Effects of alanine substitutions in alpha-helices of sperm whale myoglobin on protein stability.

The peptide backbones in folded native proteins contain distinctive secondary structures, alpha-helices, beta-sheets, and turns, with significant frequency. One question that arises in folding is how the stability of this secondary structure relates to that of the protein as a whole. To address this question, we substituted the alpha-helix-stabilizing alanine side chain at 16 selected sites in the sequence of sperm whale myoglobin, 12 at helical sites on the surface of the protein, and 4 at obviously internal sites. Substitution of alanine for bulky side chains at internal sites destabilizes the protein, as expected if packing interactions are disrupted. Alanine substitutions do not uniformly stabilize the protein, either in capping positions near the ends of helices or at mid-helical sites near the surface of myoglobin. When corrected for the extent of exposure of each side chain replaced by alanine at a mid-helix position, alanine replacement still has no clear effect in stabilizing the native structure. Thus linkage between the stabilization of secondary structure and tertiary structure in myoglobin cannot be demonstrated, probably because of the relatively small free energy differences between side chains in stabilizing isolated helix. By contrast, about 80% of the variance in free energy observed can be accounted for by the loss in buried surface area of the native residue substituted by alanine. The differential free energy of helix stabilization does not account for any additional variation.     

On the difference in stability between horse and sperm whale myoglobins

The work in the literature on apomyoglobin is almost equally divided between horse and sperm whale myoglobins. The two proteins share high homology, show similar folding behavior, and it is often assumed that all folding phenomena found with one protein will also be found with the other. We report data at equilibrium showing that horse myoglobin was 2.1 kcal/mol less stable than sperm whale myoglobin at pH 5.0, and aggregated at high concentrations as measured by gel filtration and analytical ultracentrifugation experiments. The higher stability of sperm whale myoglobin was identified for both apo and holo forms, and was independent of pH from 5 to 8 and of the presence of sodium chloride. We also show that the substitution of sperm whale myoglobin residues Ala15 and Ala74 to Gly, the residues found at positions 15 and 74 in horse myoglobin, decreased the stability by 1.0 kcal/mol, indicating that helix propensity is an important component of the explanation for the difference in stability between the two proteins.     

Probing minimal independent folding units in dihydrofolate reductase by molecular dissection.

Molecular dissection was employed to identify minimal independent folding units in dihydrofolate reductase (DHFR) from Escherichia coli. Eight overlapping fragments of DHFR, spanning the entire sequence and ranging in size from 36 to 123 amino acids, were constructed by chemical cleavage. These fragments were designed to examine the effect of tethering multiple elements of secondary structure on folding and to test if the secondary structural domains represent autonomous folding units. CD and fluorescence spectroscopy demonstrated that six fragments containing up to a total of seven alpha-helices or beta-strands and, in three cases, the adenine binding domain (residues 37-86), are largely disordered. A stoichiometric mixture of the two fragments comprising the large discontinuous domain, 1-36 and 87-159, also showed no evidence for folding beyond that observed for the isolated fragments. A fragment containing residues 1-107 appears to have secondary and tertiary structure; however, spontaneous self-association made it impossible to determine if this structure solely reflects the behavior of the monomeric form. In contrast, a monomeric fragment spanning residues 37-159 possesses significant secondary and tertiary structure. The urea-induced unfolding of fragment 37-159 in the presence of 0.5 M ammonium sulfate was found to be a well-defined, two-state process. The observation that fragment 37-159 can adopt a stable native fold with unique, aromatic side-chain packing is quite striking because residues 1-36 form an integral part of the structural core of the full-length protein.     

Conformation of a T cell stimulating peptide in aqueous solution

Using two-dimensional NMR spectroscopy and circular dichroism spectroscopy it is demonstrated that a T cell stimulating peptide corresponding to residues 132-153 of sperm whale myoglobin populates helical conformations in aqueous solution. This finding is in accordance with proposals that immunodominant sites in T cell stimulating peptides have a high conformational propensity. The observation of secondary structure in aqueous solutions of this and other immunogenic peptides has important implications for initiation of protein folding.     

Complete amino acid sequence of the myoglobin from the Pacific spotted dolphin, Stenella attenuata graffmani.

The complete amino acid sequence of the major component myoglobin from the Pacific spotted dolphin, Stenella attenuata graffmani, was determined by the automated Edman degradation of several large peptides obtained by specific cleavage of the protein. The acetimidated apomyoglobin was selectively cleaved at its two methionyl residues with cyanogen bromide and at its three arginyl residues by trypsin. By subjecting four of these peptides and the apomyoglobin to automated Edman degradation, over 80% of the primary structure of the protein was obtained. The remainder of the covalent structure was determined by the sequence analysis of peptides that resulted from further digestion of the central cyanogen bromide fragment. This fragment was cleaved at its glutamyl residues with staphylococcal protease and its lysyl residues with trypsin. The action of trypsin was restricted to the lysyl residues by chemical modification of the single arginyl residue of the fragment with 1,2-cyclohexanedione. The primary structure of this myoglobin proved to be identical with that from the Atlantic bottlenosed dolphin and Pacific common dolphin but differs from the myoglobins of the killer whale and pilot whale at two positions. The above sequence identities and differences reflect the close taxonomic relationship of these five species of Cetacea.     

Immobilized cytochrome c--an effective ligand for affinity chromatography of electron transport proteins

Preparations of horse heart cytochrome c have been obtained immobilized on Sepharose derivatives via lysine epsilon-amino groups, carboxyl groups of aspartic and glutamic acid residues, methionine and histidine residues as well as imidazole groups additionally introduced by means of chemical modification of free carboxyl groups by histamine. Dissociation constants have been determined for complexes of adrenodoxin, hepatoredoxin, cytochrome b5 heme-containing fragment and myoglobin with preparations of cytochrome c immobilized via lysine residues (adsorbent I) or additionally introduced imidazole groups (adsorbent II). The latter is found to possess a 2-3 times greater affinity for adrenodoxin and hepatoredoxin than the former. The affinity of the proteins studied for the adsorbent II constitutes the following sequence: adrenodoxin greater than or equal to hepatoredoxin greater than cytochrome b5 heme-containing fragment greater than myoglobin. The adsorbent II is shown to be effective when used for purification of hepatoredoxin, adrenodoxin, cytochrome b5 and isolation of cytochrome b5 heme-containing fragment.     

Structure studies of amylose-V complexes and retrograded amylose by action of alpha amylases, and a new method for preparing amylodextrins

Human-salivary, porcine-pancreatic, and Bacillus subtilis alpha amylases were used to study the structure of amylose-V complexes with butyl alcohol, tert-butyl alcohol, 1,1,2,2-tetrachloroethane, and 1-naphthol, and of retrograded amylose. Alpha amylase hydrolyzes the amorphous, folding areas on the surfaces of the lamella of packed helices, with the formation of resistant, amylodextrin fragments. Their degree of polymerization (d.p.) corresponds to the diameter of the helices and the folding length of the chain. The resistant fragments were fractionated on a column of Bio-Gel A-0.5m. Gel filtration of human-salivary and porcine-pancreatic alpha amylase hydrolyzates gave resistant fragments whose peak fractions, i.e., the three pooled fractions from the gel-filtration column with the highest amount of carbohydrate, had a d.p. of 75 +/- 4 for the amylose complex with butyl alcohol, 90 +/- 3 for those with tert-butyl alcohol and tetrachloroethane, and 123 +/- 2 for that with 1-naphthol. These d.p. values correspond to helices of six residues per turn with a folding length of 10 nm, seven residues per turn with a folding length of 10 nm, and eight residues per turn with a folding length of 12 nm (or nine residues per turn with a folding length of 10 nm), respectively. Acid hydrolysis of retrograded amylose gave a resistant fragment having an average d.p. of 32, human-salivary and porcine-pancreatic alpha amylases gave a resistant fragment of d.p. 43, and Bacillus subtilis alpha amylase gave a resistant fragment of d.p. 50. A structure for retrograded amylose is proposed in which there are crystalline, double-helical regions that are 10 nm long, interspersed with amorphous regions. The amorphous regions are hydrolyzed by acid and by alpha amylases, leaving the crystalline regions intact. The differences in the sizes of the resistant amylodextrins depend on the differences in the specificities of the hydrolyzing agents: acid hydrolyzes right up to the edge of the crystalline region, whereas the alpha amylases hydrolyze up to some point several D-glucosyl residues away from the crystalline region, leaving "stubs" on the ends of the amylodextrins whose sizes are dependent on the sizes of the binding sites of the individual alpha amylases.(ABSTRACT TRUNCATED AT 400 WORDS)     

Native-like partially folded conformations and folding process revealed in the N-terminal large fragments of staphylococcal nuclease: a study by NMR spectroscopy

The N-terminal large fragments of staphylococcal nuclease (SNase), SNase110 (1-110 residues), SNase121 (1-121 residues), and SNase135 (1-135 residues), and the fragment mutants G88W110, G88W121, V66W110 and V66W121 were studied by heteronuclear multidimensional NMR spectroscopy. Ensembles of co-existent native-like partially folded and unfolded states were observed for fragments. The persistent native-like tertiary interaction drives fragments to be in partially folded states, which reveal native-like beta-barrel conformations. G88W and V66W mutations modulate the extent of inherent native-like tertiary interaction in fragment molecules, and in consequence, fragment mutants fold into native-like beta-subdomain conformations. In cooperation with the inherent tertiary interaction, 2 M TMAO (trimethylamine N-oxide) can promote the folding reaction of fragments through the changes of unfolding free energy, and a native-like beta-subdomain conformation is observed when the chain length contains 135 residues. Heterogeneous partially folded conformations of 1-121 and 1-135 fragments due to cis and trans X-prolyl bond of Lys116-Pro117 make a non-unique folding pathway of fragments. The folding reaction of fragments can be characterized as a hierarchical process.     

Oxidation of tryptophans in an interhelical hydrophobic cluster of myoglobin alters the thermodynamics of the denaturation transition

Model folding studies of sperm whale myoglobin have illustrated the presence of hydrophobic interfacial regions between elements of secondary structure. The specific oxidation of two tryptophan residues, in the A-H helix contact of sperm whale myoglobin, to the less hydrophobic oxindolylalanine residues is utilized to probe the contribution of hydrophobic packing density in this contact region. The acid denaturation of the modified protein is no longer a simple two-state process exhibiting the presence of stable intermediates. The relative stability of the intermediate is shown to be +5.3 kcal/mol less stable than native myoglobin. This value is consistent with the predicted relative stability, based upon electrostatic model calculations, of the docking of the A helix with a des-A helix myoglobin. The presence of stable intermediate structures in the denaturation pathway of the modified protein is consistent with the proposed role of hydrophobic interactions in damping structural fluctuations and statistical mechanical models of noncooperative protein unfolding. These results demonstrate the relationship between large-scale fluctuations and the frictional forces governing small-scale motions within the protein core.     

Mini-myoglobin: preparation and reaction with oxygen and carbon monoxide

A domain of 108 amino acid residues (32 to 139), obtained by digestion of horse heart apomyoglobin with clostripain, was found to bind protoheme in a 1 to 1 molar ratio. This domain is 33 amino acid residues larger than the protein segment encoded by the central exon in seal myoglobin. Flash photolysis experiments have shown that reconstituted "mini-myoglobin" is very similar to myoglobin in the combination reaction with carbon monoxide and with oxygen, and in the oxygen replacement reaction by carbon monoxide. These experiments provide for the first time direct evidence for the presence of a structural and functional domain, closely corresponding to the segment encoded by the central exon of the myoglobin gene, which contains the information for binding the natural heme and for maintaining the native folding typical of a respiratory protein.     

Role of side-chains in the cooperative beta-hairpin folding of the short C-terminal fragment derived from streptococcal protein G

A short C-terminal fragment of immunoglobulin-binding domain of streptococcal protein G is known to form nativelike beta-hairpin at physiological conditions. To understand the cooperative folding of the short peptide, eight Ala-substituted mutants of the fragment were investigated with respect to their structural stabilities by analyzing temperature dependence of NMR signals. On comparison of the obtained thermodynamic parameters, we found that the nonpolar residues Tyr45 and Phe52 and the polar residues Asp46 and Thr49 are crucial for the beta-hairpin folding. The results suggest a strong interaction between the nonpolar side chains that participates in a putative hydrophobic cluster and that the polar side chains form a fairly rigid conformation around the loop (46-51). We also investigated the complex formation of the mutants with N-terminal fragment at the variety of temperature to get their thermal unfolding profiles and found that the mutations on the residues Asp46 and Thr49 largely destabilized the complexes, while substitution of Asp47 slightly stabilized the complex. From these results, we deduced that both the hydrophobic cluster formation and the rigidity of the loop (46-51) cooperatively stabilize the beta-hairpin structure of the fragment. These interactions which form a stable beta-hairpin may be the initial structural scaffold which is important in the early folding events of the whole domain.     

Amino Acid Sequence, Spectral, Oxygen-Binding, and Autoxidation Properties of Indoleamine Dioxygenase-Like Myoglobin from the Gastropod Mollusc Turbo cornutus

Myoglobin was isolated from the radular muscle of the archaeogastropod mollusc Turbo cornutus (Turbinidae). This myoglobin is a monomer carrying one protoheme group; the molecular mass was estimated by SDS–PAGE to be about 40 kDa, 2.5 times larger than that of usual myoglobin. The cDNA-derived amino acid sequence of 375 residues was determined, of which 327 residues were identified directly by chemical sequencing of internal peptides. The amino acid sequence of Turbo myoglobin showed no significant homology with any other usual 16-kDa globins, but showed 36% identity with the myoglobin from Sulculus diversicolor (Haliotiidae) and 27% identity with human indoleamine 2,3-dioxygenase, a tryptophan-degrading enzyme containing heme. Thus, the Turbo myoglobin can be counted among the myoglobins which evolved from the same ancestor as that of indoleamine 2,3-dioxygenase. The absorbance ratio of γ to CT maximum (γ/CT) of Turbo metmyoglobin was 17.8, indicating that this myoglobin probably possesses a histidine residue near the sixth coordination position of heme iron. The Turbo myoglobin binds oxygen reversibly. Its oxygen equilibrium properties are similar to those of Sulculus myoglobin, giving P ₅₀ = 3.5 mm Hg at pH 7.4 and 20°C. The pH dependence of autoxidation of Turbo oxymyoglobin was quite different from that of mammalian myoglobin, suggesting a unique protein folding around the heme cavity of Turbo myoglobin. A kinetic analysis of autoxidation indicates that the amino acid residue with pK _a = 5.4 is involved in the reaction. The autoxidation reaction was enhanced markedly at pH 7.6, but not at pH 5.5 and 6.3 in the presence of tryptophan. We suggest that a noncatalytic binding site for tryptophan, in which several dissociation groups with pK _a ≥ 7.6 are involved, remains in Turbo myoglobin as a relic of molecular evolution.     

NMR structures of 36 and 73-residue fragments of the calreticulin P-domain

Calreticulin (CRT) is an abundant, soluble molecular chaperone of the endoplasmic reticulum. Similar to its membrane-bound homolog calnexin (CNX), it is a lectin that promotes the folding of proteins carrying N-linked glycans. Both proteins cooperate with an associated co-chaperone, the thiol-disulfide oxidoreductase ERp57. This enzyme catalyzes the formation of disulfide bonds in CNX and CRT-bound glycoprotein substrates. Previously, we solved the NMR structure of the central proline-rich P-domain of CRT comprising residues 189-288. This structure shows an extended hairpin topology, with three short anti-parallel beta-sheets, three small hydrophobic clusters, and one helical turn at the tip of the hairpin. We further demonstrated that the residues 225-251 at the tip of the CRT P-domain are involved in direct contacts with ERp57. Here, we show that the CRT P-domain fragment CRT(221-256) constitutes an autonomous folding unit, and has a structure highly similar to that of the corresponding region in CRT(189-288). Of the 36 residues present in CRT(221-256), 32 form a well-structured core, making this fragment one of the smallest known natural sequences to form a stable non-helical fold in the absence of disulfide bonds or tightly bound metal ions. CRT(221-256) comprises all the residues of the intact P-domain that were shown to interact with ERp57. Isothermal titration microcalorimetry (ITC) now showed affinity of this fragment for ERp57 similar to that of the intact P-domain, demonstrating that CRT(221-256) may be used as a low molecular mass mimic of CRT for further investigations of the interaction with ERp57. We also solved the NMR structure of the 73-residue fragment CRT(189-261), in which the tip of the hairpin and the first beta-sheet are well structured, but the residues 189-213 are disordered, presumably due to lack of stabilizing interactions across the hairpin.     

Preparation of a verifiable peptide-protein immunogen: direction-controlled conjugation of a synthetic fragment of the monitor peptide with myoglobin and application for sequence analysis

A useful method for preparing a synthetic peptide-carrying protein for specific antibody production was established. The monitor peptide is a trypsin-sensitive cholecystokinin-releasing peptide purified from rat pancreatic juice on the basis of its stimulatory activity toward pancreatic enzyme secretion. The NH2-terminus fragment of the monitor peptide (residues 1-14) was synthesized by a solid phase method. Cysteine at the COOH terminus of the fragment was conjugated with amino groups of myoglobin using a hetero-bifunctional reagent. Sequence analysis of the fragment-myoglobin conjugate indicated that the peptide/myoglobin conjugation ratio was about 1/1 (mol/mol). Antiserum against the conjugate from a rabbit effectively abolished the stimulatory activity of the monitor peptide in the rat small intestine.     

Mechanism of protein folding: I. General considerations and refolding of myoglobin

To explain the rapidity of the process of protein folding, we cite two aspects of hydrophobic interaction: its long-range nature and the specificity of pairing after the formation of secondary structures. These two factors, when incorporated with the growth-type mechanism, can determine the folding pathway of proteins. This mechanism is applied to myoglobin. Appropriate introduction of side chains of amino acid residues and the heme group attached to His 93 yield a refolded tertiary structure that is in good agreement with the native structure.     

1H NMR and CD evidence of the folding of the isolated ribonuclease 50-61 fragment

In our search for potential folding intermediates we have prepared and characterized the fragment of RNase A corresponding to residues 50-61. Proton chemical shift variations with temperature, addition of stabilizing (TFE) or denaturing agents (urea) provide a strong experimental basis for concluding that in aqueous solution this RNase fragment forms an alpha-helix structure similar to that in the intact RNase A crystal. This conclusion lends strong support to the idea that elements of secondary structure (mainly alpha-helices) can be formed in the absence of tertiary interactions and act as nucleation centers in the protein folding process.     

Alignment of a sparse protein signature with protein sequences: application to fold prediction for three small globulins.

A novel algorithm has been developed for scoring the match between an imprecise sparse signature and all the protein sequences in a sequence database. The method was applied to a specific problem: signatures were derived from the probable folding nucleus and positions obtained from the determined interactions that occur during the folding of three small globular proteins and points of inter-element contact and sequence comparison of the actual three-dimensional structures of the same three proteins. In the case of two of these, lysozyme and myoglobin, the residues in the folding nucleus corresponded well to the key residues spotted by examination of the structures and in the remaining case, barnase, they did not. The diagnostic performance of the two types of signatures were compared for all three proteins. The significance of this for the application of an understanding of the protein folding mechanisms for structure prediction is discussed. The algorithm is generic and could be applied to other user-defined problems of sequence analysis.     

Probing the folding capacity and residual structures in 1-79 residues fragment of staphylococcal nuclease by biophysical and NMR methods

1-79 residues SNase fragment (SNase79) has chain length containing a sequence for helix alpha(1), omega-loop, beta(I)-sheet, and partial beta(II)-sheet of native SNase. The incomplete "beta-barrel" structural region of SNase79 makes this fragment to be interested in investigation of its conformation. For this study, we use CD, fluorescence, and NMR spectroscopy to probe the folding capacity and the residual structures in SNase79. The optical spectra obtained for SNase79 and its mutants reveal the presence of retained capacity for folding of the fragment. The NMR derived (13)C(alpha) secondary chemical shifts, (3)J(NH-Halpha) coupling constants, amide-proton temperature coefficients, interresidue NOEs, and (15)N relaxation data determine the intrinsic propensities for helix- and turn- or beta-sheet-like conformations of SNase79, which is not the result of stabilizing inter-molecular interactions by oligomerization effects. The residual turn- and helix-like structures may serve as potential local nucleation sites, whereas the residual beta(I)-sheet-like structure can be regarded as a potential non-local nucleation site in the folding of SNase79. The intrinsic local and non-local interactions in these potential initiation sites are insufficient to stabilize the folding of SNase79 due to the shortage of relevant long-range interactions from other part of the fragment. The conformational ensemble of SNase79 is a highly heterogeneous collection of interconverting conformations having transiently populated helix- and beta-sheet- or turn-like structures.     

Molecular thermodynamic model to predict the alpha-helical secondary structure of polypeptide chains in solution.

The native state of a protein molecule in aqueous solutions represents one of the lowest states of Gibbs energy [Anfinsen, C.B. (1973) Science 181, 223-230]. Much progress has been made about the rules of protein folding [King, J. (1989) Chem. Eng. News 67, 32-54] and the dominant forces in protein folding [Dill, K.A. (1990) Biochemistry 29, 7133-7155]. However, the quantitative contributions of different Gibbs energy terms to protein stability remains a controversial issue [Moult, J., & Unger, R. (1991) Biochemistry 30, 3816-3824]. A molecular thermodynamic model has been proposed for the Gibbs energy of folding a residue in aqueous homopolypeptides from a random-coiled state to either the alpha-helix state or the beta-sheet state [Chen, C.-C., Zhu, Y., King, J.A., & Evans, L.B. (1992) Biopolymers 32, 1375-1392]. In this work, we present a generalization of the molecular thermodynamic model for the Gibbs energy of folding natural and synthetic heteropolypeptides from random-coiled conformations into alpha-helical conformations. The generalized model incorporates the intrinsic folding potential due to residue-solvent interactions, the cooperative folding effect due to residue-residue interactions, and the location and length of alpha-helices. The utility of the model was demonstrated by examining the stability of alpha-helical conformations of a number of natural polypeptides including C-peptide (residues 1-13) and S-peptide (residues 1-20) of RNase A (bovine pancreatic ribonuclease A), the P alpha fragment in BPTI (bovine pancreatic trypsin inhibitor), and synthetic polypeptides (the copolymers of different amino acid residues) including alanine-based peptides (16 or 17 residues long) in water. The computed Gibbs energies correspond well with the experimental data on helicity. The results also accounted for the effects of amino acid substitution and temperature on the stability of alpha-helical conformations of the test polypeptides.