A stabilized molten globule protein

Temperature, pH, and Molecular Packing Effects on the Penetration of Oleic Acid Monolayer by α-Lactalbumin

Recently, we reported on the interfacial behavior of mixed oleic acid (OA)-α-lactalbumin monolayer and its relevance in the formation of tumoricidal HAMLET (human α-lactalbumin made lethal to tumor cells)-like complex. This complex is probably formed in the gastrointestinal tract, but it has not been proved so far. The molecular base and the underlying physicochemical forces leading to such complexation remain to be known as well. There are also several other issues related with the complex stoichiometry that need to be fully explained. This study provides insight into the mechanism of temperature, pH, and physical state of monolayer-dependent binding of OA by the milk protein- apo-α-lactalbumin. Using the Langmuir and Langmuir-Blodgett approaches, we investigated the interactions between the OA monolayer and the apo-bovine α-lactalbumin (BLA III) at different pH, temperatures, and molecular packing. We found that the most favorable conditions for the formation of mixed OA-BLA III film are relevant to the gastric environment. The stabilization of OA-BLA III at the interface is associated with the conformational changes of protein in the presence of fatty acids induced by low pH and high temperature in the expanded monolayer. Our approach helps to understand the molecular mechanism of HAMLET/bovine α-lactalbumin made lethal to tumor cells formation in vivo.

Characterization of an alternative low energy fold for bovine α-lactalbumin formed by disulfide bond shuffling

Bovine α-lactalbumin (αLA) forms a misfolded disulfide bond shuffled isomer, X-αLA. This X-αLA isomer contains two native disulfide bridges (Cys 6-Cys 120 and Cys 28-Cys 111) and two non-native disulfide bridges (Cys 61-Cys 73 and Cys 77-Cys 91). MD simulations have been used to characterize the X-αLA isomer and its formation via disulfide bond shuffling and to compare it with the native fold of αLA. In the simulations of the X-αLA isomer the structure of the α-domain of native αLA is largely retained in agreement with experimental data. However, there are significant rearrangements in the β-domain, including the loss of the native β-sheet and calcium binding site. Interestingly, the energies of X-αLA and native αLA in simulations in the absence of calcium are closely similar. Thus, the X-αLA isomer represents a different low energy fold for the protein. Calcium binding to native αLA is shown to help preserve the structure of the β-domain of the protein limiting possibilities for disulfide bond shuffling. Hence, binding calcium plays an important role in both maintaining the native structure of αLA and providing a mechanism for distinguishing between folded and misfolded species.

A Novel Conformation-Dependent Monoclonal Antibody Specific to the Native Structure of β-Lactoglobulin and Its Application

Molten globules are thought to be general intermediates in protein folding and unfolding. beta-lactoglobulin (beta-LG) is one of the major bovine whey proteins, constituting approximately 10 to 15% of total milk proteins. We have recently identified beta-LG as a superior marker for evaluating thermally processed milk. Strand D of beta-LG participates in irreversible thermal unfolding as probed by a monoclonal antibody (mAb) specific to thermally denatured beta-LG. In the present study, we used native beta-LG as an immunogen to test the hypothesis that a specific mAb against the native beta-LG could be established. As result, a mAb (4H11E8) directed against the native structure of beta-LG was made. The antibody did not recognize the heat-denatured form of beta-LG, such as its dimer and aggregates. Immunoassay using this "native" mAb showed that the stability of beta-LG was at temperatures < or =70 degrees C. beta-Lactoglobulin began to deteriorate between 70 and 80 degrees C over time. The denaturation was correlated with the transition temperature of beta-LG. Further chemical modification of Cys (carboxymethylation) or positively charged residues (acetylation) of beta-LG totally abolished its immunoreactivity, confirming the conformation-dependent nature of this mAb. Using competitive ELISA, the 4H11E8 mAb could determine the native beta-LG content in commercially processed milks. Concentrations of native beta-LG varied significantly among the local brands tested. From a technological standpoint, the mAb prepared in this study is relevant to the design and operation of appropriate processes for thermal sanitation of milk and of other dairy products.

Conformational impurity of disulfide proteins: Detection, quantification, and properties

The conformations of native proteins are in principle, and in most cases, dictated by the law of thermodynamics. Accordingly, a native protein must always exist in equilibrium with a minor concentration of nonnative (denatured) conformational isomers even at nondenaturing conditions. The presence of an infinitesimal quantity of nonnative conformational isomers at physiological conditions is biologically relevant due to their propensity to aggregate, which is an underlying cause of many neurodegenerative diseases. However, their detection and quantification are inherently difficult. In this article, we describe a simple strategy using the technique of disulfide scrambling to identify and quantify such minute concentrations of nonnative isomers. It is demonstrated that even for small stable proteins such as epidermal growth factor and hirudin, approximately 1% of heterogeneous nonnative isomers coexist with the native proteins under physiological conditions.

Beta-lactoglobulin is a thermal marker in processed milk as studied by electrophoresis and circular dichroic spectra

As much of the sterilization process involves heat treatment during the preparation of milk on an industrial scale, the unpredictable measures of the process are an essential issue in determining the quality of the milk. The purpose of the present study was to investigate the major protein change(s) of whey proteins in processed milk and extend the knowledge for future reference in the dairy industry. Using a native polyacrylamide gel electrophoresis, we showed almost a 90% loss and denaturation of beta-lactoglobulin (LG), but not alpha-lactalbumin (LA), in some brands of the processed and dry milks. Immunochemical analysis using Western blotting revealed that part of the loss was attributed to the formation of large multiple forms of LG in the processed product. Such denaturation was presumably associated with the heating procedure used in the process. Essentially, LG was the only major fraction converted to aggregates in milk heated at 95 degrees C for 30 min on 2-dimensional PAGE. The detailed thermal denaturation of purified LG and LA at various temperatures (50 to 95 degrees C) and time (5 to 960 s) were investigated using a circular dichroic analysis. The maximal changes of ellipticity at 205 nm (converting beta-structure to disordered structure) were correlated to heating temperature and time. There were no significant conformational changes of LG at temperatures below 70 degrees C for as long as 480 s. Pronounced and rapid changes occurred between 80 to 95 degrees C in a time-dependent manner. Fifty percent of the maximal changes could be reached within 15 s. In conclusion, the unique chemical and immunochemical loss and conformational changes made LG a superior marker for evaluating the thermal processing of milk. The detailed thermal denaturation curves of LG constructed with its time and temperature in this study provide a valuable reference for the dairy industry. We postulate that heat treatment over 80 degrees C in 15 s may induce a significant denaturation of milk LG.

Two-state folding of lysozyme versus multiple-state folding of alpha-lactalbumin illustrated by the technique of disulfide scrambling

The folding of lysozyme and of alpha-lactalbumin exhibits vastly different kinetics and pathways. Existing evidence indicates that folding intermediates of alphaLA form a well-populated equilibrium molten globule state that is absent in the case of hen lysozyme. We demonstrate here such divergent folding mechanisms of lysozyme and alphaLA using the technique of disulfide scrambling. Two extensively unfolded homologous isomers (beads-form) of lysozyme (Cys6-Cys30, Cys64-Cys76, Cys80-Cys94, Cys115-Cys127) and alphaLA (Cys6-Cys28, Cys61-Cys73, Cys77-Cys91, Cys111-Cys120) were allowed to refold in parallel to form the native protein. Folding kinetics was measured by the recovery of the native structure. Folding intermediates, which illustrate the folding pathway, were trapped by quenching disulfide shuffling and were analyzed by reversed-phase high-pressure liquid chromatography. The results revealed that under identical folding conditions, the folding rate of lysozyme is about 30-fold faster than that of alphaLA. Folding intermediates of lysozyme are far less heterogeneous and sparsely populated than those of alphaLA. Numerous predominant on-pathway and off-pathway intermediates observed along the folding pathway of alphaLA are conspicuously absent in the case of lysozyme. The difference is most striking under fast folding conditions performed in the presence of protein disulfide isomerase. Under these conditions, folding of lysozyme undergoes a near two-state mechanism without accumulation of stable folding intermediates.

The unfolding mechanism and the disulfide structures of denatured lysozyme

The mechanism of denaturation and unfolding of lysozyme has been characterized here using the method of disulfide scrambling. Under denaturing conditions (urea, guanidinium hydrochloride (GdmCl), guanidinium thiocyanate (GdmSCN), or elevated temperature) and in the presence of thiol initiator, lysozyme denatures by shuffling its four native disulfide bonds and converts to a mixture of fully oxidized scrambled isomers. To denature 50% of the native lysozyme requires 1.1 M of GdmSCN, 2.8 M of GdmCl and 7.4 M of urea, respectively. High temperature (75 degrees C) denatures the native lysozyme quantitatively within 20 min. Analysis by reversed-phase high-performance liquid chromatography reveals that urea and GdmCl denatured lysozyme comprise a single predominant disulfide isomer, designated as X-lysozyme-a, regardless of the concentration of the denaturant. X-Lysozyme-a was shown to adopt the beads-form structure with its four disulfide bonds formed by four consecutive pairs of cysteines (Cys6-Cys30, Cys64-Cys76, Cys80-Cys94, Cys115-Cys127). The conspicuous absence of partially structured unfolding intermediates of lysozyme contrasts to that found in the case of alpha-lactalbumin and accounts for the widely observed two-stage mechanism of lysozyme unfolding.

The folding pathway of alpha-lactalbumin elucidated by the technique of disulfide scrambling. Isolation of on-pathway and off-pathway intermediates

The technique of disulfide scrambling permits reversible conversion of the native and denatured (scrambled) proteins via shuffling and reshuffling of disulfide bonds. Under strong denaturing conditions (e.g. 6 m guanidinium chloride) and in the presence of a thiol initiator, alpha-lactalbumin (alphaLA) denatures by shuffling its four native disulfide bonds and converts to an assembly of 45 species of scrambled isomers. Among them, two predominant isomers, designated as X-alphaLA-a and X-alphaLA-d, account for about 50% of the total denatured structure of alphaLA. X-alphaLA-a and X-alphaLA-d, which adopt the disulfide patterns of (1-2,3-4,5-6,7-8) and (1-2,3-6,4-5,7-8), respectively, represent the most unfolded structures among the 104 possible scrambled isomers (Chang, J.-Y., and Li, L. (2001) J. Biol. Chem. 276, 9705-9712). In this study, X-alphaLA-a and X-alphaLA-d were purified and allowed to refold through disulfide scrambling to form the native alphaLA. Folding intermediates were trapped kinetically by acid quenching and analyzed quantitatively by reversed phase high pressure liquid chromatography. The results revealed two major on-pathway productive intermediates, two major off-pathway kinetic traps, and at least 30 additional minor transient intermediates. Of the two major on-pathway intermediates, one takes on a native-like alpha-helical domain, and the other comprises a structured beta-sheet, calcium binding domain. The two major kinetic traps are apparently stabilized by locally formed non-native-like structures. Overall, the folding mechanism of alphaLA is essentially congruent with the model of "folding funnel" furnished with a rather intricate energy landscape.

Beta-lactoglobulin molten globule induced by high pressure

Beta-lactoglobulin (beta-LG) was treated with high hydrostatic pressure (HHP) at 600 MPa and 50 degrees C for selected times as long as 64 min. The intrinsic tryptophan fluorescence of beta-LG indicated that HHP treatment conditions induced a conformational change. HHP treatment conditions also promote a 3-fold increase in the extrinsic fluorescence of 1-anilinonaphthalene-8-sulfonate and a 2.6-fold decrease for cis-paraneric acid, suggesting an increase in accessible aromatic hydrophobicity and a decrease in aliphatic hydrophobicity. Far-ultraviolet circular dichroism (CD) spectra reveal that the secondary structure of beta-LG converts from native beta-sheets to non-native alpha-helices following HHP treatment, whereas near-ultraviolet CD spectra reveal that the native tertiary structure of beta-LG essentially disappears. Urea titrations reveal that native beta-LG unfolds cooperatively, but the pressure-treated molecule unfolds noncooperatively. The noncooperative state is stable for 3 months at 5 degrees C. The nonaccessible free thiol group of cysteine121 in native beta-LG became reactive to Ellman's reagent after adequate HHP treatment. Gel electrophoresis with and without beta-mercaptoethanol provided evidence that the exposed thiol group was lost concomitant with the formation of S-S-linked beta-LG dimers. Overall, these results suggest that HHP treatments induce beta-LG into hydrophobic molten globule structures that remain stable for at least 3 months.