Coupled kinetic traps in cytochrome c folding: His-heme misligation and proline isomerization

The effect of His-heme misligation on folding has been investigated for a triple mutant of yeast iso-2 cytochrome c (N26H,H33N,H39K iso-2). The variant contains a single misligating His residue at position 26, a location at which His residues are found in several cytochrome c homologues, including horse, tuna, and yeast iso-1. The amplitude for fast phase folding exhibits a strong initial pH dependence. For GdnHCl unfolded protein at an initial pH<5, the observed refolding at final pH 6 is dominated by a fast phase (tau(2f)=20 ms, alpha(2f)=90 %) that represents folding in the absence of misligation. For unfolded protein at initial pH 6, folding at final pH 6 occurs in a fast phase of reduced amplitude (alpha(2f) approximately 20 %) but the same rate (tau(2f)=20 ms), and in two slower phases (tau(m)=6-8 seconds, alpha(m) approximately 45 %; and tau(1b)=16-20 seconds, alpha(1b) approximately 35 %). Double jump experiments show that the initial pH dependence of the folding amplitudes results from a slow pH-dependent equilibrium between fast and slow folding species present in the unfolded protein. The slow equilibrium arises from coupling of the His protonation equilibrium to His-heme misligation and proline isomerization. Specifically, Pro25 is predominantly in trans in the unligated low-pH unfolded protein, but is constrained in a non-native cis isomerization state by His26-heme misligation near neutral pH. Refolding from the misligated unfolded form proceeds slowly due to the large energetic barrier required for proline isomerization and displacement of the misligated His26-heme ligand.     

Folding of yeast iso-1-AM cytochrome c

We describe a specific modification of iso-1 cytochrome c which results in blocking a single free sulfhydryl group. The derivative differs from the unmodified protein by the introduction of a small, uncharged group, thus maintaining the same charge balance as the native protein. The modified protein, obtained by treatment of iso-1 cytochrome c with iodoacetamide, has an activity indistinguishable from that of the unmodified protein in the lactate dehydrogenase-cytochrome c reductase system from yeast and has the same stability toward denaturation by guanidine hydrochloride. The kinetics of fluorescence changes associated with the guanidine hydrochloride induced folding-unfolding transition for modified iso-1 cytochrome c (iso-1-AM) have been investigated throughout the transition zone by using stopped-flow mixing. The results are compared to those for the yeast isozyme, iso-2 cytochrome c. The main features of the fluorescence-detected folding kinetics are similar, as might be expected for homologous proteins; however, the limiting value of the fraction of fast refolding protein (alpha 2) below the transition zone is smaller for iso-1-AM (approximately 0.7) than for iso-2 (approximately 0.9).     

Native or nativelike species are transient intermediates in folding of alkaline iso-2 cytochrome c

Titration to high pH converts yeast iso-2 cytochrome c to an inactive but more stable alkaline form lacking a 695-nm absorbance band [Osterhout, J. J., Jr., Muthukrishnan, K., & Nall, B. T. (1985) Biochemistry 24, 6680-6684]. The kinetics of absorbance-detected refolding of the alkaline form have been measured by dilution of guanidine hydrochloride in a stopped-flow instrument. Fast-folding species (tau 2) are detected, as in refolding to the native state at neutral pH. An additional kinetic phase (tau a) is observed with an amplitude opposite in sign to the fast phase. The amplitude of this phase increases and the rate increases with increasing pH. Comparison to pH-jump measurements of the fully folded protein shows that phase tau a has the same sign, rate, and pH dependence as the alkaline isomerization reaction, suggesting that this new phase involves isomerization of native or nativelike species following fast folding. Absorbance difference spectra are taken at 5-s intervals during refolding at high pH. The spectra verify that nativelike species--with a 695-nm absorbance band--are formed transiently, before conversion of the protein to the alkaline form. Refolding in the presence of ascorbate shows that the transient, nativelike species are reducible, unlike alkaline iso-2. Thus, (1) refolding to the alkaline form of iso-2 cytochrome c proceeds through transient native or nativelike species, and (2) a folding pathway leading to native or nativelike forms is maintained at high pH, where native species are no longer the thermodynamically favored product.(ABSTRACT TRUNCATED AT 250 WORDS)     

Fast folding of cytochrome c.

Native iso-2 cytochrome c contains two residues (His 18, Met 80) coordinated to the covalently attached heme. On unfolding of iso-2, the His 18 ligand remains coordinated to the heme iron, whereas Met 80 is displaced by a non-native heme ligand, His 33 or His 39. To test whether non-native His-heme ligation slows folding, we have constructed a double mutant protein in which the non-native ligands are replaced by asparagine and lysine, respectively (H33N,H39K iso-2). The double mutant protein, which cannot form non-native histidine-heme coordinate bonds, folds significantly faster than normal iso-2 cytochrome c: gamma = 14-26 ms for H33N,H39K iso-2 versus gamma = 200-1,100 ms for iso-2. These results with iso-2 cytochrome c strongly support the hypothesis that non-native His-heme ligation results in a kinetic barrier to fast folding of cytochrome c. Assuming that the maximum rate of a conformational search is about 10(11) s-1, the results imply that the direct folding pathway of iso-2 involves passage through on the order of 10(9) or fewer partially folded conformers.     

Cytochrome c folds through a smooth funnel

A dominant feature of folding of cytochrome c is the presence of nonnative His-heme kinetic traps, which either pre-exist in the unfolded protein or are formed soon after initiation of folding. The kinetically trapped species can constitute the majority of folding species, and their breakdown limits the rate of folding to the native state. A temperature jump (T-jump) relaxation technique has been used to compare the unfolding/folding kinetics of yeast iso-2 cytochrome c and a genetically engineered double mutant that lacks His-heme kinetic traps, H33N,H39K iso-2. The results show that the thermodynamic properties of the transition states are very similar. A single relaxation time tau(obs) is observed for both proteins by absorbance changes at 287 nm, a measure of solvent exclusion from aromatic residues. At temperatures near Tm, the midpoint of the thermal unfolding transitions, tau(obs) is four to eight times faster for H33N,H39K iso-2 (tau(obs) approximately 4-10 ms) than for iso-2 (tau(obs) approximately 20-30 ms). T-jumps show that there are no kinetically unresolved (tau < 1-3 micros T-jump dead time) "burst" phases for either protein. Using a two-state model, the folding (k(f)) and unfolding (k(u)) rate constants and the thermodynamic activation parameters standard deltaGf, standard deltaGu, standard deltaHf, standard deltaHu, standard deltaSf, standard deltaSu are evaluated by fitting the data to a function describing the temperature dependence of the apparent rate constant k(obs) (= tau(obs)(-1)) = k(f) + k(u). The results show that there is a small activation enthalpy for folding, suggesting that the barrier to folding is largely entropic. In the "new view," a purely entropic kinetic barrier to folding is consistent with a smooth funnel folding landscape.     

Refolding rate of stability-enhanced cytochrome c is independent of thermodynamic driving force.

N52I iso-2 cytochrome c is a variant of yeast iso-2 cytochrome c in which asparagine substitutes for isoleucine 52 in an alpha helical segment composed of residues 49-56. The N52I substitution results in a significant increase in both stability and cooperativity of equilibrium unfolding, and acts as a "global suppressor" of destabilizing mutations. The equilibrium m-value for denaturant-induced unfolding of N52I iso-2 increases by 30%, a surprisingly large amount for a single residue substitution. The folding/unfolding kinetics for N52I iso-2 have been measured by stopped-flow mixing and by manual mixing, and are compared to the kinetics of folding/unfolding of wild-type protein, iso-2 cytochrome c. The results show that the observable folding rate and the guanidine hydrochloride dependence of the folding rate are the same for iso-2 and N52I iso-2, despite the greater thermodynamic stability of N52I iso-2. Thus, there is no linear free-energy relationship between mutation-induced changes in stability and observable refolding rates. However, for N52I iso-2 the unfolding rate is slower and the guanidine hydrochloride dependence of the unfolding rate is smaller than for iso-2. The differences in the denaturant dependence of the unfolding rates suggest that the N52I substitution decreases the change in the solvent accessible hydrophobic surface between the native state and the transition state. Two aspects of the results are inconsistent with a two-state folding/unfolding mechanism and imply the presence of folding intermediates: (1) observable refolding rate constants calculated from the two-state mechanism by combining equilibrium data and unfolding rate measurements deviate from the observed refolding rate constants; (2) kinetically unresolved signal changes ("burst phase") are observed for both N52I iso-2 and iso-2 refolding. The "burst phase" amplitude is larger for N52I iso-2 than for iso-2, suggesting that the intermediates formed during the "burst phase" are stabilized by the N52I substitution.     

Measuring denatured state energetics: deviations from random coil behavior and implications for the folding of iso-1-cytochrome c

The changes in the free energy of the denatured state of a set of yeast iso-1-cytochrome c variants with single surface histidine residues have been measured in 3 M guanidine hydrochloride. The thermodynamics of unfolding by guanidine hydrochloride is also reported. All variants have decreased stability relative to the wild-type protein. The free energy of the denatured state was determined in 3 M guanidine hydrochloride by evaluating the strength of heme-histidine ligation through determination of the pK(a) for loss of histidine binding to the heme. The data are corrected for the presence of the N-terminal amino group which also ligates to the heme under similar solution conditions. Significant deviations from random coil behavior are observed. Relative to a variant with a single histidine at position 26, residual structure of the order of -1.0 to -2.5 kcal/mol is seen for the other variants studied. The data explain the slower folding of yeast iso-1-cytochrome c relative to the horse protein. The greater number of histidines and the greater strength of ligation are expected to slow conversion of the histidine-misligated forms to the obligatory aquo-heme intermediate during the ligand exchange phase of folding. The particularly strong association of histidine residues at positions 54 and 89 may indicate regions of the protein with strong energetic propensities to collapse against the heme during early folding events, consistent with available data in the literature on early folding events for cytochrome c.     

Multiple folding pathways for the P4-P6 RNA domain

We recently described site-specific pyrene labeling of RNA to monitor Mg(2+)-dependent equilibrium formation of tertiary structure. Here we extend these studies to follow the folding kinetics of the 160-nucleotide P4-P6 domain of the Tetrahymena group I intron RNA, using stopped-flow fluorescence with approximately 1 ms time resolution. Pyrene-labeled P4-P6 was prepared using a new phosphoramidite that allows high-yield automated synthesis of oligoribonucleotides with pyrene incorporated at a specific 2'-amino-2'-deoxyuridine residue. P4-P6 forms its higher-order tertiary structure rapidly, with k(obs) = 15-31 s(-1) (t(1/2) approximately 20-50 ms) at 35 degrees C and [Mg(2+)] approximately 10 mM in Tris-borate (TB) buffer. The folding rate increases strongly with temperature from 4 to 45 degrees C, demonstrating a large activation enthalpy DeltaH(double dagger) approximately 26 kcal/mol; the activation entropy DeltaS(double dagger) is large and positive. In low ionic strength 10 mM sodium cacodylate buffer at 35 degrees C, a slow (t(1/2) approximately 1 s) folding component is also observed. The folding kinetics are both ionic strength- and temperature-dependent; the slow phase vanishes upon increasing [Na(+)] in the cacodylate buffer, and the kinetics switch completely from fast at 30 degrees C to slow at 40 degrees C. Using synchrotron hydroxyl radical footprinting, we confirm that fluorescence monitors the same kinetic events as hydroxyl radical cleavage, and we show that the previously reported slow P4-P6 folding kinetics apply only to low ionic strength conditions. One model to explain the fast and slow folding kinetics postulates that some tertiary interactions are present even without Mg(2+) in the initial state. The fast kinetic phase reflects folding that is facilitated by these interactions, whereas the slow kinetics are observed when these interactions are disrupted at lower ionic strength and higher temperature.     

Compressing the free energy range of substructure stabilities in iso‐1‐cytochrome c

Evolutionary conservation of substructure architecture between yeast iso-1-cytochrome c and the well-characterized horse cytochrome c is studied with limited proteolysis, the alkaline conformational transition and global unfolding with guanidine-HCl. Mass spectral analysis of limited proteolysis cleavage products for iso-1-cytochrome c show that its least stable substructure is the same as horse cytochrome c. The limited proteolysis data yield a free energy of 3.8 ± 0.4 kcal mol⁻¹ to unfold the least stable substructure compared with 5.05 ± 0.30 kcal mol⁻¹ for global unfolding of iso-1-cytochrome c. Thus, substructure stabilities of iso-1-cytochrome c span only ∼1.2 kcal mol⁻¹ compared with ∼8 kcal mol⁻¹ for horse cytochrome c. Consistent with the less cooperative folding thus expected for the horse protein, the guanidine-HCl m-values are ∼3 kcal mol⁻¹M⁻¹ versus ∼4.5 kcal mol⁻¹M⁻¹ for horse versus yeast cytochrome c. The tight free energy spacing of the yeast cytochrome c substructures suggests that its folding has more branch points than for horse cytochrome c. Studies on a variant of iso-1-cytochrome c with an H26N mutation indicate that the least and most stable substructures unfold sequentially and the two least stable substructures unfold independently as for horse cytochrome c. Thus, important aspects of the substructure architecture of horse cytochrome c, albeit compressed energetically, are preserved evolutionally in yeast iso-1-cytochrome c.     

pH dependence of folding of iso-2-cytochrome c

Starting from a standard unfolded state (3.0 M guanidine hydrochloride, pH 7.2), the kinetics of refolding of iso-2-cytochrome c have been investigated as a function of final pH between pH 3 and pH 10. Absorbance in the ultraviolet and visible spectral regions and tryptophan fluorescence are used to monitor folding. Over most of the pH range, fast and slow folding phases are detected by both fluorescence and absorbance probes. Near neutral pH, the rate of fast folding appears to be the same when monitored by absorbance and fluorescence probes. At higher and lower pH, there are two fast folding reactions, with absorbance-detected fast folding occurring in a slightly faster time range than fluorescence-detected fast folding. The rates of both fast folding reactions pass through broad minima near neutral pH, indicating involvement of ionizable groups in rate-limiting steps. The rates of slow folding also depend on the final pH. At acid pH, there appears to be a single slow folding phase for both fluorescence and absorbance probes. At neutral pH, the absorbance-detected and fluorescence-detected slow folding phases separate into distinct kinetic processes which differ in rate and relative amplitude. At high pH, absorbance-detected slow folding is no longer observed, while fluorescence-detected slow folding is decreased in amplitude. In contrast, the equilibrium and kinetic properties of proline imide bond isomerization, believed to be involved in the slow folding reactions, are largely independent of pH. The results suggest that the pH dependence of slow folding involves coupling of pH-sensitive structure to proline imide bond isomerization.(ABSTRACT TRUNCATED AT 250 WORDS)     

Fast folding of the HIV-1 and SIV gp41 six-helix bundles

Human (HIV-1) and simian (SIV) immunodeficiency virus fusion with the host cell is promoted by the receptor-triggered refolding of the gp41 envelope protein into a stable trimer-of-hairpins structure that brings viral and cellular membranes into close proximity. The core of this hairpin structure is a six-helix bundle in which an inner homotrimeric coiled coil is buttressed by three antiparallel outer HR2 helices. We have used stopped-flow circular dichroism spectroscopy to characterize the unfolding and refolding kinetics of the six-helix bundle using the HIV-1 and SIV N34(L6)C28 polypeptides. In each case, the time-course of ellipticity changes in refolding experiments is well described by a simple two-state model involving the native trimer and the unfolded monomers. The unfolding free energy of the HIV-1 and SIV trimers and their urea dependence calculated from kinetic data are in very good agreement with data measured directly by isothermal unfolding experiments. Thus, formation of the gp41 six-helix bundle structure involves no detectable population of stable, partly folded intermediates. Folding of HIV-1 N34(L6)C28 is five orders of magnitudes faster than folding of its SIV counterpart in aqueous buffer: k(on),(HIV-1)=1.3 x 10(15)M(-2)s(-1) versus k(on),(SIV)=1.1 x 10(10)M(-2)s(-1). The unfolding rates are similar: k(off),(HIV-1)=1.1 x 10(-5)s(-1) versus k(off),(SIV=)5.7 x 10(-4)s(-1). Kinetic m-values indicate that the transition state for folding of the HIV-1 protein is significantly more compact than the transition state of the SIV protein. Replacement of a single SIV threonine by isoleucine corresponding to position 573 in the HIV-1 sequence significantly stabilizes the protein and renders the folding rate close to that of the HIV-1 protein yet without making the transition state of the mutant as compact as that of the HIV-1 protein. Therefore, the overall reduction of surface exposure in the high-energy transition state seems not to account for different folding rates. While the available biological evidence suggests that refolding of the gp41 protein is slow, our study implies that structural elements outside the trimer-of-hairpins limit the rate of HIV-1 fusion kinetics.     

Design of a ruthenium-labeled cytochrome c derivative to study electron transfer with the cytochrome bc1 complex

A new ruthenium-cytochrome c derivative was designed to study electron transfer from cytochrome bc1 to cytochrome c (Cc). The single sulfhydryl on yeast H39C;C102T iso-1-Cc was labeled with Ru(2,2'-bipyrazine)2(4-bromomethyl-4'-methyl-2,2'-bipyridine) to form Ru(z)-39-Cc. The Ru(z)-39-Cc derivative has the same steady-state activity with yeast cytochrome bc1 as wild-type yeast iso-1-Cc, indicating that the ruthenium complex does not interfere in the binding interaction. Laser excitation of reduced Ru(z)-39-Cc results in electron transfer from heme c to the excited state of ruthenium with a rate constant of 1.5 x 10(6) x s(-1). The resulting Ru(I) is rapidly oxidized by atmospheric oxygen in the buffer. The yield of photooxidized heme c is 20% in a single flash. Flash photolysis of a 1:1 complex between reduced yeast cytochrome bc1 and Ru(z)-39-Cc at low ionic strength leads to rapid photooxidation of heme c, followed by intracomplex electron transfer from cytochrome c1 to heme c with a rate constant of 1.4 x 10(4) x s(-1). As the ionic strength is raised above 100 mM, the intracomplex phase disappears, and a new phase appears due to the bimolecular reaction between solution Ru-39-Cc and cytochrome bc1. The interaction of yeast Ru-39-Cc with yeast cytochrome bc1 is stronger than that of horse Ru-39-Cc with bovine cytochrome bc1, suggesting that nonpolar interactions are stronger in the yeast system.     

Changes in conformation and slow refolding kinetics in mutant iso-2-cytochrome c with replacement of a conserved proline residue

Using oligonucleotide-directed mutagenesis, we have produced a mutant form of iso-2-cytochrome c of yeast in which threonine (Thr-71) replaces a conserved proline residue (Pro-71) located between two short alpha-helical segments in the native protein. Optical spectroscopy indicates that, at pH 7.2, Thr-71 iso-2-cytochrome c folds to a nonnative conformation possibly related to the alkaline form of the native protein. On titration to pH 5.2, Thr-71 iso-2-cytochrome c regains many of the optical properties of the normal protein. We have shown that the proline residue at position 71 has no effect on the kinetics of fluorescence-detected slow refolding. However, between pH 5 and pH 7.2 the amplitude for absorbance-detected slow folding is strongly pH dependent in the mutant protein but is largely independent of pH in the normal protein. We believe this to be due to the folding of Thr-71 iso-2-cytochrome c to a nonnative conformation at pH 7.2 that does not require the slow, absorbance-detected conformational changes observed in folding to the more native-like state at pH 5-6.     

Structural intermediates in folding of yeast iso-2 cytochrome c

The kinetic properties of the folding reactions of iso-2 cytochrome c from Saccharomyces cerevisiae have been investigated by stopped-flow and temperature-jump methods. Three different structural probes are compared: (1) absorbance changes in the visible reflecting changes in heme environment, (2) ultraviolet absorbance changes due to the exposure of aromatic groups to solvent, and (3) tryptophan fluorescence attributable principally to the average distance between the tryptophan residue (donor) and the heme (quencher). In addition, two probes either indicative of or correlated with function, ascorbic acid reducibility and the 695-nm absorbance band, have been used to monitor specifically the rate of formation of the native protein on refolding. The fastest phase observed (tau 3) has a measurable relative amplitude only when monitored by visible absorbance changes, suggesting that this reaction involves changes in heme environment in the absence of significant changes in the heme to tryptophan distance or in the extent to which aromatic groups are exposed to solvent. Different slow phases are observed when complete refolding is monitored by visible or ultraviolet absorbance (tau 1a) as opposed to tryptophan fluorescence (tau 1b), the fluorescence changes being complete on a time scale 4-8-fold faster than for absorbance. A mid-range kinetic phase (tau 2) is detected by all three structural probes. When ascorbic acid reducibility or 695-nm absorbance changes are used to monitor the rate of formation of the native protein, two phases are detected: tau 2 and tau 1a. Taken together these results demonstrate that kinetic phase tau 1b results in the formation of a structural intermediate in folding with fluorescence close to that of the native protein but with distinct absorbance properties.     

Formation of electrostatically-stabilized complex at low ionic strength inhibits interprotein electron transfer between yeast cytochrome c and cytochrome c peroxidase

Electron transfer from yeast ferrous cytochrome c to H2O2-oxidized yeast cytochrome c peroxidase has been studied using flash photoreduction methods. At low ionic strength (mu less than 10 mM), where a strong complex is formed between cytochrome c and peroxidase, electron transfer occurs rather slowly (k approximately 200s-1). However, at high ionic strength where the electrostatic complex is largely dissociated, the observed first-order rate constant for peroxidase reduction increases significantly reaching a concentration independent limit of k approximately 1500 s-1. Thus, at least in some cases, formation of an electrostatically-stabilized complex can actually impede electron transfer between proteins.     

Observation of multistate kinetics during the slow folding and unfolding of barstar.

The kinetics of the slow folding and unfolding reactions of barstar, a bacterial ribonuclease inhibitor protein, have been studied at 23(+/-1) degrees C, pH 8, by the use of tryptophan fluorescence, far-UV circular dichroism (CD), near-UV CD, and transient mixing (1)H nuclear magnetic resonance (NMR) spectroscopic measurements in the 0-4 M range of guanidine hydrochloride (GdnHCl) concentration. The denaturant dependences of the rates of folding and unfolding processes, and of the initial and final values of optical signals associated with these kinetic processes, have been determined for each of the four probes of measurement. Values determined for rates as well as amplitudes are shown to be very much probe dependent. Significant differences in the intensities and rates of appearance and disappearance of several resolved resonances in the real-time one-dimensional NMR spectra have been noted. The NMR spectra also show increasing dispersion of chemical shifts during the slow phase of refolding. The denaturant dependences of rates display characteristic folding chevrons with distinct rollovers under strongly native as well as strongly unfolding conditions. Analyses of the data and comparison of the results obtained with different probes of measurement appear to indicate the accumulation of a myriad of intermediates on parallel folding and unfolding pathways, and suggest the existence of an ensemble of transition states. The energetic stabilities of the intermediates estimated from kinetic data suggest that they are approximately half as stable as the fully folded protein. The slowness of the folding and unfolding processes (tau = 10-333 s) and values of 20.5 (+/-1.4) and 18 (+/-0.5) kcal mol(-)(1) for the activation energies of the slow refolding and unfolding reactions suggest that proline isomerization is involved in these reactions, and that the intermediates accumulate and are therefore detectable because the slow proline isomerization reaction serves as a kinetic trap during folding.     

Characterization of a covalently linked yeast cytochrome c-cytochrome c peroxidase complex: evidence for a single, catalytically active cytochrome c binding site on cytochrome c peroxidase

A covalent complex between recombinant yeast iso-1-cytochrome c and recombinant yeast cytochrome c peroxidase (rCcP), in which the crystallographically defined cytochrome c binding site [Pelletier, H., and Kraut, J. (1992) Science 258, 1748-1755] is blocked, was synthesized via disulfide bond formation using specifically engineered cysteine residues in both yeast iso-1-cytochrome c and yeast cytochrome c peroxidase [Papa, H. S., and Poulos, T. L. (1995) Biochemistry 34, 6573-6580]. Previous studies on similar covalent complexes, those that block the Pelletier-Kraut crystallographic site, have demonstrated that samples of the covalent complexes have detectable activities that are significantly lower than those of wild-type yCcP, usually in the range of approximately 1-7% of that of the wild-type enzyme. Using gradient elution procedures in the purification of the engineered peroxidase, cytochrome c, and covalent complex, along with activity measurements during the purification steps, we demonstrate that the residual activity associated with the purified covalent complex is due to unreacted CcP that copurifies with the covalent complex. Within experimental error, the covalent complex that blocks the Pelletier-Kraut site has zero catalytic activity in the steady-state oxidation of exogenous yeast iso-1-ferrocytochrome c by hydrogen peroxide, demonstrating that only ferrocytochrome c bound at the Pelletier-Kraut site is oxidized during catalytic turnover.     

Parallel pathways in cytochrome c(551) folding

The folding of cytochrome c(551) from Pseudomonas aeruginosa was previously thought to follow a simple sequential mechanism, consistent with the lack of histidine residues, other than the native His16 heme ligand, that can give rise to mis-coordinated species. However, further kinetic analysis reveals complexities indicative of a folding mechanism involving parallel pathways. Double-jump interrupted refolding experiments at low pH indicate that approximately 50% of the unfolded cytochrome c(551) population can reach the native state via a fast (10 ms) folding track, while the rest follows a slower folding path with populated intermediates. Stopped-flow experiments using absorbance at 695 nm to monitor refolding confirm the presence of a rapidly folding species containing the native methionine-iron bond while measurements on carboxymethylated cytochrome c(551) (which lacks the Met-Fe coordination bond) indicate that methionine ligation occurs late during folding along the fast folding track, which appears to be dominant at physiological pH. Continuous-flow measurements of tryptophan-heme energy transfer, using a capillary mixer with a dead time of about 60 micros, show evidence for a rapid chain collapse within 100 micros preceding the rate-limiting folding phase on the milliseconds time scale. A third process with a time constant in the 10-50 ms time range is consistent with a minor population of molecules folding along a parallel channel, as confirmed by quantitative kinetic modeling. These findings indicate the presence of two or more slowly inter-converting ensembles of denatured states that give rise to pH-dependent partitioning among fast and slow-folding pathways.     

Early steps in cytochrome c folding probed by time-resolved circular dichroism and fluorescence spectroscopy.

The kinetics of protein folding for horse ferricytochrome c was investigated by stopped-flow methods, using far-UV circular dichroism (CD), near-UV CD, and tryptophan fluorescence to probe the formation of secondary structure and tertiary interactions. In the far-UV region of the CD spectrum (222 nm), 44% of the total change associated with refolding occurs within the dead time of the stopped-flow experiment, indicating that a significant amount of helical secondary structure is formed in less than 4 ms. The remaining changes in the ellipticity at 222 nm occur in two kinetic phases with time constants of about 40 ms and 0.7 s, respectively. In contrast, there is no evidence for rapid changes in the ellipticity at 289 nm: an aromatic CD band, which is indicative of the formation of a tightly packed core, only begins to appear in a 400-ms step and is completed in a final 10-s phase. The fluorescence of a single tryptophan at position 59, which becomes quenched upon folding via nonradiative energy transfer to the heme group, provides complementary information on the condensation of the polypeptide chain during refolding. The fluorescence-detected stopped-flow folding kinetics of ferricytochrome c exhibits a 35% decrease in fluorescence during the dead time, suggesting that a substantial decrease in the average tryptophan-heme distance occurs on a submillisecond time scale. The subsequent fluorescence changes exhibit two prominent phases with time constants of about 20 and 300 ms, followed by a minor 5-s phase.(ABSTRACT TRUNCATED AT 250 WORDS)