Folding and stability of trp aporepressor from Escherichia coli

Equilibrium and kinetic studies of the urea-induced unfolding of trp aporepressor from Escherichia coli were performed to probe the folding mechanism of this intertwined, dimeric protein. The equilibrium unfolding transitions at pH 7.6 and 25 degrees C monitored by difference absorbance, fluorescence, and circular dichroism spectroscopy are coincident within experimental error. All three transitions are well described by a two-state model involving the native dimer and the unfolded monomer; the free energy of folding in the absence of denaturant and under standard-state conditions is estimated to be 23.3 +/- 0.9 kcal/mol of dimer. The midpoint of the equilibrium unfolding transition increases with increasing protein concentration in the manner expected from the law of mass action for the two-state model. We find no evidence for stable folding intermediates. Kinetic studies reveal that unfolding is governed by a single first-order reaction whose relaxation time decreases exponentially with increasing urea concentration and also decreases with increasing protein concentration in the transition zone. Refolding involves at least three phases that depend on both the protein concentration and the final urea concentration in a complex manner. The relaxation time of the slowest of these refolding phases is identical with that for the single phase in unfolding in the transition zone, consistent with the results expected for a reaction that is kinetically reversible. The two faster refolding phases are presumed to arise from slow isomerization reactions in the unfolded form and reflect parallel folding channels.     

Sulfate stabilizes the folding intermediate more than the native structure of endostatin

Endostatin, a potent angiogenesis inhibitor, is an acid resistant protein with compact tertiary structure. Nuclear magnetic resonance, circular dichroism, and tryptophan emission fluorescence were used to monitor the structural changes of endostatin during acid-, heat-, and urea-induced unfolding processes. Results show that sulfate anions sensitize endostatin to acid, but specifically stabilize it against heat or urea. Moreover, the disappearance of the tertiary structure and the formation of the folding intermediate of endostatin at pH 3.0 are sulfate concentration dependent. These phenomena indicate that sulfate anions stabilize the folding intermediate more than the native structure of endostatin. In addition, heparin shows stronger effect than sodium sulfate on sensitizing endostatin against acid, and very limited stabilizing effect against urea. The loose structure of endostatin upon heparin binding may imply that the physiologically favorable structure for endostatin exerting its biological functions is not as compact as what was reported.     

Evidence for a Shared Mechanism in the Formation of Urea-Induced Kinetic and Equilibrium Intermediates of Horse Apomyoglobin from Ultrarapid Mixing Experiments

In this study, the equivalence of the kinetic mechanisms of the formation of urea-induced kinetic folding intermediates and non-native equilibrium states was investigated in apomyoglobin. Despite having similar structural properties, equilibrium and kinetic intermediates accumulate under different conditions and via different mechanisms, and it remains unknown whether their formation involves shared or distinct kinetic mechanisms. To investigate the potential mechanisms of formation, the refolding and unfolding kinetics of horse apomyoglobin were measured by continuous- and stopped-flow fluorescence over a time range from approximately 100 μs to 10 s, along with equilibrium unfolding transitions, as a function of urea concentration at pH 6.0 and 8°C. The formation of a kinetic intermediate was observed over a wider range of urea concentrations (0–2.2 M) than the formation of the native state (0–1.6 M). Additionally, the kinetic intermediate remained populated as the predominant equilibrium state under conditions where the native and unfolded states were unstable (at ~0.7–2 M urea). A continuous shift from the kinetic to the equilibrium intermediate was observed as urea concentrations increased from 0 M to ~2 M, which indicates that these states share a common kinetic folding mechanism. This finding supports the conclusion that these intermediates are equivalent. Our results in turn suggest that the regions of the protein that resist denaturant perturbations form during the earlier stages of folding, which further supports the structural equivalence of transient and equilibrium intermediates. An additional folding intermediate accumulated within ~140 μs of refolding and an unfolding intermediate accumulated in <1 ms of unfolding. Finally, by using quantitative modeling, we showed that a five-state sequential scheme appropriately describes the folding mechanism of horse apomyoglobin.     

Non-linear effects of temperature and urea on the thermodynamics and kinetics of folding and unfolding of hisactophilin

Extensive measurements and analysis of thermodynamic stability and kinetics of urea-induced unfolding and folding of hisactophilin are reported for 5-50 degrees C, at pH 6.7. Under these conditions hisactophilin has moderate thermodynamic stability, and equilibrium and kinetic data are well fit by a two-state transition between the native and the denatured states. Equilibrium and kinetic m values decrease with increasing temperature, and decrease with increasing denaturant concentration. The betaF values at different temperatures and urea concentrations are quite constant, however, at about 0.7. This suggests that the transition state for hisactophilin unfolding is native-like and changes little with changing solution conditions, consistent with a narrow free energy profile for the transition state. The activation enthalpy and entropy of unfolding are unusually low for hisactophilin, as is also the case for the corresponding equilibrium parameters. Conventional Arrhenius and Eyring plots for both folding and unfolding are markedly non-linear, but these plots become linear for constant DeltaG/T contours. The Gibbs free energy changes for structural changes in hisactophilin have a non-linear denaturant dependence that is comparable to non-linearities observed for many other proteins. These non-linearities can be fit for many proteins using a variation of the Tanford model, incorporating empirical quadratic denaturant dependencies for Gibbs free energies of transfer of amino acid constituents from water to urea, and changes in fractional solvent accessible surface area of protein constituents based on the known protein structures. Noteworthy exceptions that are not well fit include amyloidogenic proteins and large proteins, which may form intermediates. The model is easily implemented and should be widely applicable to analysis of urea-induced structural transitions in proteins.     

Differing structural characteristics of molten globule intermediate of peanut lectin in urea and guanidine-HCl

The structural characteristics of exclusive equilibrium molten globule-like intermediate formed during peanut lectin unfolding in urea and guanidine hydrochloride (GdnHCl) have been investigated by size-exclusion chromatography, circular dichroism, fluorescence, phosphorescence, and chemical modification. The elution behavior and 8-anilino-1-naphthalenesulfonate binding indicate a less compact tertiary structure in urea than in GdnHCl. Further, the urea-induced intermediate reveals perturbed, nonnative typical β-sheet conformation in contrast to native-like atypical β-structure in GdnHCl. N-bromosuccinimide oxidation shows that none of three tryptophan residues is modified for GdnHCl-induced intermediate while one gets oxidized in urea. Such difference in tryptophan environment is supported by acrylamide quenching (Stern-Volmer constant being 3.2 and 5.8 M(-1) respectively), and phosphorescence studies at 77 K which show a blue-shift of (0, 0) band from 412.4 nm (GdnHCl) to 411.4 nm (urea). These results may provide important insight into the differential effects of GdnHCl and urea on the structural characteristics of intermediate state(s) in protein folding.     

Residue-level NMR view of the urea-driven equilibrium folding transition of SUMO-1 (1-97): native preferences do not increase monotonously

SUMO-1 (1-97) is a crucial protein in the machinery of post-translational modifications. We observed by circular dichroism and fluorescence spectroscopy that urea-induced unfolding of this protein is a complex process with the possibility of occurrence of detectable intermediates along the way. The tertiary structure is completely lost around approximately 4.5 M urea with a transition mid-point at 2.53 M urea, while the secondary structure unfolding seems to show two transitions, with mid-points at 2.42 M and 5.69 M urea. We have elucidated by systematic urea titration, the equilibrium residue level structural and dynamics changes along the entire folding/unfolding transition by multidimensional NMR. With urea dilution, the protein is seen to progressively lose most of the broad beta-domain structural preferences present at 8 M urea, acquire some helical propensities at 5 M urea, and lose some of them again on further dilution of urea. Between 3 M and 2 M urea, the protein starts afresh to acquire native structural features. These observations are contrary to the conventional notion that proteins fold with monotonously increasing native-type preferences. For folding below approximately 3 M urea, the region around the alpha1 helix appears to be a potential folding initiation site. The folding seems to start with a collapse into native-like topologies, at least in parts, and is followed by formation of secondary and tertiary structure, perhaps by cooperative rearrangements. The motional characteristics of the protein show sequence-dependent variation as the concentration of urea is progressively reduced. At the sub-nanosecond level, the features are extremely unusual for denatured states, and only certain segments corresponding to the flexible regions in the native protein display these motions at the different concentrations of urea.     

Formation of fibrous aggregates from a non-native intermediate: the isolated P22 tailspike beta-helix domain.

In the assembly pathway of the trimeric P22 tailspike protein, the protein conformation critical for the partitioning between productive folding and off-pathway aggregation is a monomeric folding intermediate. The central domain of tailspike, a large right-handed parallel beta-helix, is essentially structured in this species. We used the isolated beta-helix domain (Bhx), expressed with a hexahistidine tag, to investigate the mechanism of aggregation without the two terminal domains present in the complete protein. Although Bhx has been shown to fold reversibly at low ionic strength conditions, increased ionic strength induced aggregation with a maximum at urea concentrations corresponding to the midpoint of urea-induced folding transitions. According to size exclusion chromatography, aggregation appeared to proceed via a linear polymerization mechanism. Circular dichroism indicated a secondary structure content of the aggregates similar to that of the native state, but at the same time their tryptophan fluorescence was largely quenched. Microscopic analysis of the aggregates revealed a variety of morphologies; among others, fibrils with fine structure were observed that exhibited bright green birefringence if viewed under cross-polarized light after staining with Congo red. These observations, together with the effects of folding mutations on the aggregation process, indicate the involvement of a partially structured intermediate distinct from both unfolded and native Bhx.     

Hydrophobic core variant ubiquitin forms a molten globule conformation at acidic pH

The conformational properties of hydrophobic core variant ubiquitin (Val26 to Ala mutation) in an acidic solution were studied. The intrinsic tryptophan fluorescence emission spectrum, far-UV and near-UV circular dichroic spectra, the fluorescence emission spectrum of 8-anilinonaphthalene-1-sulfonic acid in the presence of V26A ubiquitin, and urea-induced unfolding measurements indicate this variant ubiquitin to be in the partially folded molten globule conformation in solution at pH 2. The folding kinetics from molten globule to the native state was nearly identical to those from the unfolded state to the native state. This observation suggests that the equilibrium molten globule state of hydrophobic core variant ubiquitin is an on-pathway folding intermediate.     

Folding of dihydrofolate reductase from Escherichia coli

The urea-induced equilibrium unfolding transition of dihydrofolate reductase from Escherichia coli was monitored by UV difference, circular dichroism (CD), and fluorescence spectroscopy. Each of these data sets were well described by a two-state unfolding model involving only native and unfolded forms. The free energy of folding in the absence of urea at pH 7.8, 15 degrees C is 6.13 +/- 0.36 kcal mol-1 by difference UV, 5.32 +/- 0.67 kcal mol-1 by CD, and 5.42 +/- 1.04 kcal mol-1 by fluorescence spectroscopy. The midpoints for the difference UV, CD, and fluorescence transitions are 3.12, 3.08, and 3.18 M urea, respectively. The near-coincidence of the unfolding transitions monitored by these three techniques also supports the assignment of a two-state model for the equilibrium results. Kinetic studies of the unfolding and refolding reactions show that the process is complex and therefore that additional species must be present. Unfolding jumps in the absence of potassium chloride revealed two slow phases which account for all of the amplitude predicted by equilibrium experiments. Unfolding in the presence of 400 mM KCl results in the selective loss of the slower phase, implying that there are two native forms present in equilibrium prior to unfolding. Five reactions were observed in refolding: two slow phases designated tau 1 and tau 2 that correspond to the slow phases in unfolding and three faster reactions designated tau 3, tau 4, and tau 5 that were followed by stopped-flow techniques. The kinetics of the recovery of the native form was monitored by following the binding of methotrexate, a tight-binding inhibitor of dihydrofolate reductase, at 380 nm.(ABSTRACT TRUNCATED AT 250 WORDS)     

pH-dependent stability of EGX, a multi-functional cellulase from mollusca, Ampullaria crossean

Cellulose and hemicellulose are the most abundant andmajor constituents of plants and the potential rawmaterials for enzyme hydrolysis related biotechnologicalprocesses. The cellulase and hemicellulase have beenconsidered as two of the most important enzymes inbiotechnology market which can hydrolyze cellulosic ma-terials to fermentable sugars for various biotechnologicalpurposes [1,2], and can also be used in textile- and paper-making industry [3]. It is important to use these enzymesunder re…     

Effects of urea and guanidine · HCl on the folding and unfolding of pancreatic trypsin inhibitor

Concentrated solutions of urea and of guanidine · HCl produced a random spectrum of single-disulphide forms of the polypeptide chain of the pancreatic trypsin inhibitor. Guanidine · HCl also unfolded completely, with accompanying interchange of disulphide bonds, the two-disulphide form of this protein in the native-like conformation; urea produced an equilibrium mixture in which one-quarter of the molecules had the native-like conformation and disulphide bonds. The unfolded forms of the protein in the denaturants were very flexible polypeptide chains. The observations suggest that urea and guanidine · HCl are denaturants because they produce essentially equally favourable solvation of all portions of a polypeptide.The energetics of the conformational transitions involved in folding and unfolding of the inhibitor were determined in urea and compared with those observed in its absence. The denaturant lowers the stability of the native, folded inhibitor relative to that of the reduced, unfolded state by 6.5 kilocalories per mole; the greatest part of this apparent free-energy difference was expressed at the two-disulphide stage of folding. The results are consistent with other indications that most of the favourable interactions stabilizing the native conformation of this protein are not encountered until the final stage of folding, when all may occur simultaneously.The unfolded one- and two-disulphide species produced in guanidine · HCl were trapped, and their rearrangement to the normal intermediates followed after removal of the denaturant. The random single-disulphide species, with one exception, reverted very rapidly to the non-random spectrum of intermediates normally observed during folding; this confirms that these species are normally rapidly interconverted and that normal refolding of the reduced protein is not dependent kinetically upon residual stable conformation in the reduced protein. The unfolded two-disulphide species refolded to the native-like conformation more slowly, but appeared to pass through the same intermediates normally observed during refolding from the fully reduced state.     

Conformational plasticity of cryptolepain: accumulation of partially unfolded states in denaturants induced equilibrium unfolding

pH and chemical denaturant dependent conformational changes of a serine protease cryptolepain from Cryptolepis buchanani are presented in this paper. Activity measurements, near UV, far UV CD, fluorescence emission spectroscopy, and ANS binding studies have been carried out to understand the folding mechanism of the protein in the presence of denaturants. pH and chemical denaturants have a marked effect on the stability, structure, and function of many globular proteins due to their ability to influence the electrostatic interactions. The preliminary biophysical study on cryptolepain shows that major elements of secondary structure are beta-sheets. Under neutral conditions the enzyme was stable in urea while GuHCl-induced equilibrium unfolding was cooperative. Cryptolepain shows little ANS binding even under neutral conditions due to more hydrophobicity of beta-sheets. Multiple intermediates were populated during the pH-induced unfolding of cryptolepain. Temperature-induced denaturation of cryptolepain in the molten globule like state is non-cooperative, contrary to the cooperativity seen with the native protein, suggesting the presence of two parts, possibly domains, in the molecular structure of cryptolepain, with different stability that unfolds in steps. Interestingly, the GuHCl-induced unfolding of A state (molten globule state) of cryptolepain is unique, as lower concentration of denaturant, not only induces structure but also facilitate transition from one molten globule like state (MG(1)) into another (MG(2)). The increase of pH drives the protein into alkaline denatured state characterized by the absence of any ANS binding. GuHCl- and urea-induced unfolding transition curves at pH 12.0 were non-coincidental indicating the presence of an intermediate in the unfolding pathway.     

Effect of a single amino acid substitution on the folding of the alpha subunit of tryptophan synthase

The urea-induced unfolding of a missense mutant of the alpha subunit of tryptophan synthase from Escherichia coli involving the replacement of Gly by Glu at position 211 has been monitored by absorbance changes at 286 nm. Like the wild-type protein, the equilibrium unfolding curve demonstrates the presence of one or more stable intermediates. Comparison of these results with those from the wild-type alpha subunit [Matthews, C. R., & Crisanti, M. M. (1981) Biochemistry 20, 784] shows that the transition from the native conformation to the stable intermediates is displaced to higher urea concentration in the mutant alpha subunit; however, the transition from the intermediates to the unfolded form is unaffected. Kinetic studies show that the amino acid replacement slows the rate of unfolding by an order of magnitude. The effect on refolding rates is complex. One phase, previously assigned to proline isomerization [Crisanti, M. M., & Matthews, C. R. (1981) Biochemistry 20, 2700], is unaffected by the substitution. The rate of the second phase, which is urea dependent down to about 1 M urea, is slower than the corresponding phase in the wild-type protein by approximately a factor of 2. Below about 1 M urea, the rate of this phase becomes urea independent and identical with that of the wild-type alpha subunit. This change in urea dependence has been ascribed to a change in the nature of the rate-limiting step for this process from one involving folding to one involving proline isomerization. The results support the folding model for the alpha subunit proposed previously [Matthews, C. R., & Crisanti, M. M. (1981) Biochemistry 20, 784] and clarify the role of proline isomerization in limiting the rate of folding.     

Acid denaturation of recombinant porcine growth hormone: formation and self-association of folding intermediates

We have investigated the conformational changes incurred during the acid-induced unfolding and self-association of recombinant porcine growth hormone (pGH). Acidification (pH 8 to pH 2) of pGH resulted in intrinsic fluorescence, UV absorbance, and near-UV CD transitions centered at pH 4.10. At pH 2.0, a red shift in the fluorescence emission maximum of approximately 3 nm and a 15% loss of the far-UV CD signal at 222 nm imply that the protein did not become extensively unfolded. Acidification in the presence of 4 M urea resulted in similar pH-dependent transitions. However, these occurred at a higher pH (approximately 5.2). At pH 2.0 + 4 M urea, an 8 nm red shift in the fluorescence emission maximum suggests that unfolding was greater than in the absence of urea. The presence of a prominent peak centered at 298 nm in the near-UV CD spectrum, which is absent without urea, signifies further differences in the intermediates generated at pH 2. Sedimentation equilibrium experiments in the analytical ultracentrifuge showed that native pGH and the partially unfolded intermediates reversibly self-associate. Self-association was strongly promoted at pH 2 while urea reduced self-association at both pH 8 and pH 2. These results demonstrate that acidification of pGH in the absence or presence of 4 M urea induced the formation of molten globule-like states with measurable differences in conformation. Similarities and differences in these structural conformations with respect to other growth hormones are discussed.     

Urea-induced conformational changes in cold- and heat-denatured states of a protein, Streptomyces subtilisin inhibitor.

Streptomyces subtilisin inhibitor (SSI) is known to exist in at least two distinct denatured states, cold-denatured (D') and heat-denatured (D) under acidic conditions. In the present work, we investigated the manner how increasing urea concentration from 0 to 8 M changes the polypeptide chain conformation of SSI that exists initially in the D' and D states as well as in the native state (N), in terms of the secondary structure, the tertiary structure, and the chain form, based on the results of the experiments using circular dichroism (CD), small-angle X-ray scattering (SAXS) and 1H-NMR spectroscopy. Our results indicate that the urea-induced conformational transitions of SSI under typical conditions of D' (pH 1.8, 3 degrees C) occur at least in two steps. In the urea concentration range of 0-2 M (step 1), a cooperative destruction of the tertiary structure occurs, resulting in a mildly denatured state (DU), which may still contain a little amount of secondary structures. In the concentration range of 2-4 M urea (step 2), the DU state gradually loses its residual secondary structure, and increases the radius of gyration nearly to a maximum value. At 4 M urea, the polypeptide chain is highly disordered with highly mobile side chains. Increasing the urea concentration up to 8 M probably results in the more highly denatured or alternatively the stiffer chain conformations. The conformational transition starting from the N state proceeds essentially the same way as in the above scheme in which D' is replaced with N. The conformational transition starting from the D state lacks step 1 because the D state contains no tertiary structures and is similar to the DU state. The fact that similar conformations are reached at urea concentrations above 2 M from different conformations of D', D, and N indicates that the effect of urea dominates in determining the polypeptide conformation of SSI in the denatured states rather than the pH and temperature.     

Multi-state unfolding of the alpha subunit of tryptophan synthase, a TIM barrel protein: insights into the secondary structure of the stable equilibrium intermediates by hydrogen exchange mass spectrometry

The urea-induced unfolding of the alpha subunit of tryptophan synthase (alphaTS) from Escherichia coli, an eight-stranded (beta/alpha)(8) TIM barrel protein, has been shown to involve two stable equilibrium intermediates, I1 and I2, well populated at approximately 3 M and 5 M urea, respectively. The characterization of the I1 intermediate by circular dichroism (CD) spectroscopy has shown that I1 retains a significant fraction of the native ellipticity; the far-UV CD signal for the I2 species closely resembles that of the fully unfolded form. To obtain detailed insight into the disruption of secondary structure in the urea-induced unfolding process, a hydrogen exchange-mass spectrometry study was performed on alphaTS. The full-length protein was destabilized in increasing concentration of urea, the amide hydrogen atoms were pulse-labeled with deuterium, the labeled samples were quenched in acid and the products were analyzed by electrospray ionization mass spectrometry. Consistent with the CD results, the I1 intermediate protects up to approximately 129 amide hydrogen atoms against exchange while the I2 intermediate offers no protection. Electrospray ionization mass spectrometry analysis of the peptic fragments derived from alphaTS labeled at 3 M urea indicates that most of the region between residues 12-130, which constitutes the first four beta strands and three alpha helices, (beta/alpha)(1-3)beta(4), is structured. The (beta/alpha)(1-3)beta(4) module appears to represent the minimum sub-core of stability of the I1 intermediate. A 4+2+2 folding model is proposed as a likely alternative to the earlier 6+2 folding mechanism for alphaTS.     

Rapid folding and unfolding of Apaf-1 CARD

Caspase recruitment domains (CARDs) are members of the death domain superfamily and contain six antiparallel helices in an alpha-helical Greek key topology. We have examined the equilibrium and kinetic folding of the CARD of Apaf-1 (apoptotic protease activating factor 1), which consists of 97 amino acid residues, at pH 6 and pH 8. The results showed that an apparent two state equilibrium mechanism is not adequate to describe the folding of Apaf-1 CARD at either pH, suggesting the presence of intermediates in equilibrium unfolding. Interestingly, the results showed that the secondary structure is less stable than the tertiary structure, based on the transition mid-points for unfolding. Single mixing and sequential mixing stopped-flow studies showed that Apaf-1 CARD folds and unfolds rapidly and suggest a folding mechanism that contains parallel channels with two unfolded conformations folding to the native conformation. Kinetic simulations show that a slow folding phase is described by a third conformation in the unfolded ensemble that interconverts with one or both unfolded species. Overall, the native ensemble is formed rapidly upon refolding. This is in contrast to other CARDs in which folding appears to be dominated by formation of kinetic traps.     

Unfolding-refolding behaviour of chicken egg white ovomucoid and its correlation with the three domain structure of the protein

The urea and heat-induced unfolding-refolding behaviours of chicken egg white ovomucoid and its four fragments representing domains I, II + III, I + II and III were systematically investigated in 0.06 M sodium phosphate buffer (pH 7.0) by difference spectral measurements. The effect of temperature on ovomucoid and its fragments was also studied in 0.05 M sodium acetate buffer (pH 5.0) and in presence of 2 M urea at pH 7.0. Intrinsic viscosity data showed that ovomucoid and its different fragments did not lose any significant amount of their structure under mild acidic conditions (pH 4.6). Difference spectral results showed extensive disruption of the native structure by urea or temperature. Isothermal transitions showed single-step for domain I, domain I + II and domain III, and two-step having one stable intermediate, for ovomucoid and its fragment representing domain II + III. However, the presence of intermediate was not detected when the transitions were studied with temperature at pH 7.0. Strikingly, the single-step thermal transitions of ovomucoid and its fragment representing domain II + III, became two-step when measured either at pH 5.0 or in presence of 2 M urea at pH 7.0. Analysis of the equilibrium data on urea and heat denaturation showed that the second transition observed with ovomucoid or domain II + III represent the unfolding of domain III. The kinetic results of ovomucoid and its fragments indicate that the protein unfolds with three kinetic phases. A comparison of three rate constants for the unfolding of intact ovomucoid with that of its various fragments revealed that domain I, II and III of the protein correspond to the three kinetic phases having rate constants 0.456, 0.120 and 0.054 min-1, respectively. These data have led us to conclude: (i) the unusual stability of ovomucoid towards various denaturants, including temperature, is due to its domain III, (ii) initiation of the folding of the ovomucoid molecule starts from its NH2-terminal region which probably provides the nucleation site for the formation of the subsequent structure and (iii) domains I and II have greater mutual recognition between them as compared to the recognition either of them have with domain III.     

Differences in the unfolding of procerain induced by pH, guanidine hydrochloride, urea, and temperature

The structural and functional aspects along with equilibrium unfolding of procerain, a cysteine protease from Calotropis procera, were studied in solution. The energetic parameters and conformational stability of procerain in different states were also estimated and interpreted. Procerain belongs to the alpha + beta class of proteins. At pH 2.0, procerain exists in a partially unfolded state with characteristics of a molten globule-like state, and the protein is predominantly a beta-sheet conformation and exhibits strong ANS binding. GuHCl and temperature denaturation of procerain in the molten globule-like state is noncooperative, contrary to the cooperativity seen with the native protein, suggesting the presence of two parts in the molecular structure of procerain, possibly domains, with different stability that unfolds in steps. Moreover, tryptophan quenching studies suggested the exposure of aromatic residues to solvent in this state. At lower pH, procerain unfolds to the acid-unfolded state, and a further decrease in the pH drives the protein to the A state. The presence of 0.5 M salt in the solvent composition directs the transition to the A state while bypassing the acid-unfolded state. GuHCl-induced unfolding of procerain at pH 3.0 seen by various methods is cooperative, but the transitions are noncoincidental. Besides, a strong ANS binding to the protein is observed at low concentrations of GuHCl, indicating the presence of an intermediate in the unfolding pathway. On the other hand, even in the presence of urea (8 M), procerain retains all the activity as well as structural parameters at neutral pH. However, the protein is susceptible to unfolding by urea at lower pH, and the transitions are cooperative and coincidental. Further, the properties of the molten globule-like state and the intermediate state are different, but both states have the same conformational stability. This indicates that these intermediates may be located on parallel folding routes of procerain.     

Kinetic analysis of the acid and the alkaline unfolded states of staphylococcal nuclease

Thermodynamic analysis by differential scanning calorimetry shows that the folding/unfolding transition of staphylococcal nuclease is consistent with the two-state process. Stopped-flow kinetic measurements, monitoring the Trp140 fluorescence and covering five decades in time (2 ms to 300 s), indicate that the unfolding from pH 7.0 to 3.1 is monophasic (time constant 1.15 s) and from pH 7.0 to 12.2 is biphasic (time constants: one less than 2 ms and the other 0.6 s). However, the folding, either from pH 3.1 to 7.0 or from pH 12.2 to 7.0, is triphasic (time constants 150 ms, 850 ms and 30 s from acid, 90 ms, 565 ms and 33 s from alkaline). A simple sequential model, which agrees with the above observations for acidic folding/unfolding is, D3 in equilibrium D2 in equilibrium D1 in equilibrium N. The three Ds denote three sub-states of the unfolded state and N denotes the native state. These sub-states of D have similar enthalpy and tryptophan fluorescence, and their equilibrium cannot be shifted by temperature changes. However, they are kinetically distinctive. Data do not favor alternative mechanisms assuming parallel transitions of the three Ds to N, or complexity of the N state, or parallel transitions of sub-states of N1, N2 and N3 to D. Other more complex, branched or cyclic, kinetics are not considered because of the lack of evidence, pH dependence of the unfolding kinetics suggests that the unfolding is triggered by protonation of 0.8(+/- 0.3) ionizable groups, with a pKa of 3.9 or by deprotonation of 1.6(+/- 0.4) ionizable groups with pKa values near 10.5. Circular dichroisms indicate that these three D states retain nonrandom chain conformation. Possible role of these "chain conformation" in the protein folding is discussed.