The influence of amino acid substitutions on the conformational energy of cytochrome c.

Conformational energies have been evaluated for each of the staggered side-chain conformations associated with the 261 amino acid substitutions known to occur among 60 eucaryotic species. At least 86% of these substitutions can be sterically accommodated (one at a time) within the structure of horse-heart cytochrome c resulting from conformational energy refinement. Simultaneous incorporation of all pertinent amino acid substitutions found in eight representative species into the refined horse-heart structure is also shown to be sterically possible, with few exceptions. In two cases (Pekin duck cytochrome with 10 substitutions and Samia cynthia cytochrome with 24 substitutions), all substitutions could be readily incorporated, and the total energies associated with their computed structures differed by less than 10 kcal/mol from that of horse-heart cytochrome c. In the cytochromes from rattlesnake (22 substitutions), tuna (18 substitutions), and Neurospora crassa (36 substitutions), tyrosine could not be substituted for phenylalanine at position 46, within the constraints of the calculations. However, when all of the remaining substitutions were incorporated into these three cytochromes, their computed conformational energies differed by less than 30 kcal/mol from that of horse-heart cytochrome c. Between two and four amino acid substitutions cause high energies in the cytochromes from human, baker's yeast, and cotton seed, but all of the remaining substitutions are consistent with a low energy conformation. These results suggest that the structures of homologous proteins may be even more similar than has previously been recognized. Substitutions of all possible amino acid types at the invariant positions (where all eucaryotic cytochromes c bear the same amino acid) have revealed some cases where different amino acids can be accommodated, thus demonstrating that the biological constraints on amino acid substitutions are often different from the purely steric constraints investigated in this work.     

The kinetics of reoxidation of yeast complex III. An evaluation of the Q-cycle

The reoxidation of reduced yeast Complex III by oxidants believed to react with cytochrome c1 exhibited multiple phases for both cytochrome c1 and the cytochromes b; the reoxidation of cytochrome b, but not cytochrome c1, was markedly slowed by the presence of antimycin. The data are consistent with the Q-cycle or any other scheme which proposes a branched path for electron transport between the cytochrome b centers and the endogenous Q6, provided certain constraints are relaxed. The reoxidation of the endogenous quinone proceeded at a rate comparable to that of the rapidly reacting cytochrome b and appeared to be complete within 100 ms. Removal of the endogenous quinone did not change the rate or extent of reoxidation of any of the heme centers, demonstrating that quinone is not required for electron transport between cytochromes b and the iron-sulfur cluster. This result is inconsistent with the requirements of the Q-cycle. Funiculosin completely inhibited the reoxidation of cytochrome b whereas the reoxidation of cytochrome c1 exhibited simple first-order kinetics in the presence of this inhibitor, implying that the iron-sulfur cluster is on the direct path of electron transfer from cytochrome b to cytochrome c1. Potent inhibition of cytochrome b oxidation was also observed with myxothiazol and mucidin. The reaction of reduced Complex III with Q1 also exhibited multiple phases in the oxidation of the cytochrome b centers; these phases were unaffected by the presence of myxothiazol. Addition of antimycin, or removal of the endogenous quinone, eliminated the rapid phases; only one of the cytochrome b centers was oxidized under these conditions. Epr showed that it is the low-potential cytochrome b that is the species rapidly oxidized.     

THE ROLE OF THE QUINONE POOL IN THE CYCLIC ELECTRON-TRANSFER CHAIN OF RHODOPSEUDOMONAS SPHAEROIDES: A MODIFIED Q-CYCLE MECHANISM

(1) The role of the ubiquinone pool in the reactions of the cyclic electron-transfer chain has been investigated by observing the effects of reduction of the ubiquinone pool on the kinetics and extent of the cytochrome and electrochromic carotenoid absorbance changes following flash illumination. (2) In the presence of antimycin, flash-induced reduction of cytochrome b-561 is dependent on a coupled oxidation of ubiquinol. The ubiquinol oxidase site of the ubiquinol:cytochrome c(2) oxidoreductase catalyses a concerted reaction in which one electron is transferred to a high-potential chain containing cytochromes c(1) and c(2), the Rieske-type iron-sulfur center, and the reaction center primary donor, and a second electron is transferred to a low-potential chain containing cytochromes b-566 and b-561. (3) The rate of reduction of cytochrome b-561 in the presence of antimycin has been shown to reflect the rate of turnover of the ubiquinol oxidase site. This diagnostic feature has been used to measure the dependence of the kinetics of the site on the ubiquinol concentration. Over a limited range of concentration (0-3 mol ubiquinol/mol cytochrome b-561), the kinetics showed a second-order process, first order with respect to ubiquinol from the pool. At higher ubiquinol concentrations, other processes became rate determining, so that above approx. 25 mol ubiquinol/mol cytochrome b-561, no further increase in rate was seen. (4) The kinetics and extents of cytochrome b-561 reduction following a flash in the presence of antimycin, and of the antimycin-sensitive reduction of cytochrome c(1) and c(2), and the slow phase of the carotenoid change, have been measured as a function of redox potential over a wide range. The initial rate for all these processes increased on reduction of the suspension over the range between 180 and 100 mV (pH 7). The increase in rate occurred as the concentration of ubiquinol in the pool increased on reduction, and could be accounted for in terms of the increased rate of ubiquinol oxidation. It is not necessary to postulate the presence of a tightly bound quinone at this site with altered redox properties, as has been previously assumed. (5) The antimycin-sensitive reactions reflect the turnover of a second catalytic site of the complex, at which cytochrome b-561 is oxidized in an electrogenic reaction. We propose that ubiquinone is reduced at this site with a mechanism similar to that of the two-electron gate of the reaction center. We suggest that antimycin binds at this site, and displaces the quinone species so that all reactions at the site are inhibited. (6) In coupled chromatophores, the turnover of the ubiquinone reductase site can be measured by the antimycin-sensitive slow phase of the electrochromic carotenoid change. At redox potentials higher than 180 mV, where the pool is completely oxidized, the maximal extent of the slow phase is half that at 140 mV, where the pool contains approx. 1 mol ubiquinone/mol cytochrome b-561 before the flash. At both potentials, cytochrome b-561 became completely reduced following one flash in the presence of antimycin. The results are interpreted as showing that at potentials higher than 180 mV, ubiquinol stoichiometric with cytochrome b-561 reaches the complex from the reaction center. The increased extent of the carotenoid change, when one extra ubiquinol is available in the pool, is interpreted as showing that the ubiquinol oxidase site turns over twice, and the ubiquinone reductase sites turns over once, for a complete turnover of the ubiquinol:cytochrome c(2) oxidoreductase complex, and the net oxidation of one ubiquinol/complex. (7) The antimycin-sensitive reduction of cytochrome c(1) and c(2) is shown to reflect the second turnover of the ubiquinol oxidase site. (8) We suggest that, in the presence of antimycin, the ubiquinol oxidase site reaches a quasi equilibrium with ubiquinol from the pool and the high- and low-potential chains, and that the equilibrium constant of the reaction catalysed constrains the site to the single turnover under most conditions. (9) The results are discussed in the context of a detailed mechanism. The modified Q-cycle proposed is described by physicochemical parameters which account well for the results reported.     

Equilibrium unfolding of a small low-potential cytochrome, cytochrome c553 from Desulfovibrio vulgaris.

To understand general aspects of stability and folding of c-type cytochromes, we have studied the folding characteristics of cytochrome c553 from Desulfovibrio vulgaris (Hildenborough). This cytochrome is structurally similar but lacks sequence homology to other heme proteins; moreover, it has an abnormally low reduction potential. Unfolding of oxidized and reduced cytochrome c553 by guanidine hydrochloride (GuHCl) was monitored by circular dichroism (CD) and Soret absorption; the same unfolding curves were obtained with both methods supporting that cytochrome c553 unfolds by an apparent two-state process. Reduced cytochrome c553 is 7(3) kJ/mol more stable than the oxidized form; accordingly, the reduction potential of unfolded cytochrome c553 is 100(20) mV more negative than that of the folded protein. In contrast to many other unfolded cytochrome c proteins, upon unfolding at pH 7.0 both oxidized and reduced heme in cytochrome c553 become high-spin. The lack of heme misligation in unfolded cytochrome c553 implies that its unfolded structure is less constrained than those of cytochromes c with low-spin, misligated hemes.     

Kinetic barriers to the folding of horse cytochrome C in the reduced state

To determine the kinetic barrier in the folding of horse cytochrome c, a CO-liganded derivative of cytochrome c, called carbonmonoxycytochrome c, has been prepared by exploiting the thermodynamic reversibility of ferrocytochrome c unfolding induced by guanidinium hydrochloride (GdnHCl), pH 7. The CO binding properties of unfolded ferrocytochrome c, studied by 13C NMR and optical spectroscopy, are remarkably similar to those of native myoglobin and isolated chains of human hemoglobin. Equilibrium unfolding transitions of ferrocytochrome c in the presence and the absence of CO observed by both excitation energy transfer from the lone tryptophan to the ferrous heme and far-UV circular dichroism (CD) indicate no accumulation of structural intermediates to a detectable level. Values of thermodynamic parameters obtained by two-state analysis of fluorescence transitions are DeltaG(H2O) = 11.65(+/-1.13) kcal x mol(-1) and C(m) = 3.9(+/-0.1) M GdnHCl in the presence of CO, and DeltaG(H2O)=19.3(+/-0.5) kcal x mol(-1) and C(m) = 5.1(+/-0.1) M GdnHCl in the absence of CO, indicating destabilization of ferrocytochrome c by approximately 7.65 kcal x mol(-1) due to CO binding. The native states of ferrocytochrome c and carbonmonoxycytochrome c are nearly identical in terms of structure and conformation except for the Fe2+-M80 --> Fe2+-CO replacement. Folding and unfolding kinetics as a function of GdnHCl, studied by stopped-flow fluorescence, are significantly different for the two proteins. Both refold fast, but carbonmonoxycytochrome c refolds 2-fold faster (tau = 1092 micros at 10 degrees C) than ferrocytochrome c. Linear extrapolation of the folding rates to the ordinate of the chevron plot projects this value of tau to 407 micros. The unfolding rate of the former in water, estimated by extrapolation, is faster by more than 10 orders of magnitude. Significant differences are also observed in rate-denaturant gradients in the chevron. Formation and disruption of the Fe2+-M80 coordination contact clearly impose high-energy kinetic barriers to folding and unfolding of ferrocytochrome c. The unfolding barrier due to the Fe2+-M80 bond provides sufficient kinetic stability to the native state of ferrocytochrome c to perform its physiological function as an electron donor.     

Kinetic and equilibrium studies of alkaline isomerization of vertebrate cytochromes c

Equilibria and kinetics of alkaline isomerization of seven ferricytochromes c from vertebrates were studied by pH-titration and pH-jump methods in the pH region of 7-12. In the equilibrium behavior, no significant difference was detected among the cytochromes c, whereas marked differences in the kinetic behavior were observed. According to the kinetic behavior of the isomerization, the cytochromes c examined fall into three classes: Group I (horse, sheep, dog and pigeon cytochromes c), Group II (tuna and bonito cytochromes c) and Group III (rhesus monkey cytochrome c). The kinetic results are interpreted in terms of the sequential scheme: Neutral form in equilibrium with fast Transient form in equilibrium with slow Alkaline form where the neutral and alkaline forms are the species stable at neutral and alkaline pH, respectively, and the transient form is a kinetic intermediate. From comparison of the primary sequences of the seven cytochromes c and the classification of these cytochromes c, it is concluded that the amino acid substitution Phe/Tyr at the 46-th position has a major influence on the kinetic behavior. In Group II and III cytochromes c, the ionization of Tyr-46 is suggested to bring about loosening of the heme crevice and thus facilitate the ligand replacement involved in the isomerization.     

Replacement of a conserved proline eliminates the absorbance-detected slow folding phase of iso-2-cytochrome c

As a test of the proline isomerization model, we have used oligonucleotide site-directed mutagenesis to construct a mutant form of iso-2-cytochrome c in which proline-76 is replaced by glycine [Wood, L. C., Muthukrishnan, K., White, T. B., Ramdas, L., & Nall, B. T. (1988) Biochemistry (preceding paper in this issue)]. For the oxidized form of Gly-76 iso-2, an estimate of stability by guanidine hydrochloride induced unfolding indicates that the mutation destabilizes the protein by 1.2 kcal/mol under standard conditions of neutral pH and 20 degrees C (delta G degrees u = 3.8 kcal/mol for normal Pro-76 iso-2 versus 2.6 kcal/mol for Gly-76 iso-2). The kinetics of folding/unfolding have been monitored by fluorescence changes throughout the transition region using stopped-flow mixing. The rates for fast and slow fluorescence-detected refolding are unchanged, while fast unfolding is increased in rate 3-fold in the mutant protein compared to normal iso-2. A new kinetic phase in the 1-s time range is observed in fluorescence-detected unfolding of the mutant protein. The presence of the new phase is correlated with the presence of species with an altered folded conformation in the initial conditions, suggesting assignment of the phase to unfolding of this species. The fluorescence-detected and absorbance-detected slow folding phases have been monitored as a function of final pH by manual mixing between pH 5.5 and 8 (0.3 M guanidine hydrochloride, 20 degrees C).(ABSTRACT TRUNCATED AT 250 WORDS)     

Electron transfer between horse heart and Candida krusei cytochromes c in the free and bound states

Electron transfer between horse heart and Candida krusei cytochromes c in the free and phosvitin-bound states was examined by difference spectrum and stopped-flow methods. The difference spectra in the wavelength range of 540-560 nm demonstrated that electrons are exchangeable between the cytochromes c of the two species. The equilibrium constants of the electron transfer reaction for the free and phosvitin-bound forms, estimated from these difference spectra, were close to unity at 20 degrees C in 20 mM Tris-HCl buffer (pH 7.4). The electron transfer rate for free cytochrome c was (2-3).10(4) M-1.s-1 under the same conditions. The transfer rate for the bound form increased with increase in the binding ratio at ratios below half the maximum, and was almost constant at higher ratios up to the maximum. The maximum electron exchange rate was about 2.10(6) M-1.s-1, which is 60-70 times that for the free form at a given concentration of cytochrome c. The activation energy of the reaction for the bound cytochrome c was equal to that for the free form, being about 10 kcal/mol. The dependence of the exchange rate on temperature, cytochrome c concentration and solvent viscosity suggests that enhancement of the electron transfer rate between cytochromes c on binding to phosvitin is due to increase in the collision frequency between cytochromes c concentrated on the phosvitin molecule.     

Kinetics of reduction by free flavin semiquinones of the components of the cytochrome c-cytochrome c peroxidase complex and intracomplex electron transfer

The kinetics of reduction by free flavin semiquinones of the individual components of 1:1 complexes of yeast ferric and ferryl cytochrome c peroxidase and the cytochromes c of horse, tuna, and yeast (iso-2) have been studied. Complex formation decreases the rate constant for reduction of ferric peroxidase by 44%. On the basis of a computer model of the complex structure [Poulos, T.L., & Finzel, B.C. (1984) Pept. Protein Rev. 4, 115-171], this decrease cannot be accounted for by steric effects and suggests a decrease in the dynamic motions of the peroxidase at the peroxide access channel caused by complexation. The orientations of the three cytochromes within the complex are not equivalent. This is shown by differential decreases in the rate constants for reduction by neutral flavin semiquinones upon complexation, which are in the order tuna much greater than horse greater than yeast iso-2. Further support for differences in orientation is provided by the observation that, with the negatively charged reductant FMNH., the electrostatic environments near the horse and tuna cytochrome c electron-transfer sites within their respective complexes with peroxidase are of opposite sign. For the horse and tuna cytochrome c complexes, we have also observed nonlinear concentration dependencies of the reduction rate constants with FMNH.. This is interpreted in terms of dynamic motion at the protein-protein interface. We have directly measured the physiologically significant intra-complex one electron transfer rate constants from the three ferrous cytochromes c to the peroxide-oxidized species of the peroxidase. At low ionic strength these rate constants are 920, 730, and 150 s-1 for tuna, horse, and yeast cytochromes c, respectively. These results are also consistent with the contention that the orientations of the three cytochromes within the complex with CcP are not the same. The effect on the intracomplex electron-transfer rate constant of the peroxidase amino acid side chain(s) that is (are) oxidized by the reduction of peroxide was determined to be relatively small. Thus, the rate constant for reduction by horse cytochrome c of the peroxidase species in which only the heme iron atom is oxidized was decreased by only 38%, indicating that this oxidized side-chain group is not tightly coupled to the ferryl peroxidase heme iron. Finally, it was found that, in the absence of cytochrome c, neither of the ferryl peroxidase species could be rapidly reduced by flavin semiquinones.(ABSTRACT TRUNCATED AT 400 WORDS)     

Increasing the conformational stability by replacement of heme axial ligand in c-type cytochrome

To investigate the role of the heme axial ligand in the conformational stability of c-type cytochrome, we constructed M58C and M58H mutants of the red alga Porphyra yezoensis cytochrome c(6) in which the sixth heme iron ligand (Met58) was replaced with Cys and His residues, respectively. The Gibbs free energy change for unfolding of the M58H mutant in water (DeltaG degrees (unf)=1.48 kcal/mol) was lower than that of the wild-type (2.43 kcal/mol), possibly due to the steric effects of the mutation on the apoprotein structure. On the other hand, the M58C mutant exhibited a DeltaG degrees (unf) of 5.45 kcal/mol, a significant increase by 3.02 kcal/mol compared with that of wild-type. This increase was possibly responsible for the sixth heme axial bond of M58C mutant being more stable than that of wild-type according to the heme-bound denaturation curve. Based on these observations, we propose that the sixth heme axial ligand is an important key to determine the conformational stability of c-type cytochromes, and the sixth Cys heme ligand will give stabilizing effects.     

Laser flash photolysis studies of electron transfer mechanisms in cytochromes: an aromatic residue at position 82 is not required for cytochrome c reduction by flavin semiquinones or electron transfer from cytochrome c to cytochrome oxidase.

The influence of an aromatic side chain at position 82 of yeast iso-1-cytochrome c on the kinetics of its electron transfer reactions has been investigated using laser flash photolysis methods to compare a series of site-specific mutant cytochromes in their reduction by free flavin semiquinone and in electron transfer from reduced cytochrome to bovine cytochrome c oxidase. Although small (approximately 10%) but significant differences are observed between some of the mutants (S82, Y82, I82) and wild-type (F82) or G82 cytochrome in the second-order rate constant for reduction by lumiflavin semiquinone, these do not correlate with side-chain aromaticity. In the reaction between the ferrocytochromes and cytochrome c oxidase, significantly larger deviations from exponentiality are found for those mutants having aliphatic residues at position 82 than for wild type or Y82. We interpret the nonexponential behavior in terms of multiple orientations of the cytochromes within the oxidase binding site; the extent to which this occurs is apparently influenced by the character of the residue at position 82. However, a comparison of the average rate constants for electron transfer to cytochrome oxidase for the various mutants reveals that all are closely comparable to WT, except for I82 which is significantly slower (approximately threefold). These results, combined with those obtained previously from steady-state kinetic and thermodynamic measurements, suggest that the observed differences among the mutants are due to alterations in the mode of binding of the cytochrome to the oxidase, rather than to a specific requirement for the presence of an aromatic group at position 82.     

Multifrequency calorimetry of the folding/unfolding transition of cytochrome c.

The folding-unfolding transition of Fe(III) cytochrome c has been studied with the new technique of multifrequency calorimetry. Multifrequency calorimetry is aimed at measuring directly the dynamics of the energetic events that take place during a thermally induced transition by measuring the frequency dispersion of the heat capacity. This is done by modulating the folding/unfolding equilibrium using a variable frequency, small oscillatory temperature perturbation (approximately 0.05-0.1 degrees C) centered at the equilibrium temperature of the system. Fe(III) cytochrome c at pH 4 undergoes a fully reversible folding/unfolding transition centered at 67.7 degrees C and characterized by an enthalpy change of 81 kcal/mol and heat capacity difference between unfolded and folded states of 0.9 kcal/K*mol. By measuring the temperature dependence of the frequency dispersion of the heat capacity in the frequency range of 0.1-1 Hz it has been possible to examine the time regime of the enthalpic events associated with the transition. The multifrequency calorimetry results indicate that approximately 85% of the excess heat capacity associated with the folding/unfolding transition relaxes with a single relaxation time of 326 +/- 68 ms at the midpoint of the transition region. This is the first time that the time regime in which heat is absorbed and released during protein folding/unfolding has been measured.     

Do evolutionary changes in cytochrome c structure reflect functional adaptations?

Following the demonstration that the rate of evolutionary change in the amino acid sequences of cytochromes c of eukaryotic species was not constant either for a single line of phylogenetic descent during different evolutionary intervals or for separate lines of descent, the concept that neutral mutations account for the vast majority of the evolutionary variations could no longer be accepted. Previous studies had shown that all eukaryotic cytochromes c tested appeared to be functionally indistinguishable in their reaction with mitochondrial respiratory chain components. However, an examination of the kinetics at low ionic strength led to the discovery of a high affinity reaction of cytochrome c with cytochrome c oxidase that revealed large differences in activity between the cytochromes of the horse, baker's yeast and the protist Euglena. Observed Km values for this reaction of 10(-7) to 10(-8) M appear to represent actual dissociation constants, as demonstrated by direct binding studies of cytochrome c with purified cytochrome c oxidase. The high affinity reaction is sensitive to ionic strength and inhibited by ADP and ATP in the range of physiological concentrations, ATP being three times as effective as ADP. The possibility is discussed that this effect of ATP on cytochrome c binding to its oxidase could provide the basis of a mechanism for mitochondrial respiratory control. The demonstration of differences between cytochrome c of various species in this kinetic system opens the way to a systematic study of the possible evolutionary adaptations of cytochromes c to their oxidases.     

The pathway of electrons through OH2:cytochrome c oxidoreductase studied by pre-steady -state kinetics

The kinetic behaviour of the prosthetic groups and the semiquinones in in QH2:cytochrome c oxidoreductase has been studied using a combination of the freeze-quench technique, low-temperature diffuse-reflectance spectroscopy, EPR and stopped flow. (2) In the absence of antimycin, cytochrome b-562 is reduced in two phases separated by a lag time. The initial very rapid reduction phase, that coincides with the formation of the antimycin-sensitive Qin, is ascribed to high-potential cytochrome b-562 and the slow phase to low-potential cytochrome b-562. the two cytochromes are present in a 1:1 molar ratio. The lag time between the two reduction phases decreases with increasing pH. Both the [2 Fe-2S] clusters and cytochrome c1 are reduced monophasically under these conditions, but at a rate lower than that of the initial rapid reduction of cytochrome b-562. (3) In the presence of antimycin and absence of oxidant, cytochrome b-562 is still reduced biphasically, but there is no lag between the two phases. No Qin is formed and both the Fe-S clusters and cytochrome c1 are reduced biphasically, one-half being reduced at the same rate as in the absence of antimycin and the other half 10-times slower. (4) In the presence of antimycin and oxidant, the recently described antimycin-insensitive species of semiquinone anion, Qout (De Vries, S., Albracht, S.P.J., Berden, J.A. and Slater, E.C. (1982) J. Biol. Chem. 256, 11996-11998) is formed at the same rate as that of the reduction of all species of cytochrome b. In this case cytochrome b is reduced in a single phase. (5) The reversible change of the line shape of the EPR spectrum of the [2Fe-2S] cluster 1 is caused by ubiquinone bound in the vicinity of this cluster. (6) The experimental results are consistent with the basic principles of the Q cycle. Because of the multiplicity, stoicheiometry and heterogeneous kinetics of the prosthetic groups, a Q cycle model describing the pathway of electrons through a dimeric QH2:cytochrome c oxidoreductase is proposed.     

Dynamic control on the rate of the reduction of the b type cytochromes in submitochondrial particles.

1. In the presence of antimycin and KCN the reduction of cytochrome b in phosphorylating submitochondrial particles followed a biphasic first-order kinetics. The transition from the first, rapid phase to the second, slow phase occurred while the reduction of chtochromes c + c1 and a through or around the antimycin block was still linear with time. Thus, the phase transition was due to a fall-off in the rate of cytochrome b reduction. 2. The biphasic reduction of cytochrome b was observed over a wide temperature range (0--30 degrees C), with succinate of NADH as electron donors and with phosphorylating particles or coupled rat-heart mitochondria. With rat-heart mitochondria the same biphasic reduction was observed in the presence of either carbonyl cyanide p-trifluoromethoxyphenylhydrazone or oligomycin. 3. In both the rapid and the slow phases, the rate of reduction of cytochrome b-561 was equal to that of b-565. Thus both cytochromes b-561 and b-565 were affected by the mechanism which determined the reduction-rate. Furthermore, each of these cytochromes could be reduced individually with rate constants typical of the slow phase. 4. The proportion of rapidly reduced to slowly reduced cytochrome b was independent of the degree of its reducibility and could be controlled by teh experimental conditions. When antimycin was used as the only inhibitor, 96% of the b-type cytochromes were reduced in the rapid phase. If the c and a-type cytochromes were first reduced by ascorbate and tetramethyl-p-phenylenediamine in the presence of KCN and antimycin, all the b-type cytochromes were fully reduced at the slow-rate. 5. With succinate, the rate of the rapid phase depended on the activation level of the succinic-dehydrogenase. The rate constant of the second phase was unaffected by the succinic dehydrogenase activity, if the preparation was more than 20% active. Furthermore, the rate constant of the slow reduction was the same with succinate, NADH, or even with durohydroquinone (which reacted directly with cytochromes b). 6. It is suggested that cytochrome b can exist in two forms: kinetically active or sluggish. The active form is rapidly reduced by the endogenous quinone (QH2) or durohydroquinone. The rate of the reduction of the active form by succinate or NADH is probably determined by the rate of the reduction of Q by the dehydrogenases. The second form of cytochrome b is characterized by its sluggish reduction by QH2 or durohydroquinone. 7. It is proposed that the transformation from the active to the sluggish form is induced by the reduction of a controlling group, named Y, located on the oxygen side of the antimycin inhibition site. When Y is oxidized, cytochrome b is in its active form, and when Y is reduced, cytochrome b is in its sluggish form. The nature of this kinetic control and a comparison with the mechanism controlling the reducibility of cytochrome b are discussed.     

Chromous ion reduction of mammalian cytochrome oxidase and some of its derivatives.

The reduction of cytochrome c oxidase by Cr2+, followed by means of stopped-flow spectrophotometry, exhibits two phases: the faster Cr2+-concentration-dependent reaction has an initial rate constant of 1.1 X 10(4)M-1-S-1, but reaches a rate limit at high concentration of reductant; the slower phase is concentration-independent with a rate of 0.3S-1. The activation energies of the fast and the slow processes are 35 and 71 kJ/mol respectively. The reduction kinetics of the mixed-valence CO complex and the cyanide-inhibited enzyme were compared with those of the fully oxidized forms: both the liganded species have a fast phase identical with that found in the oxidized oxidase. A comparison of the kinetic difference spectra obtained for the fast phase of reduction of oxidized oxidase with those obtained on reduction of the liganded species suggests that the rapid phase arises from the reduction ofhaem a, and the slow phase from the reduction of haem a3.     

The kinetics of reduction of yeast complex III by a substrate analog

The kinetics of reduction of the cytochrome and quinone constituents of yeast complex III by the substrate homolog Q1H2 have been measured under a variety of conditions. The maximum rates of reduction of cytochromes b and c1 and of the endogenous Q6 by Q1H2 were sufficiently fast to support the Vmax for the reduction of cytochrome c by this substrate. The absorbance at 562 nm showed an initial increase which was subsequently followed by a decrease. This decrease was synchronous with the appearance of reduced cytochrome c1 and is interpreted as reflecting the absorbance contribution of c1 at 562 nm under conditions where the steady state level of the b cytochromes is constant. Prereduction of c1 and the Fe/S cluster did not affect the initial very rapid reduction of b, but the second phase was eliminated. Antimycin abolished the very rapid rate of reduction of cytochrome b in untreated complex III and completely inhibited the reduction of cytochrome b in complex III in which c1 and the Fe/S cluster had been prereduced. However, the reduction of the endogenous quinone was essentially unaffected by these treatments. Antimycin had no effect on the reduction of c1. Funiculosin also suppressed the very rapid reduction of b while both myxothiazol and 5-n-undecyl-6-hydroxy-4,7-dioxobenzothiazole did not modify this phase of the reaction; no secondary decrease in absorbance was observed in the presence of any of these inhibitors. Most of the observed kinetic changes could be reproduced by simulation of the Q-cycle; simple linear and branched schemes were unable to reproduce the data.     

Hydrogen isotope exchange kinetics of single protons in bovine pancreatic trypsin inhibitor.

The exchange kinetics of the slowest exchanging BPTI beta-sheet protons are complex compared to model peptides; the activation energy, E alpha, and the pH dependence are temperature dependent. We have measured the exchange kinetics in the range pH 1--11, 33--71 degrees C, particularly the temperature dependence. The data are fit to a model in which exchange of each proton is determined by two discrete dynamical processes, one with E alpha approximately 65 kcal/mol and less than first order dependence on catalyst ion, and one with E alpha 20--30 kcal/mol and approaching first order in catalyst ion. The low activation energy process is the mechanism of interest in the native conformation of globular proteins and involves low energy, small amplitude fluctuations; the high activation energy process involves major unfolding. The model is simple, has a precedent in the hydrogen exchange literature, and explains quantitatively the complex feature of the exchange kinetics of single protons in BPTI, including the following. For the slowest exchanging protons, in the range 36 degrees--68 degrees C, E alpha is approximately 65 kcal/mol at pH approximately 4, 20--30 kcal/mol at pH greater than 10, and rises to approximately 65 kcal/mol with increasing temperature at pH 6--10; the Arrhenius plots converge around 70 degrees C; the pH of minimum rate, pHmin, is greater than 1 pH unit higher at 68 degrees C than for model compounds; and at high pH, the pH-rate profiles shift to steeper slope; the exchange rates around pHmin are correlated to the thermal unfolding temperature in BPTI derivatives (Wagner and Wüthrich, 1979, J. Mol. Biol. 130:31). For the more rapidly exchanging protons in BPTI the model accounts for the observation of normal pHmin and E alpha of 20--30 kcal/mol at all pH's. The important results of our analysis are (a) rates for exchange from the folded state of proteins are not correlated to thermal lability, as proposed by Wuthrich et al. (1979, J. Mol. Biol. 134:75); (b) the unfolding rate for the BPTI cooperative thermal transition is equal to the observed exchange rates of the slowest exchanging protons between pH 8.4--9.6, 51 degrees C; (c) the rates for exchange of single protons from folded BPTI are consistent with our previous hydrogen-tritium exchange results and with a penetration model of the dynamic processes limiting hydrogen exchange.     

DCCD inhibits the reactions of the iron-sulfur protein in Rhodobacter sphaeroides chromatophores

N,N'-dicyclohexylcarbodiimide (DCCD) has been reported to inhibit proton translocation by cytochrome bc(1) and b(6)f complexes without significantly altering the rate of electron transport, a process referred to as decoupling. To understand the possible role of DCCD in inhibiting the protonogenic reactions of cytochrome bc(1) complex, we investigated the effect of DCCD modification on flash-induced electron transport and electrochromic bandshift of carotenoids in Rb. sphaeroides chromatophores. DCCD has two distinct effects on phase III of the electrochromic bandshift of carotenoids reflecting the electrogenic reactions of the bc(1) complex. At low concentrations, DCCD increases the magnitude of the electrogenic process because of a decrease in the permeability of the membrane, probably through inhibition of F(o)F(1). At higher concentrations (>150 microM), DCCD slows the development of phase III of the electrochromic shift from about 3 ms in control preparations to about 23 ms at 1.2 mM DCCD, without significantly changing the amplitude. DCCD treatment of chromatophores also slows down the kinetics of flash-induced reduction of both cytochromes b and c, from 1.5-2 ms in control preparations to 8-10 ms at 0.8 mM DCCD. Parallel slowing of the reduction of both cytochromes indicates that DCCD treatment modifies the reaction of QH(2) oxidation at the Q(o) site. Despite the similarity in the kinetics of both cytochromes, the onset of cytochrome c re-reduction is delayed 1-2 ms in comparison to cytochrome b reduction, indicating that DCCD inhibits the delivery of electrons from quinol to heme c(1). We conclude that DCCD treatment of chromatophores leads to modification of the rate of Q(o)H(2) oxidation by the iron-sulfur protein (ISP) as well as the donation of electrons from ISP to c(1), and we discuss the results in the context of the movement of ISP between the Q(o) site and cytochrome c(1).