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.

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.

Antibody-detected folding: kinetics of surface epitope formation are distinct from other folding phases.

The rate of macromolecular surface formation in yeast iso-2 cytochrome c and its site-specific mutant, N52I iso-2, has been studied using a monoclonal antibody that recognizes a tertiary epitope including K58 and H39. The results indicate that epitope refolding occurs after fast folding but prior to slow folding, in contrast to horse cytochrome c where surface formation occurs early. The antibody-detected (ad) kinetic phase accompanying epitope formation has k(ad) = 0.2 s(-1) and is approximately 40-fold slower than the fastest detectable event in the folding of yeast iso-2 cytochrome c (k2f approximately 8 s(-1)), but occurs prior to the absorbance- and fluorescence-detected slow folding steps (k1a approximately 0.06 s(-1); k1b approximately 0.09 s(-1)). N5I iso-2 cytochrome c exhibits similar kinetic behavior with respect to epitope formation. A detailed dissection of the mechanistic differences between the folding pathways of horse and yeast cytochromes c identifies possible reasons for the slow surface formation in the latter. Our results suggest that non-native ligation involving H33 or H39 during refolding may slow down the formation of the tertiary epitope in iso-2 cytochrome c. This study illustrates that surface formation can be coupled to early events in protein folding. Thus, the rate of macromolecular surface formation is fine tuned by the residues that make up the surface and the interactions they entertain during refolding.

Isothermal titration calorimetry of protein-protein interactions.

The interaction of biologicalmacromolecules, whether protein-DNA, antibody-antigen, hormone-receptor, etc., illustrates the complexity and diversity of molecular recognition. The importance of such interactions in the immune response, signal transduction cascades, and gene expression cannot be overstated. It is of great interest to determine the nature of the forces that stabilize the interaction. The thermodynamics of association are characterized by the stoichiometry of the interaction (n), the association constant (K(a)), the free energy (DeltaG(b)), enthalpy (DeltaH(b)), entropy (DeltaS(b)), and heat capacity of binding (DeltaC(p)). In combination with structural information, the energetics of binding can provide a complete dissection of the interaction and aid in identifying the most important regions of the interface and the energetic contributions. Various indirect methods (ELISA, RIA, surface plasmon resonance, etc.) are routinely used to characterize biologically important interactions. Here we describe the use of isothermal titration calorimetry (ITC) in the study of protein-protein interactions. ITC is the most quantitative means available for measuring the thermodynamic properties of a protein-protein interaction. ITC measures the binding equilibrium directly by determining the heat evolved on association of a ligand with its binding partner. In a single experiment, the values of the binding constant (K(a)), the stoichiometry (n), and the enthalpy of binding (DeltaH(b)) are determined. The free energy and entropy of binding are determined from the association constant. The temperature dependence of the DeltaH(b) parameter, measured by performing the titration at varying temperatures, describes the DeltaC(p) term. As a practical application of the method, we describe the use of ITC to study the interaction between cytochrome c and two monoclonal antibodies.

Thermal stability of hydrophobic heme pocket variants of oxidized cytochrome c.

Microcalorimetry has been used to measure the stabilities of mutational variants of yeast iso-1 cytochrome c in which F82 and L85 have been replaced by other hydrophobic amino acids. Specifically, F82 has been replaced by Y and L85 by A. The double mutant F82Y,L85A iso-1 has also been studied, and the mutational perturbations are compared to those for the two single mutants, F82Y iso-1 and L85A iso-1. Results are interpreted in terms of known crystallographic structures. The data show that (1) the destabilization of the mutant proteins is similar in magnitude to that which is theoretically predicted by the more obvious mutation-induced structural effects; (2) the free energy of destabilization of the double mutant, F82Y,L85A iso-1, is less than the sum of those of the two single mutants, almost certainly because, in the double mutant, the -OH group of Y82 is able to protrude into the cavity formed by the L85A substitution. The more favorable structural accommodation of the new -OH group in the double mutant leads to additional stability through (1) further decreases in the volumes of internal cavities and (2) formation of an extra protein-protein hydrogen bond.

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.

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.

Effect of prolyl isomerase on the folding reactions of staphylococcal nuclease.

The low-temperature fluorescence-detected refolding of staphylococcal nuclease (SNase) can be described by three slow kinetic phases. The slowest phase is absent in the P117G mutant of SNase. Peptidyl prolyl cis-trans isomerase (cyclophilin), which has been shown to catalyze the slow folding reactions of some proteins, was employed to determine which of the refolding reactions of SNase and P117G SNase involve proline isomerization. We report here that all three folding phases of the wild type and the slower phase of P117G SNase are catalyzed by prolyl isomerase, indicating that proline isomerization is involved in these fluorescence-detected phases in the refolding of SNase. Since the rates of these phases are denaturant-dependent, we conclude that the slow folding steps involve isomerization of non-native cis proline peptide bonds and are tightly coupled to denaturant-sensitive structural changes.

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.

Thermodynamic cycles as probes of structure in unfolded proteins.

The relationship between structure and stability has been investigated for the folded forms and the unfolded forms of iso-2 cytochrome c and a variant protein with a stability-enhancing mutation, N52I iso-2. Differential scanning calorimetry has been used to measure the reversible unfolding transitions for the proteins in both heme oxidation states. Reduction potentials have been measured as a function of temperature for the folded forms of the proteins. The combination of measurements of thermal stability and reduction potential gives three sides of a thermodynamic cycle and allows prediction of the reduction potential of the thermally unfolded state. The free energies of electron binding for the thermally unfolded proteins differ from those expected for a fully unfolded protein, suggesting that residual structure modulates the reduction potential. At temperatures near 50 degrees C the N52I mutation has a small but significant effect on oxidation state-sensitive structure in the thermally unfolded protein. Inspection of the high-resolution X-ray crystallographic structures of iso-2 and N52I iso-2 shows that the effects of the N52I mutation and oxidation state on native protein stability are correlated with changes in the mobility of specific polypeptide chain segments and with altered hydrogen bonding involving a conserved water molecule. However, there is no clear explanation of oxidation state or mutation-induced differences in stability of the proteins in terms of observed changes in structure and mobility of the folded forms of the proteins alone.

Prolyl isomerase as a probe of stability of slow-folding intermediates.

Catalysis of slow folding reactions by peptidyl prolyl cis-trans isomerase (PPI) provides estimates of stabilities of intermediates in folding of normal and mutational variants of yeast iso-2 cytochrome c. A two-state model postulating a rapid preequilibration of intermediates with the unfolded protein is employed to calculate the stabilization free energy of the intermediate from the catalytic efficiency (kcat/Km) of PPI toward slow folding species. Stability measurements have been made for two distinct slow-folding intermediates: the absorbance-detected (IIS) and fluorescence-detected (IIIS) intermediates. Mutation-induced changes in the stability of the intermediates and in the activation free energy for slow folding are compared to changes in equilibrium thermodynamic stability. The results show that (1) for iso-2 the absorbance-detected intermediates (IIS) are slightly more stable than the fluorescence-detected intermediates (IIIS), (2) most mutations have different effects on equilibrium stability and the stability of the IIS or IIIS intermediates, and (3) for both slow folding reactions the mutation-induced changes in the activation free energy are small compared to the magnitude of the activation free energy barrier. Differential effects of mutations on equilibrium stability and the stability of intermediates provides a means of assessing the sequence-encoded structural specificity for folding. Mutations with different effects on intermediate stability and equilibrium stability change the encoded folding information and may alter folding pathways and/or lead to different three-dimensional structures. Identification of mutations which stabilize a folding intermediate relative to the native conformation provides an empirical approach to the design of thermodynamically stable forms of folding intermediates.

Enthalpy of antibody--cytochrome c binding.

High-sensitivity titration calorimetry is used to measure changes in enthalpy, heat capacity, and protonation for binding of two monoclonal antibodies (MAbs) to topologically distinct surfaces of cytochrome c. MAb 2B5 binds near the exposed heme crevice in a reaction involving proton uptake, while there is no change in protonation for MAb 5F8 binding to the opposite side of the molecule. Both antibodies have association rate constants with the activation enthalpy and viscosity dependence expected of diffusion-limited reactions [Raman et al. (1992) Biochemistry 31, 10370-10379], and bind with high affinity (delta Gzerob = -12.6 kcal mol-1 for MAb 2B5 and -13.9 kcal mol-1 for MAb 5F8, at pH 7, 25 degrees C). At 25 degrees C, the equilibrium enthalpy and entropy contributions to the free energy of binding are negative for both antibodies (delta Hzerob = -21.0 kcal mol-1, delta Szerob = -28.2 cal mol-1 K-1 for MAb 2B5; and delta Hzerob = -21.7 kcal mol-1, delta Szerob = 26.3 cal mol-1 K-1 for MAb 5F8). The enthalpy of MAb 2B5-cytochrome c association exhibits a marked temperature dependence (delta Cp = -580 cal mol-1 K-1), but the enthalpy for MAb 5F8 binding is much less dependent on temperature (delta Cp = -172 cal mol-1 K-1). The large differences in delta Cp for binding of the two antibodies suggest corresponding differences in the mode of binding, or in the molecular surfaces buried in the binding reactions. In particular, factors other than hydrophobic effects may be significant contributors to the thermodynamics of antibody-cytochrome c binding, especially when delta Cp is small (MAb 5F8).

Differential scanning calorimetric study of the thermal unfolding transitions of yeast iso-1 and iso-2 cytochromes c and three composite isozymes.

The effects of regional sequence differences on the thermodynamic stability of a globular protein have been investigated by scanning microcalorimetry. Thermal transitions have been measured for two isozymes of yeast cytochrome c (iso-1-MS and iso-2) and three composite proteins (Comp1-MS, Comp2-MS, and Comp3-MS) in which amino acid segments are exchanged between the parental isozymes. There are three main observations. (1) In the temperature range of the unfolding transitions (40-60 degrees C) the unfolding free energies for the composite proteins are only slightly different from those of the parental isozymes, although in some cases there are large but compensating changes in the transitional enthalpy and entropy. At lower temperatures (0-30 degrees C), all the composites are significantly less stable than the two parental proteins. (2) Long-range structural effects are responsible for at least some of the observed differences in stability. For example, in the temperature range of the unfolding transitions (40-60 degrees C), the Comp1-MS protein which contains only a small amount of iso-2-like sequence is less stable than either of the parental isozymes, despite the fact that none of the iso-2-specific amino acid side chains impinges directly on any of the iso-1-specific amino acid side chains. (3) Changes in ionization of His 26 appear to be linked to thermal unfolding. Iso-1-MS and Comp1-MS contain a histidine residue at position 26 while iso-2 and the other two composites do not. On lowering the pH from pH 6 to 5, both iso-1-MS and Comp1-MS show a decrease in stability (lower Tm) within the unfolding transition region (40-60 degrees C), whereas the stabilities of iso-2, Comp2-MS, and Comp3-MS are essentially unchanged. The thermal unfolding transitions are highly reversible (> 95%) but mechanistically complex. A moderate dependence of Tm on protein concentration and the ratio of the van't Hoff enthalpy to the calorimetric enthalpy suggest that thermal unfolding involves the reversible association of a significant fraction of the unfolded species, at least at elevated protein concentrations.

Rapid refolding of native epitopes on the surface of cytochrome c.

Refolding of surface epitopes on horse cytochrome c has been measured by monoclonal antibody binding. Two antibodies were used to probe re-formation of native-like surface structure: one antibody (2B5) binds to native cytochrome c near a type II turn (residue 44) while the other (5F8) binds to a different epitope on the opposite face of the protein near the amino terminus of an alpha-helical segment (residue 60). The results show that within the first approximately 100 ms of refolding all of the unfolded protein collapses to native-like folding intermediates that contain both antibody binding sites. All three absorbance/fluorescence-detected kinetic phases in the folding of cytochrome c (k1 approximately 5 s-1, k2 approximately 0.4 s-1, k3 approximately 0.03 s-1) are slower than the rates of re-formation of the antibody binding sites (k(obs) > 10.0 s-1), suggesting that the formation of antibody binding sites precedes the refolding reactions observed in kinetically resolved optically-detected refolding phases. Kinetically unresolved folding processes account for 79% and 19% of the total fluorescence change and absorbance change, respectively, observed in equilibrium unfolding. Thus, kinetically unresolved folding reactions appear to be responsible for re-formation of the MAb binding sites within partially folded intermediate species. These species are non-native (incompletely folded) in that their optical properties are in between those of the unfolded and the fully folded protein. As a test of whether antibody binding to folding intermediate(s) perturbs further folding, the rate of the absorbance-detected slow refolding phase has been measured for folding intermediate(s) of cytochrome c complexed with antibodies.(ABSTRACT TRUNCATED AT 250 WORDS)

Characterization of folding intermediates using prolyl isomerase.

Structure-reactivity relationships of human peptidyl prolyl cis-trans isomerase (PPI) toward the two slow folding reactions of yeast iso-2 cytochrome c have been used to characterize the structure of folding intermediates in the vicinity of critical prolines. We propose that the relative catalytic efficiency of PPI for the protein substrate relative to a peptide substrate, (kcat/Km)rel, is a measure of structure in folding intermediates. The structural stability of slow-folding intermediates as detected by changes in (kcat/Km)rel was investigated using two structural perturbants: guanidine hydrochloride and site-directed mutagenesis. Neither of the two slow folding reactions for wild-type cytochrome c is catalyzed at low denaturant concentrations. However, both phases are catalyzed at moderate concentrations of guanidine hydrochloride. A mutation in cytochrome c enhances catalysis of the fluorescence-detected slow folding phase. For protein substrates destabilized by denaturants or mutation, we suggest that increases in (kcat/Km)rel result from a loosening of the substrate structure, providing better access of peptidyl prolyl isomerase to critical proline(s).

Diffusion-limited rates for monoclonal antibody binding to cytochrome c.

The kinetic and spectroscopic changes accompanying the binding of two monoclonal antibodies to the oxidized form of horse heart cytochrome c have been investigated. The two epitopes recognized by the antibodies are distinct and noninteracting: antibody 2B5 binds to native cytochrome c near a type II turn (residue 44) while antibody 5F8 binds on the opposite face of the protein near the amino terminus of an alpha-helical segment (residue 60). Antibody-cytochrome c binding obeys a simple bimolecular reaction mechanism with second-order rate constants approaching those expected for diffusion-limited protein-protein interactions. The association rate constants have small activation enthalpies and are inversely dependent on solvent viscosity, as expected for diffusion-controlled reactions. There is a moderate ionic strength dependence of the rate of association between the 2B5 antibody and cytochrome c, with the rate constant increasing about 4-fold as the ionic strength is varied between 0.14 and 0 M. Comparison of the rates for antibody-cytochrome c complex formation for binding to the reduced-native, oxidized-native, and alkaline conformations shows that for MAb 2B5 the forward rate constant depends slightly on cytochrome c conformation. Investigation of the pH-induced transition between the native and alkaline conformational states for free cytochrome c and for antibody-cytochrome c complexes shows that antibody binding stabilizes the native form of the protein.(ABSTRACT TRUNCATED AT 250 WORDS)

Structure determination and analysis of yeast iso-2-cytochrome c and a composite mutant protein.

As part of a study of protein folding and stability, the three-dimensional structures of yeast iso-2-cytochrome c and a composite protein (B-2036) composed of primary sequences of both iso-1 and iso-2-cytochromes c have been solved to 1.9 A and 1.95 A resolutions, respectively, using X-ray diffraction techniques. The sequences of iso-1 and iso-2-cytochrome c share approximately 84% identity and the B-2036 composite protein has residues 15 to 63 from iso-2-cytochrome c with the rest being derived form the iso-1 protein. Comparison of these structures reveals that amino acid substitutions result in alterations in the details of intramolecular interactions. Specifically, the substitution Leu98Met results in the filling of an internal cavity present in iso-1-cytochrome c. Further substitutions of Val20Ile and Cys102Ala alter the packing of secondary structure elements in the iso-2 protein. Blending the isozymic amino acid sequences in this latter area results in the expansion of the volume of an internal cavity in the B-2036 structure to relieve a steric clash between Ile20 and Cys102. Modification of hydrogen bonding and protein packing without disrupting the protein fold is illustrated by the His26Asn and Asn63Ser substitutions between iso-1 and iso-2-cytochromes c. Alternatively, a change in main-chain fold is observed at Gly37 apparently due to a remote amino acid substitution. Further structural changes occur at Phe82 and the amino terminus where a four residue extension is present in yeast iso-2-cytochrome c. An additional comparison with all other eukaryotic cytochrome c structures determined to date is presented, along with an analysis of conserved water molecules. Also determined are the midpoint reduction potentials of iso-2 and B-2036 cytochromes c using direct electrochemistry. The values obtained are 286 and 288 mV, respectively, indicating that the amino acid substitutions present have had only a small impact on the heme reduction potential in comparison to iso-1-cytochrome c, which has a reduction potential of 290 mV.

Effective concentrations of amino acid side chains in an unfolded protein.

Preferential interactions between chain segments are studied in unfolded cytochrome c. The method takes advantage of heme ligation in the unfolded protein, a feature unique to proteins with covalently attached heme. The approach allows estimation of the effective concentration of one polypeptide chain segment relative to another, and is successful in detecting differences for peptide chain segments separated by different numbers of residues in the linear sequence. The method uses proton NMR spectroscopy to monitor displacement of the histidine heme ligands by imidazole as guanidine hydrochloride unfolded cytochrome c is titrated with deuterated imidazole. When the imidazole concentration exceeds the effective (local) concentration of histidine ligands, the protein ligands are displaced by deuterated imidazole. On displacement, the histidine ring proton resonances move from the paramagnetic region of the spectrum to the diamagnetic region. Titrations have been carried out for members of the mitochondrial cytochrome c family that contain different numbers of histidine residues. These include cytochromes c from tuna (2), yeast iso-2 (3), and yeast iso-1-MS (4). At high imidazole concentration, the number of proton resonances that appear in the histidine ring C2H region of the NMR spectrum is one less than the number of histidine residues in the protein. So one histidine, probably His-18, remains as a heme ligand. The effective local concentrations of histidines-26, -33, and -39 relative to the heme (position 14-17) are estimated to be (3-16) X 10(-3) M.(ABSTRACT TRUNCATED AT 250 WORDS)

Rates and energetics of tyrosine ring flips in yeast iso-2-cytochrome c.

Isotope-edited nuclear magnetic resonance spectroscopy is used to monitor ring flip motion of the five tyrosine side chains in the oxidized and reduced forms of yeast iso-2-cytochrome c. With specifically labeled protein purified from yeast grown on media containing [3,5-13C]tyrosine, isotope-edited one-dimensional proton spectra have been collected over a 5-55 degrees C temperature range. The spectra allow selective observation of the 10 3,5 tyrosine ring proton resonances and, using a two-site exchange model, allow estimation of the temperature dependence of ring flip rates from motion-induced changes in proton line shapes. For the reduced protein, tyrosines II and IV are in fast exchange throughout the temperature range investigated, or lack resolvable differences in static chemical shifts for the 3,5 ring protons. Tyrosines I, III, and V are in slow exchange at low temperatures and in fast exchange at high temperatures. Spectral simulations give flip rates for individual tyrosines in a range of one flip per second at low temperatures to thousands of flips per second at high temperatures. Eyring plots show that two of the tyrosines (I and III) have essentially the same activation parameters: delta H++ = 28 kcal/mol for both I and III; delta S++ = 42 cal/(mol.K) for I, and delta S++ = 41 cal/(mol.K) for III. The remaining tyrosine (V) has a larger enthalpy and entropy of activation: delta H++ - 36 kcal/mol, delta S++ = 72 cal/(mol.K). Tentative sequence-specific assignments for the tyrosines in reduced iso-2 are suggested by comparison to horse cytochrome c.(ABSTRACT TRUNCATED AT 250 WORDS)