The cellular production of hydrogen peroxide

1. The enzyme–substrate complex of yeast cytochrome c peroxidase is used as a sensitive, specific and accurate spectrophotometric H₂O₂ indicator. 2. The cytochrome c peroxidase assay is suitable for use with subcellular fractions from tissue homogenates as well as with pure enzyme systems to measure H₂O₂ generation. 3. Mitochondrial substrates entering the respiratory chain on the substrate side of the antimycin A-sensitive site support the mitochondrial generation of H₂O₂. Succinate, the most effective substrate, yields H₂O₂ at a rate of 0.5nmol/min per mg of protein in state 4. H₂O₂ generation is decreased in the state 4→state 3 transition. 4. In the combined mitochondrial–peroxisomal fraction of rat liver the changes in the mitochondrial generation of H₂O₂ modulated by substrate, ADP and antimycin A are followed by parallel changes in the saturation of the intraperoxisomal catalase intermediate. 5. Peroxisomes supplemented with uric acid generate extraperoxisomal H₂O₂ at a rate (8.6–16.4nmol/min per mg of protein) that corresponds to 42–61% of the rate of uric acid oxidation. Addition of azide increases these H₂O₂ rates by a factor of 1.4–1.7. 6. The concentration of cytosolic uric acid is shown to vary during the isolation of the cellular fractions. 7. Microsomal fractions produce H₂O₂ (up to 1.7nmol/min per mg of protein) at a ratio of 0.71–0.86mol of H₂O₂/mol of NADP⁺ during the oxidation of NADPH. H₂O₂ is also generated (6–25%) during the microsomal oxidation of NADH (0.06–0.025mol of H₂O₂/mol of NAD⁺). 8. Estimation of the rates of production of H₂O₂ under physiological conditions can be made on the basis of the rates with the isolated fractions. The tentative value of 90nmol of H₂O₂/min per g of liver at 22°C serves as a crude approximation to evaluate the biochemical impact of H₂O₂ on cellular metabolism.     

Peroxidative permeabilization of liposomes induced by cytochrome c/cardiolipin complex

Interaction of cytochrome c with mitochondrial cardiolipin converting this electron transfer protein into peroxidase is accepted to play an essential role in apoptosis. Cytochrome c/cardiolipin peroxidase activity was found here to cause leakage of carboxyfluorescein, sulforhodamine B and 3-kDa (but not 10-kDa) fluorescent dextran from liposomes. A marked decrease in the amplitude of the autocorrelation function was detected with a fluorescence correlation spectroscopy setup upon incubation of dye-loaded cardiolipin-containing liposomes with cytochrome c and H₂O₂, thereby showing release of fluorescent markers from liposomes. The cytochrome c/H₂O₂-induced liposome leakage was suppressed upon increasing the ionic strength, in contrast to the leakage provoked by Fe/ascorbate, suggesting that the binding of cyt c to negatively-charged membranes was required for the permeabilization process. The cyt c/H₂O₂-induced liposome leakage was abolished by cyanide presumably competing with H₂O₂ for coordination with the central iron atom of the heme in cyt c. The cytochrome c/H₂O₂ permeabilization activity was substantially diminished by antioxidants (trolox, butylhydroxytoluene and quercetin) and was precluded if fully saturated tetramyristoyl-cardiolipin was substituted for bovine heart cardiolipin. These data favor the involvement of oxidized cardiolipin molecules in membrane permeabilization resulting from cytochrome c/cardiolipin peroxidase activity. In agreement with previous observations, high concentrations of cyt c induced liposome leakage in the absence of H₂O₂, however this process was not sensitive to antioxidants and cyanide suggesting direct membrane poration by the protein without the involvement of lipid peroxidation.     

Physical and catalytic properties of a peroxidase derived from cytochrome c

Except for its redox properties, cytochrome c is an inert protein. However, dissociation of the bond between methionine-80 and the heme iron converts the cytochrome into a peroxidase. Dissociation is accomplished by subjecting the cytochrome to various conditions, including proteolysis and hydrogen peroxide (H₂O₂)-mediated oxidation. In affected cells of various neurological diseases, including Parkinson's disease, cytochrome c is released from the mitochondrial membrane and enters the cytosol. In the cytosol cytochrome c is exposed to cellular proteases and to H₂O₂ produced by dysfunctional mitochondria and activated microglial cells. These could promote the formation of the peroxidase form of cytochrome c. In this study we investigated the catalytic and cytolytic properties of the peroxidase form of cytochrome c. These properties are qualitatively similar to those of other heme-containing peroxidases. Dopamine as well as sulfhydryl group-containing metabolites, including reduced glutathione and coenzyme A, are readily oxidized in the presence of H₂O₂. This peroxidase also has cytolytic properties similar to myeloperoxidase, lactoperoxidase, and horseradish peroxidase. Cytolysis is inhibited by various reducing agents, including dopamine. Our data show that the peroxidase form of cytochrome c has catalytic and cytolytic properties that could account for at least some of the damage that leads to neuronal death in the parkinsonian brain.     

Purification of cytochrome c peroxidase for monitoring H2O2 production

One of the most precise methods of determining hydrogen peroxide (H₂O₂) formation by biological systems is based on measuring the rate of enzyme-substrate complex formation between H₂O₂ and cytochrome c peroxidase (CCP). The main problem with this method is that CCP is not commercially available and has to be prepared in the laboratory. We have modified some currently available methods for purifying a highly active preparation of CCP in about 4 d. It includes a batch extraction of protein using DEAE-sepharose followed by concentration either by lyophilization or by passing the extract through a small DEAE-sepharose column instead of by ultrafiltration. The concentrated preparation is passed through a Sephadex G-75 column and the final CCP crystallized against water. The final preparations had a purity index (PI, ratio of absorbance at 408 nm/280 nm, equivalent to heme/protein ratio) above 1.2. These changes make the overall procedure very simple, preserving enzyme activity and spectral properties. In addition, we point out that special care has to be taken to eliminate cytochrome c from crude CCP extracts. Cytochrome c not only introduces an artifact when determining PI, but is also may act as a hydrogen donor for CCP when monitoring H₂O₂ formation, thus decreasing the sensitivity of this method.     

Pyridine nucleotides and H2 as electron donors to the respiratory and photosynthetic electron-transfer chains and to nitrogenase in Anabaena heterocysts

The pathways through which NADPH, NADH and H₂ provide electrons to nitrogenase were examined in anaerobically isolated heterocysts. Electron donation in freeze-thawed heterocysts and in heterocyst fractions was studied by measuring O₂ uptake, acetylene reduction and reduction of horse heart cytochrome c. In freeze-thawed heterocysts and membrane fractions, NADH and H₂ supported cyanide-sensitive, respiratory O₂ uptake and light-enhanced, cyanide-insensitive uptake of O₂ resulting from electron donation to O₂ at the reducing side of Photosystem I. Membrane fractions also catalyzed NADH-dependent reduction of cytochrome c. In freeze-thawed heterocysts and soluble fractions from heterocysts, NADPH donated electrons in dark reactions to O₂ or cytochrome c through a pathway involving ferredoxin:NADP reductase; these reactions were only slightly influenced by cyanide or illumination. In freeze-thawed heterocysts provided with an ATP-generating system, NADH or H₂ supported slow acetylene reduction in the dark through uncoupler-sensitive reverse electron flow. Upon illumination, enhanced rates of acetylene reduction requiring the participation of Photosystem I were observed with NADH and H₂ as electron donors. Rapid NADPH-dependent acetylene reduction occurred in the dark and this activity was not influenced by illumination or uncoupler. A scheme summarizing electron-transfer pathways between soluble and membrane components is presented.     

Oxidative stresses elevate the expression of cytochrome c peroxidase in Saccharomyces cerevisiae

Cytochrome c peroxidase (CcP) uses hydrogen peroxide as an electron acceptor to oxidize cytochrome c (Cc) in the mitochondrial intermembrane space. A null allele of yeast CCP1 gene encoding CcP was created by one-step gene disruption method in a diploid yeast strain. Haploid yeast cells with the disrupted CCP1 gene were viable and able to grow in a medium containing lactic acid or glycerol as an energy source, indicating that CcP is not essential for both cell viability and respiration. However, CCP1-disrupted cells were more sensitive to H₂O₂ than wild-type cells. We also constructed a CCP1–lacZ fused gene and integrated this gene into yeast chromosomal DNA to monitor the expression of CCP1 gene. We found that expression of CCP1 gene increases under respiratory culture conditions and by treatments with H₂O₂. These results hint that the biological function of CcP is to reduce H₂O₂ generated during aerobic respiratory process. Moreover, expression of CCP1 gene increased by treatments with peroxynitrite, indicating that CcP may act as a peroxynitrite scavenger.     

CO-binding pigments and the functional terminal oxidase of the trypanosomatid hemoflagellate Crithidia fasciculata

CO-difference absorbance spectra of both intact cells and of mitochondrial preparations isolated from Crithidia fasciculata were obtained after anaerobiosis was attained either with substrates or with dithionite. Under both sets of conditions, the CO-difference spectrum of cytochrome a₃, with difference absorbance maxima at 430 and 589 nm and minima at 443 and 612 nm, was readily identified in both the intact cells and in the mitochondria. In addition to the difference absorbance bands of cytochrome a₃-CO, three difference absorbance maxima at 417, 538 and 570 nm and a minimum at 556 nm were observed. The magnitude of the maximum at 570 nm relative to the maximum of cytochrome a₃-CO at 589 nm was less for mitochondria rendered anaerobic with substrate than for mitochondria rendered anaerobic with dithionite. This difference was taken to define operationally two groups of mitochondrial CO-binding pigments: Group I is that group observed on anaerobiosis with substrate: Group II is the additional group observed on anaerobiosis with dithionite. The Group I CO-binding pigments were virtually absent from submitochondrial particles derived by sonication, but the Group II pigments remained.Photochemical action spectra were obtained with isolated mitochondria and intact cells to ascertain if cytochrome o was present. These action spectra, obtained in CO plus O₂ atmospheres, had maxima only at 432, 550 and 588 nm, attributable to the photodissociation of cytochrome a₃-CO. Even after suppression of cytochrome a₃ activity to 10% of the normal value, no contribution of cytochrome o activity to the photochemical action spectrum was observed. Cytochrome a₃ is therefore the only functional terminal oxidase present in the mitochondria of Crithidia fasciculata.     

Hydrogen Peroxide Metabolism in Yeasts

A catalase-negative mutant of the yeast Hansenula polymorpha consumed methanol in the presence of glucose when the organism was grown in carbon-limited chemostat cultures. The organism was apparently able to decompose the H₂O₂ generated in the oxidation of methanol by alcohol oxidase. Not only H₂O₂ generated intracellularly but also H₂O₂ added extracellularly was effectively destroyed by the catalase-negative mutant. From the rate of H₂O₂ consumption during growth in chemostat cultures on mixtures of glucose and H₂O₂, it appeared that the mutant was capable of decomposing H₂O₂ at a rate as high as 8 mmol · g of cells⁻¹ · h⁻¹. Glutathione peroxidase (EC 1.11.1.9) was absent under all growth conditions. However, cytochrome c peroxidase (CCP; EC 1.11.1.5) increased to very high levels in cells which decomposed H₂O₂. When wild-type H. polymorpha was grown on mixtures of glucose and methanol, the CCP level was independent of the rate of methanol utilization, whereas the level of catalase increased with increasing amounts of methanol in the substrate feed. Also, the wild type decomposed H₂O₂ at a high rate when cells were grown on mixtures of glucose and H₂O₂. In this case, an increase of both CCP and catalase was observed. When Saccharomyces cerevisiae was grown on mixtures of glucose and H₂O₂, the level of catalase remained low, but CCP increased with increasing rates of H₂O₂ utilization. From these observations and an analysis of cell yields under the various conditions, two conclusions can be drawn. (i) CCP is a key enzyme of H₂O₂ detoxification in yeasts. (ii) Catalase can effectively compete with mitochondrial CCP for hydrogen peroxide only if hydrogen peroxide is generated at the site where catalase is located, namely in the peroxisomes.     

Removal of H₂O₂ and generation of superoxide radical: role of cytochrome c and NADH

In cells, mitochondria, endoplasmic reticulum, and peroxisomes are the major sources of reactive oxygen species (ROS) under physiological and pathophysiological conditions. Cytochrome c (cyt c) is known to participate in mitochondrial electron transport and has antioxidant and peroxidase activities. Under oxidative or nitrative stress, the peroxidase activity of Fe³⁺cyt c is increased. The level of NADH is also increased under pathophysiological conditions such as ischemia and diabetes and a concurrent increase in hydrogen peroxide (H₂O₂) production occurs. Studies were performed to understand the related mechanisms of radical generation and NADH oxidation by Fe³⁺cyt c in the presence of H₂O₂. Electron paramagnetic resonance (EPR) spin trapping studies using 5,5-dimethyl-1-pyrroline-N-oxide (DMPO) were performed with NADH, Fe³⁺cyt c, and H₂O₂ in the presence of methyl-β-cyclodextrin. An EPR spectrum corresponding to the superoxide radical adduct of DMPO encapsulated in methyl-β-cyclodextrin was obtained. This EPR signal was quenched by the addition of the superoxide scavenging enzyme Cu,Zn-superoxide dismutase (SOD1). The amount of superoxide radical adduct formed from the oxidation of NADH by the peroxidase activity of Fe³⁺cyt c increased with NADH and H₂O₂ concentration. From these results, we propose a mechanism in which the peroxidase activity of Fe³⁺cyt c oxidizes NADH to NAD^•, which in turn donates an electron to O₂, resulting in superoxide radical formation. A UV-visible spectroscopic study shows that Fe³⁺cyt c is reduced in the presence of both NADH and H₂O₂. Our results suggest that Fe³⁺cyt c could have a novel role in the deleterious effects of ischemia/reperfusion and diabetes due to increased production of superoxide radical. In addition, Fe³⁺cyt c may play a key role in the mitochondrial “ROS-induced ROS-release” signaling and in mitochondrial and cellular injury/death. The increased oxidation of NADH and generation of superoxide radical by this mechanism may have implications for the regulation of apoptotic cell death, endothelial dysfunction, and neurological diseases. We also propose an alternative electron transfer pathway, which may protect mitochondria and mitochondrial proteins from oxidative damage.     

Structural Re-arrangement and Peroxidase Activation of Cytochrome c by Anionic Analogues of Vitamin E,Tocopherol Succinate and Tocopherol Phosphate

Cytochrome c is a multifunctional hemoprotein in the mitochondrial intermembrane space whereby its participation in electron shuttling between respiratory complexes III and IV is alternative to its role in apoptosis as a peroxidase activated by interaction with cardiolipin (CL), and resulting in selective CL peroxidation. The switch from electron transfer to peroxidase function requires partial unfolding of the protein upon binding of CL, whose specific features combine negative charges of the two phosphate groups with four hydrophobic fatty acid residues. Assuming that other endogenous small molecule ligands with a hydrophobic chain and a negatively charged functionality may activate cytochrome c into a peroxidase, we investigated two hydrophobic anionic analogues of vitamin E, α-tocopherol succinate (α-TOS) and α-tocopherol phosphate (α-TOP), as potential inducers of peroxidase activity of cytochrome c. NMR studies and computational modeling indicate that they interact with cytochrome c at similar sites previously proposed for CL. Absorption spectroscopy showed that both analogues effectively disrupt the Fe-S(Met⁸⁰) bond associated with unfolding of cytochrome c. We found that α-TOS and α-TOP stimulate peroxidase activity of cytochrome c. Enhanced peroxidase activity was also observed in isolated rat liver mitochondria incubated with α-TOS and tBOOH. A mitochondria-targeted derivative of TOS, triphenylphosphonium-TOS (mito-VES), was more efficient in inducing H₂O₂-dependent apoptosis in mouse embryonic cytochrome c^+/+ cells than in cytochrome c^−/− cells. Essential for execution of the apoptotic program peroxidase activation of cytochrome c by α-TOS may contribute to its known anti-cancer pharmacological activity.     

Roles of catalase and cytochrome C in hydroperoxide-dependent lipid peroxidation and chemiluminescence in rat heart and kidney mitochondria

A recent report (Radi et al., J. Biol. Chem. 266:22028–22034, 1991) showed that rat heart mitochondria contain catalase. The protective role of mitochondrial catalase was tested by exposing heart or kidney mitochondria and mitoplasts to two oxidants (H₂O₂) or tert-butyl hydroperoxide, t-BOOH), estimating lipid peroxidation (as thiobarbituric acid-reactive substances, TBARS) and overall oxidative stress (as chemiluminescence). Additional controls included heart and kidney preparations from aminotriazole-treated (catalase-depleted) rats. Both oxidants increased TBARS in catalase-free preparations to similar extents over their respective controls (between 200 to 350%). In catalase-containing preparations, H₂O₂ lipid peroxidation increased by only 40 to 96% over controls. Similar qualitative results were obtained when measuring chemiluminescence. The catalytic role of cytochrome c in mitochondrial lipid peroxidation was investigated by exposing either control or cytochrome-c-depleted kidney mitoplasts (catalase free) to either H₂O₂ or t-BOOH. Hydrogen-peroxide-dependent mitochondrial lipid peroxidation varied with cytochrome c concentrations, remaining close to controls when cytochrome c concentration decreased by 66%, even though there was no catalase present. Tert-butyl hydroperoxide-dependent lipid peroxidation was less affected by cytochrome c remaining 2.3-fold above controls under the same conditions, suggesting that organic peroxides are more likely to remain in the less polar membrane environment being decomposed by heme or nonheme iron imbedded in the inner mitochondrial membrane. Chemiluminescence was less affected by cytochrome c depletion. Comparing control and cytochrome-c-deficient mitochondria, chemiluminescence was 1.7-fold and 2.8-fold higher when control preparations were challenged with t-BOOH or H₂O₂, respectively.     

Cytochrome c is transformed from anti- to pro-oxidant when interacting with truncated oncoprotein prothymosin α

Many apoptotic signals are known to induce release to cytosol of cytochrome c, a small mitochondrial protein with positively charged amino acid residues dominating over negatively charged ones. On the other hand, in this group, it was shown that prothymosin α (PT), a small nuclear protein where 53 of 109 amino acid residues are negatively charged, is truncated to form a protein of 99 amino acid residues which accumulates in cytosol during apoptosis [FEBS Lett. 467 (2000) 150]. It was suggested that positively charged cytochrome c and negatively charged truncated prothymosin α (tPT), when meeting in cytosol, can interact with each other. In this paper, such an interaction is shown. (1) Formation of cytochrome c⋅tPT complex is demonstrated by a blot-overlay assay. (2) Analytical centrifugation of solution containing cytochrome c and tPT reveals formation of complexes of molecular masses higher than those of these proteins. The masses increase when the cytochrome c/tPT ratio increases. High concentration of KCl prevents the complex formation. (3) In the complexes formed, cytochrome c becomes autoxidizable; its reduction by superoxide or ascorbate as well as its operation as electron carrier between the outer and inner mitochondrial membranes appear to be inhibited. (4) tPT inhibits cytochrome c oxidation by H₂O₂, catalyzed by peroxidase. Thus, tPT abolishes all antioxidant functions of cytochrome c which, in the presence of tPT, becomes in fact a pro-oxidant. A possible role of tPT in the development of reactive oxygen species- and cytochrome c-mediated apoptosis is discussed.     

The quantitative measurement of H2O2 generation in isolated mitochondria

Adequate methods to measure the rate of mitochondrial oxygen radical generation are needed since oxygen radicals are involved in many pathologies. A fluorometric method appropriate to measure the rate of generation of H₂O₂ in intact mitochondria is described. Just after isolation of functional mitochondria from fresh tissues, rates of generation of H₂O₂ are kinetically measured by fluorometry in the presence of homovanillic acid and horseradish peroxidase. The method is specific for H₂O₂ and is sensitive enough to assay mitochondrial H₂O₂ generation in the presence of respiratory substrate without inhibitors of the respiratory chain. Simultaneous measurement of mitochondrial oxygen consumption allows calculation of the free radical leak: the percentage of electrons out of sequence which reduce oxygen to oxygen radicals along the mitochondrial respiratory chain instead of reducing oxygen to water at the terminal cytochrome oxidase. The method shows instantaneous response to H₂O₂. This makes it appropriate to study the quick effects of different inhibitors and modulators on the rate of mitochondrial oxygen radical production. Its application to the localization of the sites where caloric restriction decreases mitochondrial oxygen radical generation in heart mitochondria is described.     

Cytochrome c peroxidase is a mitochondrial heme-based H2O2 sensor that modulates antioxidant defense

Hydrogen peroxide (H₂O₂) is a key signaling molecule that also induces apoptosis. Thus, cells must rapidly sense and tightly control H₂O₂ levels. Well-characterized cellular responses to exogenous H₂O₂ involve oxidation of specific cytosolic protein-based thiols but sensing of H₂O₂ generated by mitochondrial respiration is less well described. Here we provide substantial biochemical evidence that the heme enzyme Ccp1 (cytochrome c peroxidase), which is targeted to the intermembrane space, functions primarily as a mitochondrial H₂O₂ sensing and signaling protein in Saccharomyces cerevisiae. Key evidence for a sensing role for Ccp1 is the significantly higher H₂O₂ accumulation in ccp1-null cells(ccp1Δ) vs ccp1^W191F cells producing the catalytically inactive Ccp1^W191F variant. In fact, intracellular H₂O₂ levels (ccp1Δ>wildtype >ccp1^W191F) correlate inversely with the activity of the mitochondrial (and peroxisomal) heme catalase, Cta1 (ccp1Δ<wildtype <ccp1^W191F). Mitochondrial Sod2 activity also varies in the three strains (ccp1Δ>wildtype >ccp1^W191F) and ccp1Δ cells exhibit low superoxide levels. Notably, Ccp1^W191F is a more persistent H₂O₂ signaling protein than wild-type Ccp1, and this enhanced mitochondrial H₂O₂ signaling decreases the mitochondrial fitness of ccp1^W191F cells. However, these cells are fully protected from a bolus (0.4 mM) of exogenous H₂O₂ added after 12 h of growth, whereas the viability of ccp1Δ cells drops below 20%, which additionally associates Ccp1 with Yap1-dependent H₂O₂ signaling. Combined, our results strongly implicate Ccp1, independent of its peroxidase activity, in mitochondrial H₂O₂ sensing and signaling to maintain reactive oxygen species homeostasis.     

Yeast acetic acid-induced programmed cell death can occur without cytochrome c release which requires metacaspase YCA1

To investigate the role of cytochrome c (cyt c) release in yeast acetic acid-induced programmed cell death (AA-PCD), wild type (wt) and cells lacking metacaspase (Δyca1), cytochrome c (Δcyc1,7) and both (Δcyc1,7Δyca1) were compared for AA-PCD occurrence, hydrogen peroxide (H₂O₂) production and caspase activity. AA-PCD occurs in Δcyc1,7 and Δcyc1,7Δyca1 cells slower than in wt, but similar to that in Δyca1 cells, in which no cytochrome c release occurs. Both H₂O₂ production and caspase activation occur in these cells with early and extra-activation in Δcyc1,7 cells. We conclude that alternative death pathways can be activated in yeast AA-PCD, one dependent on cyt c release, which requires YCA1, and the other(s) independent on it.     

Apolar distal pocket mutants of yeast cytochrome c peroxidase: Hydrogen peroxide reactivity and cyanide binding of the TriAla,TriVal, and TriLeu variants

Three yeast cytochrome c peroxidase (CcP) variants with apolar distal heme pockets have been constructed. The CcP variants have Arg48, Trp51, and His52 mutated to either all alanines, CcP(triAla), all valines, CcP(triVal), or all leucines, CcP(triLeu). The triple mutants have detectable enzymatic activity at pH 6 but the activity is less than 0.02% that of wild-type CcP. The activity loss is primarily due to the decreased rate of reaction between the triple mutants and H₂O₂ compared to wild-type CcP. Spectroscopic properties and cyanide binding characteristics of the triple mutants have been investigated over the pH stability region of CcP, pH 4 to 8. The absorption spectra indicate that the CcP triple mutants have hemes that are predominantly five-coordinate, high-spin at pH 5 and six-coordinate, low-spin at pH 8. Cyanide binding to the triple mutants is biphasic indicating that the triple mutants have two slowly-exchanging conformational states with different cyanide affinities. The binding affinity for cyanide is reduced at least two orders of magnitude in the triple mutants compared to wild-type CcP and the rate of cyanide binding is reduced by four to five orders of magnitude. Correlation of the reaction rates of CcP and 12 distal pocket mutants with H₂O₂ and HCN suggests that both reactions require ionization of the reactants within the distal heme pocket allowing the anion to bind the heme iron. Distal pocket features that promote substrate ionization (basic residues involved in base-catalyzed substrate ionization or polar residues that can stabilize substrate anions) increase the overall rate of reaction with H₂O₂ and HCN while features that inhibit substrate ionization slow the reactions.     

Competing peroxidase and oxidase reactions in scopoletin-dependent H2O2-initiated oxidation of NADH by horseradish peroxidase

Addition of NADH inhibited the peroxidative loss of scopoletin in presence of horseradish and H₂O₂ and decreased the ratio of scopoletin (consumed):H₂O₂ (added). Concomitantly NADH was oxidized and oxygen was consumed with a stoichiometry of NADH:O₂ of 2:1. On step-wise addition of a small concentration of H₂O₂ a high rate of NADH oxidation was obtained for a progressively decreasing time period followed by termination of the reaction with NADH:H₂O₂ ratio decreasing from about 40 to 10. The rate of NADH oxidation increased linearly with increase in scopoletin concentration. Other phenolic compounds including p-coumarate also supported this reaction to a variable degree. A 418-nm absorbing compound accumulated during oxidation of NADH. The effectiveness of a small concentration of H₂O₂ in supporting NADH oxidation increased in presence of SOD and decreased in presence of cytochrome c, but the reaction terminated even in their presence. The results indicate that the peroxidase is not continuously generating H₂O₂ during scopoletin-mediated NADH oxidation and that both peroxidase and oxidase reactions occur simultaneously competing for an active form of the enzyme.     

O2-Polarographic Studies on Soluble and Mitochondrial Enzymes of Crithidia fasciculata; Glycerophosphate Enzymes*

SYNOPSIS. Mitochondrial and supernatant fractions were isolated from Crithidia fasciculata by grinding with neutral alumina and differential centrifugation. Supernatant fractions contained at least 2 NAD-linked enzymes: an α-glycerophosphate dehydrogenase and a malate dehydrogenase. The properties of these enzymes were investigated polarographically with phenazine ethosulfate acting as electron acceptor. Agaricic acid, cinnamic acid and p-NO₂-cinnamic acid were specific inhibitors of the α-glycerophosphate dehydrogenase. Succinate, malate, DL-α-glycerophosphate and NADH stimulated respiration of mitochondrial preparations; O₂ uptake was greatest with succinate. KCN and antimycin A inhibited succinate respiration more than α-glycerophosphate respiration. Amytal did not affect succinate, α-glycerophosphate or NADH oxidation. The trypanocide suramin inhibited mitochondrial respiration at least 77% with each substrate. The relevance of these results to other members of the Trypanosomatidae is discussed.     

Aging-related decrease in hepatic cytochrome oxidase of the Fischer 344 rat

The effect of aging on the hepatic mitochondrial population has been determined using a rigorously defined group of Fischer 344 rats with known survivorship data. The age groups studied included mature adult controls (8.5 months; 100% survivorship), an intermediate aged group (17.5 months; 90% survivorship), and an aged group (29 months; 20% survivorship). Cytochrome oxidase activity and content were determined in homogenates and mitochondrial fractions. The mitochondrial fractions were characterized by determination of respiratory activity, and monoamine oxidase activity as well as evaluation of the polypeptide composition by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and two-dimensional electrophoresis. The yield of protein in the isolated mitochondrial fraction as well as the mitochondrial specific content decreased significantly as a function of aging. Mitochondrial specific content was determined from the specific activities of cytochrome oxidase in the homogenate (per gram liver) and in the isolated mitochondrial fraction (per mg protein). Specific activity of hepatic cytochrome oxidase decreased approximately 15% (P = 0.035) in homogenates from the 17.5-month animals with a further, highly significant (P = 0.0002) decrease (29%) in the 29-month animals. In contrast, there was no statistically significant difference among the age groups in the cytochrome oxidase specific activity in the isolated hepatic mitochondrial fractions. However, the percentage of the total homogenate cytochrome oxidase activity recovered in the isolated mitochondrial fraction decreased significantly in the 29-month animals (P = 0.0063 vs the 8.5-month controls; P = 0.022 vs the 17.5-month group). Cytochrome aa₃ content of total liver homogenates from aged animals decreased (P = 0.00064) which is in agreement with the decline in cytochrome oxidase specific activity in this age group. In the mitochondrial fraction from the aged animals, cytochrome aa₃ content was essentially unchanged which is consistent with the lack of aging-related change in mitochondrial cytochrome oxidase specific activity. In freshly isolated mitochondrial fractions, no aging-related alterations were observed in respiratory control and $\text{ADP}\text{O}$ ratios. The addition of exogenous NADH and cytochrome c did not change significantly the respiratory rate of hepatic mitochondria from control or aged animals. These results demonstrate the integrity of freshly isolated mitochondrial preparations from both control and aged Fischer 344 rats. In addition, there was no aging-related alteration in either monoamine oxidase specific activity or polypeptide composition. The similarities observed in the specific activities of cytochrome oxidase and monoamine oxidase, as well as in the cytochrome aa₃ content and polypeptide composition of the isolated mitochondrial fraction, suggest a generalized decrease in hepatic mitochondrial content as a function of aging rather than a selective loss of mitochondrial components.     

Biological significance of methylation of cytochromes from ascomycetes and plants

The K_m and V_max values characterizing the reaction of baker's yeast iso-I-cytochrome c, whether tri-methylated or not at lysine residue 72, with crude preparations of cytochrome c peroxidase, cytochrome c oxidase and succinate cytochrome c oxidoreductase from Saccharomyces cerevisiae are similar. These results, as well as the redox potential values, the auto-oxidability parameters and the circular dichroism spectra, strongly suggest that the biological methylation of yeast cytochrome c does not alter its functional properties. The functional characteristics of baker's yeast iso-I-cytochrome c are similar to those of horse heart cytochrome c and yeast iso-2-cytochrome c.