Conformational stability of secretory leucocyte protease inhibitor: a protein with no hydrophobic core and very little secondary structure

Conformational stability of proteins (including disulfide containing proteins) has been routinely characterized by spectroscopic techniques. Proteins which lack adequate signal of circular dichroism may require unconventional technique. Secretory Leucocyte Protease Inhibitor (SLPI) is a 107 amino acids protein with a high density of disulfide pairing (eight). The native SLPI has no hydrophobic core and contains very little hydrogen bonded secondary structure [Gruetter, M., Fendrich, G., Huber, R., and Bode, W. (1988) The 2.5 A X-ray crystal structure of the acid stable proteinase inhibitor from human mucous secretions analyzed in its complex with bovine alpha-chymotrypsin. The EMBO J. 7, 345-352.]. In this study, conformational stability of SLPI has been investigated by the method of disulfide scrambling, which permits quantification of the native and denatured (scrambled) proteins by HPLC. Due to high heterogeneity of denatured SLPI, the native and scrambled SLPI are extensively overlapped on HPLC. This impediment was further overcome by the development of a novel method which distinguishes the native and scrambled isomers of SLPI by exploiting the relative stability of their disulfide bonds. The study reveals mid-point denaturation of SLPI at 1.36 M of GdmSCN, 4.0 M of GdmCl and >8 M urea. Based on the GdmCl denaturation curve, the unfolding free energy (DeltaG(H20)) of SLPI was estimated to be 4.56 kcal/mol. The results of our studies suggest an alternative strategy for analyzing conformational stability of disulfide proteins that are not suitable to the conventional spectroscopic techniques.     

Disulfide bond effects on protein stability: designed variants of Cucurbita maxima trypsin inhibitor-V

Attempts to increase protein stability by insertion of novel disulfide bonds have not always been successful. According to the two current models, cross-links enhance stability mainly through denatured state effects. We have investigated the effects of removal and addition of disulfide cross-links, protein flexibility in the vicinity of a cross-link, and disulfide loop size on the stability of Cucurbita maxima trypsin inhibitor-V (CMTI-V; 7 kD) by differential scanning calorimetry. CMTI-V offers the advantage of a large, flexible, and solvent-exposed loop not involved in extensive intra-molecular interactions. We have uncovered a negative correlation between retention time in hydrophobic column chromatography, a measure of protein hydrophobicity, and melting temperature (T(m)), an indicator of native state stabilization, for CMTI-V and its variants. In conjunction with the complete set of thermodynamic parameters of denaturation, this has led to the following deductions: (1) In the less stable, disulfide-removed C3S/C48S (Delta Delta G(d)(50 degrees C) = -4 kcal/mole; Delta T(m) = -22 degrees C), the native state is destabilized more than the denatured state; this also applies to the less-stable CMTI-V* (Delta Delta G(d)(50 degrees C) = -3 kcal/mole; Delta T(m) = -11 degrees C), in which the disulfide-containing loop is opened by specific hydrolysis of the Lys(44)-Asp(45) peptide bond; (2) In the less stable, disulfide-inserted E38C/W54C (Delta Delta G(d)(50 degrees C) = -1 kcal/mole; Delta T(m) = +2 degrees C), the denatured state is more stabilized than the native state; and (3) In the more stable, disulfide-engineered V42C/R52C (Delta Delta G(d)(50 degrees C) = +1 kcal/mole; Delta T(m) = +17 degrees C), the native state is more stabilized than the denatured state. These results show that a cross-link stabilizes both native and denatured states, and differential stabilization of the two states causes either loss or gain in protein stability. Removal of hydrogen bonds in the same flexible region of CMTI-V resulted in less destabilization despite larger changes in the enthalpy and entropy of denaturation. The effect of a cross-link on the denatured state of CMTI-V was estimated directly by means of a four-state thermodynamic cycle consisting of native and denatured states of CMTI-V and CMTI-V*. Overall, the results show that an enthalpy-entropy compensation accompanies disulfide bond effects and protein stabilization is profoundly modulated by altered hydrophobicity of both native and denatured states, altered flexibility near the cross-link, and residual structure in the denatured state.     

The disulfide structure of denatured epidermal growth factor: preparation of scrambled disulfide isomers

The conformational stability of human epidermal growth factor (EGF) and the structure of denatured EGF were investigated using the technique of disulfide scrambling. Under denaturing conditions and in the presence of a thiol catalyst, the native EGF denatures by shuffling its three native disulfide bonds and converts to a mixture of scrambled isomers. Analysis by HPLC reveals that the denatured EGF is composed of about 10 fractions of scrambled isomers. The heterogeneity varies under different denaturing conditions, with the heat-denatured samples exhibiting the highest degree of heterogeneity. The disulfide structures of eight major scrambled isomers of EGF were determined. The most predominant isomer adopts the bead-form structure with disulfide bonds bridged by three pairs of neighboring cysteines: Cys⁶-Cys¹⁴, Cys²⁰-Cys³¹, and Cys³³-Cys⁴². The denaturation curve of EGF is determined by the relative yield of the scrambled and native species of EGF. EGF is a highly stable molecule and can be effectively denatured only by guanidine chloride at a concentration of greater than 4–5 M. At 8 M urea, less than 16% of the native EGF was denatured. The unusual conformational stability of EGF was compared with that of eight different disulfide proteins that were similarly characterized by the method of disulfide scrambling.     

Denaturation and unfolding of human anaphylatoxin C3a: an unusually low covalent stability of its native disulfide bonds

The complement C3a anaphylatoxin is a major molecular mediator of innate immunity. It is a potent activator of mast cells, basophils and eosinophils and causes smooth muscle contraction. Structurally, C3a is a relatively small protein (77 amino acids) comprising a N-terminal domain connected by 3 native disulfide bonds and a helical C-terminal segment. The structural stability of C3a has been investigated here using three different methods: Disulfide scrambling; Differential CD spectroscopy; and Reductive unfolding. Two uncommon features regarding the stability of C3a and the structure of denatured C3a have been observed in this study. (a) There is an unusual disconnection between the conformational stability of C3a and the covalent stability of its three native disulfide bonds that is not seen with other disulfide proteins. As measured by both methods of disulfide scrambling and differential CD spectroscopy, the native C3a exhibits a global conformational stability that is comparable to numerous proteins with similar size and disulfide content, all with mid-point denaturation of [GdmCl]_1/2 at 3.4-5 M. These proteins include hirudin, tick anticoagulant protein and leech carboxypeptidase inhibitor. However, the native disulfide bonds of C3a is 150-1000 fold less stable than those proteins as evaluated by the method of reductive unfolding. The 3 native disulfide bonds of C3a can be collectively and quantitatively reduced with as low as 1 mM of dithiothreitol within 5 min. The fragility of the native disulfide bonds of C3a has not yet been observed with other native disulfide proteins. (b) Using the method of disulfide scrambling, denatured C3a was shown to consist of diverse isomers adopting varied extent of unfolding. Among them, the most extensively unfolded isomer of denatured C3a is found to assume beads-form disulfide pattern, comprising Cys³⁶-Cys⁴⁹ and two disulfide bonds formed by two pair of consecutive cysteines, Cys²²-Cys²³ and Cys⁵⁶-Cys⁵⁷, a unique disulfide structure of polypeptide that has not been documented previously.     

Role of disulfide bonds in conformational stability and folding of 5'-deoxy-5'-methylthioadenosine phosphorylase II from the hyperthermophilic archaeon Sulfolobus solfataricus

Sulfolobus solfataricus 5'-deoxy-5'-melthylthioadenosine phosphorylase II (SsMTAPII), is a hyperthermophilic hexameric protein with two intrasubunit disulfide bonds (C138-C205 and C200-C262) and a CXC motif (C259-C261). To get information on the role played by these covalent links in stability and folding, the conformational stability of SsMTAPII and C262S and C259S/C261S mutants was studied by thermal and guanidinium chloride (GdmCl)-induced unfolding and analyzed by fluorescence spectroscopy, circular dichroism, and SDS-PAGE. No thermal unfolding transition of SsMTAPII can be obtained under nonreducing conditions, while in the presence of the reducing agent Tris-(2-carboxyethyl) phosphine (TCEP), a Tm of 100°C can be measured demonstrating the involvement of disulfide bridges in enzyme thermostability. Different from the wild-type, C262S and C259S/C261S show complete thermal denaturation curves with sigmoidal transitions centered at 102°C and 99°C respectively. Under reducing conditions these values decrease by 4°C and 8°C respectively, highlighting the important role exerted by the CXC disulfide on enzyme thermostability. The contribution of disulfide bonds to the conformational stability of SsMTAPII was further assessed by GdmCl-induced unfolding experiments carried out under reducing and nonreducing conditions. Thermal unfolding was found to be reversible if the protein was heated in the presence of TCEP up to 90°C but irreversible above this temperature because of aggregation. In analogy, only chemical unfolding carried out in the presence of reducing agents resulted in a reversible process suggesting that disulfide bonds play a role in enzyme denaturation. Thermal and chemical unfolding of SsMTAPII occur with dissociation of the native hexameric state into denatured monomers, as indicated by SDS-PAGE.     

Effects of guanidine hydrochloride on the conformation and enzyme activity of streptomycin adenylyltransferase monitored by circular dichroism and fluorescence spectroscopy

Equilibrium denaturation of streptomycin adenylyltransferase (SMATase) has been studied by CD spectroscopy, fluorescence emission spectroscopy, and binding of the hydrophobic dye 1-anilino-8-naphthalene sulfonic acid (ANS). Far-UV CD spectra show retention of 90% native-like secondary structure at 0.5 M guanidine hydrochloride (GdnHCl). The mean residue ellipticities at 222 nm and enzyme activity plotted against GdnHCl concentration showed loss of about 50 and 75% of secondary structure and 35 and 60% of activity at 0.75 and 1.5 M GdnHCl, respectively. At 6 M GdnHCl, there was loss of secondary structure and activity leading to the formation of GdnHCl-induced unfolded state as evidenced by CD and fluorescence spectroscopy as well as by measuring enzymatic activity. The denaturant-mediated decrease in fluorescence intensity and 5 nm red shift of λ_max point to gradual unfolding of SMATase when GdnHCl is added up from 0.5 M to a maximum of 6 M. Decreasing of ANS binding and red shift (∼5 nm) were observed in this state compared to the native folded state, indicating the partial destruction of surface hydrophobic patches of the protein molecule on denaturation. Disruption of disulfide bonds in the protein resulted in sharp decrease in surface hydrophobicity of the protein, indicating that the surface hydrophobic patches are held by disulfide bonds even in the GdnHCl denatured state. Acrylamide and potassium iodide quenching of the intrinsic tryptophan fluorescence of SMATase showed that the native protein is in folded conformation with majority of the tryptophan residues exposed to the solvent, and about 20% of them are in negatively charged environment. Published in Russian in Biokhimiya, 2006, Vol. 71, No. 11, pp. 1514–1523.     

pKa values and the pH dependent stability of the N-terminal domain of L9 as probes of electrostatic interactions in the denatured state. Differentiation between local and nonlocal interactions

pKa values were measured for the 6 carboxylates in the N-terminal domain of L9 (NTL9) by following NMR chemical shifts as a function of pH. The contribution of each carboxylate to the pH dependent stability of NTL9 was estimated by comparing the pKa values for the native and denatured state of the protein. A set of peptides with sequences derived from NTL9 were used to model the denatured state. In the protein fragments, the pKa values measured for the aspartates varied between 3.8 and 4.1 and the pKa values measured for the glutamates varied between 4.1 and 4.6. These results indicate that the local sequence can significantly influence pKa values in the denatured state and highlight the difficulties in using standard pKa values derived from small compounds. Calculations based on the measured pKa values suggest that the free energy of unfolding of NTL9 should decrease by 4.4 kcal mol-1 when the pH is lowered from 6 to 2. In contrast, urea and thermal denaturation experiments indicate that the stability of the protein decreases by only 2.6 kcal mol-1 when the carboxylates are protonated. This discrepancy indicates that the protein fragments are not a complete representation of the denatured state and that nonlocal sequence effects perturb the pKa's in the denatured state. Increasing the salt concentration from 100 to 750 mM NaCl removes the discrepancy between the stabilities derived from denaturation experiments and the stability changes calculated from the pKa values. At high concentrations of salt there is also less variation of the pKa values measured in the protein fragments. Our results argue that in the denatured state of NTL9 there are electrostatic interactions between groups both local and nonlocal in primary sequence.     

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.     

Thermal denaturation of human gamma-interferon. A calorimetric and spectroscopic study.

The thermal denaturation of a recombinant human gamma-interferon has been studied as a function of pH in the range from 2 to 10 and buffer concentration in the range from 5 to 100 mM by differential scanning calorimetry, circular dichroism, fluorescence, 1H NMR, and biological activity measurements. The thermal transitions are irreversible at high buffer concentrations at all pH values studied, although they are reversible between pH 3.5 and 5.4 at low buffer concentrations. The denaturation enthalpy, DeltaH(Tm), at denaturation temperature Tm was a function of both Tm and the buffer concentration, and this resulted in heat capacity changes decreasing with buffer concentration. When the denaturation enthalpies were corrected for Tm dependence, they did not appear to change versus pH. The denaturation entropies, however, appeared to decrease with pH, leading to a small but appreciable increase in the stability of the protein with pH. The difference between the number of moles of protons stoichiometrically bound to a mole of protein in the native and thermally denatured state, was calculated from the variation of Tm versus pH at each buffer concentration. The values obtained appear to depend on pH alone rather than upon temperature or buffer concentration, a result which agrees with the invariance of the denaturation enthalpies with pH. This dependence was fitted to the titration curve of a group with a pK of 5.4.     

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.     

Difference in the mechanisms of the cold and heat induced unfolding of thioredoxin h from Chlamydomonas reinhardtii: spectroscopic and calorimetric studies

The thermodynamic stability and temperature induced structural changes of oxidized thioredoxin h from Chlamydomonas reinhardtii have been studied using differential scanning calorimetry (DSC), near- and far-UV circular dichroism (CD), and fluorescence spectroscopies. At neutral pH, the heat induced unfolding of thioredoxin h is irreversible. The irreversibly unfolded protein is unable to refold due to the formation of soluble high-order oligomers. In contrast, at acidic pH the heat induced unfolding of thioredoxin h is fully reversible and thus allows the thermodynamic stability of this protein to be characterized. Analysis of the heat induced unfolding at acidic pH using calorimetric and spectroscopic methods shows that the heat induced denaturation of thioredoxin h can be well approximated by a two-state transition. The unfolding of thioredoxin h is accompanied by a large heat capacity change [6.0 +/- 1.0 kJ/(mol.K)], suggesting that at low pH a cold denaturation should be observed at the above-freezing temperatures for this protein. All used methods (DSC, near-UV CD, far-UV CD, Trp fluorescence) do indeed show that thioredoxin h undergoes cold denaturation at pH <2.5. The cold denaturation of thioredoxin h cannot, however, be fitted to a two-state model of unfolding. Furthermore, according to the far-UV CD, thioredoxin h is fully unfolded at pH 2.0 and 0 degrees C, whereas the other three methods (near-UV CD, fluorescence, and DSC) indicate that under these conditions 20-30% of the protein molecules are still in the native state. Several alternative mechanisms explaining these results such as structural differences in the heat and cold denatured state ensembles and the two-domain structure of thioredoxin h are discussed.     

Equilibrium unfolding of RNase Rs from Rhizopus stolonifer: pH dependence of chemical and thermal denaturation

The conformational stability of RNase Rs was determined with chemical and thermal denaturants over the pH range of 1-10. Equilibrium unfolding with urea showed that values of D(1/2) (5.7 M) and DeltaG(H(2)O) (12.8 kcal/mol) were highest at pH 5.0, its pI and the maximum conformational stability of RNase Rs was observed near pH 5.0. Denaturation with guanidine hydrochloride (GdnHCl), at pH 5.0, gave similar values of DeltaG(H(2)O) although GdnHCl was 2-fold more potent denaturant with D(1/2) value of 3.1 M. The curves of fraction unfolded (f(U)) obtained with fluorescence and CD measurements overlapped at pH 5.0. Denaturation of RNase Rs with urea in the pH range studied was reversible but the enzyme denatured irreversibly >pH 11.0. Thermal denaturation of RNase Rs was reversible in the pH range of 2.0-3.0 and 6.0-9.0. Thermal denaturation in the pH range 4.0-5.5 resulted in aggregation and precipitation of the protein above 55 degrees C. The aggregate was amorphous or disordered precipitate as observed in TE micrographs. Blue shift in emission lambda(max) and enhancement of fluorescence intensity of ANS at 70 degrees C indicated the presence of solvent exposed hydrophobic surfaces as a result of heat treatment. Aggregation could be prevented partially with alpha-cyclodextrin (0.15 M) and completely with urea at concentrations >3 M. Aggregation was probably due to intermolecular hydrophobic interaction favored by minimum charge-charge repulsion at the pI of the enzyme. Both urea and temperature-induced denaturation studies showed that RNase Rs unfolds through a two-state F right arrow over left arrow U mechanism. The pH dependence of stability described by DeltaG(H(2)O) (urea) and DeltaG (25 degrees C) suggested that electrostatic interactions among the charged groups make a significant contribution to the conformational stability of RNase Rs. Since RNase Rs is a disulfide-containing protein, the major element for structural stability are the covalent disulfide bonds.     

The unfolding pathway of leech carboxypeptidase inhibitor

The unfolding and denaturation curves of leech carboxypeptidase inhibitor (LCI) were elucidated using the technique of disulfide scrambling. In the presence of thiol initiator and denaturant, the native LCI denatures by shuffling its native disulfide bonds and transforms into a mixture of scrambled species. 9 of 104 possible scrambled isomers of LCI, amounting to 90% of total denatured LCI, can be distinguished. The denaturation curve that plots the fraction of native LCI converted into scrambled isomers upon increasing concentrations of denaturant shows that the concentration of guanidine thiocyanate and guanidine hydrochloride required to reach 50% of denaturation is 2.4 and 3.6 m, respectively. In contrast, native LCI is resistant to urea denaturation even at high concentration (8 m). The LCI unfolding pathway was defined based on the evolution of the relative concentration of scrambled isoforms of LCI upon denaturation. Two populations of scrambled species suffer variations along the unfolding pathway. One accumulates as intermediates under strong denaturing conditions and corresponds to open or relaxed structures, among which the beads-form isomer is found. The other population shows an inverse correlation between their relative abundances and the denaturing conditions and should have another kind of non-native structure that is more compact than the unfolded state. The rate constants of unfolding of LCI are low when compared with other disulfide-containing proteins. Overall, the results presented in this study show that LCI, a molecule with potential biotechnological applications, has slow kinetics of unfolding and is highly stable.     

Role of disulfide bonds in conformational stability and folding of 5′-deoxy-5′-methylthioadenosine phosphorylase II from the hyperthermophilic archaeon Sulfolobus solfataricus

Sulfolobus solfataricus 5′-deoxy-5′-melthylthioadenosine phosphorylase II (SsMTAPII), is a hyperthermophilic hexameric protein with two intrasubunit disulfide bonds (C138–C205 and C200–C262) and a CXC motif (C259–C261). To get information on the role played by these covalent links in stability and folding, the conformational stability of SsMTAPII and C262S and C259S/C261S mutants was studied by thermal and guanidinium chloride (GdmCl)-induced unfolding and analyzed by fluorescence spectroscopy, circular dichroism, and SDS-PAGE. No thermal unfolding transition of SsMTAPII can be obtained under nonreducing conditions, while in the presence of the reducing agent Tris-(2-carboxyethyl) phosphine (TCEP), a Tm of 100 °C can be measured demonstrating the involvement of disulfide bridges in enzyme thermostability. Different from the wild-type, C262S and C259S/C261S show complete thermal denaturation curves with sigmoidal transitions centered at 102 °C and 99 °C respectively. Under reducing conditions these values decrease by 4 °C and 8 °C respectively, highlighting the important role exerted by the CXC disulfide on enzyme thermostability. The contribution of disulfide bonds to the conformational stability of SsMTAPII was further assessed by GdmCl-induced unfolding experiments carried out under reducing and nonreducing conditions. Thermal unfolding was found to be reversible if the protein was heated in the presence of TCEP up to 90 °C but irreversible above this temperature because of aggregation. In analogy, only chemical unfolding carried out in the presence of reducing agents resulted in a reversible process suggesting that disulfide bonds play a role in enzyme denaturation. Thermal and chemical unfolding of SsMTAPII occur with dissociation of the native hexameric state into denatured monomers, as indicated by SDS-PAGE.     

The effects of disulfide bonds on the denatured state of barnase

The effects of engineered disulfide bonds on protein stability are poorly understood because they can influence the structure, dynamics, and energetics of both the native and denatured states. To explore the effects of two engineered disulfide bonds on the stability of barnase, we have conducted a combined molecular dynamics and NMR study of the denatured state of the two mutants. As expected, the disulfide bonds constrain the denatured state. However, specific extended beta-sheet structure can also be detected in one of the mutant proteins. This mutant is also more stable than would be predicted. Our study suggests a possible cause of the very high stability conferred by this disulfide bond: the wild-type denatured ensemble is stabilized by a nonnative hydrophobic cluster, which is constrained from occurring in the mutant due to the formation of secondary structure.     

Physicochemical properties of thiol proteinase inhibitor isolated from goat pancreas

Thiol proteinase inhibitors are crucial to proper functioning of all living tissues consequent to their cathepsin regulatory and myriad important biologic properties. Equilibrium denaturation of dimeric goat pancreas thiol proteinase inhibitor (PTPI), a cystatin superfamily variant has been studied by monitoring changes in the protein's spectroscopic and functional characteristics. Denaturation of PTPI in guanidine hydrochloride and urea resulted in altered intrinsic fluorescence emission spectrum, diminished negative circular dichroism, and loss of its papain inhibitory potential. Native like spectroscopic properties and inhibitory activity are only partially restored when denaturant is diluted from guanidine hydrochloride unfolded samples demonstrating that process is partially reversible. Coincidence of transition curves and dependence of transition midpoint (3.2M) on protein concentration in guanidine hydrochloride‐induced denaturation are consistent with a two‐state model involving a native like dimer and denatured monomer. On the contrary, urea‐induced unfolding of PTPI is a multiphasic process with indiscernible intermediates. The studies demonstrate that functional conformation and stability are governed by both ionic and hydrophobic interactions. © 2010 Wiley Periodicals, Inc. Biopolymers 93: 708–717, 2010. This article was originally published online as an accepted preprint. The “Published Online” date corresponds to the preprint version. You can request a copy of the preprint by emailing the Biopolymers editorial office at biopolymers@wiley.com     

Quantitative analysis of the composition of the native and scrambled ribonuclease A

Reversible conversion between the native and scrambled proteins can be applied to analyze the denaturation curve of a disulfide-containing protein. In the case of RNase A, scrambled species could not be well separated from the native species by HPLC to permit precise quantitative analysis of the extent of denaturation. Methods are developed here to overcome this problem. The methods exploit the difference of conformational stability between the native and scrambled RNase A. When a sample of partially denatured RNase A was placed under mild reducing conditions (0.2-1 mM dithiothreitol for 10 min), the disulfide bonds of the native RNase A remain intact, whereas those of scrambled isomers become fully reduced. The native and fully reduced species of RNase A can be completely separated by HPLC. Alternatively, a mixture of partially denatured RNase A can be treated with mild concentration of proteolytic enzymes (trypsin or thermolysin). In this approach, scrambled isomers of RNase A were totally fragmented and readily separated from the native RNase A. These methods allow analysis and construction of the denaturation curves of RNase A in the presence of urea, GdmCl and GdmSCN.     

Thermal denaturation and gelation of rubisco: effects of pH and ions

In order to understand the mechanism of thermal gelation of rubisco, its native and heat denatured states were characterized by absorbance, fluorescence and circular dichroïsm spectroscopies as well as by differential scanning calorimetry in the presence of various salts. It appears that during the denaturation process, divalent anions are released while divalent cations are fixed by the protein, while it is disorganized and while the environment of its aromatic chromophores becomes more hydrophilic. The pH transition of gelation is shifted 1–2 pH units higher than the transition of denaturation temperature which occurs near the isoelectric point of the native molecule. This shift probably corresponds to the breaking of saline bridges within the protein molecule. Finally, a large effect of divalent cations on the phase diagram indicates that a particular denatured state is attained when these cations are in the denaturation medium.     

The reversible heat denaturation of chymotrypsinogen

Within a restricted range of pH and protein concentration crystalline chymotrypsinogen undergoes thermal denaturation which is wholly reversed upon cooling. At a given temperature an equilibrium exists between native and reversibly denatured protein. Within the pH range 2 to 3 the amount of denatured protein is a function of the third power of the hydrogen ion activity. The presence of small amounts of electrolyte causes aggregation of the reversibly denatured protein. A specific anion effect has been observed at pH 2 but not at pH 3. Both the reversible denaturation reaction and the reversal reaction have been found to be first order reactions with respect to protein and the kinetic and thermodynamic constants for both reactions have been approximated at pH 2 and at pH 3. Renatured chymotrypsinogen has been found to be identical with native chymotrypsinogen with respect to crystallizability, solubility, activation to δ-chymotrypsin, sedimentation rate, and behavior upon being heated. Irreversible denaturation of chymotrypsinogen has been found to depend on pH, temperature, protein concentration, and time of heating. Irreversible denaturation results in an aggregation of the denatured protein.     

Does beta-lactoglobulin denaturation occur via an intermediate state?

The denaturation of beta-lactoglobulin (BLG) in the presence of urea and GuHCl has been investigated at different pH values with various spectroscopic techniques. The equilibrium denaturation free energy values, obtained by linearly extrapolating the data to vanishing denaturant (DeltaG(D)(H2O)), are compared and discussed. The fit of the spectroscopic data monitoring the denaturation of BLG has been approached, at first, with a two-state model that describes the protein transition from the folded state (at each pH and in the absence of denaturant) to the denatured state, but in particular, along the GuHCl denaturation pathway some evidence is found of the presence of an intermediate state. Time-resolved fluorescence experiments performed on the BLG-ANS (1-anilino-8-naphthalenesulfonate) complex help to understand the results. Fluorescence polarization anisotropy (FPA) measurements accompanying the denaturation process show the presence of a fast rotational diffusion of the ANS probe, and the data are interpreted in terms of local fluctuations of a still structured tract of the denatured protein where the probe is bound.