Cooperativity of a protein folding reaction probed at multiple chain positions by real-time 2D NMR spectroscopy

The refolding reaction of S54G/P55N ribonuclease T1 is a two-step process, where fast formation of a partly folded intermediate is followed by the slow reaction to the native state, limited by a trans --> cis isomerization of Pro39. The hydrodynamic radius of this kinetic folding intermediate was determined by real-time diffusion NMR spectroscopy. Its folding to the native state was monitored by a series of 128 very fast 2D (15)N-HMQC spectra, to observe the kinetics of 66 individual backbone amide probes. We find that the intermediate is as compact as the native protein with many native chemical shifts. All 66 analyzed amide probes follow the rate-limiting prolyl isomerization, which indicates that this cooperative refolding reaction is fully synchronized. The stability of the folding intermediate was determined from the protection factors of 45 amide protons derived from a competition between refolding and H/D exchange. The intermediate has already gained 40% of the Gibbs free energy of refolding with many protected amides in not-yet-native regions.     

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.     

Replacement of proline with valine does not remove an apparent proline isomerization-dependent folding event in CRABP I

Site-directed mutagenesis has frequently been used to replace proline with other amino acids in order to determine if proline isomerization is responsible for a slow phase during refolding. Replacement of Pro 85 with alanine in cellular retinoic acid binding protein I (CRABP-I) abolished the slowest refolding phase, suggesting that this phase is due to proline isomerization in the unfolded state. To further test this assumption, we mutated Pro 85 to valine, which is the conservative replacement in the two most closely related proteins in the family (cellular retinoic acid binding protein II and cellular retinol binding protein I). The mutant protein was about 1 kcal/mole more stable than wild type. Retinoic acid bound equally well to wild type and P85V-CRABP I, confirming the functional integrity of this mutation. The refolding and unfolding kinetics of the wild-type and mutant proteins were characterized by stopped flow fluorescence and circular dichroism. The mutant P85V protein refolded with three kinetic transitions, the same number as wild-type protein. This result conflicts with the P85A mutant, which lost the slowest refolding rate. The P85V mutation also lacked a kinetic unfolding intermediate found for wild-type protein. These data suggest that proline isomerization may not be responsible for the slowest folding phase of CRABP I. As such, the loss of a slow refolding phase upon mutation of a proline residue may not be diagnostic for proline isomerization effects on protein folding.     

Folding of ribonuclease T1. 1. Existence of multiple unfolded states created by proline isomerization

It is our aim to elucidate molecular aspects of the mechanism of protein folding. We use ribonuclease T1 as a model protein, because it is a small single-domain protein with a well-defined secondary and tertiary structure, which is stable in the presence and absence of disulfide bonds. Also, an efficient mutagenesis system is available to produce protein molecules with defined sequence variations. Here we present a preliminary characterization of the folding kinetics of ribonuclease T1. Its unfolding and refolding reactions are reversible, which is shown by the quantitative recovery of the catalytic activity after an unfolding/refolding cycle. Refolding is a complex process, where native protein is formed on three distinguishable pathways. There are 3.5% fast-folding molecules, which refold within the millisecond time range, and 96.5% slow-folding species, which regain the native state in the time range of minutes to hours. These slow-folding molecules give rise to two major, parallel refolding reactions. The mixture of fast- and slow-folding molecules is produced slowly after unfolding by chain equilibration reactions that show properties of proline isomerization. We conclude that part of the kinetic complexity of RNase T1 folding can be explained on the basis of the proline model for protein folding. This is supported by the finding that the slow refolding reactions of this protein are accelerated in the presence of the enzyme prolyl isomerase. However, several properties of ribonuclease T1 refolding, such as the dependence of the relative amplitudes on the probes, used to follow folding, are not readily explained by a simple proline model.     

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.     

Effects of proline mutations on the folding of staphylococcal nuclease

Effects of proline isomerizations on the equilibrium unfolding and kinetic refolding of staphylococcal nuclease were studied by circular dichroism in the peptide region (225 nm) and fluorescence spectra of a tryptophan residue. For this purpose, four single mutants (P11A, P31A, P42A, and P56A) and four multiple mutants (P11A/P47T/P117G, P11A/P31A/P47T/P117G, P11A/P31A/P42A/P47T/P117G, and P11A/P31A/P42A/P47T/P56A/P117G) were constructed. These mutants, together with the single and double mutants for Pro47 and Pro117 constructed in our previous study, cover all six proline sites of the nuclease. The P11A, P31A, and P42A mutations did not change the stability of the protein remarkably, while the P56A mutation increased protein stability to a small extent by 0.5 kcal/mol. The refolding kinetics of the protein were, however, affected remarkably by three of the mutations, namely, P11A, P31A, and P56A. Most notably, the amplitude of the slow phase of the triphasic refolding kinetics of the nuclease observed by stopped-flow circular dichroism decreased by increasing the number of the proline mutations; the slow phase disappeared completely in the proline-free mutant (P11A/P31A/P42A/P47T/P56A/P117G). The kinetic refolding reactions of the wild-type protein assessed in the presence of Escherichia coli cyclophilin A showed that the slow phase was accelerated by cyclophilin, indicating that the slow phase was rate-limited by cis-trans isomerization of the proline residues. Although the fast and middle phases of the refolding kinetics were not affected by cyclophilin, the amplitude of the middle phase decreased when the number of the proline mutations increased; the percent amplitudes for the wild-type protein and the proline-free mutants were 43 and 13%, respectively. In addition to these three phases detected with stopped-flow circular dichroism, a very fast phase of refolding was observed with stopped-flow fluorescence, which had a shorter dead time (3.6 ms) than the stopped-flow circular dichroism. The following conclusions were drawn. (1) The effects of the P11A, P31A, and P56A mutations on the refolding kinetics indicate that the isomerizations of the three proline residues are rate-limiting, suggesting that the structures around these residues (Pro11, Pro31, and Pro56) may be organized at an early stage of refolding. (2) The fast phase corresponds to the refolding of the native proline isomer, and the middle phase whose amplitude has decreased when the number of proline mutations was increased may correspond to the slow refolding of non-native proline isomers. The occurrence of the fast- and slow-refolding reactions together with the slow phase rate-limited by the proline isomerization suggests that there are parallel folding pathways for the native and non-native proline isomers. (3) The middle phase did not completely disappear in the proline-free mutant. This suggests that the slow-folding isomer is produced not only by the proline isomerizations but also by another conformational event that is not related to the prolines. (4) The very fast phase detected with the fluorescent measurements suggests that there is an intermediate at a very early stage of kinetic refolding.     

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

The trans----cis isomerization of Pro 93 was measured during refolding of bovine ribonuclease A. This isomerization is slow (tau = 500 s) under marginally stable folding conditions of 2.0 M GdmCl, pH 6, at 10 degrees C. However, it is strongly accelerated (tau = 100 s) in samples which, prior to isomerization, had been converted to a folding intermediate by a 15 s refolding pulse under strongly native conditions (0.8 M ammonium sulfate, 0 degree C). The results demonstrate that extensive folding is possible before Pro 93 isomerizes to its native cis state and that the presence of structural folding intermediates leads to a marked increase in the rate of subsequent proline isomerization.     

Role of the Cys 2-Cys 10 disulfide bond for the structure, stability, and folding kinetics of ribonuclease T1.

The Cys 2-Cys 10 disulfide bond in ribonuclease T1 was broken by substituting Cys 2 and Cys 10 by Ser and Asn, respectively, as present in ribonuclease F1. This C2S/C10N variant resembles the wild-type protein in structure and in catalytic activity. Minor structural changes were observed by 2-dimensional NMR in the local environment of the substituted amino acids only. The thermodynamic stability of ribonuclease T1 is strongly reduced by breaking the Cys 2-Cys 10 bond, and the free energy of denaturation is decreased by about 10 kJ/mol. The folding mechanism is not affected, and the trans to cis isomerizations of Pro 39 and Pro 55 are still the rate-limiting steps of the folding process. The differences in the time courses of unfolding and refolding are correlated with the decrease in stability: the folding kinetics of the wild-type protein and the C2S/C10N variant become indistinguishable when they are compared under conditions of identical stability. Apparently, the Cys 2-Cys 10 disulfide bond is important for the stability but not for the folding mechanism of ribonuclease T1. The breaking of this bond has the same effect on stability and folding kinetics as adding 1 M guanidinium chloride to the wild-type protein.     

Time-resolved FTIR difference spectroscopy as tool for investigating refolding reactions of ribonuclease T1 synchronized with trans --> cis prolyl isomerization

The structurally well-characterized enzyme ribonuclease T1 was used as a model protein to further evaluate time-resolved Fourier transform IR difference spectroscopy in conjunction with temperature-jump techniques as a useful detection technique for protein folding studies. Compared to the wild-type protein, it was confirmed that the lack of one cis-proline bond at position 55 of the S54G/P55N variant is sufficient to significantly simplify and accelerate the refolding process. This result was sustained by the characterization of the early refolding events that occurred within the experimental dead time.     

Folding of ribonuclease T1. 2. Kinetic models for the folding and unfolding reactions

The slow refolding of ribonuclease T1 was investigated by different probes. Structural intermediates with secondary structure are formed early during refolding, as indicated by the rapid regain of a native-like circular dichroism spectrum in the amide region. This extensive structure formation is much faster than the slow steps of refolding, which are limited in rate by the reisomerization of incorrect proline isomers. The transient folding intermediates were also detected by unfolding assays, which make use of the reduced stability of folding intermediates relative to that of the native protein. The results of this and the preceding paper [Kiefhaber et al. (1990) Biochemistry (preceding paper in this issue)] were used to propose kinetic models for the unfolding and refolding of ribonuclease T1. The unfolding mechanism is based on the assumption that, after the structural unfolding step, the slow isomerizations of two X-Pro peptide bonds occur independently of each other in the denatured protein. At equilibrium a small amount of fast-folding species coexists with three slow-folding species: two with one incorrect proline isomer each and another, dominant species with both these prolines in the incorrect isomeric state. In the mechanism for refolding we assume that all slow-folding molecules can rapidly regain most of the secondary and part of the tertiary structure early in folding. Reisomerizations of incorrect proline peptide bonds constitute the slow, rate-limiting steps of refolding. A peculiar feature of the kinetic model for refolding is that the major unfolded species with two incorrect proline isomers can enter two alternative folding pathways, depending on which of the two reisomerizes first. The relative rates of reisomerization of the respective proline peptide bonds at the stage of the rapidly formed intermediate determine the choice of pathway. It is changed in the presence of prolyl isomerase, because this enzyme catalyzes these two isomerizations with different efficiency and consequently leads to a shift from the very slow to the intermediate refolding pathway.     

Enzymatic catalysis of prolyl isomerization in an unfolding protein.

Prolyl isomerases are able to accelerate slow steps in protein refolding that are limited in rate by cis/trans isomerizations of Xaa-Pro peptide bonds. We show here that prolyl isomerizations in the course of protein unfolding are also well catalyzed. To demonstrate catalysis we use cytoplasmic prolyl isomerase from Escherichia coli as the enzyme and reduced and carboxymethylated ribonuclease T1 as the substrate. This form of ribonuclease T1 without disulfide bonds is nativelike folded only in the presence of moderate concentrations of NaCl. Unfolding can be induced by reducing the NaCl concentration at ambient temperature and in the absence of denaturants. Under these conditions prolyl isomerase retains its activity and it catalyzes prolyl cis/trans isomerization in the unfolding protein. Under identical conditions within the NaCl-induced transition unfolding and refolding are catalyzed with equal efficiency. The stability of the protein and thus the final distribution of unfolded and folded molecules attained at equilibrium is unchanged in the presence of prolyl isomerase. These results demonstrate that prolyl isomerase functions in protein folding as an enzyme and catalyzes prolyl isomerization in either direction.     

New structural insights into the refolding of ribonuclease T1 as seen by time-resolved Fourier-transform infrared spectroscopy

To get new structural insights into different phases of the renaturation of ribonuclease T1 (RNase T1), the refolding of the thermally unfolded protein was initiated by rapid temperature jumps and detected by time-resolved Fourier-transform infrared spectroscopy. The characteristic spectral changes monitoring the formation of secondary structure and tertiary contacts were followed on a time scale of 10(-3) to 10(3) seconds permitting the characterization of medium and slow folding reactions. Additionally, structural information on the folding events that occurred within the experimental dead time was indirectly accessed by comparative analysis of kinetic and steady-state refolding data. At slightly destabilizing refolding temperatures of 45 degrees C, which is close to the unfolding transition region, no specific secondary or tertiary structure is formed within 180 ms. After this delay all infrared markers bands diagnostic for individual structural elements indicate a strongly cooperative and relatively fast folding, which is not complicated by the accumulation of intermediates. At strongly native folding temperatures of 20 degrees C, a folding species of RNase T1 is detected within the dead time, which already possesses significant amounts of antiparallel beta-sheets, turn structures, and to some degree tertiary contacts. The early formed secondary structure is supposed to comprise the core region of the five-stranded beta-sheet. Despite these nativelike characteristics the subsequent refolding events are strongly heterogeneous and slow. The refolding under strongly native conditions is completed by an extremely slow formation or rearrangement of a locally restricted beta-sheet region accompanied by the further consolidation of turns and denser backbone packing. It is proposed that these late events comprise the final packing of strand 1 (residues 40-42) of the five-stranded beta-sheet against the rest of this beta-sheet system within an otherwise nativelike environment. This conclusion was supported by the comparison of refolding of RNase T1 and its variant W59Y RNase T1 that enabled the assignment of these very late events to the trans-->cis isomerization reaction of the prolyl peptide bond preceding Pro-39.     

Identification of three phases in Onconase refolding

Onconase is an extremely stable member of the RNase A superfamily. The increase in the thermodynamic stability by 20 kJ x mol(-1) in comparison to RNase A was expected to result in altered folding behavior. Despite the lack of cis-Pro residues in native Onconase, refolding at low concentrations of guanidine hydrochloride was complex and showed three kinetic phases (fast, medium, and slow), with rate constants differing by a factor of about 10 each. None of the phases could be accelerated by peptidyl-prolyl cis-trans isomerases, pointing to the absence of kinetic phases that are limited by Pro isomerization. The detailed analysis by various probes indicates that the burial of the N-terminal Trp3, which is associated with the restoration of the active site, occurs in the slow phase, i.e. in the last step of refolding. Evidently, in contrast to the folding of RNase A, there is no catalytically active native-like intermediate in the folding of Onconase.     

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.     

Kinetic coupling of folding and prolyl isomerization of beta2-microglobulin studied by mutational analysis

β₂-Microglobulin (β2-m), a protein responsible for dialysis-related amyloidosis, adopts a typical immunoglobulin domain fold with the N-terminal peptide bond of Pro32 in a cis isomer. The refolding of β2-m is limited by the slow trans-to-cis isomerization of Pro32, implying that intermediates with a non-native trans-Pro32 isomer are precursors for the formation of amyloid fibrils. To obtain further insight into the Pro-limited folding of β2-m, we studied the Gdn-HCl-dependent unfolding/refolding kinetics using two mutants (W39 and P32V β2-ms) as well as the wild-type β2-m. W39 β2-m is a triple mutant in which both of the authentic Trp residues (Trp60 and Trp95) are replaced by Phe and a buried Trp common to other immunoglobulin domains is introduced at the position of Leu39 (i.e., L39W/W60F/W95F). W39 β2-m exhibits a dramatic quenching of fluorescence upon folding, enabling a detailed analysis of Pro-limited unfolding/refolding. On the other hand, P32V β2-m is a mutant in which Pro32 is replaced by Val, useful for probing the kinetic role of the trans-to-cis isomerization of Pro32. A comparative analysis of the unfolding/refolding kinetics of these mutants including three types of double-jump experiments revealed the prolyl isomerization to be coupled with the conformational transitions, leading to apparently unusual kinetics, particularly for the unfolding. We suggest that careful consideration of the kinetic coupling of unfolding/refolding and prolyl isomerization, which has tended to be neglected in recent studies, is essential for clarifying the mechanism of protein folding and, moreover, its biological significance.     

Cis proline mutants of ribonuclease A. II. Elimination of the slow-folding forms by mutation.

Ribonuclease A is known to form an equilibrium mixture of fast-folding (UF) and slow-folding (US) species. Rapid unfolding to UF is then followed by a reaction in the unfolded state, which produces a mixture of UF, USII, USI, and possibly also minor populations of other US species. The two cis proline residues, P93 and P114, are logical candidates for producing the major US species after unfolding, by slow cis <==> trans isomerization. Much work has been done in the past on testing this proposal, but the results have been controversial. Site-directed mutagenesis is used here. Four single mutants, P93A, P93S, P114A, and P114G, and also the double mutant P93A, P114G have been made and tested for the formation of US species after unfolding. The single mutants P114G and P114A still show slow isomerization reactions after unfolding that produce US species; thus, Pro 114 is not required for the formation of at least one of the major US species of ribonuclease A. Both the refolding kinetics and the isomerization kinetics after unfolding of the Pro 93 single mutants are unexpectedly complex, possibly because the substituted amino acid forms a cis peptide bond, which should undergo cis --> trans isomerization after unfolding. The kinetics of peptide bond isomerization are not understood at present and the Pro 93 single mutants cannot be used yet to investigate the role of Pro 93 in forming the US species of ribonuclease A. The double mutant P93A, P114G shows single exponential kinetics measured by CD, and it shows no evidence of isomerization after unfolding.(ABSTRACT TRUNCATED AT 250 WORDS)     

A proline switch controls folding and domain interactions in the gene-3-protein of the filamentous phage fd

The amino-terminal domains N1 and N2 of the gene-3-protein of phage fd form a bilobal structural and functional entity that protrudes from the phage tip. Domain N2 initiates the infection of Escherichia coli by binding to the F pilus. This binding results in the dissociation of the two domains and allows N1 to interact with the TolA receptor at the cell surface. The refolding of the N1-N2 fragment begins with the folding of domain N1, which takes a few milliseconds, followed by the folding of domain N2, which is complete within five minutes. The subsequent domain assembly is unusually slow and shows a time-constant of 6200 s at 25 degrees C. We found that the rate of this reaction is controlled by the trans to cis isomerization of the Gln212-Pro213 bond in the hinge subdomain of N2, a region that provides many interactions between N1 and N2 in the gene-3-protein. The substitution of Pro213 by Gly accelerated domain association 30-fold and revealed that the folding of the two individual domains and their assembly are indeed sequential steps in the refolding of the gene-3-protein. In the course of infection, the domains must separate to expose the binding site for TolA on domain N1. The kinetic block of domain reassembly caused by Pro213 isomerization could ensure that after the initial binding of N2 to the F pilus the open state persists until N1 and TolA are close enough for their mutual interaction. Pro213 isomerization might thus serve as a slow conformational switch in the function of the gene-3-protein.     

Conformational stability and mechanism of folding of ribonuclease T1

Urea and thermal unfolding curves for ribonuclease T1 (RNase T1) were determined by measuring several different physical properties. In all cases, steep, single-step unfolding curves were observed. When these results were analyzed by assuming a two-state folding mechanism, the plots of fraction unfolded protein versus denaturant were coincident. The dependence of the free energy of unfolding, delta G (in kcal/mol), on urea concentration is given by delta G = 5.6 - 1.21 (urea). The parameters characterizing the thermodynamics of unfolding are: midpoint of the thermal unfolding curve, Tm = 48.1 degrees C, enthalpy change at Tm, delta Hm = 97 kcal/mol, and heat capacity change, delta Cp = 1650 cal/mol deg. A single kinetic phase was observed for both the folding and unfolding of RNase T1 in the transition and post-transition regions. However, two slow kinetic phases were observed during folding in the pre-transition region. These two slow phases account for about 90% of the observed amplitude, indicating that a faster kinetic phase is also present. The slow phases probably result from cis-trans isomerization at the 2 proline residues that have a cis configuration in folded RNase T1. These results suggest that RNase T1 folds by a highly cooperative mechanism with no structural intermediates once the proline residues have assumed their correct isomeric configuration. At 25 degrees C, the folded conformation is more stable than the unfolded conformations by 5.6 kcal/mol at pH 7 and by 8.9 kcal/mol at pH 5, which is the pH of maximum stability. At pH 7, the thermodynamic data indicate that the maximum conformational stability of 8.3 kcal/mol will occur at -6 degrees C.     

Characterization of the folding and unfolding reactions of single-chain monellin: evidence for multiple intermediates and competing pathways

The mechanisms of folding and unfolding of the small plant protein monellin have been delineated in detail. For this study, a single-chain variant of the natively two-chain monellin, MNEI, was used, in which the C terminus of chain B was connected to the N terminus of chain A by a Gly-Phe linker. Equilibrium guanidine hydrochloride (GdnHCl)-induced unfolding experiments failed to detect any partially folded intermediate that is stable enough to be populated at equilibrium to a significant extent. Kinetic experiments in which the refolding of GdnHCl-unfolded protein was monitored by measurement of the change in the intrinsic tryptophan fluorescence of the protein indicated the accumulation of three transient partially structured folding intermediates. The fluorescence change occurred in three kinetic phases: very fast, fast, and slow. It appears that the fast and slow changes in fluorescence occur on competing folding pathways originating from one unfolded form and that the very fast change in fluorescence occurs on a third parallel pathway originating from a second unfolded form of the protein. Kinetic experiments in which the refolding of alkali-unfolded protein was monitored by the change in the fluorescence of the hydrophobic dye 8-anilino-1-naphthalenesulfonic acid (ANS), consequent to the dye binding to the refolding protein, as well as by the change in intrinsic tryptophan fluorescence, not only confirmed the presence of the three kinetic intermediates but also indicated the accumulation of one or more early intermediates at a few milliseconds of refolding. These experiments also exposed a very slow kinetic phase of refolding, which was silent to any change in the intrinsic tryptophan fluorescence of the protein. Hence, the spectroscopic studies indicated that refolding of single-chain monellin occurs in five distinct kinetic phases. Double-jump, interrupted-folding experiments, in which the accumulation of folding intermediates and native protein during the folding process could be determined quantitatively by an unfolding assay, indicated that the fast phase of fluorescence change corresponds to the accumulation of two intermediates of differing stabilities on competing folding pathways. They also indicated that the very slow kinetic phase of refolding, identified by ANS binding, corresponds to the formation of native protein. Kinetic experiments in which the unfolding of native protein in GdnHCl was monitored by the change in intrinsic tryptophan fluorescence indicated that this change occurs in two kinetic phases. Double-jump, interrupted-unfolding experiments, in which the accumulation of unfolding intermediates and native protein during the unfolding process could be determined quantitatively by a refolding assay, indicated that the fast unfolding phase corresponds to the formation of fully unfolded protein via one unfolding pathway and that the slow unfolding phase corresponds to a separate unfolding pathway populated by partially unfolded intermediates. It is shown that the unfolded form produced by the fast unfolding pathway is the one which gives rise to the very fast folding pathway and that the unfolded form produced by the slower unfolding pathway is the one which gives rise to the slow and fast folding pathways.     

Intramolecular catalysis of a proline isomerization reaction in the folding of dihydrofolate reductase.

The cis/trans isomerization of the peptide bond preceding proline residues in proteins can limit the rate at which a protein folds to its native conformation. Mutagenic analyses of dihydrofolate reductase (DHFR) from Escherichia coli show that this isomerization reaction can be intramolecularly catalyzed by a side chain from an amino acid which is distant in sequence but adjacent in the native conformation. The guanidinium NH2 nitrogen of Arg 44 forms one hydrogen bond to the imide nitrogen and a second to the carbonyl oxygen of Pro 66 in wild-type DHFR. Replacement of Arg 44 with Leu results in a change of the nature of the two slow steps in refolding from being limited by the acquisition of secondary and/or tertiary structure to being limited by isomerization. The simultaneous replacement of Pro 66 with Ala (i.e., the Leu 44/Ala 66 double mutant) eliminates this isomerization reaction and once again makes protein folding the limiting process. Apparently, one or both of the hydrogen bonds between Arg 44 and Pro 66 accelerate the isomerization of the Gln 65-Pro 66 peptide bond. The replacement of Arg 44 with Leu affects the kinetics of the slow folding reactions in a fashion which indicates that the crucial hydrogen bonds form in the transition states for the rate-limiting steps in folding.