Evidence for involvement of the electron transport system at a late step of anaerobic microbial heme synthesis.

The penultimate step in heme biosynthesis, the oxidation of protoporphyrinogen to protoporphyrin, can be anaerobically coupled to the reduction of fumarate in extracts of anaerobically-grown Escherichia coli. This coupling is approximately 90% inhibied by 2-heptyl-4-hydroxy quinoline-N-oxide (HQNO), a known inhibitor of the electron transport chain. This observation suggests that the mechanism of the anaerobic oxidation of protoporphyrinogen in E. coli involves a coupling into the anaerobic electron transport system. In contrast, the aerobic oxidation of protoporphyrinogen, which occurs in mammalian and yeast mitochondria, is known to be linked directly to oxygen without the mediation of an electron transport system.     

Nitrate,fumarate, and oxygen as electron acceptors for a late step in microbial heme synthesis

Nitrate can serve as anaerobic electron acceptor for the oxidation of protoporphyrinogen to protoporphyrin in cell-free extracts of Escherichia coli grown anaerobically in the presence of nitrate. Two kinds of experiments indicated this: anaerobic protoporphyrin formation from protoporphyrinogen, followed spectrophotometrically, was markedly stimulated by addition of nitrate; and anaerobic protoheme formation from protoporphyrinogen, determined by extraction procedures, was markedly stimulated by addition of nitrate. In contrast, anaerobic protoheme formation from protoporphyrin was not dependent upon addition of nitrate. This was the first demonstration of the ability of nitrate to serve as electron acceptor for this late step of heme synthesis. Previous studies with mammalian and yeast mitochondria had indicated an obligatory requirement for molecular oxygen at this step.In confirmation of our previous preliminary report, fumarate was also shown to be an electron acceptor for anaerobic protoporphyrinogen oxidation in extracts of E. coli grown anaerobically on fumarate. For the first time, anaerobic protoheme formation from protoporphyrinogen, but not from protoporphyrin, was shown to be dependent upon the addition of fumarate.The importance of these findings is 2-fold. First, they establish that enzymatic protoporphyrinogen oxidation can occur in the absence of molecular oxygen, in contrast to previous observations using mammalian and yeast mitochondria. Secondly, these findings help explain the ability of some facultative and anaerobic bacteria to form very large amounts of heme compounds, such as cytochrome pigments, when grown anaerobically in the presence of nitrate or fumarate. In fact, denitrifying bacteria are known to form more cytochromes when grown anaerobically than during aerobic growth.An unexpected finding was that extracts of another bacterium, Staphylococcus epidermidis, exhibited very little ability to oxidize protoporphyrinogen to protoporphyrin as compared to E. coli extracts. This finding suggests some fundamental differences in these two organisms in this key step in heme synthesis. It is known that these two facultative organisms also differ in that E. coli synthesizes cytochrome during both aerobic and anaerobic growth, while Staphylococcus only synthesizes cytochromes when grown aerobically.     

Microbial oxidation of protoporhydrinogen, an intermediate in heme and chlorphyll biosynthesis.

The oxidation of protoporphyrinogen to protoporphyrin, a late step in heme and chlorophyll synthesis, is catalyzed aerobically by a particulate fraction of Escherichia coli at a rate significantly higher than the rate of autooxidation. This activity is heat labile and is markedly inhibited by addition of respiratory substrates such as NADH. NADH is oxidized at a rate 100-fold higher than protoporphyrinogen. Particles from a cytochrome-less mutant of E. coli were markedly deficient in protoporphyrinogen oxidizing activity. Particles from a quinone-deficient mutant were also deficient. These findings suggest a possible role for the electron transport system in aerobic protoporphyrinogen oxidation. This activity was also examined in a variety of other bacteria. Particles from Streptococcus faecalis, which does not synthesize heme, were unable to oxidize protoporphyrinogen, confirming the specificity of this activity. Particles from aerobically grown Staphylococcus aureus exhibited protoporphyrinogen oxidizing activity, but particles from anaerobically grown cells had no activity above that of the nonenzymatic control. This indicates the repressible nature of this activity, and may also explain why Staphylococci synthesize cytochromes during aerobic, but not during anaerobic growth. Particles from photosynthetically grown Rhodopseudomonas spheroides, which contain both chlorophyll and heme, oxidized protoporphyrinogen at a rate no higher than the nonenzymic control. However, particles from cells grown aerobically, when bacteriochlorophyll synthesis is markedly repressed, readily exhibited protoporphyrinogen oxidizing activity. These initial findings suggest that this activity is detectable in cells primarily synthesizing heme, but not in cells primarily synthesizing bacteriochlorophyll, and could have implications both for the mechanism and regulation of the heme and bacteriochlorophyll pathways.     

The late steps of anaerobic heme biosynthesis in E. coli: role for quinones in protoporphyrinogen oxidation.

The anaerobic oxidation of protoporphyrinogen with fumarate as electron acceptor in cell-free extracts of $\text{E. coli}$ is inhibited by ultra-violet irradiation. The activity of irradiated extracts is restored by addition of menadione and the restored activity is blocked by the electron-transport inhibitor 2-heptyl-4-hydroxy quinoline-N-oxide. These observations suggest that quinones are required as electron transport carriers at this late step in the pathway of anaerobic heme biosynthesis. These findings have important implications both for the mechanism of anaerobic heme synthesis and for the physiology of cytochrome biosynthesis in anaerobic microorganisms.     

Quinones as hydrogen carriers for a late step in anaerobic heme biosynthesis in Escherichia coli

A late step in anaerobic heme synthesis, the oxidation of protoporphyrinogen with fumarate as electron acceptor, was studied in extracts and particles of Escherichia coli mutants deficient in quinones or cytochromes. Mutants specifically deficient in menaquinone did not couple protoporphyrinogen oxidation to fumarate reduction, whereas mutants containing menaquinone but deficient in either ubiquinone or cytochromes exhibited this activity. These findings indicate that this coupled reaction is dependent upon menaquinone as hydrogen carrier but independent of ubiquinone and cytochromes. Other characteristics of this coupled reaction were also studied. The activity was located exclusively in the membrane fraction of cell-free extracts. Coproporphyrinogen III could not replace protoporphyrinogen as substrate. Methylene blue, triphenyl tetrazolium and nitrate, but not nitrite, could replace fumarate as anaerobic hydrogen acceptor. These findings have implications for the mechanism and regulation of microbial heme and chlorophyll synthesis and for the physiology of cytochrome synthesis in anaerobic microorganisms.     

Non-pyridine nucleotide dependent l-(+)-glutamate oxidoreductase in Azotobacter vinelandii

l-(+)-Glutamate oxidation that is non-pyridine nucleotide dependent is readily carried out by a membrane-bound enzyme in Azotobacter vinelandii strain O. Enzyme activity concentrates in a membranous fraction that is associated with the Azotobacter electron transport system. This l-glutamate oxidation is not dependent on externally added NAD⁺, NADP⁺, FAD, or FMN for activity. O₂, phenazine methosulfate and ferricyanide all served as relatively good electron acceptors for this reaction; while cytochrome c and nitrotetrazolium blue function poorly in this capacity. Paper chromatographic analyses revealed that the 2,4-dinitrophenylhydrazine derivative formed from the enzymatic oxidation of l-glutamate was α-ketoglutarate, while microdiffusion studies indicated that ammonia was also a key end product. These findings suggest that the overall reaction is an oxidative deamination. Ammonia formation was found to be stoichiometric with the amount of oxygen consumed (2 : 1 respectively, on a molar basis). The oxidation of glutamate was limited to the l-(+)-enantiomer indicating that this reaction is not the generalized type carried out by the l-amino acid oxidase. This oxidoreductase is functionally related to the Azotobacter electron transport system: (a) the activity concentrates almost exclusively in the electron transport fraction; (b) the l-glutamate oxidase activity is markedly sensitive to electron transport inhibitors, i.e. 2-n-heptyl-4-hydroxyquinoline-N-oxide, cyanide, and 4,4,4-trifluoro-1-(2-thienyl)-1,3-butanedione; and (c) spectral studies on the Azotobacter R₃ fraction revealed that a substantial amount of the flavoprotein (non-heme iron) and cytochrome (a₂, a₁, b₁, c₄ and c₅) are reduced by the addition of l-glutamate.     

Lack of site-specificity of spinach chloroplast coupling factor 1

The irreversible inhibition of chloroplast phosphorylation by either sulfate anions, or N-ethylmaleimide, is energy dependent. Chloroplasts must first be illuminated in the presence of the inhibitors and a mediator of electron flow, for the subsequent phosphorylation to show any inhibition. Both inhibitors affect the chloroplast coupling factor 1.Electron transport only through Photosystem I can be used to activate either of these inhibitions. The subsequent inhibition in a second light reaction is the same whether ATP synthesis is supported by Photosystem I, or by Photosystem II electron transport. The reverse experiment, activating inhibition by electron transport only through Photosystem II, is possible in the case of sulfate. Again, the inhibition is expressed whether Photosystem II or Photosystem I electron flow supports ATP synthesis. We conclude that the two electron transport regions probably generate the same high energy state which is able to activate all members of a functionally uniform coupling factor population. These enzyme molecules must catalyze phosphorylation coupled to electron transport through either region of the chain. The results tend to discredit models requiring a separate group of coupling factor molecules unique to each part of the chain.     

On the functional organization of electron transport from plastoquinone to Photosystem I

Signal I, the EPR signal of P-700, induced by long flashes as well as the rate of linear electron transport are investigated at partial inhibition of electron transport in chloroplasts. Inhibition of plastoquinol oxidation by dibromothymoquinone and bathophenanthroline, inhibition of plastocyanin by KCN and HgCl₂, and inhibition by 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide are used to study a possible electron exchange between electron-transport chains after plastoquinone. (1) At partial inhibition of plastocyanin the reduction kinetics of P-700⁺ show a fast component comparable to that in control chloroplasts and a new slow component. The slow component indicates P-700⁺ which is not accessible to residual active plastocyanin under these conditions. We conclude that P-700 is reduced via complexed plastocyanin. (2) The rate of linear electron transport at continuous illumination decreases immediately when increasing amounts of plastocyanin are inhibited by KCN incubation. This is not consistent with an oxidation of cytochrome f by a mobile pool of plastocyanin with respect to the reaction rates of plastocyanin being more than an order of magnitude faster than the rate-limiting step of linear electron transport. It is evidence for a complex between the cytochrome b₆ - f complex and plastocyanin. The number of these complexes with active plastocyanin is concluded to control the rate-limiting plastoquinol oxidation. (3) Partial inhibition of the electron transfer between plastoquinone and cytochrome f by dibromothymoquinone and bathophenanthroline causes decelerated monophasic reduction of total P-700⁺. The P-700 kinetics indicate an electron transfer from the cytochrome b₆ - f complex to more than ten Photosystem I reaction center complexes. This cooperation is concluded to occur by lateral diffusion of both complexes in the membrane. (4) The proposed functional organization of electron transport from plastoquinone to P-700 in situ is supported by further kinetic details and is discussed in terms of the spatial distribution of the electron carriers in the thylakoid membrane.     

Redox mechanisms in “oxidant-dependent” hexose fermentation by Rhodopseudomonas capsulata

Trimethylamine N-oxide (TMAO) can function as an electron acceptor in the anaerobic metabolism of both Rhodopseudomonas capsulata and Escherichia coli. In both bacteria, anaerobic growth in the presence of TMAO induces a system that can reduce TMAO to trimethylamine (TMA). Comparative studies, however, show that TMAO reduction serves different purposes in the organisms noted. In E. coli, anaerobic growth on sugars does not require the presence of TMAO, but in cells induced for TMAO reductase, TMAO can act as the terminal electron acceptor for membrane-associated oxidative phosphorylation. Anaerobic dark growth of R. capsulata is dependent on the presence of TMAO (or an analog) and in this organism a soluble system catalyzes anaerobic oxidation of NADH with TMAO. The mechanism, in R. capsulata, appears to involve a flavoprotein of the flavodoxin type and presumably represents a system for maintenance of redox balance during anaerobic dark fermentation of hexoses and related compounds.     

The anaerobic oxidation of dihydroorotate by Escherichia coli K-12

The oxidation of dihydroorotate under anaerobic conditions has been examined using various mutant strains of Escherichia coli K-12. This oxidation in cells grown anaerobically in a glucose minimal medium is linked via menaquinone to the fumarate reductase enzyme coded for by the frd gene and is independent of the cytochromes. The same dihydroorotate dehydrogenase protein functions in both the anaerobic and aerobic oxidation of dihydroorotate. Ferricyanide can act as an artificial electron acceptor for dihydroorotate dehydrogenase and the dihydroorotate-menaquinone-ferricyanide reductase activity can be solubilised by 2 M guanidine · HCl with little loss of activity.     

Rates and properties of endogenous cyclic photophosphorylation of isolated intact chloroplasts measured by CO2 fixation in the presence of dihydroxyacetone phosphate

1. Dihydroxyacetone phosphate in concentrations ? 2.5 mM completely inhibits CO₂-dependent O₂ evolution in isolated intact spinach chloroplasts. This inhibition is reversed by the addition of equimolar concentrations of P_i, but not by addition of 3-phosphoglycerate. In the absence of P_i, 3-phosphoglycerate and dihydroxyacetone phosphate, only about 20% of the ¹⁴C-labelled intermediates are found in the supernatant, whereas in the presence of each of these substances the percentage of labelled intermediates in the supernatant is increased up to 70–95%. Based on these results the mechanism of the inhibition of O₂ evolution by dihydroxyacetone phosphate is discussed with respect to the function of the known phosphate translocator in the envelope of intact chloroplasts.2. Although O₂ evolution is completely suppressed by dihydroxyacetone phosphate, CO₂ fixation takes place in air with rates of up to 65μ mol · mg^?1 chlorophyll · h^?1. As non-cyclic electron transport apparently does not occur under these conditions, these rates must be due to endogenous pseudocyclic and/or cyclic photophosphorylation.3. Under anaerobic conditions, the rates of CO₂ fixation in presence of dihydroxyacetone phosphate are low (2.5–7 μmol · mg^?1 chlorophyll · h^?1), but they are strongly stimulated by addition of dichlorophenyl-dimethylurea (e.g. 2 · 10^?7 M) reaching values of up to 60 μmol · mg^?1 chlorophyll · h^?1. As under these conditions the ATP necessary for CO₂ fixation can be formed by an endogenous cyclic photophosphorylation, the capacity of this process seems to be relatively high, so it might contribute significantly to the energy supply of the chloroplast. As dichlorophenyl-dimethylurea stimulates CO₂ fixation in presence of dihydroxyacetone phosphate under anaerobic but not under aerobic conditions, it is concluded that only under anaerobic conditions an “overreduction” of the cyclic electron transport system takes place, which is removed by dichlorophenyl-dimethylurea in suitable concentrations. At concentrations above 5 · 10^?7 M dichlorophenyl-dimethylurea inhibits dihydroxyacetone phosphate-dependent CO₂ fixation under anaerobic as well as under aerobic conditions in a similar way as normal CO₂ fixation. Therefore, we assume that a properly poised redox state of the electron transport chain is necessary for an optimal occurrence of endogenous cyclic photophosphorylation.4. The inhibition of dichlorophenyl-dimethylurea-stimulated CO₂ fixation in presence of dihydroxyacetone phosphate by dibromothymoquinone under anaerobic conditions indicates that plastoquinone is an indispensible component of the endogenous cyclic electron pathway.     

Variations in the pathways of malate oxidation and phosphorylation in different species of Mycobacteria

Mycobacterium tuberculosis H₃₇ Rv, the slow-growing human pathogenic strain of tubercle bacilli and Mycobacterium smegmatis and Mycobacterium phlei, the fast-growing saprophytes, have shown variations regarding the type of dehydrogenase that initiates malate oxidation in the respiratory chain.M. tuberculosis H₃₇Rv is characterized by having a malate oxidase system (designated MAL_NAD pathway) in which malate oxidation is mediated by the NAD⁺_? dependent malate dehydrogenase (EC 1.1.1.37) but not by FAD-dependent malatevitamin K reductase. M. smegmatis possesses a different malate oxidase system (designated MAL_FAD pathway) in which malate oxidation is exclusively carried out by the FAD-dependent malate-vitamin K reductase because NAD⁺-dependent malate dehydrogenase is absent in this organism. M. phlei has a mixed system of malate oxidase (designated MAL_NAD+FAD pathways) in which both the NAD⁺_? and FAD-dependent dehydrogenases take part. In all the three systems, the rest of the electron transport chain is common.     

Anaerobic Expression of Escherichia coli Succinate Dehydrogenase: Functional Replacement of Fumarate Reductase in the Respiratory Chain during Anaerobic Growth

Succinate-ubiquinone oxidoreductase (SQR) from Escherichia coli is expressed maximally during aerobic growth, when it catalyzes the oxidation of succinate to fumarate in the tricarboxylic acid cycle and reduces ubiquinone in the membrane. The enzyme is similar in structure and function to fumarate reductase (menaquinol-fumarate oxidoreductase [QFR]), which participates in anaerobic respiration by E. coli. Fumarate reductase, which is proficient in succinate oxidation, is able to functionally replace SQR in aerobic respiration when conditions are used to allow the expression of the frdABCD operon aerobically. SQR has not previously been shown to be capable of supporting anaerobic growth of E. coli because expression of the enzyme complex is largely repressed by anaerobic conditions. In order to obtain expression of SQR anaerobically, plasmids which utilize the P_FRD promoter of the frdABCD operon fused to the sdhCDAB genes to drive expression were constructed. It was found that, under anaerobic growth conditions where fumarate is utilized as the terminal electron acceptor, SQR would function to support anaerobic growth of E. coli. The levels of amplification of SQR and QFR were similar under anaerobic growth conditions. The catalytic properties of SQR isolated from anaerobically grown cells were measured and found to be identical to those of enzyme produced aerobically. The anaerobic expression of SQR gave a greater yield of enzyme complex than was found in the membrane from aerobically grown cells under the conditions tested. In addition, it was found that anaerobic expression of SQR could saturate the capacity of the membrane for incorporation of enzyme complex. As has been seen with the amplified QFR complex, E. coli accommodates the excess SQR produced by increasing the amount of membrane. The excess membrane was found in tubular structures that could be seen in thin-section electron micrographs.     

Anaerobic transport of amino acids coupled to the glycerol-3-phosphate-fumarate oxidoreductase system in a cytochrome-deficient mutant of Escherichia coli

The uptake of proline and glutamine by cytochrome-deficient cells of Escherichia coli SASX76 grown aerobically on glucose or anaerobically on pyruvate was stimulated by these two substrates. Pyruvate could not stimulate transport in the glucose-grown cells. Uptake of these amino acids energized by glucose was inhibited by inhibitors of the Ca²⁺, Mg²⁺-stimulated ATPase such as DCCD, pyrophosphate, and azide, and by the uncouplers CCCP and 2,4-dinitrophenol. Glycerol (or glycerol 3-phosphate) in the presence of fumarate stimulated the transport of proline and glutamine under anaerobic conditions in cytochrome-deficient cells but not in membrane vesicles prepared from these cells although glycerol 3-phosphate-fumarate oxidoreductase activity could be demonstrated in the vesicle preparation. In contrast, in vesicles prepared from cytochrome-containing cells of E. coli SASX76 amino acid transport was energized under anaerobic conditions by this system. Inhibitors of the Ca²⁺, Mg²⁺-activated ATPase and uncoupling agents inhibited the uptake of proline and glutamine in cytochrome-deficient cells dependent on the glycerol-fumarate oxidoreductase system. Ferricyanide could replace fumarate as an electron acceptor to permit transport of phenylalanine in cytochrome-deficient or cytochrome- containing cells under anaerobic conditions. It is concluded that in cytochrome-deficient cells using glucose, pyruvate, or glycerol in the presence of fumarate, transport of both proline and glutamine under anaerobic conditions is energized by ATP through the Ca²⁺, Mg²⁺-activated ATPase. In cytochrome-containing cells under anaerobic conditions electron transfer between glycerol and fumarate can also drive transport of these amino acids.     

Respiration and Growth of Shewanella decolorationis S12 with an Azo Compound as the Sole Electron Acceptor

The ability of Shewanella decolorationis S12 to obtain energy for growth by coupling the oxidation of various electron donors to dissimilatory azoreduction was investigated. This microorganism can reduce a variety of azo dyes by use of formate, lactate, pyruvate, or H₂ as the electron donor. Furthermore, strain S12 grew to a maximal density of 3.0 × 10⁷ cells per ml after compete reduction of 2.0 mM amaranth in a defined medium. This was accompanied by a stoichiometric consumption of 4.0 mM formate over time when amaranth and formate were supplied as the sole electron acceptor and donor, respectively, suggesting that microbial azoreduction is an electron transport process and that this electron transport can yield energy to support growth. Purified membranous, periplasmic, and cytoplasmic fractions from S12 were analyzed, but only the membranous fraction was capable of reducing azo dyes with formate, lactate, pyruvate, or H₂ as the electron donor. The presence of 5 μM Cu²⁺ ions, 200 μM dicumarol, 100 μM stigmatellin, and 100 μM metyrapone inhibited anaerobic azoreduction activity by both whole cells and the purified membrane fraction, showing that dehydrogenases, cytochromes, and menaquinone are essential electron transfer components for azoreduction. These results provide evidence that the microbial anaerobic azoreduction is linked to the electron transport chain and suggest that the dissimilatory azoreduction is a form of microbial anaerobic respiration. These findings not only expand the number of potential electron acceptors known for microbial energy conservation but also elucidate the mechanisms of microbial anaerobic azoreduction.     

Chlorophyll fluorescence induction in anaerobic Scenedesmus obliquus

Fluorescence time curves (Kautsky effect) were studied in anaerobic Scenedesmus obliquus, with an apparatus capable of simultaneous recording of O₂ exchange, and far-red actinic illumination. Results, as interpreted in terms of electron transport reactions, suggest: In the course of becoming anaerobic, fluorescence induction undergoes a series of changes, indicating at least three different effects of the absence of O₂ on electron transport. (1) Immediately on removal of O₂, once the pool of intermediates between the two photo-systems is reduced by light reaction II, electron flow stops, resulting in high fluorescence yield and a cessation of O₂ evolution. O₂ appears to regulate linear electron flow and cyclic feedback of electrons to the intermediate pool. (2) An endogenous reductant formed anaerobically reduces the System II acceptors in the dark. The time course of this reduction is at least biphasic, indicative of inhomogeneity of the primary acceptor pool. Prolonged dark anaerobic treatment induces maximal initial fluorescence which decays rapidly in light and with a System I action spectrum. (3) Anaerobic treatment eventually results in deactivation of the oxidizing side of System II, limiting System II even when the acceptors are oxidized by System I pre-illumination.     

Phosphate transport in membrane vesicles from Escherichia coli

Escherichia coli strain AN710 possesses only the PIT system for phosphate transport. Membrane vesicles from this strain, which contain phosphate internally, perform exchange and active transport of phosphate. The energy for active transport is supplied by the respiratory chain with ascorbate-phenazine methosulphate as electron donor. To a lesser extent also the oxidation of d-lactate energizes phosphate transport; the oxidation of succinate is only marginally effective. Phosphate transport is driven by the proton-motive force and in particular by the pH gradient across the membrane. This view is supported by the observation that phosphate transport is stimulated by valinomycin, inhibited by nigericin and abolished by the uncoupler carbonyl cyanide m-chlorophenylhydrazone. Neither inhibitor affects phosphate exchange. The phosphate analogue arsenate inhibits both the exchange reaction and active transport. Both processes are stimulated by K⁺ and Mg²⁺, the highest activities being observed with both ions present.Membrane vesicles have also been isolated from Escherichia coli K10, a strain which possesses only a functional PST phosphate transport system. These vesicles perform neither exchange nor active transport of phosphate, although active transport of amino acids is observed in the presence of ascorbate-phenazine methosulphate or d-lactate.     

Proton-translocating cytochrome c oxidase in artificial phospholipid vesicles

The proton translocating properties of cytochrome c oxidase have been studied in artificial phospholipid vesicles into the membranes of which the isolated and purified enzyme was incorporated.Initiation of oxidation of ferrocytochrome c by addition of the cytochrome, or by addition of oxygen to an anaerobic vesicle suspension, leads to ejection of H⁺ from the vesicles provided that charge compensation is permitted by the presence of valinomycin and K⁺. Proton ejection is not observed if the membranes have been specifically rendered permeable to protons.The proton ejection is the result of true translocation of H⁺ across the membrane as indicated by its dependence on the intravesicular buffering power relative to the number of particles (electrons and protons) transferred by the system, and since it can be shown not to be due to a net formation of acid in the system.Comparison of the initial rates of proton ejection and oxidation of cytochrome c yields a $\text{H}{}^{\mathrm{+}}\text{e}{}^{\mathrm{?}}$ quotient close to 1.0 both in cytochrome c and oxygen pulse experiments. An approach towards the same stoichiometry is found by comparison of the extents of proton ejection and electron transfer under appropriate experimental conditions.It is concluded that cytochrome c oxidase is a proton pump, which conserves redox energy by converting it into an electrochemical proton gradient through electrogenic translocation of H⁺.