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1.
1. The reduction of cytochrome c oxidase by hydrated electrons was studied in the absence and presence of cytochrome c.

2. Hydrated electrons do not readily reduce the heme of cytochrome c oxidase. This observation supports our previous conclusion that heme a is not directly exposed to the solvent.

3. In a mixture of cytochrome c and cytochrome c oxidase, cytochrome c is first reduced by hydrated electrons (k = 4 · 1010 M−1 · s−1 at 22 °C and pH 7.2) after which it transfers electrons to cytochrome c oxidase with a rate constant of 6 · 107 M−1 · s−1 at 22 °C and pH 7.2.

4. It was found that two equivalents of cytochrome c are oxidized initially per equivalent of heme a reduced, showing that one electron is accepted by a second electron acceptor, probably one of the copper atoms of cytochrome c oxidase.

5. After the initial reduction, redistribution of electrons takes place until an equilibrium is reached similar to that found in redox experiments of Tiesjema, R. H., Muijsers, A. O. and Van Gelder, B. F. (1973) Biochim. Biophys. Acta 305, 19–28.  相似文献   


2.
Superoxide anions (O2.−) generated by the reaction of xanthine with xanthine oxidase were measured by the reduction of cytochrome c and by electron paramagnetic resonance (EPR) spectroscopy using the spin trap 5,5-dimethyl-1-pyrroline-N-oxide (DMPO). Studies were performed to determine the relative sensitivities of these two techniques for the measurement of O2.−. Mixtures of xanthine, xanthine oxidase, DMPO generated two adducts, a transient DMPO-OOH and a smaller but longer-lived DMPO-OH. Both adducts were inhibited by superoxide dismutase (SOD), demonstrating they originated from O2.−, and were also significantly decreased when the experiments were performed using unchelated buffers, suggesting that metal ion impurities in unchelated buffers alter the formation or degradation of DMPO-adducts. O2.−, generated by concentrations of xanthine as low as 0.05 μM, were detectable using EPR spin trapping. In contrast, mixtures of xanthine, xanthine oxidase, and cytochrome c measured spectrophotometrically at 550 nm demonstrated that concentrations of xanthine above 1 μM were required to produce measurable levels of reduced cytochrome c. These studies demonstrate that spin trapping using DMPO was at least 20-fold more sensitive than the reduction of cytochrome c for the measurement of superoxide anions. However, at levels of superoxide generation where cytochrome c provides a linear measurement of production, EPR spin trapping may underestimate radical production, probably due to degradation of DMPO radical adducts.  相似文献   

3.
P.Muir Wood 《BBA》1974,357(3):370-379
The rate of electron transfer between reduced cytochrome ƒ and plastocyanin (both purified from parsley) has been measured as k = 3.6 · 107 M−1 · s−1, at 298 °K and pH 7.0, with activation parameters ΔH = 44 kJ · mole−1 and ΔS = +46 J · mole−1 · °K−1. Replacement of cytochrome ƒ with red algal cytochrome c-553, Pseudomonas cytochrome c-551 and mammalian cytochrome c gave rates at least 30 times slower: k = 5 · 105, 7.5 · 105 and 1.0 · 106 M−1 · s−1, respectively.

Similar measurements made with azurin instead of plastocyanin gave k = 6 · 106 and approx. 2 · 107 M−1 · s−1 for reaction of reduced azurin with cytochrome ƒ and algal cytochrome respectively.

Rate constants of 115 and 80 M−1 · s−1 were found for reduction of plastocyanin by ascorbate and hydroquinone at 298 °K and pH 7.0. The rate constants for the oxidation of plastocyanin, cytochrome ƒ, Pseudomonas cytochrome c-551 and red algal cytochrome c-553 by ferricyanide were found to be between 3 · 104 and 8 · 104 M−1 · s−1.

The results are discussed in relation to photosynthetic electron transport.  相似文献   


4.
Direct evidence obtained by means of the technique of pulse radiolysis-kinetic spectrometry, with measurements in the time range 10−6 to 1 s, is presented that, consequent upon reaction of a single H-atom with a single molecule of ferricytochrome c, a reducing equivalent is transmitted via the protein structure to the ferriheme moiety. Such transmission accounts for at least 70% of the total reduction of the ferri to the ferro state of cytochrome c. The remainder of the total reduction takes place without stages resolvable on the time scale of these experiments. Reduction brought about by H atoms appears to follow a different course than reduction by hydrated electrons. In the latter case, intramolecular transmission of reducing equivalents could not be demonstrated (Lichtin, N. N., Shafferman, A. and Stein, G. (1973) Biochim. Biophys. Acta 314, 117–135).

Not every H-atom reacts with ferricytochrome c at a site which results in conversion of the Fe(III) state to the Fe(II) state. Approximately half of reacting H-atoms do not produce reduction.

The following second order rate constants have been determined in solutions of low ionic strength at 20±2 °C: k[H+ferricytochrome c] = (1.0±0.2) · 1010 M−1 · s−1 at pH 3.0 and 6.7; k[H+ferrocytochrome c] = (1.3±0.2) · 1010 M−1 · s−1 at pH 3.0; k[eaq + ferrocytochrome c] = (1.9±0.4) · 1010 M−1 · s−1 at pH 6.7.  相似文献   


5.
Hiroshi Seki  Yael A. Ilan  Yigal Ilan  Gabriel Stein   《BBA》1976,440(3):573-586
The reduction of ferricytochrome c by O2 and CO2 was studied in the pH range 6.6–9.2 and Arrhenius as well as Eyring parameters were derived from the rate constants and their temperature dependence. Ionic effects on the rate indicate that the redox process proceeds through a multiply-positively charged interaction site on cytochrome c. It is shown that the reaction with O2 and correspondingly with O2 of ferrocytochrome c) is by a factor of approx. 103 slower than warranted by factors such as redox potential. Evidence is adduced to support the view that this slowness is connected with the role of water in the interaction between O2/O2 and ferri-ferrocytochrome c in the positively charged interaction site on cytochrome c in which water molecules are specifically involved in maintaining the local structure of cytochrome c and participate in the process of electron equivalent transfer.  相似文献   

6.
Horse-heart ferrocytochrome c has been labeled with N-(2,2,5,5-tetramethyl-3-pyrrolidinyl-1-oxyl) iodoacetamide at methionine-65. The paramagnetic resonance spectrum of labeled ferricytochrome c indicates a weak immobilization of the radical (τc = 9.3·10−10 sec) which becomes stronger upon binding of labeled cytochrome c to cytochrome c-depleted mitochondrial membranes (τc = 3.3·10−9 sec). The hyperfine coupling constant remains, however, unchanged (16.7 ± 0.1 gauss) indicating that the cytochrome c binding site is highly polar. The region where cytochrome c is bound to the membrane is insensitive to large variations of medium viscosity.  相似文献   

7.
J. Butler  G.G. Jayson  A.J. Swallow 《BBA》1975,408(3):215-222

1. 1. The superoxide anion radical (O2) reacts with ferricytochrome c to form ferrocytochrome c. No intermediate complexes are observable. No reaction could be detected between O2 and ferrocytochrome c.

2. 2. At 20 °C the rate constant for the reaction at pH 4.7 to 6.7 is 1.4 · 106 M−1 · s−1 and as the pH increases above 6.7 the rate constant steadily decreases. The dependence on pH is the same for tuna heart and horse heart cytochrome c. No reaction could be demonstrated between O2 and the form of cytochrome c which exists above pH ≈ 9.2. The dependence of the rate constant on pH can be explained if cytochrome c has pKs of 7.45 and 9.2, and O2 reacts with the form present below pH 7.45 with k = 1.4 · 106 M−1 · s−1, the form above pH 7.45 with k = 3.0 · 105 M−1 · s−1, and the form present above pH 9.2 with k = 0.

3. 3. The reaction has an activation energy of 20 kJ mol−1 and an enthalpy of activation at 25 °C of 18 kJ mol−1 both above and below pH 7.45. It is suggested that O2 may reduce cytochrome c through a track composed of aromatic amino acids, and that little protein rearrangement is required for the formation of the activated complex.

4. 4. No reduction of ferricytochrome c by HO2 radicals could be demonstrated at pH 1.2–6.2 but at pH 5.3, HO2 radicals oxidize ferrocytochrome c with a rate constant of about 5 · 105–5 · 106 M−1 · s−1

.  相似文献   


8.
Three-dimensionally (3D) ordered macroporous active carbon has been fabricated and used as electrode substrate for the direct electrochemistry of horse heart cytochrome c (Cyt c). The Cyt c immobilized on the surface of the ordered macroporous active carbon shows a pair of well-defined and nearly reversible redox waves at the formal potential of −0.033 V in pH 6.8 phosphate buffer solution. The interaction between Cyt c and the 3D macroporous active carbon makes the formal potential shift negatively compared to that of Cyt c in solution. Spectrophotometric and electrochemical methods have been used to investigate the interaction between Cyt c and the porous active carbon. The immobilized Cyt c maintains its biological activity, and shows a surface controlled electrode process with the electron-transfer rate constant (ks) of 17.6 s−1 and the charge-transfer coefficient (a) of 0.52, and displays the features of a peroxidase in the electrocatalytic reduction of hydrogen peroxide (H2O2). A potential application of the Cyt c-immobilized porous carbon electrode as a biosensor to monitor H2O2 has been investigated. The steady-state current response increases linearly with H2O2 concentration from 2.0 × 10−5 to 2.4 × 10−4 mol l−1. The detection limit (3σ) for determination of H2O2 has been found to be 1.46 × 10−5 mol l−1.  相似文献   

9.
Y. Lam  D. J. D. Nicholas 《BBA》1969,180(3):459-472
The formation of nitrite reductase and cytochrome c in Micrococcus denitrificans was repressed by O2. The purified nitrite reductase utilized reduced forms of cytochrome c, phenazine methosulphate, benzyl viologen and methyl viologen, respectively, as electron donors. The enzyme was inhibited by KCN, NaN3 and NH2OH each at 1 mM, whereas CO and bathocuproin, diethyl dithiocarbamate, o-phenanthroline and ,'-dipyridyl at 1 mM concentrations were relatively ineffective. The purified enzyme contains cytochromes, probably of the c and a2 types, in one complex. A Km of 46 μM for NO2 and a pH optimum of 6.7 were recorded for the enzyme. The molecular weight of the enzyme was estimated to be around 130000, and its anodic mobility was 6.8·10−6 cm2·sec−1·V−1 at pH 4.55.

The most highly purified nitrite reductase still exhibited cytochrome c oxidase activity with a Km of 27 μM for O2. This activity was also inhibited by KCN, NaN3 and NH2OH and by NO2.

A constitutive cytochrome oxidase associated with membranes was also isolated from cells grown anaerobically with NO2. It was inhibited by smaller amounts of KCN, NaN3 and NH2OH than the cytochrome oxidase activity of the nitrite reductase enzyme and also differed in having a pH optimum of about 8 and a Km for O2 of less than 0.1 μM. Spectroscopically, cytochromes b and c were found to be associated with the constitutive oxidase in the particulate preparation. Its activity was also inhibited by NO2.

The physiological role of the cytochrome oxidase activity associated with the purified nitrite reductase is likely to be of secondary importance for the following reasons: (a) it accounts for less than 10% of total cytochrome c oxidase activity of cell extracts; (b) the constitutive cytochrome c oxidase has a smaller Km for O2 and would therefore be expected to function more efficiently especially at low concentrations of O2.  相似文献   


10.
J. A. Berden  E. C. Slater 《BBA》1970,216(2):237-249
1. Succinate-cytochrome c reductase activity was reconstituted by incubating a mixture of succinate dehydrogenase, cytochrome c1, ubiquinone-10, phospholipid and a preparation of cytochrome b, made by the method of .

2. Preparations of cytochrome b active in reconstitution contained 5–28% native cytochrome b, as adjudged by reducibility with succinate in the reconstituted preparation and by lack of reaction with CO. Preparations of cytochrome b containing no native cytochrome b according to this criterion were inactive in reconstitution.

3. With a fixed amount of cytochrome b, the activity of the reconstituted preparation increased with increasing amounts of cytochrome c1 until a ratio of about 2b (total): 1c1 (allowing for the cytochrome c1 present in the cytochrome b preparation) was reached.

4. The amount of antimycin necessary for maximal inhibition of the reconstituted enzyme is a function of the amount of the cytochrome b and is independent of the amount of cytochrome c1. It is equal to about one half the amount of native cytochrome b.

5. Preparations of intact or reconstituted succinate-cytochrome c reductase or of cytochrome b completely quench the fluorescence of added antimycin, until an amount of antimycin equal to onehalf the amount of native cytochrome b present was added. Antimycin added in excess of this amount fluoresces with normal intensity. The quenching is only partial in the presence of Na2S2O4. Denatured cytochrome b does not quench the fluorescence.

6. Since preparations of cytochrome b active in reconstitution contained cytochrome c1 in an amount exceeding one half the amount of native cytochrome b present in the preparation, there is no evidence that native cytochrome b has been resolved from cytochrome c1. The stimulatory action of cytochrome c1 may be due to the restoration of a damaged membrane conformation.

7. Based on the assumption that the bc1 segment of the respiratory chain contains 2b:1c1:1 antimycin-binding sites, the specific quenching of antimycin fluorescence by binding to cytochrome b enables an accurate determination of the absorbance coefficients of cytochromes b and c1. These are 25.6 and 20.1 mM−1×cm−1 for the wavelength pairs 563–577 nm and 553–539 nm, respectively, in the difference spectrum reduced minus oxidized.  相似文献   


11.
The interaction of horse ferricytochrome c with the reagents [Fe(EDTA)(H2O)] and [Cr(CN)6]3− were studied at pH 7 and 25°C by 1H-NMR spectroscopy. Two binding regions near to the heme crevice of cytochrome c were identified. Both regions bound both reagents but they exhibited different selectivities.

The relevance of this finding to the electron-transfer function of cytochrome c is discussed.  相似文献   


12.
The Fe3+-doxorubicin complex undergoes reactions that suggest that the complex self-reduces to a ferrous oxidized-doxorubicin free radical species. The Fe3+-doxorubicin system is observed to reduce ferricytochrome c, consume O2 and react with 2,2′-bipyridine. Bipyridine acts as a “ferrous ion scavenger” as it reacts with the ferrous ion produced by Fe3+-doxorubicin self-reduction. In the absence of O2, a ferrous doxorubicin complex accumulates. In the presence of oxygen, Fe2+ recycles back to Fe3+. The rates of these reactions were measured and the Fe3+-doxorubicin self-reduction was determined to be the rate-determining step. The Fe3+-doxorubicin induced inactivation of cytochrome c oxidase and NADH cytochrome c reductase on beef heart submitochondrial particles occurs at a rate similar to Fe3+-doxorubicin self-reduction. Thus the rate at which damage to these mitochondrial enzymes occurs may be controlled by a nonezymatic Fe3+-doxorubicin self-reduction.  相似文献   

13.
Inhibition by 3-(3,4-dichlorophenyl)-1,1-dimethylurea (DCMU) of the following partial reactions of bacterial photosynthesis has been examined using chromatophores prepared from light-grown Rhodospirillum rubrum: ascorbate- and PMS-induced photophosphorylation, NADH oxidation, NADH oxidatively coupled phosphorylation, NADH-cytochrome c2 reduction, succinate-NAD+ photoreduction, and anaerobic NADH oxidation by fumarate. All of these reactions were found to be inhibited by DCMU (and 3-(p-chlorophenyl)-1,1-dimethylurea) at concentrations in the 0.1 to 1.0 mM range. However, succinate-cytochrome c2 reduction, NADH-2,6-dichlorophenolindophenol reduction and soluble NADH: cytochrome c2 reductase were not inhibited. Based on these findings, it is proposed that DCMU and related compounds inhibit electron transport in chromatophores at a site(s) between NADH and either cytochrome b or a component on the reducing side of cytochrome b.  相似文献   

14.
C.H. Huang  C.P. Lee   《BBA》1975,376(3):398-414
We have recently reported that with a linear sucrose density gradient centrifugation two distinct types of membrane fragments, designated as X- and Y-fragments are obtained (Huang, C. H., Keyhani, E. and Lee, C. P. (1973) Biochim. Biophys. Acta 305, 455–473). Further characterization of these two membrane fragments is reported. (1) Potassium chloride at the concentration of 0.15 M extracts 7% and 30% of cytochrome c from the X- and Y-fragments, respectively. (2) When cytochrome c was added to the mitochondrial suspension prior to sonication, the cytochrome c content was increased by 6–8-fold in both X- and Y-fragments. Subsequently KCl extraction resulted in loss of cytochrome c by 1/4 in the X- and by 2/3 in the Y-fragments. (3) With partially inhibitory concentrations of KCN, cytochrome c in either the X- or the KCl extracted X-fragments showed uncoupler-sensitive, biphasic reduction kinetics upon the addition of NADH to the oligomycin-supplemented system. Under identical conditions rapid first order reduction kinetics were seen for cytochrome c in Y-fragments supplemented with either oligomycin or oligomycin + carbonyl cyanide p-trifluoromethoxyphenylhydrazone (FCCP). (4) When cytochrome c was added to the mitochondrial suspension after sonication, a significant amount of cytochrome c was bound to both X- and Y-fragments, but was readily removed with a high ionic strength medium. (5) Lubrol had little effect on the ATPase activity of the X- and the Y-fragments, suggesting a lack of membrane-buried ATPase. (6) Partial depletion of ATPase in X-fragments did not induce an increase in reactivity towards externally added cytochrome c. (7) Both the X- and the Y-fragments showed an energy-linked fluorescence enhancement of 8-anilinonaphthalene-1-sulfonate and an energy-linked fluorescence decrease of quinacrine. (8) In the presence of K+ nigericin alone or in combination with valinomycin exhibited a stimulating effect on the rate of NADH oxidase of the oligomycin-supplemented X- and Y-fragments.  相似文献   

15.
Toshikazu Noguchi  Minoru Nakano 《BBA》1974,368(3):446-455
Purified NADPH cytochrome c reductase catalyzes the oxidation of NADPH in the presence of Fe3+, ADP and EDTA. EDTA in this system appears to elevate the redox potential of ferric ion and of its iron complex thereby facilitating the transfer of one electron from NADPH to tri-valent iron (more rapidly than superoxide is formed) through a flavin moiety in the reductase, but it diminishes the concentration of free iron to be required for phospholipid peroxidation.

The reduction of Fe3+ by the xanthine-xanthine oxidase system is different from that manifested by the NADPH-NADPH cytochrome c reductase system in the manner in which the former is carried out in the main by Ostaggered2staggered− · generated by the substrate - O2 - enzyme interaction.

Reduced iron, which is free in the solution, plays an important role for the initiation and propagation of the phospholipid peroxidation, monitored by malondialdehyde assay and light emission.

In the xanthine-induced lipoxygenation system, the ·OH radical, probably produced from hydrogen peroxide by the action of Fe2+, is not involved in the initiation of the peroxidative cleavage of phospholipid in microsomal lipoprotein.  相似文献   


16.
The kinetics of the reaction of hydrated electron (eaq) and carboxyl anion radical (CO2) with Pseudomonas aeruginosa ferricytochrome c-551 were studied by pulse radiolysis. The rate of reaction of eaq with the negatively charged ferricytochrome c-551 (17 nM−1 · s−1) is significantly slower than the larger positively charged horse heart ferricytochrome c (70 nM · s). This difference cannot be explained solely by electrostatic effects on the diffusion-controlled reactions. After the initial encounter of eaq with the protein, ferricytochrome c-551 is less effective in transferring an electron to the heme which may be due to the negative charge on the protein. The charge on ferricytochrome c-551 is estimated to be −5 at pH 7 from the effect of ionic strength on the reaction rate. A slower relaxation (2 · 104 s−1) observed after fast eaq reduction is attributed to a small conformational change. The rate of reaction of CO2 with ferricytochrome c-551 (0.7 nM−1 · s) is, after electrostatic correction, the same as ferricytochrome c, indicating that the steric requirements for reaction are similar. This reaction probably takes place through the exposed heme edge.  相似文献   

17.
《BBA》1972,275(3):485-490
Formation of a membrane potential in two types of liposomes, one inlayed with cytochrome c + cytochrome oxidase, and another, with oligomycin-sensitive ATPase, has been demonstrated. To detect a membrane potential, phenyl dicarbaundecaborane (PCB), a penetrating anion probe, was used.

The first type of liposome was reconstituted from a solution of purified cytochrome oxidase, mitochondrial phospholipids and cytochrome c, the latter being enclosed inside liposomes. Cytochrome c bound to the outer surface of the liposome membrane was removed by washing with NaCl. Such liposomes catalyzed oxidation of ascorbate by oxygen in the presence of phenazine methosulfate or N,N,N′,N′-tetramethyl-p-phenylenediamine. The oxidation was found to support the PCB uptake by liposomes. The PCB response was prevented and reversed by cyanide, protonophorous uncouplers and external cytochrome c.

Liposomes of the second type were prepared from a solution of mitochondrial phospholipids, coupling factors F1and Fc, and the hydrophobic proteins of the oligomycin-sensitive ATPase. These liposomes catalyzed ATP hydrolysis coupled with the PCB uptake. The latter effect was prevented and reversed by oligomycin and uncouplers.

The conclusion is made that membrane potential can be independently formed by enzymic reactions of two different kinds: (1) redox (e.g. cytochrome c oxidase) and (2) hydrolytic (ATPase).  相似文献   


18.
(1) The reaction of the resting form of oxidised cytochrome c oxidase from ox heart with dithionite has been studied in the presence and absence of cyanide. In both cases, cytochrome a reduction in 0.1 M phosphate (pH 7) occurs at a rate of 8.2 · 104 M−1 · s−1. In the absence of cyanide, ferrocytochrome a3 appears at a rate (kobs) of 0.016 s−1. Ferricytochrome a3 maintains its 418 nm Soret maximum until reduced. The rate of a3 reduction is independent of dithionite concentration over a range 0.9 mM–131 mM. In the presence or cyanide, visible and EPR spectral changes indicate the formation of a ferric a3/cyanide complex occurs at the same rate as a3 reduction in the absence of cyanide. A g = 3.6 signal appears at the same time as the decay of a g = 6 signal. No EPR signals which could be attributed to copper in any significant amounts could be detected after dithionite addition, either in the presence or absence of cyanide. (2) Addition of dithionite to cytochrome oxidase at various times following induction of turnover with ascorbate/TMPD, results in a biphasic reduction of cytochrome a3 with an increasing proportion of the fast phase of reduction occurring after longer turnover times. At the same time, the predominant steady state species of ferri-cytochrome a3 shifts from high to low spin and the steady-state level of reduction of cytochrome a drops indicating a shift in population of the enzyme molecules to a species with fast turnover. In the final activated form, oxygen is not required for fast internal electron transfer to cytochrome a3. In addition, oxygen does not induce further electron uptake in samples of resting cytochrome oxidase reduced under anaerobic conditions in the presence of cyanide. Both findings are contrary to predictions of certain O-loop types of mechanism for proton translocation. (3) A measurement of electron entry into the resting form of cytochrome oxidase in the presence of cyanide, using TMPD or cytochrome c under anaerobic conditions, shows that three electrons per oxidase enter below a redox potential of around +200 mV. An initial fast entry of two electrons is followed by a slow (kobs ≈ 0.02 s) entry of a third electron. Above +200 mV, the number of electrons taken up in the initial fast phase drops as a redox center (presumably CuA) titrates with an apparent mid-point potential of +240 mV. The slow phase of reduction remains at the more positive redox values. (4) The results are interpreted in terms of an initial fast reduction of cytochrome a (and CuA at redox values more negative than +240 mV) followed by a slow reduction of CuB. CuB reduction is proposed to spin-uncouple cytochrome a3 to form a cyanide sensitive center, and trigger a conformational change to an activated form of the enzyme with faster intramolecular electron transfer.  相似文献   

19.
Bacon Ke  Thomas H. Chaney  Dan W. Reed 《BBA》1970,216(2):373-383
1. By means of Q-switched ruby-laser flash excitation, the photooxidation of P870 in the reaction-center complex isolated from Rhodopseudomonas spheroides takes place within 1 μsec. The reduction of photooxidized P870 in the dark follows a first-order kinetics, with a pseudo first-order rate constant of 1.85×108 l×mole-1×sec-1 and an activation energy of 6 kcal/mole.

2. Through an electrostatic interaction of the bacteriochlorophyll reaction-center complex and mammalian cytochrome c, an intimate contact between the two components resulted, and a collision-independent electron-transfer with a halftime of 25 μsec can be attained by laser-flash excitation. The absorbance changes at 870 and 550 nm indicated a good stoichiometry of the reaction. The oxidation of the c-type cytochrome in cells of Rps. spheroides (R-26 mutant) has a halftime of 12 μsec.

3. The portion of P870 which recovered rapidly was closely related to the mole ratio of cytochrome/P870. Complete recovery with a halftime of 25 μsec occurred when the cytochrome/P870 ratio was above approx. 10. At cytochrome/P870 ratios lower than 10, only the fraction of the reaction-center complex which have cytochromes bound at the active site can recover with the rapid decay time. Ultrafiltration measurements showed that each particle of the reaction-center complex can bind approx. 24 cytochrome molecules.

4. An electro static interaction is expected simply from the large difference between the isoelectric points of cytochrome c ( 10) and that of the reaction-center complex (4.1 measured by electro-focusing). The electro static interaction was further evidenced by the effects of pH, ionic strength, and by polylysine displacement of binding sites on the coupled oxidation of ferrocytochrome c by P870. From the limiting polylysine concentration giving complete blocking of cytochrome coupling, it was calculated that each reaction-center complex with a particle weight of 6.5×105 contained approx. 500 negative charges.

5. Arrhenius plot of the first-order rate constants vs. the reciprocal absolute temperature yielded an activation energy of 12 kcal/mole for the cytochrome/P870 reaction, which is presumably the energy needed for cytochrome to achieve the most favorable orientation for the rapid electron transfer. Below the freezing temperature of the sample, the cytochrome reaction appeared to be uncoupled. The temperature dependence is consistent with the effect of viscosity on the reaction rate.

6. Double flash excitations spaced 200 μsec apart showed that at a cytochrome/P870 ratio of 24, the first flash caused maximum oxidation, indicating that all the reaction-center particles have at least one cytochrome attached to the active site. However, only 60% of the particles have a second cytochrome closely attached and capable of undergoing the rapid electron transport.  相似文献   


20.
1. Fluoride is a mixed-type inhibitor of the cytochrome c oxidase activity with a Ki for the free enzyme of 10 mM and a Ki for the cytochrome c-complexed enzyme of 35 mM.

2. Fluoride shifts the γ-band of the enzyme from 423 to 421 nm and the -band from 597 to 598 nm. The difference spectrum (oxidized enzyme in the presence of fluoride minus oxidized enzyme) has peaks at 400, 453, 482, 605 and 638 nm and troughs at 430, 520, 552 and 674 nm. The changes in absorbance are small (about 3% at absorbance maxima) with respect to those of other hemoproteins.

3. On addition of fluoride to isolated cytochrome c oxidase 3 reactions can be distinguished: (I) a bimolecular binding reaction (Kon = 4 M−1 · s−1 and koff = 2.9 · 10−2s−1 at 25 °C, pH 7.4) contributing at 638 nm and 430 nm; (II) a first-order reaction (k = 2.4 · 10−2) s−1 at 22 °C, pH 7.2) visible mainly at 430 nm and (III) a very slow reaction with a half-time in the order of 10 min.

4. The spectroscopic dissociation constants for the fluoride binding, determined from Hill plots using the absorbance changes at 638 and 430 nm, are similar (7 and 10 mM, respectively, at 22 °C, pH 7.2).

5. A mechanism for the reaction is discussed in which the bimolecular binding reaction is followed by a conformational change of the enzyme-fluoride complex.  相似文献   


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