Equilibrium and kinetic studies on folding of canine milk lysozyme

Thermal and chemical unfolding studies of the calcium-binding canine lysozyme (CL) by fluorescence and circular dichroism spectroscopy show that, upon unfolding in the absence of calcium ions, a very stable equilibrium intermediate state is formed. At room temperature and pH 7.5, for example, a stable molten globule state is attained in 3 M GdnHCl. The existence of such a pure and stable intermediate state allowed us to extend classical stopped-flow fluorescence measurements that describe the transition from the native to the unfolded form, with kinetic experiments that monitor separately the transition from the unfolded to the intermediate state and from the intermediate to the native state, respectively. The overall refolding kinetics of apo-canine lysozyme are characterized by a significant drop in the fluorescence intensity during the dead time, followed by a monoexponential increase of the fluorescence with k = 3.6 s(-1). Furthermore, the results show that, unlike its drastic effect on the stability, Ca(2+)-binding only marginally affects the refolding kinetics. During the refolding process of apo-CL non-native interactions, comparable to those observed in hen egg white lysozyme, are revealed by a substantial quenching of tryptophan fluorescence. The dissection of the refolding process in two distinct steps shows that these non-native interactions only occur in the final stage of the refolding process in which the two domains match to form the native conformation.     

Characterization of kinetic folding intermediates of recombinant canine milk lysozyme by stopped-flow circular dichroism

The intermediate in the equilibrium unfolding of canine milk lysozyme induced by a denaturant is known to be very stable with characteristics of the molten globule state. Furthermore, there are at least two kinetic intermediates during refolding of this protein: a burst-phase (first) intermediate formed within the dead time of stopped-flow measurements and a second intermediate that accumulates with a rate constant of 22 s(-)(1). To clarify the relationships of these intermediates with the equilibrium intermediate, and also to characterize the structural changes of the protein during refolding, here we studied the kinetic refolding reactions using stopped-flow circular dichroism at 10 different wavelengths and obtained the circular dichroism spectra of the intermediates. Comparison of the circular dichroism spectra of the intermediates, as well as the absence of observed kinetics in the refolding from the fully unfolded state to the equilibrium intermediate, has demonstrated that the burst-phase intermediate is equivalent to the equilibrium intermediate. The difference circular dichroism spectrum that represented changes from the kinetic intermediate to the native state had characteristics of an exciton coupling band, indicating that specific packing of tryptophan residues in this protein occurred in this phase. From these findings, we propose a schematic model of the refolding of canine milk lysozyme that is consistent with the hierarchical mechanism of protein folding.     

The folding pathway of T4 lysozyme: an on-pathway hidden folding intermediate

T4 lysozyme has two easily distinguishable but energetically coupled domains: the N and C-terminal domains. In earlier studies, an amide hydrogen/deuterium exchange pulse-labeling experiment detected a stable submillisecond intermediate that accumulates before the rate-limiting transition state. It involves the formation of structures in both the N and C-terminal regions. However, a native-state hydrogen exchange experiment subsequently detected an equilibrium intermediate that only involves the formation of the C-terminal domain. Here, using stopped-flow circular dichroism and fluorescence, amide hydrogen exchange-folding competition, and protein engineering methods, we re-examined the folding pathway of T4-lysozyme. We found no evidence for the existence of a stable folding intermediate before the rate-limiting transition state at neutral pH. In addition, using native-state hydrogen exchange-directed protein engineering, we created a mimic of the equilibrium intermediate. We found that the intermediate mimic folds with the same rate as the wild-type protein, suggesting that the equilibrium intermediate is an on-pathway intermediate that exists after the rate-limiting transition state.     

Thermal transition of core particle is not a two-state process

Thermal transition of core particle which occurs before melting of DNA and can be followed by circular dichroism is not a two-state process; it is the result of two processes which cannot be dissociated in static experiments: unfolding of core particles is immediately followed by their aggregation. It is thus impossible to get thermodynamic parameters of core particle unfolding from its thermal transition monitored by circular dichroism. Thermal denaturation kinetics of core particles gives some information about their stability. Finally core particle structure is more stable in chromatin than in its isolated state.     

Energetics of MazG Unfolding in Correlation with Its Structural Features

MazG is a homodimeric α-helical protein that belongs to the superfamily of all-α NTP pyrophosphatases. Its function has been connected to the regulation of the toxin-antitoxin module mazEF, implicated in programmed growth arrest/cell death of Escherichia coli cells under conditions of amino acid starvation. The goal of the first detailed biophysical study of a member of the all-α NTP pyrophosphatase superfamily, presented here, is to improve molecular understanding of the unfolding of this type of proteins. Thermal unfolding of MazG monitored by differential scanning calorimetry, circular dichroism spectroscopy, and fluorimetry at neutral pH in the presence of a reducing agent (dithiothreitol) can be successfully described as a reversible four-state transition between a dimeric native state, two dimeric intermediate states, and a monomeric denatured state. The first intermediate state appears to have a structure similar to that of the native state while the final thermally denatured monomeric state is not fully unfolded and contains a significant fraction of residual α-helical structure. In the absence of dithiothreitol, disulfide cross-linking causes misfolding of MazG that appears to be responsible for the formation of multimeric aggregates. MazG is most stable at pH 7-8, while at pH < 6, it exists in a molten-globule-like state. The thermodynamic parameters characterizing each step of MazG denaturation transition obtained by global fitting of the four-state model to differential scanning calorimetry, circular dichroism, and fluorimetry temperature profiles are in agreement with the observed structural characteristics of the MazG conformational states and their assumed functional role.     

The Conformational State of Apomyoglobin in the Presence of Phospholipid Vesicles at Neutral pH

The conformational state of sperm whale apomyoglobin (apoMb) was studied at neutral pH in the presence of negatively charged vesicles using near and far UV circular dichroism, tryptophan fluorescence, differential scanning microcalorimetry, and fast performance liquid chromatography. Under these conditions, the apoMb structure undergoes transition from its native to an intermediate state. In this state the protein loses its rigid native structure but retains its secondary structure. However, the environment of tryptophan residues remains rather hydrophobic. This intermediate state of apoMb shows properties similar to those of its molten globule state in solution. It is shown that apoMb can bind to negatively charged phospholipid vesicles even at neutral pH. A possible functional role of this intermediate state is discussed.     

Conformational status of apomyoglobin in the presence of phospholipid vesicles at neutral pH

The conformational state of sperm whale apomyoglobin (apoMb) was studied at neutral pH in the presence of negatively charged vesicles using near- and far-UV circular dichroism, tryptophan fluorescence, differential scanning microcalorimetry, and fast performance liquid chromatography. Under these conditions, the apoMb structure undergoes transition from its native to an intermediate state. In this state the protein loses its rigid native structure but retains its secondary structure. However, the environment of tryptophan residues remains rather hydrophobic. This intermediate state of apoMb shows properties similar to those of its molten globule state in solution. It is shown that apoMb can bind to negatively charged phospholipid vesicles even at neutral pH. A possible functional role of this intermediate state is discussed.     

Ca2+-induced alteration in the unfolding behavior of alpha-lactalbumin

Comparative studies of the unfolding equilibria of two homologous proteins, bovine alpha-lactalbumin and hen lysozyme, induced by treatment with guanidine hydrochloride have been made by analysis of the peptide and the aromatic circular dichroism spectra. The effect of the specific binding of Ca2+ ion by the former protein was taken into account in interpreting the unfolding equilibria of the protein. Proton nuclear magnetic resonance spectra of alpha-lactalbumin were also measured for the purpose of characterizing an intermediate structural state of the protein. In previous studies, alpha-lactalbumin was shown to be an exceptional protein whose equilibrium unfolding does not obey the two-state model of unfolding, although lysozyme is known to follow the two-state unfolding mechanism. The present results show that the apparent unfolding behavior of alpha-lactalbumin depends on Ca2+ concentration. At a low concentration of Ca2+, alpha-lactalbumin unfolds with a stable intermediate that has unfolded tertiary structure, as evidenced by the featureless nuclear magnetic resonance and aromatic circular dichroism spectra, but has folded secondary structure as evidenced by the peptide circular dichroism spectra. However, in the presence of a sufficiently high concentration of Ca2+, the unfolding transition of alpha-lactalbumin resembles that of lysozyme. The transition occurs between the two states, the native and the fully unfolded states, and the cooperativity of the unfolding is essentially the same as that of lysozyme. Such a change in the apparent unfolding behavior evidently results from an increase in the stability of the native state relative to that of the intermediate induced by the specific Ca2+ binding to native alpha-lactalbumin. The results are useful for understanding the relationship between the protein stability and the apparent unfolding behavior.     

Apolipoprotein A-I(Milano) unfolds via an intermediate state as studied by differential scanning calorimetry and circular dichroism.

In this study the thermal and denaturant induced denaturation behaviors of apolipoprotein A-I(Milano) (apo A-IM) have been studied by differential scanning calorimetry and circular dichroism spectroscopy, as well as solution properties by analytical ultracentrifugation. Thermal denaturation is dependent on pH, sodium phosphate concentration and NaCl concentration. The protein is highly self-associated at the protein concentrations used in this study. Denaturation of apo A-IM at pH 7.4 and 8.0 occurs in two steps. The midpoint between the transition is at 37 degrees C. The first step at 31 degrees C involves melting of tertiary structure and rearrangement of protein association complexes, i.e. a transition into an intermediate molten globular-like state. Subsequent melting of this intermediate state into an unfolded state occurs at 52 degrees C. At pH 2.8 the protein lacks all tertiary structure and denaturation occurs over a large temperature interval, indicating the induction of a molten globular-like state at low pH.     

Investigation of the folding pathway of the TEM-1 β-lactamase

The TEM-1 β-lactamase is a globular protein containing 12 proline residues. The folding mechanism of this enzyme was investigated by kinetic and equilibrium experiments with the help of fluorescence spectroscopy and circular dichroism. The equilibrium denaturation of the protein induced by guanidine hydrochloride occurs in two discrete steps, indicating the existence of a thermodynamically stable intermediate state. Thisstate is 5.2 ± 0.4 kcal/mol less stable than the native conformation and 5.7 ± 0.2 kcal/mol more stable than the fully denaturedprotein. This intermediate state exhibits a high content of native secondary structure elements but is devoid of specific tertiary organization; its relation to the “molten globule” is discussed. Refolding kinetic experimentsrevealed the existence of a transient intermediate conformation between thethermodynamically stable intermediate and the native protein. This transient intermediate appears rapidly during the folding reaction. It exhibits a secondary structure content very similar to that of the native protein and has also recovered a significant amount of tertiary organisation. The final refolding step of the TEM-1 β-lactamase, leading to the native enzyme, is dominated by two major slow kinetic phases which probablyreflect a very complex process kinetically limited by proline cis/transisomerization. © 1995 Wiley-Liss, Inc.     

Detection of an intermediate during unfolding of bacterial cell division protein FtsZ: loss of functional properties precedes the global unfolding of FtsZ

Using environment-sensitive fluorescence of 1-anilinonaphthalene-8-sulfonic acid, polarization of fluorescein 5'-isothiocyanate-labeled FtsZ, and far-UV circular dichroism spectroscopy, the chemical unfolding of FtsZ was found to proceed through two steps. The first step of the urea-induced unfolding produced an intermediate, which then unfolded at higher concentrations of urea. The intermediate state contains native-like secondary structure and much less tertiary structure compared with the native state. It is distinct from the native state as well as from the unfolded state. Similar to urea-induced unfolding of FtsZ, thermal unfolding of FtsZ also occurs in two steps. The midpoints for the first and second thermal unfolding transitions were found to be 38 +/- 4 and 77 +/- 5 degrees C, respectively. Further, the functional properties of FtsZ are extremely sensitive to urea, guanidium chloride, and sodium dodecyl sulfate. For example, 50% inhibition of the FtsZ assembly and GTP hydrolysis occurred at 0.1 and 0.2 m of urea, respectively. FtsZ lost its functional properties before any significant perturbation in the secondary or tertiary structure was detected by using several fluorescence techniques and far UV-CD indicating preferential local unfolding of the functional region(s). In addition, the unfolded FtsZ regains its ability to polymerize fully upon removal of urea. The data taken together suggest that FtsZ unfolds reversibly through a multistep process, and local responses that inhibit functional properties precede the global transition of FtsZ to the unfolded state.     

Identification of equilibrium and kinetic intermediates involved in folding of urea-denatured creatine kinase

The unfolding transition and kinetic refolding of dimeric creatine kinase after urea denaturation were monitored by intrinsic fluorescence and far ultraviolet circular dichroism. An equilibrium intermediate and a kinetic folding intermediate were identified and characterized. The fluorescence intensity of the equilibrium intermediate is close to that of the unfolded state, whereas its ellipticity at 222 nm is about 50% of the native state. The transition curves measured by these two methods are therefore non-coincident. The kinetic folding intermediate, formed during the burst phase of refolding under native-like conditions, possesses 75% of the native secondary structure, but is mostly lacking in native tertiary structure. In moderate concentrations of urea, only the initial, rapid change in fluorescence intensity or negative ellipticity is observed, and the final state values do not reach the equivalent unfolding values. The unfolding and refolding transition curves measured under identical conditions are non-coincident within the transition from intermediate to fully unfolded state. It is observed by SDS-PAGE that disulfide bond-linked dimeric or oligomeric intermediates are formed in moderate urea concentrations, especially in the refolding reaction. These rapidly formed, soluble intermediates represent an off-pathway event that leads to the hysteresis in the refolding transition curves.     

Unfolding of the trp repressor from Escherichia coli monitored by fluorescence, circular dichroism and nuclear magnetic resonance

The denaturation of the trp repressor from Escherichia coli has been studied by fluorescence, circular dichroism and proton magnetic resonance spectroscopy. The dependences of the fluorescence emission of the two tryptophan residues on the concentration of urea are not identical. The dependence of the quenching of tryptophan fluorescence by iodide as a function of urea concentration also rules out a two-state transition. The circular dichroism at 222 nm decreases in two phases as urea is added. Normalised curves for different residues observed by 1H NMR also do not coincide, and require the presence of at least one stable intermediate. Analysis of the dependence of the denaturation curves on the concentration of protein indicate that the first transition is a partial unfolding of the dimeric repressor, resulting in a loss of about 25% of the helical content. The second transition is the dissociation and unfolding of the partially unfolded dimer. At high concentrations of protein (500 microM) about 73% of the repressor exists as the intermediate in 4 M urea. The apparent dissociation constant is about 10(-4) M; the subunits are probably strongly stabilised by the subunit interaction. The native repressor is stable up to at least 70 degrees C, whereas the intermediate formed at 4 M urea can be denatured reversibly by heating (melting temperature approximately 60 degrees C, delta H approximately 230 kJ/mol).     

On the stability of the extracellular hemoglobin of Glossoscolex paulistus, in two iron oxidation states, in the presence of urea

The stability of the Glossoscolex paulistus hemoglobin (HbGp), in two iron oxidation states (and three forms), as monitored by optical absorption, fluorescence emission and circular dichroism (CD) spectroscopies, in the presence of the chaotropic agent urea, is studied. HbGp oligomeric dissociation, denaturation and iron oxidation are observed. CD data show that the cyanomet-HbGp is more stable than the oxy-form. Oxy- and cyanomet-HbGp show good fits on the basis of a two state model with critical urea concentrations at 220-222 nm of 5.1±0.2 and 6.1±0.1 mol/L, respectively. The three-state model was able to reveal a subtle second transition at lower urea concentration (1.0-2.0 mol/L) associated to partial oligomeric dissociation. The intermediate state for oxy- and cyanomet-HbGp is very similar to the native state. For met-HbGp, a different equilibrium, in the presence of urea, is observed. A sharp transition at 1.95±0.05 mol/L of denaturant is observed, associated to oligomeric dissociation and hemichrome formation. In this case, analysis by a three-state model reveals the great similarity between the intermediate and the unfolded states. Analysis of spectroscopic data, by two-state and three-state models, reveals consistency of obtained thermodynamic parameters for HbGp urea denaturation.     

Guanidinium chloride and urea denaturations of beta-lactoglobulin A at pH 2.0 and 25 degrees C: the equilibrium intermediate contains non-native structures (helix, tryptophan and hydrophobic patches)

We have carried out guanidinium chloride (GdmCl) and urea denaturations of bovine beta-lactoglobulin A (beta-lgA) at pH 2.0 and 25 degrees C, using far-UV and near-UV circular dichroism, near-UV absorption and tryptophan fluorescence spectroscopies. The stable intermediate state that occurs during GdmCl denaturation has been characterized by the far- and near-UV circular dichroism, tryptophan difference absorption, tryptophan fluorescence and 8-anilino-1-naphthalene sulphonic acid binding measurements. Following conclusions have been reached. (a) Urea-induced denaturation is not a two-state process. (b) GdmCl-induced denaturation is composed of two distinct two-state processes. (c) alpha-Helical content, burial of tryptophan residues and burial of hydrophobic surface area are more in the GdmCl-induced stable intermediate than those originally present in the native protein.     

The equilibrium unfolding of Azotobacter vinelandii apoflavodoxin II occurs via a relatively stable folding intermediate.

A flavodoxin from Azotobacter vinelandii is chosen as a model system to study the folding of alpha/beta doubly wound proteins. The guanidinium hydrochloride induced unfolding of apoflavodoxin is demonstrated to be reversible. Apoflavodoxin thus can fold in the absence of the FMN cofactor. The unfolding curves obtained for wild-type, C69A and C69S apoflavodoxin as monitored by circular dichroism and fluorescence spectroscopy do not coincide. Apoflavodoxin unfolding occurs therefore not via a simple two-state mechanism. The experimental data can be described by a three-state mechanism of apoflavodoxin equilibrium unfolding in which a relatively stable intermediate is involved. The intermediate species lacks the characteristic tertiary structure of native apoflavodoxin as deduced from fluorescence spectroscopy, but has significant secondary structure as inferred from circular dichroism spectroscopy. Both spectroscopic techniques show that thermally-induced unfolding of apoflavodoxin also proceeds through formation of a similar molten globule-like species. Thermal unfolding of apoflavodoxin is accompanied by anomalous circular dichroism characteristics: the negative ellipticity at 222 nM increases in the transition zone of unfolding. This effect is most likely attributable to changes in tertiary interactions of aromatic side chains upon protein unfolding. From the presented results and hydrogen/deuterium exchange data, a model for the equilibrium unfolding of apoflavodoxin is presented.     

Conformational studies on the gramicidin A transmembrane channel in lipid micelles and liposomes

The interaction of gramicidin A with lysolecithin micelles and with lecithin liposomes is demonstrated by circular dichroism to result in several metastable conformational states. A stable state can be obtained after extensive heating when the gramicidin A was added dry or in ethanol solution to the phospholipid dispersion but the stable state is readily obtained when gramicidin A is added in a trifluoroethanol solution. The circular dichroism of the stable conformational state is characterized by negative ellipticity below 205 nm and principally by a positive 220 nm band on which is superposed a weak 230 nm band (the latter likely arising from tryptophan side chains). The stable conformational state is considered to be that of the functional transmembrane channel primarily on the basis of extensive studies on its interaction with sodium ions.     

Spectroscopic characterization of heat-induced nonnative beta-lactoglobulin monomers

Previous studies have shown that two altered monomeric species were formed in the early steps of thermal denaturation of bovine beta-lactoglobulin (beta-lg), the well-known Cys121-exposed intermediate (Mcys121), and a new, stable monomer with exposed nonnative Cys119 (Mcys119). In this study, circular dichroism and fluorescence spectroscopies were used to characterize the structural features of these molecules. The structural characteristics of MCys121 after heating and cooling cycles are similar to those of native beta-lg. In contrast, Mcys119 monomer exhibits some characteristics of the well-known molten-globule state. Combined with other published data, these results indicate that heating induces at least two molten globule-like states of beta-lg, a highly reactive Mcys121 that returns to native state after cooling, and a less-reactive Mcys119 that is trapped and stabilized in a molten globule-like state by nonnative disulfide bond.     

Is folding of beta-lactoglobulin non-hierarchic? Intermediate with native-like beta-sheet and non-native alpha-helix

The refolding of beta-lactoglobulin, a beta-barrel protein consisting of beta strands betaA-betaI and one major helix, is unusual because non-native alpha-helices are formed at the beginning of the process. We studied the refolding kinetics of bovine beta-lactoglobulin A at pH 3 using the stopped-flow circular dichroism and manual H/(2)H exchange pulse labeling coupled with heteronuclear NMR. The protection pattern from the H/(2)H exchange of the native state indicated the presence of a stable hydrophobic core consisting of betaF, betaG and betaH strands. The protection pattern of the kinetic intermediate obtained about one second after initiating the reaction was compared with that of the native state. In this relatively late kinetic intermediate, which still contains some non-native helical structure, the disulfide-bonded beta-hairpin made up of betaG and betaH strands was formed, but the rest of the molecule was fluctuating, where the non-native alpha-helices may reside. Subsequently, the core beta-sheet extends, accompanied by a further alpha-helix to beta-sheet transition. Thus, the refolding of beta-lactoglobulin exhibits two elements: the critical role of the core beta-sheet is consistent with the hierarchic mechanism, whereas the alpha-helix to beta-sheet transition suggests the non-hierarchic mechanism.