The reaction of Pseudomonas nitrite reductase and nitrite. A stopped-flow and EPR study

The reaction between reduced Pseudomonas nitrite reductase and nitrite has been studied by stopped-flow and rapid-freezing EPR spectroscopy. The interpretation of the kinetics at pH 8.0 is consistent with the following reaction mechanism (where k1 and k3 much greater than k2). [formula: see text] The bimolecular step (Step 1) is very fast, being lost in the dead time of a rapid mixing apparatus; the stoichiometry of the complex has been estimated to correspond to one NO2- molecule/heme d1. The final species is the fully reduced enzyme with NO bound to heme d1; and at all concentrations of nitrite, there is no evidence for dissociation of NO or for further reduction of NO to N2O. Step 2 is assigned to an internal electron transfer from heme c to reduced NO-bound heme d1 occurring with a rate constant of 1 s-1; this rate is comparable to the rate of internal electron transfer previously determined when reducing the oxidized enzyme with azurin or cytochrome c551. When heme d1 is NO-bound, the rate at which heme c can accept electrons from ascorbate is remarkably increased as compared to the oxidized enzyme, suggesting an increase in the redox potential of the latter heme.     

Complexes of iron and cobalt tetrasulfonated phthalocyanines with apocytochrome c

Artificial cytochromes c have been prepared with Fe(III) and Co(III) tetrasulfonated phthalocyanines in place of heme. Their structure and properties have been investigated by difference spectroscopy, CD, epr, electrophoresis, molecular weight estimation, and potentiometric measurements. The visible absorption spectra show the main peak at 650 nm for the iron compound 685 nm for the cobalt one. It is shown by CD experiments that incorporation of Fe(III)L or Co(III)L into apocytochrome c markedly increases helical content of the protein. Its conformation is, however, significantly altered as compared with the native cytochrome c. The epr and spectroscopic data show that the iron and cobalt phthalocyanine models represent the low spin species with the metal ions in trivalent state. Electrophoresis and molecular weight estimation indicate these complexes to be monomers. Both phthalocyanine complexes have not affinity for additional ligands characteristic for hemoglobin. They react, however, with CO, NO, and CN- when they are reduced with dithionite. Moreover, Co(II)L-apocyt c is able to combine with oxygen suggesting a structural feature in common with the oxygen-carrying heme proteins. Iron(II) complex in the same conditions is oxidized directly to the ferric state. The half-reduction potentials of Fe(III)L-apocyt c and Co(III)L-apocyt c are +374 mV and +320 mV, respectively. These complexes are reduced by cytochrome c and cytochrome c reductase (cytochrome bc1).     

Metal phthalocyanine substituted hemoglobins. Complexes of manganese and zinc tetrasulfonated phthalocyanines with apohemoglobin

Artificial hemoglobins have been prepared with Mn(III) and Zn(II) tetrasulfonated phthalocyanines in place of heme. Their structure and properties have been investigated by difference spectroscopy, CD, epr, electrophoresis, and molecular weight estimation.Spectrophotometric titration data indicate the ratio of the reagents in this process to be 1:1. The visible absorption spectra show the main peak at 625 nm for the manganese compound and 681 nm for the zinc one. It is evident from CD experiments that incorporation of Mn(III)L into apohemoglobin increases helical content of the protein whereas that of Zn(II)L increases its unfolding due to the change of electronic configuration of Zn(II) ion on coordination with the protein.On the basis of spectroscopic and epr data, the formula of the manganese complex is suggested to be (O)Mn(IV)L-globin, whereas that of the zinc complex Zn(II)L-globin. Electrophoresis and molecular weight estimation indicate both complexes to be dimers.Manganese complex binds additional ligands as CN^?, imidazole, CO, and NO. Spectroscopic and epr data indicate reduction of the manganese complex and formation of the NO adduct with probable formula (NO)⁺Mn(II)L-globin. Mechanism of this process is suggested.Both phthalocyanine globins are not able to combine reversibly with oxygen and cannot act as physiological oxygen carriers.     

The identification of cytochromes involved in the transfer of electrons to the periplasmic NO3- reductase of Rhodobacter capsulatus and resolution of a soluble NO3(-)-reductase--cytochrome-c552 redox complex

The involvement of cytochromes in the electron-transport pathway to the periplasmic NO3- reductase of Rhodobacter capsulatus was studied in cells grown photoheterotrophically in the presence of nitrate with butyrate as carbon source. The specific rate of NO3- reduction by such cells was five times higher than when malate was carbon source. Reduced minus NO3(-)-oxidized spectra of cells had peaks in the alpha-band region for cytochromes at 552 nm and 559 nm, indicating the involvement of c- and b-type cytochromes in the electron-transport pathway to NO3-. The total ferricyanide-oxidizable cytochrome that was also oxidized in the steady state by NO3- was greater in cells grown with butyrate rather than malate. Low concentrations of cyanide inhibited NO3- reduction. Neither CN-, nor a previously characterized inhibitor of NO3- reduction, 2-n-heptyl-4-hydroxyquinoline N-oxide, prevented the oxidation of the cytochromes by NO3-. This suggested a site of action for these inhibitors on the reducing side of the b- and c-type cytochromes involved in electron transport to the NO3- reductase. The predominant cytochrome in a periplasmic fraction prepared from cells of R. capsulatus grown on butyrate medium was cytochrome c2 but a c-type cytochrome with an alpha-band reduced absorbance maximum at 552 nm could also be identified. The reduced form of this latter cytochrome, but not that of cytochrome c2, was oxidized upon addition of NO3- to a periplasmic fraction. The NO3(-)-oxidizable cytochrome co-purified with the periplasmic NO3- reductase through fractionation procedures that included ammonium sulphate precipitation, gel filtration at low and high salt concentrations, and ion-exchange chromatography. A NO3(-)-reductase-cytochrome-c552 redox complex that comprised two types of polypeptide, a nitrate reductase subunit and a c-type cytochrome subunit, was purified. The polypeptides were separated when the complex was chromatographed on a phenyl-Sepharose hydrophobic chromatography column.     

Manganese (III) phthalocyanine-substituted cytochrome c

Manganese phthalocyanine-substituted cytochrome c has been prepared by the reaction of Mn(III) tetrasulfonated phthalocyanine with apocytochrome c in acetate buffer, pH 5.8. Its structure and properties have been investigated by difference spectroscopy, circular dichroism (cd), electron paramagnetic resonance (epr), electrophoresis, molecular weight estimation, and potentiometric measurements. The epr and spectroscopic data show that the manganese phthalocyanine-substituted cytochrome c represents the low spin, six-coordinated. Mn(Ill) complex with the metal ion in the plane of the phthalocyanine ring. The sixth ligand, which is coordinated axially to the metal ion, is probably the methionine-80. Electrophoresis and molecular weight studies show this complex to be a monomer. As is shown by cd experiments, Mn(III)L-apocyt has a more ordered structure than that of apocytochrome c. Its conformation is, however, significantly altered compared to native cytochrome c. The manganese(III)-phthalocyanine complex is able to combine with cyanide. The cyanide derivative gives a stable reduced form upon dithionite reduction. If, however, Mn(IlI)Lapocyt is reduced with dithionite before addition of cyanide, it loses its ability to coordinate with cyanide. Nitric oxide reacts with the manganese(III) complex to form, in all probability, the nitrosyl derivative. The half-reduction potential of Mn(IlI)L-apocyt is about +400 mV, and the complex is reduced by cytochrome c. Spectroscopic data suggest that the mechanism of this process is complicated.     

Nitrogenase of Klebsiella pneumoniae. Water proton NMR relaxation studies on the binding of divalent metal ions and nucleotides to the iron protein.

Interactions between the iron protein, Kp2, of nitrogenase manganese ions, magnesium ions, and the nucleotides ATP or ADP, have been studied in aqueous solution by monitoring the water proton NMR relaxation rate enhancement caused by Mn2+. Binding of Mn2+ to a molecule of Kp2 occurs at four sites, indistinguishable within experimental error, having a Kd = 350 +/- 50 micron. The Mn2+ - Kp2 complex has a low characteristic enhancement (epsilonb = 6 +/- 0.5). All four sites can alternatively bind Mg2+, not necessarily with the same dissociation constant, but with a mean Kd = 1.7 +/- 0.3 mM. Ternary complexes with the configuration EMS or (formula: see text) are formed between Kp2, Mn2+ and nucleotide (ATP or ADP). The ternary complexes with Mg2+ in place of Mn2+ probably have the latter configuration. A novel treatment of enhancement data (a 'high metal' approximation) is given.     

Cytochrome spectrum of an obligate anaerobe, Eubacterium lentum.

An obligately anaerobic bacterium, Eubacterium lentum, was shown to contain cytochromes a, b, and c and a carbon monoxide-binding pigment. Extracts of cells grown with hemin gave a typical absorption spectrum for cytochrome c with maxima at 424, 525, and 553 nm. Extracts from cells grown in the absence of hemin also had an absorption peak corresponding to cytochrome b (562 nm) in their reduced versus oxidized spectrum. Extraction of hemes and formation of pyridine hemochromes allowed quantitation of protoheme IX and heme c. Large amounts of cytochrome c masked the presence of cytochrome b in cells grown in medium containing hemin. When cells were grown in the presence of 50 mM nitrate, cytochrome A (606 nm) was detected. In anaerobic extracts of cells grown either with or without nitrate, cytochromes b and c were reduced by formate and oxidized by NO3. Cytochrome a appeared to be partially oxidized by NO3 and completely oxidized by air.     

Kinetic studies on the reaction between cytochrome c oxidase and ferrocytochrome c.

In stopped-flow experiments in which oxidized cytochrome c oxidase was mixed with ferrocytochrome c in the presence of a range of oxygen concentrations and in the absence and presence of cyanide, a fast phase, reflecting a rapid approach to an equilibrium, was observed. Within this phase, one or two molecules of ferrocytochrome were oxidized per haem group of cytochrome a, depending on the concentration of ferrocytochrome c used. The reasons for this are discussed in terms of a mechanism in which all electrons enter through cytochrome a, which, in turn, is in rapid equilibrium with a second site, identified with 'visible' copper (830 nm-absorbing) Cud (Beinert et al., 1971). The value of the bimolecular rate constant for the reaction between cytochromes c2+ and a3+ was between 10(6) and 10(7) M(-1)-S(-1); some variability from preparation to preparation was observed. At high ferrocytochrome c concentrations, the initial reaction of cytochrome c2+ with cytochrome a3+ could be isolated from the reaction involving the 'visible' copper and the stoicheiometry was found to approach one molecule of cytochrome c2+ oxidized for each molecule of cytochrome a3+ reduced. At low ferrocytochrome c concentrations, however, both sites (i.e. cytochrome a and Cud) were reduced simultaneously and the stoicheiometry of the initial reaction was closer to two molecules of cytochrome c2+ oxidized per molecule of cytochrome a reduced. The bleaching of the 830 nm band lagged behind or was simultaneous with the formation of the 605 nm band and does not depend on the cytochrome c concentration, whereas the extinction at the steady-state does. The time-course of the return of the 830 nm-absorbing species is much faster than the bleaching of the 605 nm-absorbing component, and parallels that of the turnover phase of cytochrome c2+ oxidation. Additions of cyanide to the oxidase preparations had no effect on the observed stoicheiometry or kinetics of the reduction of cytochrome a and 'visible' copper, but inhibited electron transfer to the other two sites, cytochrome a3 and the undetectable copper, Cuu.     

Observation of fast release of NO from ferrous d₁ haem allows formulation of a unified reaction mechanism for cytochrome cd₁ nitrite reductases

Cytochrome cd1 nitrite reductase is a haem-containing enzyme responsible for the reduction of nitrite into NO, a key step in the anaerobic respiratory process of denitrification. The active site of cytochrome cd1 contains the unique d1 haem cofactor, from which NO must be released. In general, reduced haems bind NO tightly relative to oxidized haems. In the present paper, we present experimental evidence that the reduced d1 haem of cytochrome cd1 from Paracoccus pantotrophus releases NO rapidly (k=65-200 s(-1)); this result suggests that NO release is the rate-limiting step of the catalytic cycle (turnover number=72 s(-1)). We also demonstrate, using a complex of the d1 haem and apomyoglobin, that the rapid dissociation of NO is largely controlled by the d1 haem cofactor itself. We present a reaction mechanism proposed to be applicable to all cytochromes cd1 and conclude that the d1 haem has evolved to have low affinity for NO, as compared with other ferrous haems.     

Nickel cytochrome c.Effect of protein moiety on the metal ion coordination.

Nickel cytochrome c has been synthesized by the reaction of metal-free porphyrin cytochrome c with Ni(II) ions in 0.6 Mglycylglycine and 4 M KSCN. Electronic spectra and susceptibility measurement showed the nickel to be in a high-spin octahedral configuration exemplifying the strong influence of the protein moiety as a macrocyclic ligand on the coordination chemistry of the metal ion. Nickel cytochrome c has the same electrophoretic mobility, helicity and pK values of conformational transitions as the native enzyme. At high pH, the partially denatured nickel cytochrome c becomes dimeric. Nitric oxide reacts with nickel cytochrome c to form the nitrosyl derivative with (formula: see text). Reaction of NO with nickel protoporphyrin IX dimethyl ester in toluene, pyridine, or methylthioethanol produced no stable nitrosyl products, clearly demonstrating the effect of protein on metal ion ligation.     

Reduction of cytochromes by nitrite in electron-transport particles from Nitrobacter winogradskyi: proposal of a mechanism for H+ translocation.

1. A novel component in the respiratory chain of Nitrobacter winogradskyi was identified. This component absorbs maximally at 552.5 nm when in its reduced form, has an Eo' (pH7.0) value of-110mV and undergoes reduction by a mechanism involving the transfer of a single electron. 2. Degrees of reduction of cytochromes c and a1 in electron-transport (ET) particles were monitored during the course of NO2- oxidation, and the effects of ADP together with Pi, oligomycin and of carbonyl cyanide phenylhydrazone were determined. 3. The influences of ionophorous antibiotics, NH4Cl and cyclohexylamine hydrochloride on the reductions of cytochromes c and a1 by NO2- indicate that the flow of reducing equivalents from cytochrome a1 (+350mV) to cytochrome c (+270mV) is facilitated by deltapsi, the electrical component of the protonmotive force. 4. Cytochromes c and a1 in ET particles are reduced by the non-physiological reductant KBH4 in a manner similar to that observed with the physiological reductant NO2-. 5. To account both for the observed cytochrome reductions and for the translocation of H+ ions which accompanies NO2- oxidation, a mechanism is proposed which involves the transfer of a hydride equivalent (H+ plus 2e) inward across the membrane of the ET particle in response to deltapsi.     

Two types of cytochrome cd1 in the aerobic photosynthetic bacterium, Erythrobacter sp. OCh 114

Components I and II of cytochrome cd1 which had different spectral features were purified from the aerobic photosynthetic bacterium, Erythrobacter sp. strain OCh 114. Component I showed an absorption maxima at 700 and 406 nm in the oxidized form, and at 621, 552.5, 548 and 416 nm in the reduced form. Component II showed an absorption maxima at 635 and 410 nm in the oxidized form and at 628, 552.5, 548 and 417 nm in the reduced form. The relative molecular mass, Mr, of both cytochromes was determined to be 135,000 with two identical subunits. Components I and II showed pI values of 7.6 and 6.8, respectively. The redox potential of hemes ranged from +234 mV to +242 mV, except for the heme d1 of component I (Em7 = +134 mV). Components I and II showed both cytochrome c oxidase and nitrite reductase activities. Cytochrome c oxidase activity was strongly inhibited by a low concentration of nitrite and cyanide. Erythrobacter cytochromes c-551 and c-552 were utilized as electron donors for the cytochrome c oxidase reaction. The high affinity of cytochrome c-552 to component II (Km = 1.27 microM) suggested a physiological significance for this cytochrome. Erythrobacter cytochromes cd1 are unique in their presence in cells grown under aerobic conditions as compared to other bacterial cytochromes cd1 which are formed only under denitrifying conditions.     

Cytochrome c'''' isolated from Methylophilus methylotrophus. An example of bis-histidine-co-ordinated Fe3+ haem, with near-perpendicular orientation of the ligands.

Cytochrome c' (Methylophilus methylotrophus) is a soluble protein, Mr 15,000, possessing one haem which is high-spin in the reduced state but switches to a low-spin form on oxidation. Low-temperature electron-paramagnetic-resonance spectroscopy of the oxidized state shows a low-spin signal at gz = 3.65 with a folded line-shape typical of a haem of low rhombicity, and the near-infrared magnetic-circular-dichroism (m.c.d.) spectra reveal an unusually intense (delta epsilon = 400 M-1.cm-1 at 5 T, 4.2 K) charge-transfer band at 1560 nm, establishing that the oxidized haem is co-ordinated by two His residues in a near-perpendicular orientation. This conformation is well established for transmembrane b cytochromes, but this appears to be the first example in a water-soluble cytochrome. The low-temperature m.c.d. spectra of the reduced form of the protein confirms that the haem contains a high-spin Fe2+ ligated by one His residue. The redox-linked spin-state change releases a His group. Since this residue is likely to bind a proton at pH values less than 6.5, this cytochrome may provide a useful model of a molecular mechanism of a redox-linked proton uptake and release process.     

The co-oxidation of ammonia to nitrite during the aerobic xanthine oxidase reaction

The xanthine oxidase reaction causes a co-oxidation of NH3 to NO2-, which was inhibitable by superoxide dismutase, catalase, hydroxyl radical scavengers, or by the chelating agents, desferrioxamine or diethylene triaminepentaacetic acid. Hydroxylamine was oxidized to NO2- much more rapidly than was NH3, and in this case superoxide dismutase or the chelating agents inhibited but catalase or the HO. scavengers did not. Hydrazine was not detectably oxidized to NO2-, and NO2- was not oxidized to NO3-, by the xanthine oxidase reaction. These results are accommodated by a reaction scheme involving (a) the metal-catalyzed production of HO. from O2- + H2O2; (b) the oxidation of H3N to H2N. by OH.; (c) the coupling of H2N. with O2- to yield peroxylamine, which hydrolyzes to hydroxylamine plus H2O2; (d) the metal-catalyzed oxidation of HO-NH2 to (Formula: see text), which couples with O2- to yield (Formula: see text), which finally dehydrates to yield NO2-.     

Comparison of the redox reactions of various types of cytochrome c with iron hexacyanides

The dynamic behavior of various types of cytochromes c in the redox reaction with iron hexacyanides was studied using a temperature-jump method in order to elucidate the molecular mechanism of the redox reaction of cytochromes with their oxidoreductants. Transmittance after the temperature jump changed through a single exponential decay for all cytochromes investigated. Under a constant concentration of anion, the redox reaction of various types of cytochrome c with iron hexacyanides was analyzed according to the scheme: (see formula in text) where C(III) and C(II) are ferric and ferrous cytochromes, respectively, Fe(III) and Fe(II) are ferri- and ferrocyanides, respectively, C(III) . Fe(II) is the ferricytochrome-ferrocyanide complex and C(II) . Fe(III) is the ferrocytochrome-ferricyanide complex. When step B is slower than the other two steps A and C, tau-1 can be represented approximately as (see formula in text) where the bar over the variables denotes the equilibrium value. In a large excess of ferrocyanide against cytochrome, we can estimate kappa 2, kappa-2, K1 and K3 independently. In the case of horse cytochrome c at 18 degrees C in 0.1 M phosphate buffer at pH 7 with 0.3 M KNO3, the estimated parameters are kappa 2 = 100 +/- 50 S-1, kappa-2 = (3.5 +/- 1.0) . 10(3) S-1, K1 = 15 +/- 7 M-1 and K3 = (8.5 +/- 1.5). 10(-4) M. From the same experiments for seven cytochromes (cytochrome c from horse, tuna, Candida krusei, Saccharomyces oviformis, Rhodospirillum rubrum cytochrome c2, Spirulina platensis cytochrome c-554 and Thermus thermophilus cytochrome c-552), the following results can be deduced. (1) Each parameter defined in the scheme above (kappa 2, kappa-2, K1, K3) diverged beyond the error range. Above all, kappa 2 values of cytochromes c-554 and c-552 are as large as 1 . 10(4) S-1 and much larger than those for the other cytochromes (to 50 approx. 700 S-1). (2) The variance of kappa 2K1 and kappa-2/K3 are relatively less than the variances of individual parameters (kappa 2, kappa-2, K1 and K3), which suggests that the values of kappa 2K1 and kappa-2/K3 have been conserved during the course of evolution.     

Participation of cytochromes in some oxidation-reduction systems in Campylobacter fetus.

Campylobacter species are rich in c-type cytochromes, including forms which bind carbon monoxide. The role of the various forms of cytochromes in Campylobacter fetus has been examined in cell-free preparations by using physiological electron donor and acceptor systems. Under anaerobic conditions, NADPH reduced essentially all of the cytochrome c in crude cell extracts, whereas the reduction level with succinate was 50 to 60%. The carbon monoxide spectrum with NADPH was predominated by the cytochrome c complex; evidence of a cytochrome o type was seen in the succinate-reduced extracts and in membrane fractions. Succinate-reduced cytochrome c was oxidized by oxygen via a cyanide-sensitive, membrane-associated system. NADPH-reduced cytochrome c was oxidized by a cyanide-insensitive system. Partially purified carbon monoxide-binding cytochrome c, isolated from the cytoplasm, could serve as electron acceptor for NADPH-cytochrome c oxidoreductase; the reduced cytochrome was oxidized by oxygen by a cyanide-insensitive system present in the cytoplasmic fraction. Horse heart cytochrome c was also reducible by NADPH and by succinate; the reduced cytochrome was oxidized by a cyanide-sensitive system in the membrane fraction. NADPH and NADH oxidase activities were observed aerobically and under anaerobic conditions with fumarate. NADPH was more active than NADH. NADP was also more effective than NAD as an electron acceptor for the coenzyme A-dependent pyruvate and alpha-ketoglutarate dehydrogenase activities found in crude extracts. These dehydrogenases used methyl viologen and metronidazole as electron acceptors; they could be loci for oxygen inhibition of growth. It is proposed that energy provision via the high-potential cytochrome c oxidase system in the cytoplasmic membrane is limited by oxygen-sensitive primary dehydrogenases and that the carbon monoxide-binding cytochrome c may have a role as an oxygen scavenger.     

Proteolysis as a measure of the free energy difference between cytochrome c and its derivatives.

Limited cleavage of oxidized and reduced horse heart cytochrome c (Cyt c) and the azide complex of Cyt c by proteinase K at room temperature yields a single cut within the central loop (36-60 in the sequence). Using an assay that allows spectroscopic evaluation of the fraction of intact protein as a function of time, together with a simple kinetic model for proteolysis, fluctuation opening of the loop can be related to the free energy of the corresponding protein. This allows us to estimate quantitatively the free energy difference between the oxidized form of Cyt c and other states using proteolysis as a probe. The results we obtain indicate that oxidized Cyt c is 2.0 kcal mol(-1) less stable than the reduced form, and 0.07 kcal mol(-1) is more stable than the Cyt c: azide complex at 25 degrees C. These values agree in magnitude with results from hydrogen exchange and unfolding studies, suggesting that the stability of a protein can be directly related to its structural dynamics.     

The characterization and magnetic properties of the azide and imidazole derivatives of Pseudomonas nitrite reductase

Optical absorption, mcd, and epr spectroscopy have been used to characterize the azide and imidazole derivatives of oxidized Pseudomonas nitrite reductase. At pH 7.0 azide binds solely to heme d1 with an affinity constant, Kaff = 360 M-1, whereas imidazole binds to both hemes c and d1 with kaff = 35 and 55 M-1, respectively. Low-temperature mcd and epr spectroscopy indicate that c and d1 are low-spin ferrihemes in both derivatives, although the epr of the heme d1-azide component is very weak and requires explanation. Attempts to obtain a high-spin heme d1 in the intact enzyme using the weak field ligands fluoride and thiocyanate have proved unsuccessful. Electron paramagnetic resonance experiments involving an oxidized enzyme derivatives in which heme d1 is complexed by NO, and hence epr silent, have enabled unambiguous assignment of the epr spectrum of Pseudomonas nitrite reductase.     

Kinetic studies on redox reactions of hemoproteins. I. Reduction of thermoresistant cytochrome c-552 and horse heart cytochrome c by ferrocyanide.

The oxidation-reduction reaction of horse heart cytochrome c and cytochrome c (552, Thermus thermophilus), which is highly thermoresistant, was studied by temperature-jump method. Ferrohexacyanide was used as reductant. (Formula: see text.) Thermodynamic and activation parameters of the reaction obtained for both cytochromes were compared with each other. The results of this showed that (1) the redox potential of cytochrome c-552, + 0.19 V, is markedly less than that of horse heart cytochrome c. (2) deltaHox of cytochrome c-552 is considerably lower than that of horse heart cytochrome c. (3) deltaSox and deltaSred of cytochrome c-552 are more negative than those of horse heart cytochrome c. (4) kred of cytochrome c-552 is much lower than that of horse heart cytochrome c at room temperature.     

Kinetic characterization of the membrane-bound cytochromes of Escherichia coli grown under a variety of conditions by using a stopped-flow dual-wavelength spectrophotometer.

A study was made of the rapid oxidation kinetics of the cytochromes of Escherichia coli. The b-type cytochromes were kinetically heterogeneous, with one species (presumably cytochrome o) oxidized so rapidly that it could fully support observed oxidation rates. Cytochrome d but not cytochrome a1 was also kinetically competent to support respiration. However, in cells grown anaerobically in the presence of NO3-, cytochrome d exhibited slow oxidation kinetics and a red-shift in its reduced-minus-oxidized difference spectrum.