Proline isomerization during refolding of ribonuclease A is accelerated by the presence of folding intermediates

FK506-Binding Protein 2 Participates in Proinsulin Folding

Apart from chaperoning, disulfide bond formation, and downstream processing, the molecular sequence of proinsulin folding is not completely understood. Proinsulin requires proline isomerization for correct folding. Since FK506-binding protein 2 (FKBP2) is an ER-resident proline isomerase, we hypothesized that FKBP2 contributes to proinsulin folding. We found that FKBP2 co-immunoprecipitated with proinsulin and its chaperone GRP94 and that inhibition of FKBP2 expression increased proinsulin turnover with reduced intracellular proinsulin and insulin levels. This phenotype was accompanied by an increased proinsulin secretion and the formation of proinsulin high-molecular-weight complexes, a sign of proinsulin misfolding. FKBP2 knockout in pancreatic β-cells increased apoptosis without detectable up-regulation of ER stress response genes. Interestingly, FKBP2 mRNA was overexpressed in β-cells from pancreatic islets of T2D patients. Based on molecular modeling and an in vitro enzymatic assay, we suggest that proline at position 28 of the proinsulin B-chain (P28) is the substrate of FKBP2's isomerization activity. We propose that this isomerization step catalyzed by FKBP2 is an essential sequence required for correct proinsulin folding.

Cis-trans peptide variations in structurally similar proteins

The presence of energetically less favourable cis peptides in protein structures has been observed to be strongly associated with its structural integrity and function. Inter-conversion between the cis and trans conformations also has an important role in the folding process. In this study, we analyse the extent of conservation of cis peptides among similar folds. We look at both the amino acid preferences and local structural changes associated with such variations. Nearly 34% of the Xaa-Proline cis bonds are not conserved in structural relatives; Proline also has a high tendency to get replaced by another amino acid in the trans conformer. At both positions bounding the peptide bond, Glycine has a higher tendency to lose the cis conformation. The cis conformation of more than 30% of β turns of type VIb and IV are not found to be conserved in similar structures. A different view using Protein Block-based description of backbone conformation, suggests that many of the local conformational changes are highly different from the general local structural variations observed among structurally similar proteins. Changes between cis and trans conformations are found to be associated with the evolution of new functions facilitated by local structural changes. This is most frequent in enzymes where new catalytic activity emerges with local changes in the active site. Cis-trans changes are also seen to facilitate inter-domain and inter-protein interactions. As in the case of folding, cis-trans conversions have been used as an important driving factor in evolution.

Isothermal calorimetry as a tool to investigate slow conformational changes in proteins and peptides

A new calorimetric method has been developed to follow the time course of slow conformational changes during the refolding of denatured proteins. The method is based on the ability of isothermal titration calorimeters (ITC) to detect small amounts of heat continuously over a minute to an hour time range without being disturbed by baseline drift. We benchmarked the method on the basis of the slow kinetic phases resulting from prolyl cis/trans isomerization of oligopeptides. Using this method, the simultaneous investigation of the kinetics and thermodynamics of slow phases in the refolding of GdmCl-denatured RNase A by single jump techniques was performed. Time traces of heat production in the presence of a peptidyl prolyl cis/trans isomerase support the classical model of rate-limiting prolyl trans to cis isomerizations in the folding reactions of RNase A. However, we also observed that, unlike prolyl cis/trans isomerizations in oligopeptides, those found in RNase A refolding are highly exothermic. It appears that coupling between slow prolyl trans to cis isomerization and relocation of remote backbone segments increases the number of contacting sites during formation of the native protein. The results demonstrate that calorimetrically monitored folding kinetics will be of relevance in the detection of otherwise silent folding events.

Effect of Multiple Prolyl Isomerization Reactions on the Stability and Folding Kinetics of the Notch Ankyrin Domain: Experiment and Theory

Studies on the folding kinetics of the Notch ankyrin domain have demonstrated that the major refolding phase is slow, the minor refolding phase is limited by the isomerization of prolyl peptide bonds, and that unfolding is multiexponential. Here, we explore the relationship between prolyl isomerization and folding heterogeneity using a combination of experiment and simulation. Proline residues were replaced with alanine, both singly and in various combinations. These destabilizing substitutions combine to eliminate the minor refolding phase, although unfolding heterogeneity persists even when all seven proline residues are replaced. To test whether prolyl isomerization influences the major refolding phase, we modeled folding and prolyl isomerization as a system of sequential reactions. Simulations that use rate constants of the major folding phase of the Notch ankyrin domain to represent intrinsic folding indicate that even with seven prolyl isomerization reactions, only two significant phases should be observed, and that the fast observed phase provides a good approximation of the intrinsic folding in the absence of prolyl isomerization. These results indicate that the major refolding phase of the Notch ankyrin domain reflects an intrinsically slow folding transition, rather than coupling of fast folding events with slow prolyl isomerization steps. This is consistent with the observation that the single observed refolding phase of a construct in which all proline residues are replaced remains slow. Finally, the simulation fails to produce a second unfolding phase at high urea concentrations, indicating that prolyl isomerization does not play a role in the three-state mechanism that leads to this heterogeneity.

Proline isomerization in bovine pancreatic ribonuclease A. 2. Folding conditions

The kinetics of cis-trans isomerization of individual X-Pro peptide groups is used to study the backbone dynamics of bovine pancreatic ribonuclease A (RNase A). We previously developed and validated a fluorescence method for monitoring the cis-trans isomerization of the Tyr92-Pro93 and Asn113-Pro114 peptide groups of RNase A under unfolding conditions [Juminaga, D., Wedemeyer, W. J., and Scheraga, H. A. (1998) Biochemistry 37, 11614-11620]. The essence of this method is to introduce a fluorescent residue (Tyr or Trp) in a position adjacent to the isomerizing proline (if one is not already present) and to eliminate the fluorescence of other such residues adjacent to prolines by mutating them to phenylalanine. Here, we extend this method to observe the cis-trans isomerization of these peptide groups under folding conditions using two site-directed mutants (Y92F and Y115F) of RNase A. Both isomerizations decelerate with increasing concentrations of GdnHCl, with nearly identical m values (1.11 and 1.19 M(-1), respectively) and extrapolated zero-GdnHCl time constants (42 and 32 s, respectively); by contrast, under unfolding conditions, the cis-trans isomerizations of both Pro93 and Pro114 are independent of GdnHCl concentration. Remarkably, the isomerization rates under folding conditions at GdnHCl concentrations above 1 M are significantly slower than those measured under unfolding conditions. The temperature dependence of the Pro114 isomerization under folding conditions is also unusual; whereas Pro93 exhibits an activation energy typical of proline isomerization (19.4 kcal/mol), Pro114 exhibits a sharply reduced activation energy of 5.7 kcal/mol. A structurally plausible model accounts for these results and, in particular, shows that folding conditions strongly accelerate the cis-trans isomerization of both peptide groups to their native cis conformation, suggesting the presence of flickering local structure in their beta-hairpins.

Identification of proline residues responsible for the slow folding kinetics in pectate lyase C by mutagenesis

The folding mechanism of pectate lyase C (pelC) involves two slow phases that have been attributed to proline isomerization. To have a more detailed and complete understanding of the folding mechanism, experiments have been carried out to identify the prolyl-peptide bonds responsible for the slow kinetics. Site-directed mutagenesis has been used to mutate each of the prolines in pelC to alanine or valine. It has been determined that isomerization of the Leu219-Pro220 peptide bond is responsible for the slowest folding phase observed. The mutant P220A shows kinetic behavior that is identical to the wild-type protein except that the 46-s phase is eliminated. The Leu219-Pro220 peptide bond is cis in the native enzyme. An analysis of the free energy of unfolding of this mutant indicates that the mutation destabilizes the protein by about 4 kcal/mol. However, it appears that the major refolding pathways are unaltered. Further mutations were carried out in order to assign the peptide bond responsible for the 21-s folding phase in pelC. Mutation of the remaining 11 prolines, which are trans in the native enzyme, resulted in no significant changes in the kinetic folding behavior. The conclusion from these experiments is that the 21-s phase involves isomerization of more than one prolyl-peptide bond with similar activation energies.

Stability and folding of the tumour suppressor protein p16

The tumour suppressor p16 is a member of the INK4 family of inhibi tors of the cyclin D-dependent kinases, CDK4 and CDK6, that are involved in the key growth control pathway of the eukaryotic cell cycle. The 156 amino acid residue protein is composed of four ankyrin repeats (a helix-turn-helix motif) that stack linearly as two four-helix bundles resulting in a non-globular, elongated molecule. The thermodynamic and kinetic properties of the folding of p16 are unusual. The protein has a very low free energy of unfolding, Delta GH-2O/D-N, of 3.1 kcal mol-1 at 25 degreesC. The rate-determining transition state of folding/unfolding is very compact (89% as compact as the native state). The other unusual feature is the very rapid rate of unfolding in the absence of denaturant of 0.8 s-1 at 25 degreesC. Thus, p16 has both thermodynamic and kinetic instability. These features may be essential for the regulatory function of the INK4 proteins and of other ankyrin-repeat-containing proteins that mediate a wide range of protein-protein interactions. The mechanisms of inactivation of p16 by eight cancer-associated mutations were dissected using a systematic method designed to probe the integrity of the secondary structure and the global fold. The structure and folding of p16 appear to be highly vulnerable to single point mutations, probably as a result of the protein's low stability. This vulnerability provides one explanation for the striking frequency of p16 mutations in tumours and in immortalised cell lines.

Functional and structural analysis of cis-proline mutants of Escherichia coli aspartate aminotransferase

To elucidate the role of the two conserved cis-proline residues of aspartate aminotransferase (AspAT), one double and two single mutants of the enzyme from Escherichia coli (EcAspAT) were prepared: P138A, P195A and P138A/P195A in which the two prolines were replaced by alanine. The crystal structures of P195A and P138A/P195A have been determined at 2.3-2.1 A resolution. The wild-type geometry, including the cis conformation of the 194-195 peptide bond is retained upon substitution of proline 195 by alanine, whereas the trans conformation is adopted at the 137-138 peptide bond. Quite surprisingly, the replacement of each of the two prolines by alanine does not significantly affect either the activity or the stability of the protein. All the three mutants follow the same pathway as the wild type for unfolding equilibrium induced by guanidine hydrochloride [Herold, M., and Kirschner, K. (1990) Biochemistry 29, 1907-1913]. The kinetics of renaturation of P195A, where the alanine retains the wild-type cis conformation, is faster than wild type, whereas renaturation of P138A, which adopts the trans conformation, is slower. We conclude that cis-prolines seem to have been retained throughout the evolution of aspartate aminotransferase to possibly play a subtle role in directing the traffic of intermediates toward the unique structure of the native state, rather than to respond to the needs for a specific catalytic or functional role.

Stability and folding of the cell cycle regulatory protein, p13(suc1)

p13(suc1) (suc1) is a member of the CDC28 kinase specific family of cell cycle regulatory proteins that bind to the cyclin-dependent kinase CDK2 and regulate its activity. suc1 has two distinct conformational and assembly states, a compact globular monomer and a beta strand-exchanged dimer. The dimerisation is an example of domain-swapping, and is mediated by a molecular hinge mechanism that is conserved across the entire CKS family. It has been proposed that the function of suc1 may be modulated by the dimerisation process with monomer-dimer switching occurring in response to a change in the cell environment. We have investigated the stability and folding of suc1 as a first step in determining the mechanism and functional role of the strand exchange. Suc1 unfolds reversibly at equilibrium in a two-state manner with a free energy of unfolding of 7.2 kcal mol-1. The kinetics of folding and unfolding are complex, and double-jump stopped-flow methods revealed that there are at least three parallel folding pathways arising from distinct unfolded and partly folded, intermediate states. The major population of unfolded species fold rapidly according to a three-state mechanism, D1->I1->N, with a rate constant for the formation of native species, N, from the intermediate, I1, of 65 s-1 in water. Two minor populations of unfolded molecules fold more slowly. Folding of one population is limited by proline isomerisation in a partly folded state, and some expansion of the protein is required for isomerisation to occur. The other population could be assigned to rate-limiting isomerisation of the peptidyl-proline bond of residue 90, which is located in the molecular hinge. A minor, fast phase was detected in the unfolding kinetics that corresponds to unfolding of a small population of a distinct native-like form. Heterogeneity was removed upon mutation of Pro90 to Ala. The unfolding kinetics of the strand-exchanged dimer were also investigated and showed that the dimer unfolds at the same rate as the monomer.

Unfolding and refolding of active apple polyphenol oxidase

For the first time, unfolding (6 M guanidine) and refolding of partially proteolysed purified polyphenol oxidase (PPOr) was achieved, with 88% of activity recovered. Optimal refolding conditions consisted in stepwise dialysis of guanidine treated extracts, the dialysis buffers containing 1 M (NH4)2SO4 and 100 microM CuSO4. However, CuSO4 had limited effect on the recovering of PPOr activity, whereas (NH4)2SO4 was essential. Concerning the PPO tertiary structure, denaturing conditions (combinations of boiling and reducing agent) used on SDS-PAGE have shown (i) a compact tertiary structure and (ii) the presence of disulfide bonds in PPOr, accounting for the shift between 27 and 41 kDa, and 41 and 42 kDa, respectively. Resistance to proteolytic cleavage was used to study the conformational changes induced by the denaturing treatments. Folded PPOr was resistant to further proteolysis whereas unfolded PPO was totally digested, indicating the role of tertiary structure of PPOr in the resistance to proteases.

Proline isomerization in bovine pancreatic ribonuclease A. 1. Unfolding conditions

The slow fluorescence unfolding phase of bovine pancreatic ribonuclease A is studied by stopped-flow kinetics and site-directed mutagenesis of tyrosines to phenylalanine and prolines to alanine. It is shown conclusively that this phase arises from two specific sources: Tyr92 reporting on the cis-trans isomerization of Pro93 and Tyr115 reporting on the cis-trans isomerization of Pro114. Previous studies have conjectured that the slow unfolding phase arises from only one source (Tyr92-Pro93 cis-trans isomerization) based primarily on studies of the homologous protein guinea pig ribonuclease A [Schmid, F. X., Grafl, R., Wrba, A., and Beintema, J. J. (1986) Proc. Natl. Acad. Sci. U.S.A. 83, 872-876]; it is proposed here that Lys113 in the latter protein interferes with the isomerization of the Lys113-Pro114 peptide group. The site-directed mutations studied here enable the individual isomerizations of Pro93 and Pro114 to be monitored, providing an optical technique by which these well-defined molecular folding events can be studied, under both folding and unfolding conditions, and compared to molecular simulations. The time constants for Pro93 and Pro114 isomerization agree closely with those of our box model of proline isomerization under unfolding conditions, which had been derived from exhaustive statistical modeling of double-jump refolding data [Juminaga, D., Wedemeyer, W. J., Garduño-Júarez, R., McDonald, M. A., and Scheraga, H. A. (1997) Biochemistry 36, 10131-10145].

The rate of isomerisation of peptidyl-proline bonds as a probe for interactions in the physiological denatured state of chymotrypsin inhibitor 2

There are four peptidyl-proline bonds in the 64-residue protein chymotrypsin inhibitor 2 (CI2), all of which are in the trans conformation in the native structure. The isomerisation of one or more of these peptidyl-proline bonds to the cis conformation in the denatured state gives rise to heterogeneity, leading to both fast and slow-folding species. The refolding of the fast-folding species, which has all trans peptidyl-proline bonds, is much faster than that of the slow-folding species, which have one or more cis peptidyl-proline bonds. In CI2, the slow-folding species can be classified into two groups by their rates of refolding, temperature-dependence, pH-dependence and [GdmCl]-dependence of the rate constants and the effect of peptidyl-prolyl isomerase on the rate constants. The replacement of Pro6 by Ala removes one of the slow refolding phases, suggesting that the cis peptidyl-Pro6 conformation is solely responsible for one of the slow-folding species. Pro6 is located in a region of the protein where non-random interactions have been found in a series of N-terminal fragments of CI2 (residues 1 to 13, 1 to 25, 1 to 28 and 1 to 40). In addition, NMR studies on a mutant fragment, (1-40)T3A, have confirmed that this non-native interaction is associated with the bulky side-chain of Trp5. The atypical rate of cis to trans isomerisation of the peptidyl-Pro bond is indicative of the presence of a similar hydrophobic cluster in the physiological denatured state of intact CI2.

Autocatalyzed protein folding

Proline isomerization, an intrinsically slow process, kinetically traps intermediates in slow protein folding reactions. Thus, enzymes that catalyze proline isomerization (prolyl isomerases) often catalyze protein folding. We have investigated the folding kinetics of FKBP, a prolyl isomerase. The main conclusion is that FKBP catalyzes its own folding. Altogether, the FKBP refolding kinetics are resolved into three exponential phases: a fast phase, tau 3; an intermediate phase, tau 2; and a slow phase, tau 1. Unfolding occurs in a single phase, the unfolding branch of phase tau 2. In the presence of native FKBP, both the intermediate (tau 2) and slow (tau 1) phases are faster, suggesting that folding phases tau 1 and tau 2 involve proline cis-trans isomerization. In the absence of added native FKBP, autocatalytic folding of FKBP is detected. For refolding starting with all the FKBP unfolded initially, the slowest folding phase (tau 1) is almost 2-fold faster at a final concentration of 14 microM FKBP than at 2 microM FKBP, suggesting that catalytically active FKBP formed in the fast (tau 3) or intermediate (tau 2) folding phases catalyzes the slow folding phase (tau 1). Moreover, autocatalysis of folding is inhibited by FK506, an inhibitor of the FKBP prolyl isomerase activity. The results show that the slow phase in FKBP folding is an autocatalyzed formation of native FKBP from kinetically trapped species with non-native proline isomers. While the magnitude of the catalytic effects reported here are modest, FKBP folding may provide a prototype for autocatalysis of kinetically trapped macromolecular conformational changes in other systems.

Quantitative analysis of the kinetics of denaturation and renaturation of barstar in the folding transition zone

The fluorescence-monitored kinetics of folding and unfolding of barstar by guanidine hydrochloride (GdnHCl) in the folding transition zone, at pH 7, 25 degrees C, have been quantitatively analyzed using a 3-state mechanism: U(S)<-->UF<-->N. U(S) and UF are slow-refolding and fast-refolding unfolded forms of barstar, and N is the native protein. U(S) and UF probably differ in possessing trans and cis conformations, respectively, of the Tyr 47-Pro 48 bond. The 3-state model could be used because the kinetics of folding and unfolding of barstar show 2 phases, a fast phase and a slow phase, and because the relative amplitudes of the 2 phases depend only on the final refolding conditions and not on the initial conditions. Analysis of the observed kinetics according to the 3-state model yields the values of the 4 microscopic rate constants that describe the transitions between the 3 states at different concentrations of GdnHCl. The value of the equilibrium unfolded ratio U(S):UF (K21) and the values of the rate constants of the U(S)-->UF and UF-->U(S) reactions, k12 and k21, respectively, are shown to be independent of the concentration of GdnHCl. K21 has a value of 2.1 +/- 0.1, and k12 and k21 have values of 5.3 x 10(-3) s-1 and 11.2 x 10(-3) s-1, respectively. Double-jump experiments that monitor reactions that are silent to fluorescence monitoring were used to confirm the values of K21, k12, and k21 obtained from the 3-state analysis and thereby the validity of the 3-state model.(ABSTRACT TRUNCATED AT 250 WORDS)

Slow-folding kinetics of ribonuclease-A by volume change and circular dichroism: evidence for two independent reactions

The slow refolding of guanidine-HCl-denatured ribonuclease-A was studied by volume change and by kinetic CD at 222 and 276 nm. Dilatometric measurements revealed that on refolding there is a fast volume change of +232 mL/mol of protein. This is followed by a very slow nonexponential change that takes about 25 min to reach equilibrium. By adding varying amounts of (NH4)2SO4, the slow volume change curve was resolved into 2 concurrent reactions. The faster of the 2 slow events entails a negative volume change of -64 mL/mol of protein and appears to arise from proline isomerization. The slower process, attended by a positive change of +53 mL/mol of protein, has properties consistent with the "XY" reaction of Lin and Brands (1983, Biochemistry 22:563-573). This reaction is so named because the conformational nature of neither its initial (Y) nor its final state (X) is known; the transition is characterized solely by its absorbance and fluorescence kinetics. These are the first direct physical measures attributable to the "XY" process. The early formation of a compact structure in the event responsible for the rapid +232-mL/mol volume change, however, is consistent with the sequential model of folding (Cook KH, Schmid FX, Baldwin RL, 1979, Proc Natl Acad Sci USA 76:6157-6161; Kim PS, Baldwin RL, 1980, Biochemistry 19:6124-6129). The usefulness of volume change measurements as a method of detecting structural rearrangements was confirmed by finding agreement between time constants obtained from parallel volume change and kinetic CD experiments. The measured volume changes arise from both changes in hydration and changes in the packing of atoms in the interior of the protein.

The refolding of cis- and trans-peptidylprolyl isomers of barstar

Barstar, a small globular protein which undergoes reversible unfolding, is a good candidate for studies on protein folding. It possesses two cysteine residues that complicate folding studies by forming a variable mixture of disulfide-bridged forms. We have constructed and analyzed, therefore, a double mutant Cys40-->Ala,Cys82-->Ala. Equilibrium unfolding with urea follows a simple two-step mechanism. The midpoint for unfolding ([U]1/2) is 3.87 +/- 0.03 M urea, with m(delta delta G/delta [urea]) = 1.25 +/- 0.04 kcal/mol2. The free energy of unfolding, delta GU-FH2O, is 4.84 +/- 0.18 kcal/mol. Identical results were found on monitoring the intrinsic tryptophan fluorescence or the circular dichroism signal at 221 nm, showing that the transition is due to the global denaturation of the protein. Barstar contains two proline residues, one of which (Pro48) has a cis N-aminoacyl bond conformation in the folded state. A transiently generated form of the unfolded protein, which contains the proline residues in their native conformations, has a rate constant for refolding (31 s-1) similar to that for refolding of the equilibrium-unfolded protein, which results in a "misfolded" form of the protein (32 s-1). The two refolded states are different: the free energies of unfolding measured from kinetic constants for the native and misfolded variants are 5.4 +/- 0.3 and 2.85 +/- 0.1 kcal/mol, respectively. The rate constant for the unfolding in water of the misfolded protein is 0.87 s-1, compared with 0.068 s-1 for the unfolding of the native protein. This difference can be explained by a nonnative trans peptidyl-proline bond at position 48 in the misfolded protein.(ABSTRACT TRUNCATED AT 250 WORDS)

Folding of RNase T1 is decelerated by a specific tertiary contact in a folding intermediate

The replacement of tryptophan 59 of ribonuclease T1 by a tyrosine residue does not change the stability of the protein. However, it leads to a strong acceleration of a major, proline-limited reaction that is unusually slow in the refolding of the wild-type protein. The distribution of fast- and slow-folding species and the kinetic mechanism of slow folding are not changed by the mutation. Trp-59 is in close contact to Pro-39 in native RNase T1 and probably also in an intermediate that forms rapidly during folding. We suggest that this specific interaction interferes with the trans----cis reisomerization of the Tyr-38-Pro-39 bond at the stage of a native-like folding intermediate. The steric hindrance is abolished either by changing Trp-59 to a less bulky residue, such as tyrosine, or, by a destabilization of folding intermediates at increased concentrations of denaturant. Under such conditions folding of the wild-type protein and of the W59Y variant no longer differ. These results provide strong support for the proposal that trans----cis isomerization of Pro-39 is responsible for the major, very slow refolding reaction of RNase T1. They also indicate that specific tertiary interactions in folding intermediates do exist, but do not necessarily facilitate folding. They can have adverse effects and decelerate rate-limiting steps by trapping partially folded structures.

Identification of a new site of conformational heterogeneity in unfolded ribonuclease A

The results presented here indicate that there are two slowly exchanging conformational isomers in unfolded bovine pancreatic ribonuclease A (RNase A) in the vicinity of Lys-41. The conformational heterogeneity is not observed in the fully folded protein. Therefore, one of the isomers may correspond to one of the slow-folding forms of the protein observed when refolding is initiated. These results were obtained from a chemically modified form of the protein, CL(7-41) RNase A, that has a dinitrophenyl cross-link between the epsilon-amino groups of Lys-7 and Lys-41. Extensive physical studies have shown that the cross-link does not significantly perturb the structure or the folding pathways of the protein. Therefore, the results obtained from this modified form of the protein are relevant to intact RNase A. The one-dimensional (1D) NMR spectrum of heat-unfolded CL(7-41) RNase A reveals that the singlet resonance for the C3H ring proton of the dinitrophenyl cross-link has been split into two unequal peaks in a 3:1 ratio, indicating that there are two distinct environments for the dinitrophenyl group. Variations in temperature, and the addition of urea, do not affect the relative peak intensities. The two peaks collapse into one after the protein is refolded. The observed splitting must originate from a slow reversible isomerization (greater than 100 msec) in a neighboring bond. The two most likely candidates are either the cis/trans isomerization of the Lys-41-Pro-42 peptide bond or hindered rotation about the disulfide bond between Cys-40 and Cys-95.

Protein folding

Images

Refolding of denatured ribonuclease observed by size exclusion chromatography

The unfolding and refolding of pancreatic ribonuclease have been observed by absorbance, fluorescence, and size exclusion chromatographic measurements in solutions of guanidinium chloride continuously maintained at pH 6.0 and 4 degrees C. The spectral measurements were fitted with a minimal number of kinetic phases while the chromatographic measurements were simulated from an explicit mechanism. All of the measurements are consistent with a minimal mechanism involving seven components. The folded components include the native protein and two transiently stable intermediates each having the same hydrodynamic volume. The intermediate having all native peptide isomers has an unfolding midpoint in 3.8 M denaturant while the intermediate having one nonnative peptide isomer has an unfolding midpoint in 1.3 M denaturant. The unfolded protein is distributed among four components having the same hydrodynamic volume but differing peptide isomers. At equilibrium, 10% of the denatured protein has all native isomers, 60% has one nonnative isomer, 5% has a different nonnative isomer, and 25% has both nonnative isomers. In low denaturant concentrations, the dominant component with one nonnative isomer can refold to transiently populate the compact intermediate with the same nonnative isomer.

The effect of methanol and temperature on the kinetics of refolding of ribonuclease A

Unfolded ribonuclease A consists of 20% fast refolding (Uf) and 80% slow refolding material (Us). The latter consists of at least two different forms which refold at different rates. We have used absorbance and fluorescence spectrophotometry to compare the kinetics of refolding in aqueous and aqueous-methanol solutions. At 1 degree C and pH 3.0, the addition of increasing concentrations of methanol (to 50%, v/v) had negligible effect on the rates and amplitudes of the slow refolding Us states. The effect of temperature on the two slow phases of refolding was determined in 35 and 50% methanol. From Arrhenius plots the energies of activation were found to be in the vicinity of 20 kcal/mol for both processes. The results suggest that both slow phases correspond to proline isomerization, and that the presence of methanol does not significantly perturb the overall refolding process. It is possible that the faster of the slow refolding phases corresponds to the isomerization of a proline residue which is trans in the folded native state but which undergoes extensive isomerization to the cis conformation in the unfolded state.

Folding/unfolding kinetics of mutant forms of iso-1-cytochrome c with replacement of proline-71

Proline-71, an evolutionally conserved residue that separates two short alpha-helical regions, is replaced by valine, threonine, or isoleucine in at least partially functional forms of iso-1-cytochrome c from Saccharomyces cerevisiae [Ernst, J. F., Hampsey, D. M., Stewart, J. W., Rackovsky, S., Goldstein, D., & Sherman, F. (1985) J. Biol. Chem. 260, 13225-13236]. To assign the effects of perturbations at position 71 to steps in the process of protein folding, the kinetic properties of the folding/unfolding reactions of normal protein and the three mutant forms are compared. At pH 6.0, 20 degrees C, fluorescence-detected folding/unfolding kinetics are monitored below, within, and above the equilibrium transition zone by using stopped-flow mixing to perform guanidine hydrochloride concentration jumps. Three kinetic phases are detected for each of the four proteins. The fastest of these phases (tau 3) differs in rate for the wild type and mutant proteins. The remaining kinetic phases (tau 1 and tau 2) have similar rates for all four proteins over the entire range of folding/unfolding conditions. The guanidine hydrochloride dependence of the relative amplitudes of the kinetic phases is complex and is sensitive to the nature of the substituent at position 71: each of the four proteins shows differences in the fraction of folding/unfolding associated with the two fastest rate processes. The results suggest that it is the location of the mutation in the primary structure rather than the nature of the substituent that determines which kinetic step (or steps) is changed in rate.(ABSTRACT TRUNCATED AT 250 WORDS)

Folding mechanism of porcine ribonuclease

The kinetics of unfolding and refolding of porcine ribonuclease were investigated. The unfolded state of this protein was found to consist of a fast-refolding species (UF) and two slow-refolding species (UIS and UIIS). After the rapid collapse of the structure during the N (native)----UF unfolding reaction, UIS and UIIS are produced from UF by two independent slow isomerizations of the unfolded polypeptide chain, leading ultimately to a mixture of about 10% UF, 20% UIIS and 70% UIS molecules at equilibrium. This is at variance with all other ribonucleases investigated to date, which show a distribution of 20% UF, 60 to 70% UIIS and only 10 to 20% UIS. The two isomerizations of the unfolded porcine protein differ strongly in rate. The first process with tau = 250 seconds (10 degrees C) leads to an increase in the fluorescence of Tyr92 and was identified as cis in equilibrium trans isomerization of Pro93. At equilibrium, most unfolded molecules contain an incorrect trans Pro93. The second isomerization is much slower (tau = 1300 s at 10 degrees C) and leads to a predominance of the incorrect isomer as well. Like isomerization of Pro93, it is governed by an activation enthalpy of 22 kcal/mol (92 kJ/mol) and it was tentatively assigned to the Pro114-Pro115 sequence of porcine ribonuclease. Because of the wide separation in rate between the two reactions, molecules with an incorrect isomer only at Pro93 accumulate transiently after unfolding. These are the UIIS molecules. Most of them are finally converted to UIS by the 1300 second process. All molecules that have undergone this isomerization refold very slowly, i.e. the UIS molecules. The major fraction contains two incorrect isomers. A 1300 second isomerization after unfolding and a predominant very slow refolding reaction were observed only for the porcine protein. We suggest that these changes in the folding mechanism may be correlated with the presence of the Pro114-Pro115 sequence, which occurs only in porcine ribonuclease. The refolding pathway of porcine UIIS involves the rapid formation of a native-like intermediate with an incorrect trans Pro93 as was found previously for the bovine ribonuclease, where the UIIS species predominates in the unfolded state.