Secondary structural changes in the intact and the disulfide bridges cleaved beta-lactoglobulin A and B in solutions of urea, guanidine hydrochloride, and sodium dodecyl sulfate

The relative proportions of -helix, -sheet, and unordered form in -lactoglobulin A and B were examined in solutions of urea, guanidine, and sodium dodecyl sulfate (SDS). In the curve-fitting method of circular dichroism (CD) spectra, the reference spectra of the corresponding structures determined by Chen et al. (1974) were modified essentially according to the secondary structure of -lactoglobulin B predicted by Creamer et al. (1983), i.e., that the protein has 17% -helix and 41% -sheet. The two variants showed no appreciable difference in structural changes. The reduction of disulfide bridges in the proteins increased -sheet up to 48% but did not affect the -helical proportion. The -helical proportions of nonreduced -lactoglobulin A and B were not affected below 2 M guanidine or below 3 M urea, but those of the reduced proteins began to decrease in much lower concentrations of these denaturants. By contrast, the -helical proportions of the nonreduced and reduced proteins increased to 40–44% in SDS. The -sheet proportions of both nonreduced and reduced proteins, which remained unaffected even in 6 M guanidine and 9 M urea, decreased to 24–25% in SDS.     

Enantiomer enrichment in early peptides

The two main ordered conformations of polypeptides, the -helix and the -sheet, were considered as possible asymmetric supports for stereoselection processes leading to the enrichment in one enantiomer. -Helices can accomodate residues of both chirality distributed in the same chain, whereas the formation of -sheets arises from the association of chain segments containing at least seven residues of the same chirality. When the residue composition departs from the racemic mixture, one handedness of the helix is favored, whereas the -sheet nuclei become predominantly of a unique chirality. Taking into account these observations, processes of enrichment specific for -and -structures were envisaged theoretically as well as experimentally.     

Interactions between NFκB and Its Inhibitor iκB: Biophysical Characterization of a NFκB/iκB-α Complex

The N-terminal domain (1–318 amino acids) of mouse NFB (p65) has been purified to homogeneity from the soluble fraction of Escherichia coli cells expressing this protein. Its complex with a full-length iB- (MAD3, 1–317 amino acids) molecule was generated by binding the E. coli-derived iB- to the purified NFB and purifying the complex by sequential chromatography. The stoichiometry of NFB to iB in the complex was determined to be 2 to 1 by light scattering and SDS–polyacrylamide gel electrophoresis. The secondary structure of the NFB (p65) determined by Fourier-transform infrared (FTIR) spectroscopy is in good agreement with that of the p50 in the crystal structure of the p50/DNA complex, indicating that no significant structural change in NFB occurs upon binding of DNA. The FTIR spectrum of the NFB/iB complex indicates that its secondary structure is composed of 17% -helix, 39% -strand, 18% irregular structures, and 26% -turns and loops. By comparing these data to the FTIR data for NFB alone, it is concluded that the iB (MAD3) in the complex contains 35% -helix, 27% -strand, 22% irregular structures, and 16% -turns and loops. Circular dichroism (CD) analysis of a shorter form of iB (pp40) indicates that it contains at least 20% -helix and that the iB subunit accounts for nearly all of the -helix present in the NFB/iB complex, consistent with the FTIR results. The stabilities of NFB, iB, and their complex against heat-induced denaturation were investigated by following changes in CD signal. The results indicate that the thermal stability of iB is enhanced upon the formation of the NFB/iB complex.     

Interaction of chlorpromazine with milk proteins

The mode and nature of the binding of chlorpromazine (CPZ), a psychotropic drug, with milk proteins – -lactalbumin (with substantial amounts of -helix, -sheet and random coil), -lactoglobulin (a major -sheeted protein) and _s-casein (a random coiled protein) have been studied spectrofluorometrically and spectropolarimetrically. The binding affinity of CPZ for unfolded proteins is comparatively less than that of folded proteins although the number of binding sites is smaller in the latter case, due to the greater extent of binding of CPZ for folded proteins. Thermodynamic analysis reveals that CPZ binds to -lactalbumin and _s-casein in an endothermic (H^o is positive) and hydrophobic manner but with -lactoglobulin in an exothermic (H^o is negative) manner. Far UV Circular dichroic studies reveal that CPZ increases the secondary structure of the major -sheeted protein, -lactoglobulin possibly by increasing the relative contact orders (non-local contacts) within the residues. On the other hand, for proteins possessing random coil, it increases the unfolded state of the protein. CPZ does not affect local contacts in a-helix when its interaction is compared with a major -helical protein, myoglobin.     

Conformational Variety of Polyanionic Peptides At Low Salt Concentrations

Cordially dedicated to Dr. Leslie Orgel on the occasion of his 70th birthday.Sequential oligo- and polypeptides based on glutamic acid and leucine residues have been synthesized. In pure water, they exhibit a random coil conformation. Addition of very small amounts of divalent metallic cations induces the formation of ordered structure in the peptides which remain in solution. Higher salt concentrations precipitate the peptides. Polypeptides with alternating glutamic acid and leucine residues undergo a coil to -sheet transition in the presence of Ca²⁺, Ba²⁺, Mn²⁺, Co²⁺, Zn²⁺ and Hg²⁺. Addition of Cu²⁺ or Fe²⁺ induces the formation of an -helix. Solid amorphous CdS generates water soluble -sheets, as well. Sequential poly(Leu-Glu-Glu-Leu) adopts an -helix in the presence of divalent cations. The sequence-dependent conformational diversity was extended to poly(Asp-Leu) and poly(Leu-Asp-Asp-Leu).     

13Cα and 13Cβ chemical shifts as a tool to delineate β-hairpin structures in peptides

Unravelling the factors that contribute to the formation and the stability of -sheet structure in peptides is a subject of great current interest. A -hairpin, the smallest -sheet motif, consists of two antiparallel hydrogen-bonded -strands linked by a loop region. We have performed a statistical analysis on protein -hairpins showing that the most abundant types of -hairpins, 2:2, 3:5 and 4:4, have characteristic patterns of ¹³C and ¹³C conformational shifts, as expected on the basis of their and angles. This fact strongly supports the potential value of ¹³C and ¹³C conformational shifts as a means to identify -hairpin motifs in peptides. Their usefulness was confirmed by analysing the patterns of ¹³C and ¹³C conformational shifts in 13 short peptides, 10–15 residues long, that adopt -hairpin structures in aqueous solution. Furthermore, we have investigated their potential as a method to quantify -hairpin populations in peptides.     

Measurement of15N-13C J couplings in staphylococcal nuclease

Summary ¹⁵N-C and¹⁵N-C J couplings were measured for the backbone of staphylococcal nuclease, uniformly enriched with¹⁵N and¹³C. It is found that the^IJ_C'N coupling is similar for -sheet, J=14.8 ± 0.5 and for -helix, J = 14.8 ± 0.4 but tends to be larger for the unstructured N- and C-terminal ends of the protein (J=15.6 ± 0.5). On average,¹J_NC are smaller for -helical residues (J=9.6 ± 0.3 Hz) compared to -sheet (J=10.9 ± 0.8 Hz) and a substantial difference is observed for²J_NC in -helices (J=6.4 ± 0.4 Hz) and -sheets (J=8.3 ± 0.8 Hz).Dedicated to the memory of Professor V.F. Bystrov     

Solvent assistance in regiospecific disulfide formation in dimethylsulfoxide

This paper describes a convenient oxidative refolding method that exploits the dual property of dimethylsulfoxide (DMSO) as an oxidant and a solvent 'chaperon' in assisting disulfide formation in peptides. Synthetic peptides with preferred secondary structures were used as models. For -sheet peptides, an active fragment of fibroblast growth factor containing the tetrapeptide Arg-Ser-Arg-Arg at a reverse turn was used. A disulfide scan consisting of 16 analogs is designed in which different pairs of amino acids on the antiparallel -sheets flanking the active determinants are replaced with cysteine. DMSO in aqueous buffer at pH 6 or 8 was found to minimize aggregation due to -sheet formation in all 16 -stranded peptides and provided monocyclic disulfide peptides within 7 h. In contrast, air oxidation required a significantly longer duration for completion under similar conditions, and only 8 of 16 peptides formed intramolecular disulfides. Rate accelerations at pH 8 were found in exo-disulfide formation involving peptides with amino terminal cysteine, irrespective of oxidation conditions. The exo-disulfide effect in accelerating disulfide formation may be useful for regiospecific disulfide formation. For -helix peptides, the two-disulfide endothelin (ET) was used as a model. DMSO in combination with trifluoroethanol (TFE) was found to favor the desired bicyclic 1,4-disulfide bridged ET (1,4-ET) over the incorrectly folded 1,3-ET. Under aqueous conditions at pH 5–11, 1,4-ET to 1,3-ET was formed in the ratio of approximately 3:1, while the use of DMSO and TFE increased the ratio to 11:1. This solvent combination may stabilize an -helical stretch found in ET and contribute to enhanced selectivity. Thus, our results show that DMSO in disulfide formation in an aqueous or helix-promoting solution may serve as an oxidant and a 'chaperon' solvent system to provide regiospecificity for oxidative disulfide formation.     

Measuring the chi 1 torsion angle in protein by CH-CH cross-correlated relaxation: a new resolution-optimised experiment

Here we introduce an experiment with high sensitivity and resolution for the measurement of CH-CH dipolar-dipolar cross-correlated relaxation rates (CCRR) in protein side-chains. The new methodology aims to the determination of structural and dynamical parameters around the torsion angle ₁ by measuring CH-CH cross-correlated relaxation rates. The method is validated on the protein ubiquitin: the ₁ angles determined from the CCRR data are compared with the ₁ angles of a previously determined NMR structure. The agreement between the two data sets is excellent for most residues. The few discrepancies that were found between the CCR-derived ₁ angles and the angles of the previously determined NMR structure could be explained by taking internal motion into account. The new methodology represents a very powerful tool to determine both structure and dynamics of protein side-chains in only one experiment.