The respiratory chain of Paramecium tetraurelia in wild type and the mutant Cl1 I. Spectral properties and redox potentials

1. Purified mitochondria have been prepared from wild type Paramecium tetraurelia and from the mutant Cl₁ which lacks cytochrome aa₃. Both mitochondrial preparations are characterized by cyanide insensitivity. Their spectral properties and their redox potentials have been studied.2. Difference spectra (dithionite reduced minus oxidized) of mitochondria from wild type P. tetraurelia at 77 K revealed the α peaks of b-type cytochrome(s) at 553 and 557 nm, of c-type cytochrome at 549 nm and a-type cytochrome at 608 nm. Two α peaks at 549 and 545 nm could be distinguished in the isolated cytochrome c at 77 K. After cytochrome c extraction from wild type mitochondria, a new peak at 551 nm was unmasked, probably belonging to cytochrome c₁. The a-type cytochrome was characterized by a split Soret band with maxima at 441 and 450 nm. The mitochondria of the mutant Cl₁ in exponential phase of growth differed from the wild type mitochondria in that cytochrome aa₃ was absent while twice the quantity of cytochrome b was present. In stationary phase, mitochondria of the mutant were characterized by a new absorption peak at 590 nm.3. Cytochrome aa₃ was present at a concentration of 0.3 nmol/mg protein in wild type mitochondria and ubiquinone at a concentration of 8 nmol/mg protein both in mitochondria of the wild type and the mutant Cl₁. Cytochrome aa₃ was more susceptible to heat than cytochromes b and c,c₁.4. CO difference spectra at 77 K revealed two different Co-cytochrome complexes. The first, found only in wild type mitochondria, was a typical CO-cytochrome a₃ complex characterized by peaks at 596 and 435 nm and troughs at 613 and 450 nm. The second, found both in mitochondria of the wild type and the mutant, was a CO-cytochrome b complex with peaks at 567, 539 and 420 nm and a trough at 558-549 nm. Both complexes are photo-dissociable.5. Spectral evidence was obtained for interaction of cyanide with the a-type cytochrome (shift of the α peak at 77 K from 608 to 605 nm), but not with the b-type cytochrome.6. The mid-point potentials of the different cytochromes at neutral pH are as follows: cytochrome aa₃ 235 and 395 mV, cytochrome c,c₁ 233 mV, cytochromes b 120 mV.     

The Cytochromes of Prototheca zopfii

The respiratory pigments of Prototheca zopfii include seven cytochromes: two c-type cytochromes, a soluble c(549) and a membrane bound c(551); three b-type cytochromes, b(555), b(559) and b(564); and cytochromes a and a₃. Cytochromes a and a₃ could be resolved spectrally in the α-band region by reducing the cells in the presence of methanol and cyanide. Methanol shifted the absorption maximum of cytochrome a from 598 to 603 nanometers and permitted dithionite (or substrate) to reduce the cyanide-cytochrome a₃ complex to give a well defined 595-nanometer absorption band. Methanol did not interfere with CO binding by cytochrome a₃, and CO did not alter the methanol effect on cytochrome a. Azide and cyanide, which partially inhibited exogenous respiration, stimulated endogenous respiration. Frozen steady states of the electron transport chain in the presence of cyanide and azide indicated that the stimulation by these inhibitors was due to an increased autooxidation of one of the b-type cytochromes, possibly b(564).     

Purification of Two Nitrate Reductases from Xanthomonas maltophilia Grown in Aerobic Cultures

Xanthomonas maltophilia ATCC 17666 is an obligate aerobe that accumulates nitrite when grown on nitrate. Spectra of membranes from nitrate-grown cells exhibited b-type cytochrome peaks and A_615-630 indicative of d-type cytochrome but no absorption peaks corresponding to c-type cytochromes. The nitrate reductase (NR) activity was located in the membrane fraction. Triton X-100-extracted reduced methyl viologen-NRs were purified on DE-52, hydroxylapatite, and Sephacryl S-300 columns to specific activities of 52 to 67 μmol of nitrite formed per min per mg of protein. The cytochrome-containing NR_I separated on sodium dodecyl sulfate-polyacrylamide gel electrophoresis into a 135-kDa α-subunit, a 64-kDa β-subunit, and a 23-kDa γ-subunit with relative band intensities indicative of a 1:1:1 α/β/γ subunit ratio and a M_r of 222,000. The electronic spectrum of dithionite-reduced purified NR displayed peaks at 425, 528, and 558 nm, indicative of the presence of a cytochrome b, an interpretation consistent with the pyridine hemochrome spectrum formed. The cytochrome b of the NR was reduced under anaerobic conditions by menadiol and oxidized by nitrate with the production of nitrite. This NR contained 0.96 Mo, 12.5 nonheme iron, and 1 heme per 222 kDa: molybdopterin was detected with the Neurospora crassa nit-1 assay. A smaller reduced methyl viologen-NR (169 kDa), present in various concentrations in the Triton X-100 preparations, lacked a cytochrome spectrum and did not oxidize menadiol. The characteristics of the NRs and the absence of c-type cytochromes provide insights into why X. maltophilia accumulates nitrite.     

The cytochromes of mitochondria from Tetrahymena pyriformis strain ST

1. Mitochondria of the obligately aerobic ciliate protozoon, Tetrahymena pyriformis strain ST, are unusual in that they possess a cytochrome oxidase system that does not react with reduced mammalian cytochrome c; the presence of cytochromes a₆₀₃+a₃ is masked in the α-band region of spectra by the broad absorption band of cytochrome a₆₂₀. 2. Other haemoproteins present include cytochromes b₅₆₀, b₅₅₆, c₅₅₃ and c₅₄₉. 3. The reaction of reduced cytochrome a₃ with CO is reversed by flash photolysis, and in the presence of O₂ the subsequent oxidation of this cytochrome is followed by that of cytochrome a₆₀₃. 4. Cytochromes a₆₂₀ and b₅₆₀ also react with CO and with KCN; the latter cytochrome corresponds with that designated cytochrome o by other workers. 5. The contribution of cytochrome a₆₀₃ to difference spectra is revealed by making use of the fact that it does not react with KCN. 6. Cytochrome a₆₂₀ is unstable, and its α-absorption band is lost from spectra of mitochondria which have been aged or treated with ultrasound, detergents or organic solvents. 7. Possible pathways of electron transport via the several different terminal oxidases in Tetrahymena mitochondria are proposed.     

Spectral Characterization of the Photoreducible b-Type Cytochrome of Dictyostelium discoideum

Irradiation of a soluble extract from broken cells of Dictyostelium discoideum causes the photoreduction of a b-type cytochrome. The cytochrome b can be separated from cytochrome c, which is also present in the extract, by column chromatography on Brushite, but the cytochrome b is no longer sensitive to light after separation on the column. Low temperature spectroscopy shows that reduced form of the photoreducible cytochrome b has a Soret band at 423 nm and a split α band with maxima at 558 and 551 nm similar to the b-type cytochrome in complex II of beef heart mitochondria.     

The electron-transport chains of the obligate methylotroph Methylophilus methylotrophus

The cytochrome complement of Methylophilus methylotrophus and its respiratory properties were determined during batch culture and in continuous culture under conditions of methanol-, nitrogen- and O₂-limitation. About 35% of the cytochrome c produced by the bacteria was released into the growth medium, and of the remaining cytochrome c about half was membrane-bound and half was soluble. Two cytochromes c were always present on membranes (redox potentials 375mV and 310mV), and these probably correspond to the soluble cytochromes c described previously [Cross & Anthony (1980) Biochem. J. 192, 421–427]. A third minor component of cytochrome c (midpoint potential 356mV) was only detected on membranes of methanol-limited bacteria. M. methylotrophus always contained two membrane-bound cytochromes b with α-band absorption maxima of about 556 and 563nm (measured at room temperature) and midpoint potentials of 110 and 60mV respectively. There appeared to be relatively more of the cytochrome b₅₆₃ in methanol-limited bacteria. A third b-type cytochrome with an α-band absorption maximum at 558 (at 77K) reacted with CO and had a high midpoint redox potential (260mV); it is thus a potential oxidase and hence is called cytochrome o. The roles of these cytochromes in electron transport were confirmed by investigating the patterns of respiratory inhibition. It is proposed that two cytochromes are physiological oxidases: cytochrome a+a₃, which is present only in methanol-limited conditions, and the cytochrome o, which is induced 10-fold in conditions of methanol excess. Schemes for electron transport from methanol and NAD(P)H to O₂ in M. methylotrophus under various limitations are proposed. Spectra and potentiometric titrations of cytochromes in whole cells and membranes of M. methylotrophus grown under various nutrient limitations have been deposited as Supplementary Publication SUP 50111 (10 pages) at the British Library Lending Division, Boston Spa, Wetherby, West Yorkshire LS23 7BQ, U.K., from whom copies can be obtained on the terms indicated in Biochem. J. (1978) 169, 5.     

The respiratory chain components of higher plant mitochondria

Tightly coupled mitochondria have been prepared from a variety of plant sources: white potato (Solanum tuberosum), Jerusalem artichoke (Heliantus tuberosus), cauliflower buds (Brassica oleracea), and mung bean hypocotyls (Phaseolus aureus). Mitochondria with no appreciable coupling were also prepared from skunk cabbage spadices (Symplocarpus foetidus).

Room temperature difference spectra show that these mitochondria are very similar in the qualitative and quantitative composition of their electron carriers. The different cytochromes are present in the amounts of 0.1 to 0.3 mμmole per mg of mitochondrial protein. The molar ratios of the different electron carriers are, on the average: 0.7:0.7:1.0:3 to 4:10 to 15 respectively for cytochrome aa₃, cytochromes b, cytochromes c, flavoproteins, and pyridine nucleotides.

From low temperature difference spectra carried out under particular experimental conditions, it can be deduced that these mitochondria contain 3 b cytochromes whose α bands are located at 552, 557, and 561 mμ, and 2 c cytochromes, one of which, a c₁-like cytochrome, is firmly bound to the mitochondrial membrane. Cytochrome oxidase can be optically resolved into its 2 components a and a₃.

For all kinds of mitochondria, the rates of oxidation of succinate are similar as well as the turnover of cytochrome oxidase (50-70 sec⁻¹), regardless of the metabolic activities of the tissues. The number of mitochondria per cell appears to be the controlling factor of the intensity of tissue respiration.

     

Inhibition of Respiration in Prototheca zopfii by Light

Irradiation of cells of Prototheca zopfii with blue light inhibited the respiratory capacity of the cells. The inhibition of respiration was correlated with a photodestruction of cytochrome c(551), cytochrome b(559), and cytochrome a₃. Cytochrome c(549), cytochrome b(555), and cytochrome b(564) were unaffected by the irradiation treatment. The α-band of reduced cytochrome a was shifted from 599 to 603 nm by irradiation, an effect similar to that observed when methanol was added to nonirradiated cells. The presence of oxygen was required during irradiation for both photoinhibition of respiration and photodestruction of the cytochromes. Cytochrome a₃ was protected against photodestruction by cyanide. Photodestruction of these same cytochromes also occurred when washed mitochondria of P. zopfii were irradiated.     

Particulate cytochromes of mung bean seedlings

Efforts have been made to solubilize cytochrome components from particulate fractions of etiolated mung bean seedlings. Low temperature spectrophotometry reveals that the cytochrome composition of mitochondria isolated from whole seedlings is the same as that reported by Bonner for mung bean hypocotyls. On the basis of the identity in position of the α-bands in low temperature difference spectra for mitochondria, for a partially purified haemoprotein from mitochondria, and for purified cytochrome b-555, it is suggested that cytochrome b-555 is an intrinsic component of mung bean mitochondria. Difference spectra show that both the mitochondrial and microsomal fractions contain at least 2 b-type cytochromes. Cytochrome b-555 is almost certainly present in the microsomes, since the low temperature difference spectrum for the cytochrome is identical with the spectrum for this particulate fraction.

By freezing and thawing mung bean mitochondria in 4% cholate and centrifuging, cytochrome oxidase activity can be concentrated in the supernatant fraction, although it is not completely solubilized. The oxidase is inhibited by high concentrations of cytochrome c. A particle-bound cytochrome c can be obtained from mitochondria by digestion with snake venom. However, the autoxidizability of the preparation indicates that the cytochrome has been solubilized in a modified form. A CO-binding pigment can be obtained from mung bean microsomes by digestion with snake venom.

     

The electron transport systems of Fasciola hepatica mitochondria.

The electron transport systems of Fasciola hepatica mitochondria were investigated spectrophotometrically at room temperature and at −196°. The mitochondria were found to contain substrate reducible a-, b- and c-type cytochromes. All of the cytochrome components of the classical mammalian type of respiratory chain were present, although the concentration of cytochromes aa₃ was low. In addition to the mammalian type of respiratory chain, the Fasciola mitochondria contained a substrate reducible b-type cytochrome component (557 nm) which included a CO reactive o-type cytochrome. The results suggest that F. hepatica mitochondria contain a branched electron transport system including a mammalian type of chain and involving two terminal oxidases and at least two b-type cytochromes.     

Biochemical heterogeneity of rat liver mitochondria separated by rate zonal centrifugation

1. Rat liver mitochondria were separated on the basis of their sedimentation coefficients in an iso-osmotic gradient of Ficoll–sucrose by rate zonal centrifugation. The fractions (33, each of 40ml) were collected in order of decreasing density. Fractions were analysed by spectral analysis to determine any differences in the concentrations of the cytochromes and by enzyme analyses to ascertain any differences in the activities of NADH dehydrogenase, succinate dehydrogenase and α-glycerophosphate dehydrogenase. 2. When plotted as% of the highest specific concentration, the contents of cytochrome a+a₃ and cytochrome c+c₁ were constant in all fractions but cytochrome b was only 65% of its maximal concentration in fraction 7 and increased with subsequent fractions. As a result, the cytochrome b/cytochrome a+a₃ ratio almost doubled between fractions 7 and 25 whereas the cytochrome c+c₁/cytochrome a+a₃ ratio was unchanged. 3. Expression of the dehydrogenase activities as% of highest specific activity showed the following for fractions 6–26: NADH dehydrogenase activity remained fairly constant in all fractions; succinate dehydrogenase activity was 62% in fraction 6 and increased steadily to its maximum in fraction 18 and then decreased; the activity of α-glycerophosphate dehydrogenase was only 53% in fraction 6 and increased slowly to its peak in fractions 22 and 24. 4. These differences did not result from damaged or fragmented mitochondria or from microsomal contamination. 5. These results demonstrate that isolated liver mitochondria are biochemically heterogeneous. The importance of using a system for separating biochemically different mitochondria in studies of mitochondrial biogenesis is discussed.     

Properties of Ascaris muscle mitochondria. I. Cytochromes

1. The cytochrome system in Ascaris muscle mitochondria was further characterized using purer preparations.2. Difference spectra (at 22 °C and ?196 °C) of the mitochondrial preparations using succinate and ascorbate plus N,N,N′,N′-tetramethyl-p-phenylenediamine show that Ascaris muscle mitochondria contain cytochromes c₁, c and aa₃, and also at least three b-type cytochromes. The b-type cytochrome is the predominant component.3. Cytochrome c and Ascaris cytochrome b-560 can be extracted from the mitochondrial preparations with 150 mM KCl, leaving the membrane-bound cytochromes c₁, b and aa₃ in the KCl residue.     

Light-inducible Cytochrome Reduction in Membrane Preparations from Corn Coleoptiles: I. STABILIZATION AND SPECTRAL CHARACTERIZATION OF THE REACTION

Conditions for obtaining reproducible light-induced reduction of a b-type cytochrome in membrane fractions from coleoptiles of dark-grown Zea mays L. include a glucose-glucose oxidase system that lowers O₂ tension and generates H₂O₂, substrate amounts of ethylenediaminetetraacetic acid which, in some manner, facilitates photoreduction by both added flavin and the endogenous photoreceptor and a sample temperature below 10 C. Cytochrome reduction could be obtained by photoexcitation of either a tightly bound endogenous receptor, which is probably a flavin, or added riboflavin, flavin mononucleotide, or flavin adenine dinucleotide. The latter flavin was the least effective. The endogenous photoreceptor appears to be rather firmly bound to the membranes, suggesting that this association may also exist in vivo. When any of the above four photoreceptors or methylene blue were used to sensitize the reaction, a cytochrome with a reduced α-band near 560 nanometers and a Soret difference peak near 429 nanometers was the electron acceptor. This cytochrome could be clearly distinguished spectrally from other cytochromes that predominated in the membrane preparations.     

Studies of cytochrome synthesis in rat liver

The incorporation of radioactive amino acids and of δ-amino[2,3-³H₂]laevulinate into rat liver cytochromes b₅ and c and cytochrome oxidase has been examined with and without protein-synthesis inhibitors. Cycloheximide promptly inhibits labelling of both haem and protein for cytochrome c in parallel fashion. Although incorporation of ¹⁴C-labelled amino acid into microsomal cytochrome b₅ is also rapidly inhibited, cycloheximide incompletely inhibits haem labelling of cytochrome b₅ and cytochrome a+a₃, and inhibition occurs only after repeated antibiotic injections. The possibility of apo-protein pools, or of haem exchange, with a rapidly renewed `free' haem pool, is considered. Consistent with this model is the observation of non-enzymic haem exchange in vitro between cytochrome b₅ and methaemoglobin. Chloramphenicol, injected intravenously over 5h, results in a 20–40% decrease in incorporation of δ-amino[2,3-³H₂]laevulinate into haem a+a₃ and haem of cytochromes b₅ and c. With the dosage schedule of chloramphenicol studied, amino acid labelling of total liver protein and of cytochrome c was not inhibited. Similarly, ferrochelatase activity was not decreased.     

Characteristics of b-type cytochromes in brain microsomes: Comparison with liver microsomes

Biochemical aspects of b-type cytochromes in swine cerebral microsomes were different from those of cytochrome b₅ in liver microsomes, as well as the difference in absorption spectra. First, the kinetic constants, K_m and V_max, in rotenone-insensitive NADH-cytochrome c reductase activity were different from those of liver microsomes, and the activity of cerebral microsomes was higher than that of liver microsomes. Second, midpoint potentials (E_m) of b-type cytochromes in cerebral microsomes were measured and compared with liver microsomal cytochrome b₅. In cerebral microsomes two components of b-type cytochromes were resolved, and showed E_m's of ?30 and +50 mV, respectively, in the presence of 2 mm KCN. On the other hand, the E_m of liver microsomal cytochrome b₅ was ?6 mV. The high-potential component of cerebral microsomal b-type cytochromes was identified as brain-b′₅ [S. Yoshida, T. Yubisui, and M. Takeshita (1983)Biochem. Int. 7, 291–298] and the low-potential component as brain-b₅. The significance of the difference between cerebral and liver microsomal b-type cytochromes was discussed.     

Quinol-cytochrome c Oxidoreductase and Cytochrome c4 Mediate Electron Transfer during Selenate Respiration in Thauera selenatis

Selenate reductase (SER) from Thauera selenatis is a periplasmic enzyme that has been classified as a type II molybdoenzyme. The enzyme comprises three subunits SerABC, where SerC is an unusual b-heme cytochrome. In the present work the spectropotentiometric characterization of the SerC component and the identification of redox partners to SER are reported. The mid-point redox potential of the b-heme was determined by optical titration (E_m + 234 ± 10 mV). A profile of periplasmic c-type cytochromes expressed in T. selenatis under selenate respiring conditions was undertaken. Two c-type cytochromes were purified (∼24 and ∼6 kDa), and the 24-kDa protein (cytc-Ts4) was shown to donate electrons to SerABC in vitro. Protein sequence of cytc-Ts4 was obtained by N-terminal sequencing and liquid chromatography-tandem mass spectrometry analysis, and based upon sequence similarities, was assigned as a member of cytochrome c₄ family. Redox potentiometry, combined with UV-visible spectroscopy, showed that cytc-Ts4 is a diheme cytochrome with a redox potential of +282 ± 10 mV, and both hemes are predicted to have His-Met ligation. To identify the membrane-bound electron donors to cytc-Ts4, growth of T. selenatis in the presence of respiratory inhibitors was monitored. The specific quinol-cytochrome c oxidoreductase (QCR) inhibitors myxothiazol and antimycin A partially inhibited selenate respiration, demonstrating that some electron flux is via the QCR. Electron transfer via a QCR and a diheme cytochrome c₄ is a novel route for a member of the DMSO reductase family of molybdoenzymes.     

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.     

Respiratory Electron Transport Systems of Aquatic Fungi. I. Leptomitus lacteus and Apodachlya punctata

The electron transport systems of 2 species of aquatic fungi, Leptomitus lacteus and A podachlya punctata, contained cytochrome a-a₃ (605 mμ), 2 b type cytochromes (564 and 557 mμ), c type cytochrome (551 mμ), and flavoprotein, but they appeared to lack cytochrome c₁. Reduced-minus-oxidized difference spectra and difference spectra in the presence of antimycin A or cyanide were used to characterize these systems. Studies with the electron microscope revealed that hyphae of Leptomitus lacteus contained numerous, conspicuous mitochondria with tubular cristae.     

Cyanide-insensitive Respiration in Plant Mitochondria

Pathways of electron transport have been studied in mitochondria isolated from hypocotyls of etiolated mung bean seedlings and skunk cabbage spadices that show cyanide-resistant respiratory activity. The residual flux through cytochrome c oxidase is shown to be small in comparison with the flux through an unidentified alternative oxidase that is known to have a high affinity for oxygen. This alternative oxidase is not a cytochrome. Skunk cabbage and mung bean mitochondria contain cytochromes a and a₃ that have absorption peaks differing slightly from those of animal preparations. A slow oxidation-reduction of cytochrome a₃-CN has been demonstrated. Cytochromes b undergo oxidation and reduction in the presence of cyanide but play no essential role in the cyanide-resistant pathway. Antimycin inhibits to an extent similar to that of cyanide; the respiratory chain bifurcates on the substrate side of the antimycin-sensitive site. Evidence is presented for the selective inhibition by thiocyanate, α, α′-dipyridyl, and 8-hydroxyquinoline of the alternative oxidase pathway, which may therefore contain a non-heme iron protein.