native, fully reduced, and single-disulfide species in equilibrium mixtures of STb in redox buffers indicate that the formation of the two disulfide bonds in STb is only moderately cooperative. Similar measurements in the presence of 8 M urea suggest that the native secondary structure significantly stabilizes the disulfide bonds.     

Nucleic acid vibrational circular dichroism, absorption, and linear dichroism spectra. I. A DeVoe theory approach.

Infrared (IR) vibrational circular dichroism (VCD), absorption, and linear dichroism (LD) spectra of four homopolyribonucleotides, poly(rA), poly(rG), poly(rC), and poly(rU), have been calculated, in the 1750-1550 cm-1 spectral region, using the DeVoe polarizability theory. A newly derived algorithm, which approximates the Hilbert transform of imaginaries to reals, was used in the calculations to obtain real parts of oscillator polarizabilities associated with each normal mode. The calculated spectra of the polynucleotides were compared with previously measured solution spectra. The good agreement between calculated and measured polynucleotide spectra indicates, for the first time, that the DeVoe theory is a useful means of calculating the VCD and IR absorption spectra of polynucleotides. For the first time, calculated DeVoe theory VCD and IR absorption spectra of oriented polynucleotides are presented. The calculated VCD spectra for the oriented polynucleotides are used to predict the spectra for such measurements made in the future. The calculated IR spectra for the oriented polynucleotides are useful in interpreting the linear dichroism of the polynucleotides.     

A 13C nuclear magnetic resonance and circular dichroism study of the collagen-gelatin transformation in enzyme solubilized collagen.

Natural abundance Fourier transform 13C nuclear magnetic resonance (13C NMR) were obtained for enzyme solubilized collagen at 1 degrees intervals through the transition region. The transition of collagen molecules from the rigid triple helical state to single-stranded, random-coil state is accompanied by a change from broadened carbon resonances unobservable under high-resolution conditions to narrow line spectra. Thus distinction can be made between helical and random-coil states of individual residues. The transition is monophasic, as determined by examination of 14 different carbon resonances, and the entire structure is found to melt cooperatively over a temperature interval of 5 +/- 1 degrees. All the residues seem to be involved in the unfolding process concurrently. The transition was also studied by examining the changes in the circular dichroism spectrum brought about by heating. The experiments corroborated the observation that the transition proceeded cooperatively over a temperature interval of 4 degrees. Enzyme soluble collagen is seen to melt less cooperatively than native collagen. The enthalpy change was determined by assuming an equilibrium between three random coil gelatin chains and tropocollogen molecules. From the enthalpy, the average length of the tripeptide sequences (70-85) involved in the transition can be estimated. The shortening of the cooperative unit could arise as a result of some alteration of the native conformation through proctase treatment.     

Protein folding and stability investigated by fluorescence, circular dichroism (CD), and nuclear magnetic resonance (NMR) spectroscopy: the flavodoxin story

In this review, the experimental results obtained on the folding and stability of Azotobacter vinelandii flavodoxin are summarised. By doing so, three main spectroscopic techniques used to investigate protein folding and stability are briefly introduced. These techniques are: circular dichroism (CD) spectroscopy, fluorescence emission spectroscopy, and nuclear magnetic resonance (NMR) spectroscopy in combination with the hydrogen exchange methodology. Results on the denaturant-induced and thermal equilibrium unfolding of apoflavodoxin from A. vinelandii, i.e. flavodoxin in the absence of the riboflavin-5'-monophosphate (FMN) cofactor, are discussed. A scheme for the equilibrium unfolding of apoflavodoxin is presented which involves a relatively stable molten globule-like intermediate. Denaturant-induced apoflavodoxin (un)folding as followed at the residue-level by NMR shows that the transition of native A. vinelandii apoflavodoxin to its molten globule state is highly co-operative. However, the unfolding of the molten globule to the unfolded state of the protein is non-co-operative. A comparison of the folding of A. vinelandii flavodoxin with the folding of flavodoxin from Anaboena PCC 7119 is made. The local stabilities of apo- and holoflavodoxin from A. vinelandii as measured by NMR spectroscopy are compared. Both Che Y and cutinase, which have no sequence homology with apoflavodoxin but which share the flavodoxin-like topology, have stabilisation centres different from that of apoflavodoxin from A. vinelandii. The stable centres of structurally similar proteins can thus reside in different parts of the same protein topology. Insight in the variations in (local) unfolding processes of structurally similar proteins can be used to stabilise proteins with a flavodoxin-like fold. Finally, the importance of some recent experimental and theoretical developments for the study of flavodoxin folding is briefly discussed.     

Thermal stability of the three domains of streptokinase studied by circular dichroism and nuclear magnetic resonance.

Streptococcus equisimilis streptokinase (SK) is a single-chain protein of 414 residues that is used extensively in the clinical treatment of acute myocardial infarction due to its ability to activate human plasminogen (Plg). The mechanism by which this occurs is poorly understood due to the lack of structural details concerning both molecules and their complex. We reported recently (Parrado J et al., 1996, Protein Sci 5:693-704) that SK is composed of three structural domains (A, B, and C) with a C-terminal tail that is relatively unstructured. Here, we report thermal unfolding experiments, monitored by CD and NMR, using samples of intact SK, five isolated SK fragments, and two two-chain noncovalent complexes between complementary fragments of the protein. These experiments have allowed the unfolding processes of specific domains of the protein to be monitored and their relative stabilities and interdomain interactions to be characterized. Results demonstrate that SK can exist in a number of partially unfolded states, in which individual domains of the protein behave as single cooperative units. Domain B unfolds cooperatively in the first thermal transition at approximately 46 degrees C and its stability is largely independent of the presence of the other domains. The high-temperature transition in intact SK (at approximately 63 degrees C) corresponds to the unfolding of both domains A and C. Thermal stability of domain C is significantly increased by its isolation from the rest of the chain. By contrast, cleavage of the Phe 63-Ala 64 peptide bond within domain A causes thermal destabilization of this domain. The two resulting domain portions (A1 and A2) adopt unstructured conformations when separated. A1 binds with high affinity to all fragments that contain the A2 portion, with a concomitant restoration of the native-like fold of domain A. This result demonstrates that the mechanism whereby A1 stimulates the plasminogen activator activities of complementary SK fragments is the reconstitution of the native-like structure of domain A.     

Binding of a calcium sensitizer, bepridil, to cardiac troponin C. A fluorescence stopped-flow kinetic, circular dichroism, and proton nuclear magnetic resonance study

Stopped-flow fluorescence kinetic measurements, circular dichroism (CD), and 1H nuclear magnetic resonance (NMR) spectroscopy at 360 MHz have been used to study the interaction of the calcium-channel blocker and calmodulin antagonist bepridil with cardiac troponin C (cTnC) in the presence of calcium. The kinetic data show that bepridil reduces the rate of calcium release only from the low affinity, calcium-specific site and not from the two high affinity calcium/magnesium sites. CD measurements indicate that drug binding leads to a small increase in the alpha-helical content of the complex. 1H NMR shows that the protein binds one equivalent of bepridil, with a dissociation constant of approximately 20 microM, only when the low affinity calcium site is occupied. Exchange is fast or intermediate on the chemical shift time scale. Drug binding is shown to be largely localized in the N-terminal domain, containing the low affinity calcium site, by observing the shifting and broadening of several resonances associated with that domain. These include assigned aromatic signals together with methionyl and other methyl signals. Observation of intermolecular nuclear Overhauser effects was precluded by extensive spectral overlap. Consideration of the data from the three techniques permitted a model of the bepridil-cTnC complex to be constructed, using the model of cTnC derived from the x-ray structure of calmodulin (MacLachlan L. K., Reid, D. G., and Carter, N. (1990) J. Biol. Chem. 265, 9754-9763). Binding of bepridil to a prominent hydrophobic depression in the N-terminal domain can be invoked to explain many of the induced changes in the spectral and kinetic properties of the protein. The implications of the model for the calcium sensitizing action of bepridil are discussed.     

Study of the phosphorylatable light chains of skeletal and gizzard myosins by nuclear magnetic resonance spectroscopy.

31P and 1H n.m.r. studies of the phosphorylatable light chains from rabbit fast skeletal and chicken gizzard muscles in the isolated state and in the intact myosin molecule indicate that the N-terminal region of the light chain containing the sites of phosphorylation has independent segmental flexibility. The ionization behaviour of serine phosphate in both rabbit skeletal and chicken gizzard P light chains exhibits cooperativity and is compatible with the phosphate group being influenced by neighbouring positively charged side-chains. No marked difference in phosphate ionization behaviour was apparent between the monophosphorylated P light chains of rabbit skeletal and chicken gizzard myosins. From 1H and 31P n.m.r. studies of the overall conformation, side-chain ionization properties and the spectral effects of titration with an anionic paramagnetic reagent bound at the basic N-terminal region, it is concluded that Thr-18 and Ser-19 are phosphorylated in the bisphosphorylated P light chain of gizzard myosin, the latter residue being the site of monophosphorylation. In the presence of F-actin the mobility of the serine phosphate of the P light chain of intact gizzard myosin was reduced. No interaction between the isolated P light chain and F-actin was however detected. These results are discussed with reference to the observed conformational features of the P light chain.     

Conformation of malformin A: a proton magnetic resonance and a circular dichroism study

Malformin A is a cyclic pentapeptide with an intramolecular disulfide bridge. The conformation in solution of this molecule has been studied by NMR and CD. The 270 MHz Proton spectrum in dimethyl sulfoxide is well resolved and the peaks corresponding to the five residues have been assigned. From the temperature dependence of chemical shifts of the peptide protons and from the exchange rate of these protons, it is concluded that the NH proton of one Cys is shielded from the solvent. This observation and H? N? _αC? H angles, estimated from the corresponding coupling constants, a proposed conformation of the peptide backbone. From the H? _βC? _αC? H coupling constants, a P chirality for the disulfide bridge is proposed. Such a conformation is confirmed by the circular dichroism spectrum which shows a negative band at λ > 250 nm. It is concluded that the conformation of malformin A is rigid and that the disulfide bridge is exposed to interact with biological receptors.     

Unfolding of the trp repressor from Escherichia coli monitored by fluorescence, circular dichroism and nuclear magnetic resonance

The denaturation of the trp repressor from Escherichia coli has been studied by fluorescence, circular dichroism and proton magnetic resonance spectroscopy. The dependences of the fluorescence emission of the two tryptophan residues on the concentration of urea are not identical. The dependence of the quenching of tryptophan fluorescence by iodide as a function of urea concentration also rules out a two-state transition. The circular dichroism at 222 nm decreases in two phases as urea is added. Normalised curves for different residues observed by 1H NMR also do not coincide, and require the presence of at least one stable intermediate. Analysis of the dependence of the denaturation curves on the concentration of protein indicate that the first transition is a partial unfolding of the dimeric repressor, resulting in a loss of about 25% of the helical content. The second transition is the dissociation and unfolding of the partially unfolded dimer. At high concentrations of protein (500 microM) about 73% of the repressor exists as the intermediate in 4 M urea. The apparent dissociation constant is about 10(-4) M; the subunits are probably strongly stabilised by the subunit interaction. The native repressor is stable up to at least 70 degrees C, whereas the intermediate formed at 4 M urea can be denatured reversibly by heating (melting temperature approximately 60 degrees C, delta H approximately 230 kJ/mol).     

Structural information on a membrane transport protein from nuclear magnetic resonance spectroscopy using sequence-selective nitroxide labeling.

The lactose transport protein (LacS) from Streptococcus thermophilus bearing a single cysteine mutation, K373C, within the putative interhelix loop 10-11 has been overexpressed in native membranes. Cross-polarization magic-angle spinning nuclear magnetic resonance spectroscopy (NMR) could selectively distinguish binding of (13)C-labeled substrate to just 50-60 nmol of LacS(K373C) in the native fluid membranes. Nitroxide electron spin-label at the K373C location was essentially immobile on the time scale of both conventional electron spin resonance spectroscopy (ESR) (<10(-8)s) and saturation-transfer ESR (<10(-3)s), under the same conditions as used in the NMR studies. The presence of the nitroxide spin-label effectively obscured the high-resolution NMR signal from bound substrate, even though (13)C-labeled substrate was shown to be within the binding center of the protein. The interhelix loop 10-11 is concluded to be in reasonably close proximity to the substrate binding site(s) of LacS (<15 A), and the loop region is expected to penetrate between the transmembrane segments of the protein that are involved in the translocation process.     

Conformations of fibroblast and E. coli-derived recombinant human interferon-beta s as studied by nuclear magnetic resonance and circular dichroism

The conformations of fibroblast and E. coli-derived recombinant human interferon-beta s were studied by circular dichroism and nuclear magnetic resonance spectroscopy in the acidic pH region of 4.6 to 1.6. Both interferons have very similar conformations with high alpha-helix contents (approximately 70%). These results suggest that glycosylation does not appreciably change the conformation of human interferon-beta. Moreover, a slow conformational change is observed below pH 2.0, which induces the disruption of beta-sheets.     

Synchrotron radiation circular dichroism spectroscopy of proteins: secondary structure, fold recognition and structural genomics

Recent developments in instrumentation and bioinformatics show that the technique of synchrotron radiation circular dichroism spectroscopy can provide novel information on protein secondary structures and folding motifs, and has the potential to play an important role in structural genomics studies, both as a means of target selection and as a high-throughput, low-sample-requiring screening method. This is possible because of the additional information content in the low-vacuum ultraviolet wavelength data obtainable with intense synchrotron radiation light sources, compared with that present in spectra from conventional lab-based circular dichroism instruments.     

A new approach for heparin standardization: combination of scanning UV spectroscopy, nuclear magnetic resonance and principal component analysis

The year 2007 was marked by widespread adverse clinical responses to heparin use, leading to a global recall of potentially affected heparin batches in 2008. Several analytical methods have since been developed to detect impurities in heparin preparations; however, many are costly and dependent on instrumentation with only limited accessibility. A method based on a simple UV-scanning assay, combined with principal component analysis (PCA), was developed to detect impurities, such as glycosaminoglycans, other complex polysaccharides and aromatic compounds, in heparin preparations. Results were confirmed by NMR spectroscopy. This approach provides an additional, sensitive tool to determine heparin purity and safety, even when NMR spectroscopy failed, requiring only standard laboratory equipment and computing facilities.