Conformational changes of alpha-lactalbumin induced by the stepwise reduction of its disulfide bridges: the effect of the disulfide bridges on the structural stability of the protein in sodium dodecyl sulfate solution

The role of hydrophobic interactions in the molten globule state of globular protein modulated by surfactants

In order to highlight the role of hydrophobic interactions in the molten globule (MG) state of globular protein modulated by surfactants, the interactions of bovine α-lactalbumin (α-LA) with alkyl trimethylammonium bromides (CnTAB, n = 10, 12, 14, and 16) have been studied by experimental and theoretical techniques. Isothermal titration calorimetry (ITC) showed that the enthalpy changes (ΔH) and area of the enthalpogram increased with increasing the chain length of CnTAB. The result of fluorescence, circular dichroism (CD) and 1H nuclear magnetic resonance (NMR) spectrum suggested that C10TAB and C12TAB unfolded α-LA partially, C14TAB reconstructed protein with a native-like secondary structure content, and C16TAB induced an MG state α-LA. The SAXS results confirmed that the tertiary structure of α-LA was disrupted by C16TAB forming an MG state complex with a micelle-like structure even at the surfactants concentrations below CMC. As indicated by MD results, the β-domain and unstructured region(s) were involved in the MG state α-LA modulated by CnTAB. This work not only provides molecular insights into the role of hydrophobic interactions in the MG state of a globular protein but also helps understand the mechanism of preparing α-LA based biomacromolecule modulated by hydrophobic interactions.

Secondary structural changes of homologous proteins, lysozyme and α-lactalbumin, in thermal denaturation up to 130 °C and sodium dodecyl sulfate (SDS) effects on these changes: comparison of thermal stabilities of SDS-induced helical structures in these proteins

The thermal stability of two homologous proteins, lysozyme and α-lactalbumin, was examined by circular dichroism. The present study clearly showed two different aspects between the homologous proteins: (1) the original helices of lysozyme and α-lactalbumin were unchanged at heat treatments up to 60 and 40 °C, respectively, indicating a higher thermal stability of lysozyme, and (2) upon cooling to 25 °C, the original helices of lysozyme were never reformed after they were once disrupted, while those of α-lactalbumin, disrupted at a particular temperature range between 40 and 60 °C, were completely reformed. In addition, the structural changes were also examined in the coexistence of sodium dodecyl sulfate (SDS), which induced the formation of helical structures in these proteins at 25 °C. A distinct difference appeared in the thermal stabilities of the SDS-induced helices. All of the SDS-induced helices of lysozyme were disrupted below 60 °C, while those of α-lactalbumin at 10 mM SDS were unchanged up to 130 °C. A similarity was also fixed. Not only the SDS-induced helices but also the original helices of the two proteins were reformed upon cooling to 25 °C after the thermal denaturation below 100 °C in the coexistence of 10 mM SDS.

Mechanism of suppression of dithiothreitol-induced aggregation of bovine alpha-lactalbumin by alpha-crystallin

The kinetics of dithiothreitol (DTT)-induced aggregation of alpha-lactalbumin from bovine milk has been studied using dynamic light-scattering technique. Analysis of the distribution of the particles formed in the solution of alpha-lactalbumin after the addition of DTT by size showed that the initial stage of the aggregation process was the stage of formation of the start aggregates with the hydrodynamic radius (R(h)) of 80-100nm. Further growth of the protein aggregates proceeds as a result of sticking of the start aggregates. Suppression of alpha-lactalbumin aggregation by alpha-crystallin is mainly due to the increase in the duration of the lag period on the kinetic curves of aggregation. It is assumed that the initially formed complexes of unfolded alpha-lactalbumin with alpha-crystallin were transformed to the primary clusters prone to aggregation as a result of the redistribution of the denatured protein molecules on the surface of the alpha-crystallin particles.

Amyloidogenesis of natively unfolded proteins

Aggregation and subsequent development of protein deposition diseases originate from conformational changes in corresponding amyloidogenic proteins. The accumulated data support the model where protein fibrillogenesis proceeds via the formation of a relatively unfolded amyloidogenic conformation, which shares many structural properties with the pre-molten globule state, a partially folded intermediate first found during the equilibrium and kinetic (un)folding studies of several globular proteins and later described as one of the structural forms of natively unfolded proteins. The flexibility of this structural form is essential for the conformational rearrangements driving the formation of the core cross-beta structure of the amyloid fibril. Obviously, molecular mechanisms describing amyloidogenesis of ordered and natively unfolded proteins are different. For ordered protein to fibrillate, its unique and rigid structure has to be destabilized and partially unfolded. On the other hand, fibrillogenesis of a natively unfolded protein involves the formation of partially folded conformation; i.e., partial folding rather than unfolding. In this review recent findings are surveyed to illustrate some unique features of the natively unfolded proteins amyloidogenesis.

Disulfide bridge based PEGylation of proteins

PEGylation is a clinically proven strategy for increasing the therapeutic efficacy of protein-based medicines. Our approach to site-specific PEGylation exploits the thiol selective chemistry of the two cysteine sulfur atoms from an accessible disulfide. It involves two key steps: (1) disulfide reduction to release the two cystine thiols, and (2) bis-alkylation to give a three-carbon bridge to which PEG is covalently attached. During this process, irreversible denaturation of the protein does not occur. Mechanistically, the conjugation is conducted by a sequential, interactive bis-alkylation using alpha,beta-unsaturated-beta'-mono-sulfone functionalized PEG reagents. The combination of: - (a) maintaining the protein's tertiary structure after reduction of a disulfide, (b) bis-thiol selectivity of the PEG reagent, and (c) PEG associated steric shielding ensure that only one PEG molecule is conjugated at each disulfide. Our studies have shown that peptides, proteins, enzymes and antibody fragments can be site-specifically PEGylated using a native and accessible disulfide without destroying the molecules' tertiary structure or abolishing its biological activity. As the stoichiometric efficiency of our approach also enables recycling of any unreacted protein, it offers the potential to make PEGylated biopharmaceuticals as cost-effective medicines.

Study of the disulfide reduction of denatured proteins by liquid chromatography coupled with on-line cold-vapor-generation atomic-fluorescence spectrometry (LC-CVGAFS)

Hydrophobic-interaction chromatography coupled on-line with chemical-vapor-generation atomic-fluorescence spectrometry (HIC-CVGAFS), optimized recently for the analysis of thiol-containing proteins under denaturing conditions, has been used to study the chemical reduction of denatured proteins. Four proteins chosen as models (human serum albumin (HSA), bovine serum albumin (BSA), alpha-lactalbumin (alpha-Lac) from bovine milk, and lysozyme from chicken egg (Lys)) were denatured with urea and reduced with dithiothreitol (DTT), with selenol as catalyst. The method is based on derivatization of the -SH groups of proteins with p-hydroxymercurybenzoate (PHMB), followed by HIC separation and post-column on-line reaction of the derivatized reduced, denatured proteins with bromine generated in situ. HgII, derived from rapid conversion of uncomplexed and protein-complexed PHMB, is selectively detected by AFS in an Ar/H2 miniaturized flame after sodium borohydride (NaBH4) reduction to Hg degrees . The yield of the reduction was studied as a function of reductant concentration, reduction time (tred), and urea concentration. Results showed that the optimum values for DTT and selenol concentrations and for tred were between 1 and 100 mmol L(-1) and between 1 and 20 min, respectively, depending on the protein studied. The percentage disulfide bond reduction increases as the urea concentration used for protein denaturation increases, giving a single-step sigmoid increment for single-domain, low-MW proteins (alpha-Lac and Lys), and a two-step sigmoid increment for multi-domain, high MW proteins (HSA and BSA). The shapes of plots of percentage reduced disulfide against urea concentration are characteristic of each protein and are correlated with the location of S-S in the protein. Under the adopted conditions complete protein denaturation is the conditio sine qua non for obtaining 100% S-S reduction. The detection limit for denatured, reduced proteins examined under the optimized conditions was found to be in the range 1-5 x 10(-12) mol L(-1) (10-30 pg), depending on the protein considered.

Induction of ‘molten globule’ like state in acid-denatured state of unmodified preparation of stem bromelain: Implications of disulfides in protein folding

A denatured state of unmodified preparation of stem bromelain representing a structureless form has been characterized at pH 2.0 and the effect of increasing concentration of TFE on the acid-denatured state has been investigated by circular dichroism (CD), fluorescence emission spectroscopy and binding of the hydrophobic dye, 1-anilino-8-naphthalene sulfonic acid (ANS). Far-UV CD spectra show considerable accumulation of secondary structure when the acid-denatured bromelain is subjected to 70% (v/v) TFE and exhibited close resemblance to spectral features of those of pH 7.0 preparation. Interestingly, the acid-denatured state also regained some tertiary structure/interactions, with increasing concentration of TFE and at 60% (v/v) TFE, these approached almost those of the native like state. However, further increase to 70% (v/v) TFE resulted in complete loss of tertiary structure/interactions. Tryptophan fluorescence emission studies also suggested the induction of significant compact structure at 60% (v/v) concentration of TFE. In addition the acid-denatured state showed enhanced binding of ANS in presence of 60% (v/v) TFE. Taken together these observations suggest the existence of a molten globule state in acid-denatured bromelain between 60 and 70% (v/v) TFE. A similar molten globule state under identical conditions has been identified in reduced and carboxymethylated preparation of stem bromelain as reported in our earlier communication [Arch. Biochem. Biophys. 413 (2003) 199]. Comparison suggests unfolding/folding behavior of the bromelain to be independent of the intactness of the disulfide bonds.

Conformational prerequisites for alpha-lactalbumin fibrillation

Bovine alpha-lactalbumin, a small acidic Ca(2+)-binding milk protein, formed amyloid fibrils at low pH, where it adopted the classical molten globule-like conformation. Fibrillation was accompanied by a dramatic increase in the beta-structure content and a characteristic increase in the thioflavin T fluorescence intensity. S-(Carboxymethyl)-alpha-lactalbumin, a disordered form of the protein with three out of four disulfide bridges reduced, was even more susceptible to fibrillation. Other partially folded conformations induced in the intact protein at neutral pH, either by the removal of Ca(2+) or by the binding of Zn(2+) to the Ca(2+)-protein complex, did not fibrillate, although Zn(2+)-loaded alpha-lactalbumin precipitated out of solution as amorphous aggregates. Our data suggest that the transformation of a protein into an essentially unfolded (thus, highly flexible) conformation is required for successful fibril formation, whereas more rigid (but still flexible) species may form amorphous aggregates.

Single disulfide bond reduced papain exists in a compact intermediate state

Partially reduced proteins and other chemically modified derivatives are very useful model systems to understand the protein folding in vivo. Upon reduction, proteins attain different conformations with varying degrees of compactness. The reduction of papain in the presence of 8 M urea leads to the partial reduction of one disulfide bond. This derivative (single disulfide reduced carboxymethylated 1RCM papain (3RCM papain)) was characterized by spectroscopic methods and the effect of this reduction on the unfolding of the protein was investigated. Under this partial reduction, papain exhibits more than half of the tertiary and most of the secondary structures relative to the non-reduced molecule (free cysteine reduced and carboxymethylated papain (1RCM papain)). Hydrophobic regions are exposed to the solvent as observed through 8-anilino-1-naphthalene sulfonic acid binding which was absent in the fully intact and unfolded protein, at neutral pH. Hydrodynamic studies indicated that 3RCM papain, under neutral conditions, possess expanded conformation as compared to the native protein. Tryptophan fluorescence quenching studies suggested the exposure of aromatic residues to solvent. Guanidine hydrochloride induced unfolding of this derivative, at neutral pH, showed a non-cooperative transition contrary to the cooperativity seen with intact protein. Thermal unfolding indicates that 3RCM papain is less stable compared to the intact protein. These findings suggest that partial reduction of papain has a significant effect on the unfolding behavior of papain.

A novel methodology for assignment of disulfide bond pairings in proteins

A novel methodology is described for the assignment of disulfide bonds in proteins of known sequence. The denatured protein is subjected to limited reduction by tris(2-carboxyethyl)phosphine (TCEP) in pH 3.0 citrate buffer to produce a mixture of partially reduced protein isomers; the nascent sulfhydryls are immediately cyanylated by 1-cyano-4-dimethylamino-pyridinium tetrafluoroborate (CDAP) under the same buffered conditions. The cyanylated protein isomers, separated by and collected from reversed-phase HPLC, are subjected to cleavage of the peptide bonds on the N-terminal side of cyanylated cysteines in aqueous ammonia to form truncated peptides that are still linked by residual disulfide bonds. The remaining disulfide bonds are then completely reduced to give a mixture of peptides that can be mass mapped by MALDI-MS. The masses of the resulting peptide fragments are related to the location of the paired cysteines that had undergone reduction, cyanylation, and cleavage. A side reaction, beta-elimination, often accompanies cleavage and produces overlapped peptides that provide complementary confirmation for the assignment. This strategy minimizes disulfide bond scrambling and is simple, fast, and sensitive. The feasibility of the new approach is demonstrated in the analysis of model proteins that contain various disulfide bond linkages, including adjacent cysteines. Experimental conditions are optimized for protein partial reduction, sulfhydryl cyanylation, and chemical cleavage reactions.