Studies on the reaction of imidazole with cytochrome c3 from Desulfovibrio vulgaris

1. Cytochrome c₃, a unique hemoprotein with a negative redox potential and four heme groups bound to a single polypeptide chain, reacts with imidazole in the reduced state to form a low-spin ferro · imidazole complex which is spectrally characterized by a 3.1 nm blue shift in the α-peak (from 550.5 to 547.4 nm). The spectral imidazole · cytochrome c₃ complex is detectable at 77 but not at 298 K.2. Mammalian ferrocytochrome c did not undergo a spectral interaction with imidazole at either 77 or 298 K, indicating that the imidazole · cytochrome c₃ complex reflects a unique event for cytochrome c₃.3. Formation of the imidazole · cytochrome c₃ complex is strongly dependent on imidazole concentration (apparent K_d of approx. 50 mM), and is abolished in the presence of 100 mM phosphate. This latter effect is attributable to formation of an imidazole · phosphate complex. A pH titration of the imidazole · cytochrome c₃ spectral complex implicates ionization of an imidazole function (pK = 8.5).4. EPR studies at 8.5 K of ferricytochrome c₃ before and after one reduction-oxidation cycle indicate that at least two of the hemes undergo reaction with imidazole forming two different low-spin ferric heme · imidazole complexes, with significant shifts in the g values of two heme signals.5. The spectral and EPR results are consistent with formation as the primary event of a low-spin ferrocytochrome c₃ · imidazole complex in which increased hydrophobicity and protonation-deprotonation effects are contributary to the consequent lability of cytochrome c₃.     

Isolation and preliminary characterization of new cytochrome c from autotrophic haloalkaliphilic sulfur-oxidizing bacterium Thioalkalivibrio nitratireducens

New small cytochrome c (TniCYT) was purified from haloalkaliphilic sulfur-oxidizing bacterium Thioalkalivibrio nitratireducens. The protein was analyzed by mass spectrometry as well as using visible, CD and EPR spectroscopy. It was found that TniCYT is a monomer with a molecular mass of 9461 Da which contains two hemes per molecule. The data of CD and EPR spectroscopy showed that two hemes possess different optical activity and are in distinct, high and low spin states. TniCYT was also demonstrated to have unusual characteristics in the visible spectrum, namely, the splitting of characteristic peaks was observed in α- and β-bands of the heme spectrum when the reduced form of cytochrome was analyzed. The α-band has two peaks with maximum at 548 and 556 nm whereas the β-band showes ones at 520 and 528 nm. According to the MALDI finger-print analysis, the new cytochrome has a unique amino acid sequence.     

The influence of pH on the EPR and redox properties of cytochrome c oxidase in detergent solution and in phospholipid vesicles

The EPR signals of oxidized and partially reduced cytochrome oxidase have been studied at pH 6.4, 7.4, and 8.4. Isolated cytochrome oxidase in both non-ionic detergent solution and in phospholipid vesicles has been used in reductive titrations with ferrocytochrome c.The g values of the low- and high-field parts of the low-spin heme signal in oxidized cytochrome oxidase are shown to be pH dependent. In reductive titrations, low-spin heme signals at g 2.6 as well as rhombic and nearly axial high-spin heme signals are found at pH 8.4, while the only heme signals appearing at pH 6.4 are two nearly axial g 6 signals. This pH dependence is shifted in the vesicles.The g 2.6 signals formed in titrations with ferrocytochrome c at pH 8.4 correspond maximally to 0.25–0.35 heme per functional unit (aa₃) of cytochrome oxidase in detergent solution and to 0.22 heme in vesicle oxidase. The total amount of high-spin heme signals at g 6 found in partially reduced enzyme is 0.45–0.6 at pH 6.4 and 0.1–0.2 at pH 8.4. In titrations of cytochrome oxidase in detergent solution the g 1.45 and g 2 signals disappear with fewer equivalents of ferrocytochrome c added at pH 8.4 compared to pH 6.4.The results indicate that the environment of the hemes varies with the pH. One change is interpreted as cytochrome a₃ being converted from a high-spin to a low-spin form when the pH is increased. Possibly this transition is related to a change of a liganded H₂O to OH^? with a concomitant decrease of the redox potential. Oxidase in phosphatidylcholine vesicles is found to behave as if it experiences a pH, one unit lower than that of the medium.     

Cytochrome c-556, a di-heme protein from Pseudomonas aeruginosa

A procedure is described for the purification of cytochrome c-556 from Pseudomonas aeruginosa. The isolated hemoprotein exists as a dimer with a molecular weight of approximately 77 200. The dimer can be dissociated into a monomeric species (or single polypeptide chain) of 40 500 molecular weight by means of sodium dodecyl sulfate or 4 M urea. The amino acid composition demonstrates the presence of four half-cystine residues per 43 000 molecular weight. Heme and iron analyses indicate that two c-type hemes are covalently linked to each polypeptide chain. The absorption spectrum of ferrocytochrome c-556 has a double α-band with a peak at 556 nm and a shoulder at 552 nm; the β-band appears at 521 nm and the Soret band at 420 nm.The electron paramagnetic resonance spectrum of ferricytochrome c-556 contains the elements of two ferric iron species, one a low spin and the other a high spin form.The function of cytochrome c-556 is obscure. The purified cytochrome does not react with Pseudomonas cytochrome oxidase nor with the Pseudomonas cytochrome c-551 or copper protein.The properties of cytochrome c-556 indicate that it is probably not the same species as the cytochrome c-554 previously isolated from the same organism.     

Reactions of mercaptans with cytochrome c oxidase and cytochrome c

1. The steady-state oxidation of ferrocytochrome c by dioxygen catalyzed by cytochrome c oxidase, is inhibited non-competitively towards cytochrome c by methanethiol, ethanethiol, 1-propanethiol and 1-butanethiol with K_i values of 4.5, 91, 200 and 330 μM, respectively.2. The inhibition constant K_i of ethanethiol is found to be constant between pH 5 and 8, which suggests that only the neutral form of the thiol inhibits the enzyme.3. The absorption spectrum of oxidized cytochrome c oxidase in the Soret region shows rapid absorbance changes upon addition of ethanethiol to the enzyme. This process is followed by a very slow reduction of the enzyme. The fast reaction, which represents a binding reaction of ethanethiol to cytochrome c oxidase, has a k₁ of 33 M^?1 · s^?1 and dissociation constant K_d of 3.9 mM.4. Ethanethiol induces fast spectral changes in the absorption spectrum of cytochrome c, which are followed by a very slow reduction of the heme. The rate constant for the fast ethanethiol reaction representing a bimolecular binding step is 50 M^?1 · s^?1 and the dissociation constant is about 2 mM. Addition of up to 25 mM ethanethiol to ferrocytochrome c does not cause spectral changes.5. EPR (electron paramagnetic resonance) spectra of cytochrome c oxidase, incubated with methanethiol or ethanethiol in the presence of cytochrome c and ascorbate, show the formation of low-spin cytochrome a₃-mercaptide compounds with g values of 2.39, 2.23, 1.93 and of 2.43, 2.24, 1.91, respectively.     

The EPR spectrum of isolated Complex III

It has been found that antimycin shifts the EPR signal of oxidized Complex III at g = 3.44 (ferricytochrome b-562) to g = 3.48, while the signal at g = 3.8 (ferricytochrome b-566) sharpens. Antimycin also affects the optical spectrum of ferricytochrome b by sharpening the α-band and splitting the γ-band. It is shown that nitric oxide reacts irreversibly with the non-heme iron components of Complex III. A reaction of NO with ferrocytochrome b-566 is suggested, resulting in lines at g = 2.10, 2.07 and 2.01.     

A 1H-NMR longitudinal relaxation study of the interaction between cytochrome c and cytochrome c oxidase

The interaction between the oxidized forms of cytochrome c and cytochrome c oxidase (EC 1.9.3.1) has been investigated by ¹H-NMR longitudinal relaxation measurements. It is found that relaxation of methyl groups on the heme ring of cytochrome c markedly deviates from a simple exponential behavior in the presence of small amounts of cytochrome oxidase. A comparison with the relaxation behavior of cytochrome c modified by 4-carboxy-3,5-dinitrophenyl at Lys-13 shows that the oxidase induces a conformation in native cytochrome c that is closely related to that of the derivative. It is suggested that this change in conformation consists of a rupture of the salt bridge between Lys-13 and Glu-90 and a concomitant perturbation of the methionine ligand.     

Copper and manganese electron spin resonance studies of cytochrome c oxidase from Paracoccus denitrificans

The two-subunit cytochrome c oxidase from Paracoccus denitrificans contains two heme a groups and two copper atoms. However, when the enzyme is isolated from cells grown on a commonly employed medium, its electron paramagnetic resonance (EPR) spectrum reveals not only a Cu(II) powder pattern, but also a hyperfine pattern from tightly bound Mn(II). The pure Mn(II) spectrum is observed at ?40°C; the pure Cu(II) spectrum can be seen with cytochrome c oxidase from P. denitrificans cells that had been grown in a Mn(II)-depleted medium. This Cu(II) spectrum is very similar to that of cytochrome c oxidase from yeast or bovine heart. Manganese is apparently not an essential component of P. denitrificans cytochrome c oxidase since it is present in substoichiometric amounts relative to copper or heme a and since the manganese-free enzyme retains essentially full activity in oxidizing ferrocytochrome c. However, the manganese is not removed by EDTA and its EPR spectrum responds to the oxidation state of the oxidase. In contrast, manganese added to the yeast oxidase or to the manganese-free P. denitrificans enzyme can be removed by EDTA and does not respond to the oxidation state of the enzyme. This suggests that the manganese normally associated with P. denitrificans cytochrome c oxidase is incorporated into one or more internal sites during the biogenesis of the enzyme.     

Nitric Oxide Binds to the Proximal Heme Coordination Site of the Ferrocytochrome c/Cardiolipin Complex: FORMATION MECHANISM AND DYNAMICS*

Mammalian mitochondrial cytochrome c interacts with cardiolipin to form a complex (cyt. c/CL) important in apoptosis. Here we show that this interaction leads to structural changes in ferrocytochrome c that leads to an open coordinate site on the central iron, resulting from the dissociation of the intrinsic methionine residue, where NO can rapidly bind (k = 1.2 × 10⁷ m⁻¹ s⁻¹). Accompanying NO binding, the proximal histidine dissociates leaving the heme pentacoordinate, in contrast to the hexacoordinate nitrosyl adducts of native ferrocytochrome c or of the protein in which the coordinating methionine is removed by chemical modification or mutation. We present the results of stopped-flow and photolysis experiments that show that following initial NO binding to the heme, there ensues an unusually complex set of kinetic steps. The spectral changes associated with these kinetic transitions, together with their dependence on NO concentration, have been determined and lead us to conclude that NO binding to cyt. c/CL takes place via an overall scheme comparable to that described for cytochrome c′ and guanylate cyclase, the final product being one in which NO resides on the proximal side of the heme. In addition, novel features not observed before in other heme proteins forming pentacoordinate nitrosyl species, include a high yield of NO escape after dissociation, rapid (<1 ms) dissociation of proximal histidine upon NO binding and its very fast binding (60 ps) after NO dissociation, and the formation of a hexacoordinate intermediate. These features all point at a remarkable mobility of the proximal heme environment induced by cardiolipin.     

Oxido-reductive titrations of cytochrome c oxidase followed by EPR spectroscopy

Experiments are described on oxido-reductive titrations of cytochrome c oxidase as followed by low-temperature EPR and reflectance spectroscopy. The reductants were cytochrome c or NADH and the oxidant ferricyanide. Experiments were conducted in the presence and absence of either cytochrome c or carbon monoxide, or both. An attempt is made to provide a complete quantitative balance of the changes observed in the major EPR signals. During reduction, the maximal quantity of heme represented in the high-spin ferric heme signals (g ～ 6; 2) is 25% of the total heme present, and during reoxidation 30%. With NADH reduction there is little difference between the pattern of disappearance of the low-spin ferric heme signals in the absence or presence of cytochrome c. The copper and high-spin heme signals, however, disappear at higher titrant concentrations in the presence of cytochrome c than in its absence. In these titrations, as well as in those with ferrocytochrome c, the quantitative balance indicates that, in addition to EPR-detectable components, EPR-undetectable components are also reduced, increasingly so at higher titrant concentrations. The quantity of EPR-undetectable components reduced appears to be inversely related to pH. A similar inverse relationship exists between pH and appearance of high-spin signals during the titration. At pH 9.3 the quantity of heme represented in the high-spin signals is < 5%, whereas it approximately doubles from pH 7.4 to pH 6.1. In the presence of CO less of the low-spin heme and copper signals disappears for the same quantity of titrant consumed, again implying reduction of EPR undetectable components. At least one of these components is represented in a broad absorption band centered at 655 nm. The stoichiometry observed on reoxidation, particularly in the presence of CO, is not compatible with the notion that the copper signal represents 100% of the active copper of the enzyme as a pair of interacting copper atoms.     

A covalent complex between horse heart cytochrome c and yeast cytochrome c peroxidase: kinetic properties

The kinetic properties of a 1:1 covalent complex between horse-heart cytochrome c and yeast cytochrome c peroxidase (ferrocytochrome-c:hydrogen-peroxide oxidoreductase, EC 1.11.1.5) have been investigated by transient-state and steady-state kinetic techniques. Evidence for heterogeneity in the complex is presented. About 50% of the complex reacts with hydrogen peroxide with a rate 20–40% faster than that of native enzyme; 20% of the complex exists in a conformation which does not react with hydrogen peroxide but converts to the reactive form at a rate of 20 ± 5 s⁻¹; 30% of the complex does not react with hydrogen peroxide to form the oxidized enzyme intermediate, cytochrome c peroxidase Compound I. Intramolecular electron transfer between covalently bound ferrocytochrome c and an oxidized site in cytochrome c peroxidase Compound I is too fast to measure, but a lower limit of 600 s⁻¹ can be estimated at 5°C in a 10 mM potassium phosphate buffer at pH 7.5. Free ferrocytochrome c reduces cytochrome c peroxidase Compound I covalently bound to ferricytochrome c at a rate 10⁻⁴ to 10⁻⁵-times slower than for free Compound I. The transient-state ferrocytochrome c reduction rates of Compound I covalently linked to ferricytochrome c are about 70-times too slow to account for the steady-state catalytic properties of the 1:! covalent complex. This indicates that hydrogen peroxide can interact with the 1:1 complex at sites other than the heme of cytochrome c peroxidase, generating additional species capable of oxidizing free ferrocytochrome c.     

Responses of the a3 component of cytochrome c oxidase to substrate and ligand addition

We have previously described a transient high spin ferric heme species in cytochrome c oxidase (EC 1.9.3.1) which represents a³⁺₃ (Beinert, H. and Shaw, R.W. (1977) Biochim. Biophys. Acta 462, 121–130), and can be detected and quantitatively determined by EPR. We have now used our ability to generate this species to study reactions of a³⁺₃ with substrates and ligands and also responses to pH changes. This was accomplished by multiple rapid mixing and freezing techniques in conjunction with low temperature EPR and optical reflectance spectroscopies. The substrates used were O₂ and ferrocytochrome c and the ligands cyanide, sulfide, azide and carbon monoxide. Contrary to the oxidized, resting form of the enzyme, the transient high spin species of a³⁺₃ reacts within <10 ms stoichiometrically with cyanide and sulfide and at a slower rate with azide. The transient a³⁺₃ species responds to O₂ and CO by changes in signal size or shape, although no oxidoreduction is involved, indicating that a³⁺₃ registers the presence of these gases. The high spin signal of the transient species is readily abolished by ferrocytochrome c or on raising the pH. Decreasing the pH induces a shift from the rhombic towards the axial component of the signal. Since the responses to CO and pH are analogous for the rhombic transient species to those observed with the rhombic high spin ferric heme species produced on partial reduction, it is suggested that the rhombic signals represent a³⁺₃ in either case. In all these experiments, in which EPR detectable a³⁺₃ was observed in large yield, no extra signals for copper or correspondingly increased intensity in the copper signal at g = 2 were seen. The relationship is discussed of the obviously reactive transient species of a³⁺₃ to other ‘activated’ species that have been reported and to the oxidized resting form of the enzyme, which is known to react only slowly with ligands and to respond sluggishly to substrate.     

Cytochrome c interaction with membranes. II. Comparative study of the interaction of c cytochromes with the mitochondrial membrane

A comparative study of the interaction of various cytochromes c with phospholipid vesicles and with mitochondrial membranes was undertaken. Both mammalian and yeast types of cytochrome c bind preferentially in the oxidized form as evidenced by the midpoint redox potential (E_m 7.0) becoming more negative upon binding. Cytochrome c which is reincorporated into cytochrome c-depleted mitochondria is kinetically comparable with the native cytochrome c component; rate of cytochrome b oxidation is maximally restored at ratios of c₁:c:a of 1:1:1. Comparison between the electron paramagnetic spectrum of cytochrome c labeled at methionine 65 or cysteine 103 reveals that upon binding to the mitochondrial membrane, the former is immobilized and not the latter. This result suggests that cytochrome c binds to the membrane at the side at which methionine 65 is located.     

Biochemical and biophysical studies on cytochrome c oxidase XVI. Circular dichroic study of cytochrome c oxidase and its ligand complexes

1. CD spectra of cytochrome c oxidase have been determined both in the absence and presence of the extrinsic ligands CO, NO, cyanide and azide.2. CO and NO affect the CD spectrum of cytochrome c oxidase in a similar way.3. Cyanide and azide also affect the CD spectrum of cytochrome c oxidase in a similar way, but distinctly different from CO and NO.4. From the CD spectra of the oxidized and reduced enzyme, in the presence and absence of extrinsic ligands, CD difference spectra (reduced minus oxidized) are calculated for the so-called cytochrome a and cytochrome a₃ moieties of the enzyme.5. These spectra are largely dependent on the extrinsic ligand used. It is therefore concluded that these spectra do not represent independent cytochrome a and cytochrome a₃ difference spectra, but that heme-heme interactions occur within the cytochrome c oxidase molecule, in such a way that binding of a ligand to one of the heme a groups of cytochrome c oxidase affects the spectral properties of the other heme a group.6. As a consequence, ligand-binding studies cannot give information as to the pre-existence of separate cytochrome a and cytochrome a₃ moieties in the absence of extrinsic ligands.     

Methionine sulfoxide cytochrome c.

Cytochrome c has been chemically modified by methylene blue mediated photooxidation. It is established that the methionine residues of the protein have been specifically converted to methionine sulfoxide residues. No oxidation of any other amino acid residues or the cysteine thioether bridges of the molecule occurs during the photooxidation reaction. The absorbance spectrum of methionine sulfoxide ferricytochrome c at neutrality is similar to that of the unmodified protein except for an increase in the extinction coefficient of the Soret absorbance band and for the complete loss of the ligand sensitive 695 nm absorbance band in the spectrum of the derivative. The protein remains in the low spin configuration which implies the retention of two strong field ligands. Spin state sensitive spectral titrations and model studies of heme peptides indicate that the sixth ligand is definitely not provided by a lysine residue but may be methionine-80 sulfoxide coordinated via its sulfur atom. Circular dichroism spectra indicate that the heme crevice of methionine sulfoxide ferri- and ferrocytochrome c is weakened relative to native cytochrome c. The redox potential of methionine sulfoxide cytochrome c is 184 mV which is markedly diminished from the 260 mV redox potential of native cytochrome c. The modified protein is equivalent to native cytochrome c as a substrate for cytochrome oxidase and is not autoxidizable at neutral pH but is virtually inactive with succinate-cytochrome c reductase. These results indicate that the major role of the methionine-80 in cytochrome c is to preserve a closed hydrophobic heme crevice which is essential for the maintainance of the necessary redox potential.     

The reactivity of cytochrome c with soft ligands

The spectral changes caused by binding soft ligands to the cytochrome c iron and their correlation to ligand affinities support the hypothesis that the iron—methionine sulfur bond of this heme protein is enhanced by delocalization of the metal l₂, electrons into the empty 3d orbitals of the ligand atom. These findings also explain the unique spectrum of cytochrome c in the far red.     

Kinetic studies on cytochrome c oxidase by combined EPR and reflectance spectroscopy after rapid freezing

1. Techniques and experiments are described concerned with the millisecond kinetics of EPR-detectable changes brought about in cytochrome c oxidase by reduced cytochrome c and, after reduction with various agents, by reoxidation with O₂ or ferricyanide. Some experiments in the presence of ligands are also reported. Light absorption was monitored by low-temperature reflectance spectroscopy.2. In the rapid phase of reduction of cytochrome c oxidase by cytochrome c (< 50 ms) approx. 0.5 electron equivalent per hame a is transferred mainly to the low-spin heme component of cytochrome c oxidase and partly to the EPR-detectable copper. In a slow phase (> 1 s) the copper is reoxidized and high-spin ferric heme signals appear with a predominant rhombic component. Simultaneously the absorption band at 655 nm decreases and the Soret band at 444 nm appears between the split Soret band (442 and 447 nm) of reduced cytochrome a.3. On reoxidation of reduced enzyme by oxygen all EPR and optical features are restored within 6 ms. On reoxidation by O₂ in the presence of an excess of reduced cytochrome c, states can be observed where the low-spin heme and copper signals are largely absent but the absorption at 655 nm is maximal, indicating that the low-spin heme and copper components are at the substrate side and the component(s) represented in the 655 nm absorption at the O₂ side of the system. On reoxidation with ferricyanide the 655 nm absorption is not readily restored but a ferric high-spin heme, represented by a strong rhombic signal, accumulates.4. On reoxidation of partly reduced enzyme by oxygen, the rhombic high-spin signals disappear within 6 ms, whereas the axial signals disappear more slowly, indicating that these species are not in rapid equilibrium. Similar observations are made when partly reduced enzyme is mixed with CO.5. The results of this and the accompanying paper are discussed and on this basis an assignment of the major EPR signals and of the 655 nm absorption is proposed, which in essence is that published previously (Hartzell, C. R., Hansen, R. E. and Beinert, H. (1973) Proc. Natl. Acad. Sci. U.S. 70, 2477–2481). Both the low-spin (g = 3; 2.2; 1.5) and slowly appearing high-spin (g = 6; 2) signals are attributed to ferric cytochrome a, whereas the 655 nm absorption is thought to arise from ferric cytochrome a₃, when it is present in a state of interaction with EPR-undetectable copper. Alternative possibilities and possible inconsistencies with this proposal are discussed.     

Interaction of beta-lactoglobulin and cytochrome c: complex formation and iron reduction.

β-Lactoglobulin forms a soluble complex with cytochrome c in mildly alkaline solutions of low ionic strength. Sedimentation velocity experiments suggest that the complex (maximum s₂₀ = 3.7) consists of one cytochrome c molecule per β-lactoglobulin monomer unit. At pH 8 or higher, the presence of β-lactoglobulin causes reduction of ferri- to ferrocytochrome c. The initial rate of reduction at a single temperature depends primarily on the concentration of β-lactoglobulin, although the final percentage ferrocytochrome c obtained is constant at molar ratios of three or more β-lactoglobulin monomers to one cytochrome c molecule. The temperature dependence of the initial rate of iron reduction resembles that for alkaline denaturation of β-lactoglobulin. The displacement of N-dansylaziridine, a sulfhydryl specific dye, from bovine β-lactoglobulin during iron reduction, and the formation of nonreducing complexes between the analogous swine protein (no sulfhydryls) and cytochrome c suggest that the sulfhydryl group of β-lactoglobulin is the electron donor.     

One-electron reactions in biochemical systems as studied by pulse radiolysis. VI. Stages in the reduction of ferricytochrome c

When ferricytochrome c at pH about 9 is reduced by hydrated electrons and/or CO₂^?, it gives rise to an unstable form of ferrocytochrome c whose absorption spectrum, particularly in the Soret region, differs from that of normal ferrocytochrome c. This form changes intramolecularly (life-time about 0.1 s at ambient temperature) to yield normal ferrocytochrome c, and by 0.5 s the change in absorption spectrum in the range 225–600 nm produced by e^?_aq and/or CO₂^? is identical to the final change produced by reduction with an equivalent amount of sodium dithionite. This shows that both e^?_aq and CO^?₂ reduce cytochrome c with practically 100% efficiency. In the range 600–800 nm the spectrum of the unstable form is the same as that of normal ferrocytochrome c, both having small absorptions at 695 nm as compared with ferricytochrome c. As the unstable form disappears however a further loss of absorption at 695 nm occurs. This is taken to imply that the unstable form decays to a second unstable form which then rapidly donates an electron to the unchanged neutral form of ferricytochrome c, so reducing absorption in the 695 nm band. Subsequent to this process the absorption in the 695 nm band increases over a period of minutes owing to re-equilibration between the neutral and alkaline formes of ferricytochrome c. Between pH 7 and 10 the effect of pH on the absorption changes is consistent with the hypothesis of a second unstable form of ferrocytochrome c. Additional phenomena arise in more alkaline solutions. The rates of the various unimolecular processes are thought to be determined by the rates of change of conformation of the protein parts of the molecule following the change in oxidation state.