The effect of inhibitors on the oxygen kinetics of terminal oxidases of Acanthamoeba castellanii.

1. Respiration of growing cultures of Acanthamoeba castellanii is inhibited less than 60% by azide (35 mM); the respiration of early-exponential-phase cultures differs from that of late-exponential-phase cultures in being stimulated by up to 120% by low concentrations (less than 1 mM) of this inhibitor. Azide (0.5 mM) plus 1 mM-salicylhydroxamic acid gives 80% inhibition of respiration in early- or late-exponential-phase cultures. 2. Lineweaver-Burk plots of 1/v against 1/[O2] for growing and stationary-phase cultures give values of less than 1 muM for the apparent Km for oxygen. 3. These values are not significantly altered when determined in the presence of 1 mM-salicylhydroxamic acid. 4. Higher values (greater than 7 muM) for apparent Km values for oxygen were obtained in the presence of azide, which gives non-linear Lineweaver-Burk plots. 5. Competitive inhibition of respiration by CO occurs with Ki 2.4 muM. 6. The results are discussed in terms of the presence of three terminal oxidases in this organism, namely two oxidases with high affinities for oxygen (cytochrome c oxidase of the main phosphorylating electron-transport chain and the salicylhydroxamic acid-sensitive oxidase) and a third oxidase with a low affinity for oxygen, sensitive to inhibition by cyanide but not by azide or salicylhydroxamic acid. The relative contributions to oxygen utilization by these oxidases change during the growth of a batch culture.     

Azide-stimulated oxygen consumption by the green alga Selenastrum minutum

Dark O₂ consumption by the green alga Selenastrum minutum was sensitive to inhibition by the cytochrome pathway respiration inhibitor cyanide in the absence of an alternative oxidase inhibitor, consistent with previous work that suggested that this alga lacks alternative oxidase capacity. In contrast, addition of low concentrations of the cytochrome pathway inhibitor azide (50–750 μ M ) resulted in a stimulation of dark O₂ consumption, while higher concentrations of azide (1–2 m M ) partially inhibited O₂ consumption. Measurements of changes in cellular levels of pyruvate, malate and pyridine nucleotides upon cyanide addition were consistent with the absence of alternative oxidase capacity, and suggested that cyanide inhibition of O₂ consumption was not due to nonspecific effects of cyanide. Addition of salicylhydroxamic acid (SHAM) also resulted in an increase in the rate of O₂ consumption. Both azide- and SHAM-stimulated O₂ consumption were sensitive to inhibition by 50 m M ascorbate or by cyanide. However, the ubiquinone analogs chloroquine and quinacrine specifically inhibited azide-stimulated O₂ consumption, with only minor effects on SHAM-stimulated O₂ consumption. These results suggest that azide-stimulated O₂ consumption was not mediated by the previously characterized SHAM-stimulated oxidase, and are consistent with the possibility that azide-stimulated O₂ consumption is mediated by a plasma membrane redox system.     

Alternative Cyanide-sensitive Oxidase Interacting with Photosynthesis in Synechocystis PCC6803. Ancestor of the Terminal Oxidase of Chlororespiration?

Influence of respiration on photosynthesis in Synechocystis PCC6803 was studied by measuring the redox transients of cytochrome f (cyt f) upon excitation of the cells with repetitive single turnover flashes. Upon the addition of KCN the flash-induced oxidation of cyt f was increased and the rereduction of cyt f+ was accelerated. Dependence of these effects on the concentration of KCN clearly demonstrated the existence of two cyanide-sensitive oxidases interacting with photosynthesis: cyt aa3, which was sensitive to low concentrations of cyanide, and an alternative oxidase, which could be suppressed by using 1 mM KCN. The interaction between the photosynthetic and the respiratory electron transport chains was regulated mainly by the activity of the alternative cyanide-sensitive oxidase. The oxidative pathway involving the alternative cyanide-sensitive oxidase was insensitive to salicyl hydroxamic acid and azide. The close resemblance of the inhibition pattern reported here and that described for chlororespiration in algae and higher plants strongly suggest that an oxidase of the same type as the alternative cyanide-sensitive oxidase of cyanobacteria functions as a terminal oxidase in chloroplasts.     

Energy transduction in photosynthetic bacteria. X. Composition and function of the branched oxidase system in wild type and respiration deficient mutants of Rhodopseudomonas capsulata.

The respiratory chain of Rhodopseudomonas capsulata, strain St. Louis and of two respiration deficient mutants (M6 and M7) has been investigated by examining the redox and spectral characteristics of the cytochromes and their response to substrates and to specific respiratory inhibitors. Since the specific lesions of M6 and M7 have been localized on two different branches of the multiple oxidase system of the wild type strain, the capability for aerobic growth of these mutants can be considered as a proof of the physiological significance of both branched systems "in vivo". Using M6 and M7 mutants the response of the branched chain to respiratory inhibitors could be established. Cytochrome oxidase activity, a specific function of an high potential cytochrome b (E'0 = +413 mV) is sensitive to low concentrations of KCN (5-10(-5) M); CO is a specific inhibitor of an alternative oxidase, which is also inhibited by high concentrations of KCN (10(-3) M). Antimycin A inhibits preferentially the branch of the chain affected by low concentrations of cyanide. Redox titrations and spectral data indicate the presence in the membrane of three cytochromes of b type (E'0 = +413, +260, +47 vM) and two cytochromes of c type (E'0 = +342, +94 mV). A clear indication of the involvement in respiration of cytochrome b413, cytochrome c342 and cytochrome b47 has been obtained. Only 50% of the dithionite reducible cytochrome b can be reduced by respiratory substrates also in the presence of high concentrations of KCN or in anaerobiosis. The presence and function of quinones in the respiratory electron transport system has been clearly demonstrated. Quinones, which are reducible by NADH and succinate to about the same extent can be reoxidized through both branches of the respiratory chain, as shown by the response of their redox state to KCN. The possible site of the branching of the electron transport chain has been investigated comparing the per cent level of reduction of quinones and of cytochromes b and c as a function of KCN concentrations in membranes from wild type and M6 mutants cells. The site of the branching has been localized at the level of quinones-cytochrome b47. A tentative scheme of the respiratory chains operating in Rhodopseudomonas capsulata, St. Louis and in the two respiration deficient mutants, M6 and M7 is presented.     

Action of Respiratory Inhibitors on Seed Germination and Oxygen Uptake in Avena fatua L.

The effects of sodium azide, potassium cyanide (cytochrome oxidaseinhibitors), and salicylhydroxamic acid (SHAM; an alternativerespiration inhibitor) on germination and respiration of Avenafatua L. seeds were studied. Azide and cyanide released seeddormancy at similar concentrations and treatment durations.Cyanide, however, stimulated germination of seeds with littleafter-ripening, whereas azide had no effect under similar conditionsunless the seeds were after-ripened for several months; theduration of after-ripening required for seeds to respond toazide varied with seed batch. There was also a greater lag priorto germination in the case of azide, compared to cyanide treatedseeds. SHAM inhibited the stimulation of germination and respirationby azide, but not by cyanide. Furthermore, respiration induced by azide or cyanide could notbe inhibited by the subsequent application of SHAM. These findingssuggest that the respiration stimulated by azide and cyanideis not alternative (SHAM-sensitive) and, therefore, this respiratorypathway cannot be involved in the stimulation of germinationby cytochrome oxidase inhibitors. While embryos excised fromcontrol, azide or cyanide pretreated seeds had the capacityto perform alternative respiration, the actual contributionof this pathway was negligible. A large proportion of respirationof embryos excised from azide or cyanide pretreated seeds wasresidual, i.e. insensitive to both SHAM and cyanide. Alternative respiration, azide, cyanide, dormancy, salicylhydroxamic acid, wild oats     

Azide inhibition of mitochondrial electron transport II. Spectral changes induced by azide

Azide inhibition of coupled mitochondrial transport is accompanied by spectral changes which indicate that the cytochrome a₃ is oxidized and cytochrome a reduced. The cytochrome a absorption band is shifted to shorter wavelengths in the azideinhibited system. This shift in the absorption band can be reversed by conditions leading to reduction of cytochrome a₃ such as uncouplers and anaerobiosis, or terminal inhibitors such as sulfide, cyanide or CO.

Titrations of the azide-induced spectral changes indicate the binding of one azide molecule in the complex, and that the dissociation constant is experimentally indistinguishable from the uncompetitive inhibitor constants for inhibition of State 3 respiration. The azide inhibition is postulated to involve the formation of a reduced cytochrome a azide compound which is unstable in the presence of reduced cytochrome a₃.     

Cyanide Resistance in Achromobacter I. Induced Formation of Cytochrome a(2) and Its Role in Cyanide-Resistant Respiration.

Arima, Kei (University of Tokyo, Tokyo, Japan), and Tetuo Oka. Cyanide resistance in Achromobacter. I. Induced formation of cytochrome a(2) and its role in cyanide-resistant respiration. J. Bacteriol. 90:734-743. 1965.-By following the cytochrome concentrations during the growth cycle and under various conditions (aerobic, aerobic plus KCN, reduced aeration, anaerobic plus NaNO(3)) in Achromobacter strain D, a close relationship between the formation of cytochrome a(2) (and a(1)) and the difficulty of oxygen utilization was demonstrated. Cytochrome o, which was the only oxidase found in aerobic log-phase cells, was present in bacterial cells grown under various conditions; the amount present had no relation to the degree of cyanide resistance. On the other hand, cytochrome a(2) (and a(1)) was inducible, and a close relation was observed between the amount of cytochrome and resistance to cyanide. Spectrophotometric observations indicated that, among the cytochromes present in resistant cells, cytochrome a(2) could be oxidized most easily in the presence of cyanide and that cytochrome b(1) could be oxidized without the oxidation of cytochrome a(1). We concluded that cytochrome a(2) is a cyanide-resistant oxidase capable of catalyzing the oxidation of cytochromes in the presence of cyanide. Cytochrome a(2) is also resistant to azide, an inhibitor of cytochrome oxidase.     

Biochemical and biophysical studies on cytochrome c oxidase. XIX. An EPR study of the photodissociation of carboxycytochrome c oxidase in the presence of azide

1. The photodissociation reaction of the cytochrome c oxidase-CO compound in the presence of azide was studied by EPR at 15°K. Addition of CO in the dark to cytochrome c oxidase, partially reduced (2 electrons per 4 metal ions) in the presence of azide brings about a decrease in intensity of the azide-induced low-spin heme signal at g = 2.9, 2.2 and 1.67 and an increase in intensity of both the low-spin heme signal at g = 3 and the copper signal at g = 2. Subsequent illumination with white light at room temperature of this sample causes an enhancement of the azide-induced signal at g = 2.9, and a decrease in intensity of both signals at g = 3 and g = 2. It is shown that these changes in the EPR spectrum are reversible.

2. These results demonstrate that upon photodissociation, CO is replaced by azide wheras upon incubation in the dark CO expels azide from its binding site in cytochrome c oxidase.

3. Concomitantly with the binding of CO and dissociation of the azide molecule, and vice versa, electron redistributions occur as inferred from the changes in the intensity of the copper signal at g = 2.

4. The results are explained in a model of cytochrome c oxidase with either a common binding site (cytochrome a₃)^* for CO and azide or in a model with anti-cooperative interaction between two different sites of binding.

5. Similar types of experiments with cyanide instead of azide show that cyanide is more firmly bound to partially reduced cytochrome c oxidase than CO and azide. The affinity of ligands for partially reduced enzyme decreases in the sequence: cyanide, CO (dark), azide and CO (illuminated).     

Isolation and characterization of mutants defective in the cyanide-insensitive respiratory pathway of Pseudomonas aeruginosa.

The branched respiratory chain of Pseudomonas aeruginosa contains at least two terminal oxidases which are active under normal physiological conditions. One of these, cytochrome co, is a cytochrome c oxidase which is completely inhibited by concentrations of the respiratory inhibitor potassium cyanide as low as 100 microM. The second oxidase, the cyanide-insensitive oxidase, is resistant to cyanide concentrations in excess of 1 mM as well as to sodium azide. In this work, we describe the isolation and characterization of a mutant of P. aeruginosa defective in cyanide-insensitive respiration. This insertion mutant was isolated with mini-D171 (a replication-defective derivative of the P. aeruginosa phage D3112) as a mutagen and by screening the resulting tetracycline-resistant transductants for the loss of ability to grow in the presence of 1 mM sodium azide. Polarographic studies on the NADH-mediated respiration rate of the mutant indicated an approximate 50% loss of activity, and titration of this activity against increasing cyanide concentrations gave a monophasic curve clearly showing the complete loss of cyanide-insensitive respiration. The mutated gene for a mutant affected in the cyanide-insensitive, oxidase-terminated respiratory pathway has been designated cio. We have complemented the azide-sensitive phenotype of this mutant with a wild-type copy of the gene by in vivo cloning with another mini-D element, mini-D386, carried on plasmid pADD386. The complemented cio mutant regained the ability to grow on medium containing 1 mM azide, titration of its NADH oxidase activity with cyanide gave a biphasic curve similar to that of the wild-type organism, and the respiration rate returned to normal levels. Spectral analysis of the cytochrome contents of the membranes of the wild type, the cio mutant, and the complemented mutant suggests that the cio mutant is not defective in any membrane-bound cytochromes and that the complementing gene does not encode a heme protein.     

Characterization of oxidative phosphorylation in the colorless chlorophyte Polytomella sp. Its mitochondrial respiratory chain lacks a plant-like alternative oxidase

The presence of an alternative oxidase (AOX) in Polytomella sp., a colorless relative of Chlamydomonas reinhardtii, was explored. Oxygen uptake in Polytomella sp. mitochondria was inhibited by KCN (94%) or antimycin (96%), and the remaining cyanide-resistant respiration was not blocked by the AOX inhibitors salicylhydroxamic acid (SHAM) or n-propylgallate. No stimulation of an AOX activity was found upon addition of either pyruvate, alpha-ketoglutarate, or AMP, or by treatment with DTT. An antibody raised against C. reinhardtii AOX did not recognized any polypeptide band of Polytomella sp. mitochondria in Western blots. Also, PCR experiments and Southern blot analysis failed to identify an Aox gene in this colorless alga. Finally, KCN exposure of cell cultures failed to stimulate an AOX activity. Nevertheless, KCN exposure of Polytomella sp. cells induced diminished mitochondrial respiration (20%) and apparent changes in cytochrome c oxidase affinity towards cyanide. KCN-adapted cells exhibited a significant increase of a-type cytochromes, suggesting accumulation of inactive forms of cytochrome c oxidase. Another effect of KCN exposure was the reduction of the protein/fatty acid ratio of mitochondrial membranes, which may affect the observed respiratory activity. We conclude that Polytomella lacks a plant-like AOX, and that its corresponding gene was probably lost during the divergence of this colorless genus from its close photosynthetic relatives.     

Respiratory metabolism of normal and divisionless strains of Candida albicans

Respiration of a normal strain of Candida albicans was compared with that of a divisionless mutant which has a biochemical lesion such that metabolically generated hydrogen "spills over," during growth, for non-specific dye reduction. This waste is not at expense of growth, since both strains grow at essentially similar rates, nor at expense of respiration, since the mutant reduces oxygen more rapidly than the normal strain. Respiration in both strains is qualitatively similar, and seemingly unique among highly aerobic organisms in that it is not mediated by cytochrome oxidase. In resting cells of both strains, respiration is not only resistant to, but markedly stimulated by, high concentrations of cyanide, carbon monoxide, and azide. In contrast, growth of these yeasts is inhibited by low concentrations of cyanide and azide. Cytochrome oxidase could not be detected in cell-free preparations; reduced cytochrome c was not oxidized by such preparations. Cytochrome bands could not be observed in thick cell suspensions treated with reducing agents. However, incorporation of superoptimal levels of zinc and iron into the culture medium resulted in growth of cells possessing distinct cytochrome bands; respiration of these cells remained insensitive to cyanide, monoxide, and azide, and the bands were maintained in a reduced form on oxygenation. In the divisionless yeast, tetrazolium dyes compete with oxygen for reduction; this is not the case in the normal strain. The firmness with which hydrogen transfer is channeled in the latter for reduction of disulfide bonds (of importance in the division mechanism) and of oxygen, is contrasted with the lack of such control in the mutant.     

Sulfide-Resistant Respiration in Leaves of Elodea canadensis Michx: Comparison with Cyanide-Resistant Respiration

The rate of dark O₂ uptake of Elodea canadensis leaves was titrated with either cyanide or sulfide in the presence and in the absence of 5 millimolar salicylhydroxamic acid (SHAM), an inhibitor of the alternative oxidase. The inhibition of O₂ uptake by SHAM alone was very small (3-6%), suggesting that actual respiration mainly occurred through the cytochrome pathway. O₂ uptake was slightly stimulated by cyanide at concentrations of 50 micromolar or higher, but in the presence of SHAM respiration was strongly suppressed. The effects of sulfide on O₂ uptake were similar to those of cyanide, except that the percent stimulation of O₂ uptake by sulfide alone was somewhat higher than that of cyanide. However, the estimates of the capacity of the alternative pathway were similar with both inhibitors. Another difference is that maximal inhibition of respiration in the presence of SHAM was observed with lower concentrations of sulfide (50 micromolar) than cyanide (250 micromolar). The results suggest that sulfide can be used as a suitable inhibitor of cytochrome c oxidase in studies with intact plant tissues, and that sulfide does not apparently inhibit the alternative oxidase.     

Cyanide- and hydroxamate-resistant respiration in Neurospora crassa.

Strain inl-89601 of Neurospora crassa respires exclusively by means of the mitochondrial cytochrome chain. The respiration of this strain is entirely inhibited by cyanide or antimycin A, the classical inhibitors of cytochrome chain respiration. When this strain was grown in the presence of chloramphenicol, however, two additional terminal oxidases were detected. One of these oxidases is inhibited by substituted hydroxamic acids and has been described previously. The second oxidase was not inhibited by cyanide or hydroxamic acid but was inhibited by azide in the presence of both cyanide and hydroxamic acid. This azide-sensitive respiration was due to a single respiratory pathway with a Ki for azide of 200 micrometer. A small amount of azide-sensitive respiration was detected in mitochondrial fractions obtained from chloramphenicol-treated cells, and it is likely that the azide-sensitive oxidase is localized in the mitochondrion. The determinants for the azide-sensitive and hydroxamate-sensitive oxidases segregate in a Mendelian manner in crosses and are either unlinked or not closely linked to each other.     

Cyanide- and carbon monoxide-resistant mutants of Vitreoscilla: altered cytochromes and respiratory properties

Two respiratory mutants of the aerobic bacterium, Vitreoscilla, have been studied: a CO-resistant mutant that can grow in 50% CO-50% oxygen, and a cyanide-resistant mutant that can grow in 1 mM KCN. Wild-type cells are unable to grow under either condition. This report presents evidence that the resistance of the CO mutant is due to an altered membrane-bound cytochrome o [cytochrome o(m)], and that of the cyanide mutant is due to the presence of an increased amount of cytochrome d, which has a lower affinity for cyanide than cytochrome o(m). The evidence was obtained from spectral studies on the three types of intact cells as well as enzymatic and ligand-binding techniques on the cytoplasmic cytochromes o[cytochrome o(s)] and the respiring membrane vesicles isolated from these cells. Carbon monoxide difference spectra of intact cells revealed a 5-nm shift in an absorption maximum of a CO-binding pigment in the CO mutant relative to that of the wild type. The formation of oxygenated cytochrome o(s) and its conversion to the reduced form when the cells became anaerobic due to cellular respiration were inhibited when 1 mM KCN was added to a cell suspension of wild-type cells; the cyanide mutant cells showed resistance to cyanide in this experiment. Cytochrome o(s) purified from all three cell types had identical physical, electron transferring, and ligand binding properties within experimental error. Respiring membrane vesicles isolated from the two mutants showed more resistance to inhibition by cyanide and carbon monoxide than those from the wild type. Carbon monoxide difference spectra of these membrane vesicles revealed that there was a fivefold increase in the amount of cytochrome d in the cyanide mutant relative to the wild type. A CO absorption band of the membrane-bound cytochrome o in the CO mutant membrane vesicles showed a 5-nm shift relative to that of the wild type.     

The respiratory responses to cyanide of a cyanide-resistant Klebsiella oxytoca bacterial strain

The respiratory system of a cyanide-resistant Klebsiella oxytoca was analyzed by monitoring the changes in the cytochrome contents in response to various inhibitors in the presence of various concentrations of cyanide. The cells grown in the medium without cyanide (KCN) have two terminal oxidases, cytochrome d (Ki = 10(-5) M KCN) and o (Ki = 10(-3) M KCN). When cells were grown on medium with 1 mM KCN, the expression of both b-type cytochrome and cytochrome d in the plasma membranes of the cell decreased by more than 50%, while cytochrome o increased by 70%, as compared with the cells grown in the absence of KCN. Two terminal oxidases with Ki values of about 10(-3) M and 1.7 x 10(-2) M KCN were observed in the plasma membrane fractions of the cells growing on KCN enriched medium. 2-n-Heptyl-4-hydroxyquinoline-N-oxide markedly inhibited the oxidation of NADH by the plasma membranes from the cells grown in the medium without KCN, but not in those plasma membranes from KCN-grown cells. The NADH oxidases in plasma membranes of K. oxytoca grown with and without KCN were equally sensitive to UV irradiation. Adding freshly isolated quinone to the UV-damaged plasma membranes restored the NADH oxidase activity from both types of plasma membranes. From these results, we propose the presence of a non-heme type of terminal oxidase to account for the KCN resistance in K. oxytoca.     

Further studies on the NADH oxidase of the cytoplasmic membrane of Mycobacterium tuberculosis

The cytoplasmic membrane of the H₃₇Ra strain of Mycobacterium tuberculosis has been isolated free of cell wall.

These membrane preparations contain very small quantities of cytochromes c, b and cytochrome oxidase. The cytochrome c is not extracted by any method attempted. The cytochrome b is reducible only by dithionite and is believed not to be involved in the direct transfer of electrons during the oxidation of NADH by these preparations. The NADH oxidase activity of the membrane is inhibited by high concentrations of cyanide and also by 2-(n-heptyl)-4-hydroxyquinoline-N-oxide (HQNO). The cytochrome oxidase of the membrane contains both cytochromes a and a₃ and is present in low concentrations relative to cytochrome c. The cytochrome a₃ component was identified by characteristic complexes with both CO and cyanide and shows a γ-band absorption maximum at a slightly lower wavelength than the cytochrome oxidase of mammalian mitochondria (442 nm vs. 445 nm). The functional activity of the cytochrome oxidase is indicated by the inhibition of reoxidation of reduced cytochromes c and a in the presence of cyanide.     

Respiration of barley roots: Assessment of activity of the alternative path using SHAM

The activity of the alternative path of O₂ consumption in detached and intact roots of barley [ Hordeum distichum (L.) Lam. cv. Maris Mink] was determined by titration with salicylhydroxamic acid (SHAM) in the presence and absence of cyanide. In the absence of cyanide, only high concentrations were inhibititory (> 5 m M ). whilst in its presence low SHAM concentrations (2.5–5.0 m M ) gave maximum inhibition: the resulting ϱ V_alt plots were non-linear. A SHAM-stimulated peroxidase could readily be washed from these roots, but non-linearity cannot be explained in terms of SHAM-stimulation of this peroxidase as it is not active in the absence of an exogenous supply of NADH. In detached roots the degree of inhibition of respiration with 25 m M SHAM was nearly double the capacity of the alternative path (measured as the degree of inhibition by SHAM in the presence of cyanide), suggesting non-specific inhibition. Effects of SHAM on cytochrome path activity in intact roots were examined by reverse titration with cyanide in the presence and absence of SHAM. At 5 m M SHAM had no effect on the cytochrome path, but at 25 m M it inhibited. We conclude that the only factor causing non-linearity of ϱV_alt plots in barley roots is non-specific inhibition of the cytochrome path by high concentrations of SHAM; consequently only low concentrations of SHAM (2.5–5.0 m M ) are suitable for estimating alternative path activity in barley roots.     

PARTICIPATION OF A NON-RESPIRATORY FERROUS COMPLEX DURING MITOSIS IN ROOTS

A systematic survey was undertaken, of the effects of carbon monoxide and hydrogen cyanide (in the presence of 20 per cent oxygen), in darkness and light, on the relative rates of respiration, mitosis, and interphase in pea root tips. The inhibition of respiration by carbon monoxide was light-sensitive, but the inhibition by hydrogen cyanide was light-stable. The inhibitions were presumably due to combination of the inhibitor with the iron of cytochrome oxidase, in its divalent and trivalent forms respectively. In contrast, the inhibitions of mitosis by both poisons proved to be light-sensitive. The light-sensitive inhibition of mitosis by carbon monoxide shows that an iron complex is responsible for the process. That the inhibition of mitosis by hydrogen cyanide is also light-reversible shows that, in contrast with cytochrome oxidase, the mitotic iron complex remains always in the divalent state. The relative affinities of the mitotic ferrous complex, in molar units, were 0.68 for CO/O₂, and 0.37 for HCN/O₂. The properties of the complex are analogous to, yet distinct from, Gastrophilus haemoglobin and reduced cytochrome oxidase. It is considered that the arrest of mitosis by oxygen lack, carbon monoxide, and hydrogen cyanide is definitely due to interference with this unidentified, non-respiratory ferrous complex.     

Inhibition and stimulation of root respiration in pisum and plantago by hydroxamate : its consequences for the assessment of alternative path activity

The contribution of the alternative pathway in root respiration of Pisum sativum L. cv Rondo, Plantago lanceolata L., and Plantago major L. ssp major was determined by titration with salicylhydroxamate (SHAM) in the absence and presence of cyanide. SHAM completely inhibited the cyanide-resistant component of root respiration at 5 to 10 millimolar with an apparent K_i of 600 micromolar. In contrast, SHAM enhanced pea root respiration by 30% at most, at concentrations below 15 millimolar. An unknown oxidase appeared to be responsible for this stimulation. Its maximum activity in the presence of low SHAM concentrations (1-5 millimolar) was 40% of control respiration rate in pea roots, since 25 millimolar SHAM resulted in 10% inhibition. In plantain roots, the maximum activity was found to be 15%. This hydroxamate-activated oxidase was distinct from the cytochrome path by its resistance to antimycin. The results of titrations with cyanide and antimycin indicated that high SHAM concentrations (up to 25 millimolar) block the hydroxamate-activated oxidase, but do not affect the cytochrome path and, therefore, are a reliable tool for estimating the activity of the alternative path in vivo. A considerable fraction of root respiration was mediated by the alternative path in plantain (45%) and pea (15%), in the latter because of the saturation of the cytochrome path.     

The effect of inhibitors on the oxygen kinetics of cytochrome c oxidase.

1. The oxygen kinetics of purified beef heart cytochrome c oxidase were investigated. 2. The effect of addition of various fixed concentrations of the inhibitors CO, HN3, HCOOH, HCN and H2S on the double reciprocal plot of respiration rate against oxygen concentration was studied. 3. CO is strictly competitive, azide and formate are uncompetitive, and cyanide and sulfide are non-competitive inhibitors towards oxygen. 4. Binding constants for the various inhibitors from secondary plots of the oxygen kinetics at pH 7.4 are: CO: Ki = 0.32 micronM, azide: Ki = 33 micronM; formate: Ki = 15 mM; cyanide: Ki = 0.2 micronM and sulfide: Ki = 0.2 micronM. 5. The possible significance of these results in the elucidation of the reaction mechanism is discussed.