Structural characterisation of the human alpha-lactalbumin molten globule at high temperature

Molten globules are partially folded forms of proteins thought to be general intermediates in protein folding. The 15N-1H HSQC NMR spectrum of the human alpha-lactalbumin (alpha-LA) molten globule at pH 2 and 20 degrees C is characterised by broad lines which make direct study by NMR methods difficult; this broadening arises from conformational fluctuations throughout the protein on a millisecond to microsecond timescale. Here, we find that an increase in temperature to 50 degrees C leads to a dramatic sharpening of peaks in the 15N-1H HSQC spectrum of human alpha-LA at pH 2. Far-UV CD and ANS fluorescence experiments demonstrate that under these conditions human alpha-LA maintains a high degree of helical secondary structure and the exposed hydrophobic surfaces that are characteristic of a molten globule. Analysis of the H(alpha), H(N) and 15N chemical shifts of the human alpha-LA molten globule at 50 degrees C leads to the identification of regions of native-like helix in the alpha-domain and of non-native helical propensity in the beta-domain. The latter may be responsible for the observed overshoot in ellipticity at 222 nm in kinetic refolding experiments.     

Stability of the molten globule state of a domain-exchanged chimeric protein between human and bovine alpha-lactalbumins

A domain-exchanged chimeric alpha-lactalbumin (alpha-LA), which consisted of the alpha-domain of human alpha-LA and the beta-domain of bovine alpha-LA, was constructed. Like native alpha-LA, the chimeric protein was in a molten globule state in the absence of Ca(2+) at neutral pH and low salt concentration. The stability of the molten globule state of the constructed chimeric protein was identical to that of the recombinant human protein and was higher than that of the recombinant bovine protein. The stability of the molten globule state of alpha-LA is defined by the stability of the alpha-domain.     

A stabilized molten globule protein

A predominant conformational isomer of non-native alpha-lactalbumin (alpha-LA) has been purified by thermal denaturation of the native alpha-LA using the technique of disulfide scrambling. This unique isomer retains a substantial content of alpha-helical structure. It is stabilized by two native disulfide bonds within the alpha-helical domain and two scrambled non-native disulfide bonds at the beta-sheet domain. This denatured isomer of alpha-LA exhibits structural characteristics that are consistent with the well-documented molten globule state. The ability to prepare a stabilized and structurally defined molten globule provides a useful model for studying the folding and unfolding pathways of proteins.     

Structural characterization of the molten globule of alpha-lactalbumin by solution X-ray scattering.

A compact denatured state is often observed under a mild denaturation condition for various proteins. A typical example is the alpha-lactalbumin molten globule. Although the molecular compactness and shape are the essential properties for defining the molten globule, there have been ambiguities of these properties for the molten globule of alpha-lactalbumin. Using solution X-ray scattering, we have examined the structural properties of two types of molten globule of alpha-lactalbumin, the apo-protein at neutral pH and the acid molten globule. The radius of gyration for the native holo-protein was 15.7 A, but the two different molten globules both had a radius of gyration of 17.2 A. The maximum dimension of the molecule was also increased from 50 A for the native state to 60 A for the molten globule. These values clearly indicate that the molten globule is not as compact as the native state. The increment in the radius of gyration was less than 10% for the alpha-lactalbumin molten globule, compared with up to 30% for the molten globules of other globular proteins. Intramolecular disulfide bonds restrict the molecular expansion of the molten globule. The distance distribution function of the alpha-lactalbumin molten globule is composed of a single peak suggesting a globular shape, which is simply swollen from the native state. The scattering profile in the high Q region of the molten globule indicates the presence of a significant amount of tertiary fold. Based on the structural properties obtained by solution X-ray scattering, general and conceptual structural images for the molten globules of various proteins are described and compared with the individual, detailed structural model obtained by nuclear magnetic resonance.     

Determination of the structural ensemble of the molten globule state of a protein by computer simulations

We have used computer simulations to investigate the structural nature of the molten globule (MG) state of canine milk lysozyme. To sample the conformational space efficiently, we performed replica-exchange umbrella sampling simulations with the radius of gyration as a reaction coordinate. We applied the Weighted Histogram Analysis Method to the trajectory of the simulations to obtain the potential of mean force, from which we identified representative structures corresponding to local minima in the free energy surface. The representative structures obtained in this way are in accord with the characteristics of the MG state reported previously by experimental studies. We conjecture that the MG state comprises a series of partially structured states undergoing relatively fast conformational interchange.     

Local and global cooperativity in the human alpha-lactalbumin molten globule

NMR spectroscopy has been used to follow the urea-induced unfolding of the low pH molten globule states of a single-disulfide variant of human alpha-lactalbumin ([28-111] alpha-LA) and of two mutants, each with a single proline substitution in a helix. [28-111] alpha-LA forms a molten globule very similar to that formed by the wild-type four-disulfide protein, and this variant has been used as a model for the alpha-lactalbumin (alpha-LA) molten globule in a number of studies. The urea-induced unfolding behavior of [28-111] alpha-LA is similar to that of the four-disulfide form of the protein, except that [28-111] alpha-LA is less stable and has greater cooperativity in the loss of different elements of structure. For one mutant, L11P, the helix containing the mutation is highly destabilized such that it is completely unfolded even in the absence of urea. By contrast, for the other mutant, Q117P, the helix containing the mutation retains its compact structure. Both mutations, however, show significant long-range destabilization of the overall fold showing that the molten globule state has a degree of global cooperativity. The results reveal that different permutations of three of the four major alpha-helices of the protein can form a stable, locally cooperative, compact structural core. Taken together, these findings demonstrate that the molten globule state of alpha-LA is an ensemble of conformations, with different subsets of structures linked by a range of long-range interactions.     

Side chain accessibility and dynamics in the molten globule state of alpha-lactalbumin: a (19)F-NMR study

The molten globule state of alpha-lactalbumin (alpha-LA) has been considered a prototype of partially folded proteins. Despite the importance of molten globules in understanding the mechanisms of protein folding and its relevance to some biological phenomena, site-specific information on the structure and dynamics of a molten globule is limited, largely because of the high conformational flexibility and heterogeneity. Here, we use selective isotope labeling and (19)F NMR to investigate the solvent accessibility and side-chain dynamics of aromatic residues in the molten globule of alpha-LA. Comparison of these properties with those of the native and unfolded protein indicates that the alpha-LA molten globule is highly heterogeneous; each residue has its unique solvent accessibility and motional environment. Many aromatic residues normally buried in the interior of native alpha-LA remain significantly buried in the molten globule and the side-chain dynamics of these residues are highly restricted. Our results suggest that hydrophobic and van der Waals interactions mediated by the inaccessible surface area could be sufficient to account for all the stability of the alpha-LA molten globule, which is approximately 50% of the value for the native protein.     

Alpha-lactalbumin forms a compact molten globule in the absence of disulfide bonds.

Human alpha-lactalbumin (alpha-LA) is a four disulfide-bonded protein that adopts partially structured conformations under a variety of mildly denaturing conditions. At low pH, the protein is denatured but compact, with a high degree of secondary structure and a native-like fold. This is commonly referred to as a molten globule. A variant of alpha-LA, in which all eight cysteines have been mutated to alanine (all-Ala alpha-LA), has been studied using NMR spectroscopy. At low pH all-Ala alpha-LA is nearly as compact as wild type alpha-LA. Urea-induced unfolding experiments reveal that the residues that remain compact in the absence of disulfide bonds are those that are most resistant to unfolding in the wild-type alpha-LA molten globule. This is particularly remarkable because this stable core is formed by segments of the polypeptide chain from both the N- and C-termini. These results show that the overall architecture of the protein fold of alpha-LA is determined by the polypeptide sequence itself, and not as the result of cross-linking by disulfide bonds, and provide insight into the way in which the sequence codes for the fold.     

The structure of denatured alpha-lactalbumin elucidated by the technique of disulfide scrambling: fractionation of conformational isomers of alpha-lactalbumin

The structure of denatured alpha-lactalbumin (alpha-LA) has been characterized using the method of disulfide scrambling. Under denaturing conditions (urea, guanidine hydrochloride, guanidine thiocyanate, organic solvent or elevated temperature) and in the presence of thiol initiator, alpha-LA denatures by shuffling its four native disulfide bonds and converts to a mixture of fully oxidized scrambled structures. Analysis by reversed-phase HPLC reveals that the denatured alpha-LA comprises a minimum of 45 fractions of scrambled isomers. Among them, six well populated isomers have been isolated and structurally characterized. Their relative concentrations, which represent the fingerprinting of the denatured alpha-LA, vary substantially under different denaturing conditions. These results permit independent plotting of the denaturation and unfolding curves of alpha-LA. Most importantly, unique isomers of partially unfolded alpha-LA were shown to populate at mild and selected denaturing conditions. Organic solvent disrupts preferentially the hydrophobic alpha-helical domain, generating a predominant isomer containing two native disulfide bonds at the beta-sheet domain and two scrambled disulfide bonds at the alpha-helical region. Thermal denaturation selectively unfolds the beta-sheet domain of alpha-LA, producing a prevalent isomer that exhibits structural characteristics of the molten globule state of alpha-LA.     

Structure and dynamics of the alpha-lactalbumin molten globule: fluorescence studies using proteins containing a single tryptophan residue

The fluorescence properties of three variants of alpha-lactalbumin (alpha-LA) containing a single tryptophan residue were investigated under native, molten globule, and unfolded conditions. These proteins have levels of secondary structure and stability similar to those of the wild type. The fluorescence signal in the native state is dominated by that of W104, with the signal of W60 and W118 significantly quenched by the disulfide bonds in their vicinity. In the molten globule state, the magnitude of the fluorescence signal of W60 and W118 increases, due to the loss of rigid, specific side chain packing. In contrast, the magnitude of the signal of W104 decreases in the molten globule state, perhaps due to the protonation of H107 or quenching by D102 or K108. The solvent accessibilities of individual tryptophan residues were investigated by their fluorescence emission maximum and by acrylamide quenching studies. In the native state, the order of solvent accessibility is as follows: W118 > W60 > W104. This order changes to W60 > W104 > W118 in the molten globule state. Remarkably, the solvent accessibility of W118 in the alpha-LA molten globule is lower than that in the native state. The dynamic properties of the three tryptophan residues were examined by time-resolved fluorescence anisotropy decay studies. The overall rotation of the molecule can be observed in both the native and molten globule states. In the molten globule state, there is an increase in the extent of local backbone fluctuations with respect to the native state. However, the fluctuation is not sufficient to result in complete motional averaging. The three tryptophan residues in the native and molten globule states have different degrees of motional freedom, reflecting the folding pattern and dynamic heterogeneity of these states. Taken together, these studies provide new insight into the structure and dynamics of the alpha-LA molten globule, which serves as a prototype for partially folded proteins.     

Characterization of the molten globule of human serum retinol-binding protein using NMR spectroscopy

The molten globule state is a partially folded conformer of proteins that has been the focus of intense study for more than two decades. This non-native fluctuating conformation has been linked to protein-folding intermediates, to biological function, and more recently to precursors in amyloid fibril formation. The molten globule state of human serum retinol-binding protein (RBP) has been postulated previously to be involved in the mechanism of ligand release (Ptitsyn, O. B., et al. (1993) FEBS Lett. 317, 181-184). Conserved residues within RBP have been identified and proposed to be key to folding and stability, although a link to a molten globule state has not previously been shown (Greene, L. H., et al. (2003) FEBS Lett. 553, 39-44). In this work, a detailed characterization of the acid-induced molten globule of RBP is presented. Using stopped-flow fluorescence spectroscopy in the presence of 8-anilino-1-naphthalene sulfonic acid (ANS), we show that RBP populates a state with molten-globule-like characteristics early in refolding. To gain insight into the structural features of the molten globule of RBP, we have monitored the denaturant-induced unfolding of this ensemble using NMR spectroscopy. The transition at the level of individual residues is significantly more cooperative than that found previously for the archetypal molten globule, alpha-lactalbumin (alpha-LA); this difference may be due to a predominantly beta-sheet structure present in RBP in contrast to the alpha-helical nature of the alpha-LA molten globule.     

Local and long-range interactions in the molten globule state: A study of chimeric proteins of bovine and human alpha-lactalbumin

The molten globule state of alpha-lactalbumin has ordered secondary structure in the alpha-domain, which comprises residues 1 to 34 and 86 to 123. In order to investigate which part of a polypeptide is important for stabilizing the molten globule state of alpha-lactalbumin, we have produced and studied three chimeric proteins of bovine and human alpha-lactalbumin. The stability of the molten globule state formed by domain-exchanged alpha-lactalbumin, in which the amino acid sequence in the alpha-domain comes from human alpha-lactalbumin and that in the beta-domain comes from bovine alpha-lactalbumin, is the same as that of human alpha-lactalbumin and is substantially greater than that of bovine alpha-lactalbumin. Therefore, our results show that the stability of the molten globule state of alpha-lactalbumin is determined by the alpha-domain and the beta-domain is not important for stabilizing the molten globule state. The substitution of residues 1 to 34 of bovine alpha-lactalbumin with those of human alpha-lactalbumin substantially increases the stability of the molten globule state, while the substitution of residues 86 to 123 of bovine alpha-lactalbumin with those of human alpha-lactalbumin decreases the stability of the molten globule state. Therefore, residues 1 to 34 in human alpha-lactalbumin is more important for the stability of the human alpha-lactalbumin molten globule state than residues 86 to 123. The stabilization of the molten globule state due to substitution of both residues 1 to 34 and 86 to 123 is not identical with the sum of the two individual substitutions, demonstrating the non-additivity of the stabilization of the molten globule state. This result indicates that there is a long-range interaction between residues 1 to 34 and 86 to 123 in the molten globule state of human alpha-lactalbumin. The differences in the stabilities of the molten globule states are well correlated with the averaged helical propensity values in the alpha-domain when the long-range interactions are negligible, suggesting that the local interaction is the dominant term for determining the stability of the molten globule state. Our results also indicate that the apparent cooperativity is closely linked to the stability of the molten globule state, even if the molten globule state is weakly cooperative.     

Molecular dynamics model structures for the molten globule state of alpha-lactalbumin: aromatic residue clusters I and II

To model the molten globule structure of alpha-lactalbumin, molecular dynamics (MD) simulations were carried out for the protein in explicit water at high temperature. In these simulations, long-range Coulomb interactions were evaluated explicitly with an original method (particle-particle and particle-cell: PPPC) to avoid artifacts caused by the cut-off. The MD simulations were started from two initial conditions to verify that similar results would be obtained. From the last 150 ps trajectories of the two MD simulations, two partially unfolded average structures were obtained. These structures had the following common structural features which are characteristic of the molten globule state. The radii of gyration for these conformations were 7.4 and 9.6% larger than that of the native state. These values were almost the same as the experimental value (9.6%) observed recently by small-angle X-ray scattering (Kataoka,M., Kuwajima,K., Tokunaga,F. and Goto,Y., 1997, Protein Sci., 6, 422-430). Furthermore, aromatic residues of clusters I and II in these structures were far apart from each other except for Try103-Trp104. This result is in good agreement with NMR experimental results for the acid-denatured molten globule state (Alexandrescu et al., 1992, 1993); that is, NOE signals between the aromatic residues were not observed, except for that of Try103-Trp104 in the molten globule state. Other structural features of these models for the molten globule state are discussed with reference to native state structures.     

Elucidating the binding thermodynamics of 8-anilino-1-naphthalene sulfonic acid with the A-state of alpha-lactalbumin: an isothermal titration calorimetric investigation

Isothermal titration calorimetry has been used to demonstrate that the heat profile associated with the binding of 8-anilino-1-naphthalene sulfonic acid (ANS) with the acid induced molten globule state (A-state) of alpha-lactalbumin (alpha-LA) is different from that with the native and denatured states of the protein. The results corroborate the spectroscopic observations that ANS binds more strongly to the partially folded states of the protein compared to that with the native and denatured states. ANS binds to the A-state of alpha-LA at two independent binding sites that remain nearly the same in the temperature range of 10-35 degrees C. The number of moles of ANS binding at site 1 at 10 degrees C is 14.0+/-0.2 and remains nearly the same with rise in temperature. However, the number of moles of ANS molecules binding at site 2 show an increase from 1.6+/-0.2 at 10 degrees C to 4.1+/-0.1 at 35 degrees C. The deviation of the slope of enthalpy-entropy compensation plot from unity and nonadherence to van't Hoff dictates implies that the binding sites on the A-state of alpha-LA for ANS are not well defined and specific; rather, these binding sites are formed due to greater exposure of hydrophobic clusters in the A-state of the protein. The results for the first time demonstrate the use of isothermal titration calorimetry in characterizing the A-state of alpha-LA both qualitatively and quantitatively.     

Stepwise proteolytic removal of the beta subdomain in alpha-lactalbumin. The protein remains folded and can form the molten globule in acid solution.

Bovine alpha-lactalbumin (alpha-LA) is an alpha/beta protein which adopts partly folded states when dissolved at low pH (A-state), by removal of the protein-bound calcium at neutral pH and low salt concentration (apo-state), as well as in aqueous trifluoroethanol. Previous spectroscopic studies have indicated that the A-state of alpha-LA at pH 2.0, considered a prototype molten globule, has a native-like fold in which the helical core is mostly retained, while the beta subdomain is less structured. Here, we investigate the conformational features of three derivatives of alpha-LA characterized by a single peptide bond fission or a deletion of 12 or 19/22 amino-acid residues of the beta subdomain of the native protein (approximately from residue 34 to 57). These alpha-LA derivatives were obtained by limited proteolysis of the protein in its partly folded state(s). A nicked alpha-LA species consisting of fragments 1-,3-40 and 41-123 (nicked-LA) was prepared by thermolytic digestion of the 123-residue chain of alpha-LA in 50% (v/v) aqueous trifluoroethanol. Two truncated or gapped protein species given by fragments 1-40 and 53-123 (desbeta1-LA) or fragments 1-34 and 54-,57-123 (desbeta2-LA) were obtained by digestion of alpha-LA with pepsin in acid or with proteinase K at neutral pH in its apo-state, respectively. The two protein fragments of nicked or gapped alpha-LA are covalently linked by the four disulfide bridges of the native protein. CD measurements revealed that, in aqueous solution at neutral pH and in the presence of calcium, the three protein species maintain the helical secondary structure of intact alpha-LA, while the tertiary structure is strongly affected by the proteolytic cleavages of the chain. Temperature effects of CD signals in the far- and near-UV region reveal a much more labile tertiary structure in the alpha-LA derivatives, while the secondary structure is mostly retained even upon heating. In acid solution at pH 2.0, the three alpha-LA variants adopt a conformational state essentially identical to the molten globule displayed by intact alpha-LA, as demonstrated by CD measurements. Moreover, they bind strongly the fluorescent dye 8-anilinonaphthalene-1-sulfonate, which is considered a diagnostic feature of the molten globule of proteins. Therefore, the beta subdomain can be removed from the alpha-LA molecule without impairing the capability of the rest of the chain to adopt a molten globule state. The results of this protein dissection study provide direct experimental evidence that in the alpha-LA molten globule only the alpha domain is structured.     

Theory of cooperative transitions in protein molecules. II. Phase diagram for a protein molecule in solution

The thermodynamically stable states of denatured protein in solution are investigated. These states are distinguished from the native state by the absence of tight packing of side chains while the compactness of denatured protein may vary within a wide region. The following regimes are outlined: 1. the "wet" molten globule, i.e., the compact state with pores occupied by solvent; 2. the swollen globule ("wet," of course); and 3. the coil. The "dry" molten globule, when solvent does not penetrate inside the protein, is excluded for all experimental conditions. All the transitions within the denatured globule state are gradual while the denatured globule-coil phase transition is a second order one. The conditions of protein denaturation as well as conditions of transitions and crossovers within the denatured state are outlined.     

Pressure-induced unfolding of the molten globule of all-Ala alpha-lactalbumin

Pressure-induced unfolding of a molten globule (MG) was studied in a residue-specific manner with (1)H-(15)N two-dimensional NMR spectroscopy using a variant of human alpha-lactalbumin (alpha-LA), in which all eight cysteines had been replaced with alanines (all-Ala alpha-LA). The NMR spectrum underwent a series of changes from 30 to 2000 bar at 20 degrees C and from -18 degrees C to 36 degrees C at 2000 bar, showing a highly heterogeneous unfolding pattern according to the secondary structural elements of the native structure. Unfolding began in the loop part of the beta-domain, and then extended to the remainder of the beta-domain, after which the alpha-domain began to unfold. Within the alpha-domain, the pressure stability decreased in the order: D-helix approximately 3(10)-helix > C-helix approximately B-helix > A-helix. The D-helix, C-terminal 3(10)-helix and a large part of B- and C-helices did not unfold at 2000 bar, even at 36 degrees C or at -18 degrees C. The results verify that the MG state consists of a mixture of variously unfolded conformers from the mostly folded to the nearly totally unfolded that differ in stability and partial molar volume. Not only heat but also cold denaturation was observed, supporting the view that the MG state is stabilized by hydrophobic interactions.     

Molecular basis of cooperativity in protein folding. V. Thermodynamic and structural conditions for the stabilization of compact denatured states

The heat-denatured state of proteins has been usually assumed to be a fully hydrated random coil. It is now evident that under certain solvent conditions or after chemical or genetic modifications, the protein molecule may exhibit a hydrophobic core and residual secondary structure after thermal denaturation. This state of the protein has been called the “compact denatured” or “molten globule” state. Recently is has been shown that α-lactalbumin at pH < 5 denatures into a molten globule state upon increasing the temperature (Griko, Y., Freire, E., Privalov, P. L. Biochemistry 33:1889–1899, 1994). This state has a lower heat capacity and a higher enthalpy at low temperatures than the unfolded state. At those temperatures the stabilization of the molten globule state is of an entropic origin since the enthalpy contributes unfavorably to the Gibbs free energy. Since the molten globule is more structured than the unfolded state and, therefore, is expected to have a lower configurational entropy, the net entropic gain must originate primarily from solvent related entropy arising from the hydrophobic effect, and to a lesser extent from protonation or electrostatic effects. In this work, we have examined a large ensemble of partly folded states derived from the native structure of α-lactalbumin in order to identify those states that satisfy the energetic criteria of the molten globule. It was found that only few states satisfied the experimental constraints and that, furthermore, those states were part of the same structural family. In particular, the regions corresponding to the A, B, and C helices were found to be folded, while the β sheet and the D helix were found to be unfolded. At temperatures below 45°C the states exhibiting those structural characteristics are enthalpically higher than the unfolded state in agreement with the experimental data. Interestingly, those states have a heat capacity close to that observed for the acid pH compact denatured state of α-lactalbumin [980 cal (mol.K)^?l]. In addition, the folded regions of these states include those residues found to be highly protected by NMR hydrogen exchange experiments. This work represents an initial attempt to model the structural origin of the thermodynamic properties of partly folded states. The results suggest a number of structural features that are consistent with experimental data. © 1994 Wiley-Liss, Inc.