Mechanisms of active transport in isolated bacterial membrane vesicles. XII. Active transport by a mutant of Escherichia coli uncoupled for oxidative phosphorylation

Amino acid and β-galactoside transport activity catalyzed by whole cells and membrane vesicles prepared from an Escherichia coli mutant uncoupled for oxidative phosphorylation is comparable to the activity of analogous preparations from the parent strain. Valinomycin-induced rubidium uptake is also similar in membrane vesicles prepared from wild-type and mutant cells. The properties of the transport systems in mutant vesicles are the same as those of wild-type vesicles with respect to electron donors which stimulate transport, and with respect to inhibition by anoxia, cyanide, and 2,4-dinitrophenol.Magnesium ion markedly stimulates the ATPase activity of wild-type membrane vesicles and ethylenediaminetetraacetate markedly inhibits. However, these compounds have relatively slight effects on either the initial rate or extent of transport. Dicyclohexylcarbodiimide does not inhibit respiration-dependent transport despite inhibition of the calcium, magnesium-activated ATPase activity of wild-type vesicles.These results confirm earlier observations indicating that oxidative phosphorylation is not involved in respiration-linked active transport.     

Arabidopsis PPR40 connects abiotic stress responses to mitochondrial electron transport

Oxidative respiration produces adenosine triphosphate through the mitochondrial electron transport system controlling the energy supply of plant cells. Here we describe a mitochondrial pentatricopeptide repeat (PPR) domain protein, PPR40, which provides a signaling link between mitochondrial electron transport and regulation of stress and hormonal responses in Arabidopsis (Arabidopsis thaliana). Insertion mutations inactivating PPR40 result in semidwarf growth habit and enhanced sensitivity to salt, abscisic acid, and oxidative stress. Genetic complementation by overexpression of PPR40 complementary DNA restores the ppr40 mutant phenotype to wild type. The PPR40 protein is localized in the mitochondria and found in association with Complex III of the electron transport system. In the ppr40-1 mutant the electron transport through Complex III is strongly reduced, whereas Complex IV is functional, indicating that PPR40 is important for the ubiqinol-cytochrome c oxidoreductase activity of Complex III. Enhanced stress sensitivity of the ppr40-1 mutant is accompanied by accumulation of reactive oxygen species, enhanced lipid peroxidation, higher superoxide dismutase activity, and altered activation of several stress-responsive genes including the alternative oxidase AOX1d. These results suggest a close link between regulation of oxidative respiration and environmental adaptation in Arabidopsis.     

Role of vitamin K2 in the organization and function of Staphylococcus aureua membranes.

A mutant of Staphylococcus aureus auxotrophic for menadione (a vitamin K2 precursor) was used to study the effects of menadione deprivation on the structure and function of the cell membrane. The phospholipid composition and metabolism was essentially unaltered by menadione deprivation. Removal of this percursor caused cellular levels of the cytochromes, protoheme, vitamin K2, and several membrane-bound flavoprotein dehydrogenase activities to decrease as a function of growth dilution. The cytochromes were enzymatically reducible and maintained in the same proportions as menadione-supplemented cells. Oxidative phosphorylation, however, was reduced more than 10-fold and membrane vesicles obtained from menadione-deprived cells were unable to couple glycine transport to L-lactate oxidation. Succinic dehydrogenase and adenosine 5' triphosphate hydrolysis appeared unaffected by menadione deprivation. These data suggest that menadione deprivation in the mutant stops the synthesis of vitamin K2 and other electron transport chain components and prosthetic groups. Although individual electron transport chain members remained fully functional during menadione deprivation, the overall efficiency of the chain, measured in terms of its function in electron transport, oxidative phosphorylation, and electron transport chain-linked transport, dropped greatly. This suggests that the synthesis of vitamin K2 is modulated to the synthesis of other components of the electron transport system, and that their organization into a functional system requires a specific concentration of vitamin K2 with respect to total membrane lipid.     

Succinate Transport in Escherichia coli Mutants Defective in Succinate Metabolism

To investigate the operation of a succinate transport system in Escherichia coli, mutants defective in succinate metabolism were isolated. Although the metabolic blocks in the mutant cells were not complete, the succinate transport assays became possible.

Pyruvate, lactate or many other carbon sources stimulated succinate uptake, and the uptake was strongly inhibited by some electron transport inhibitors, uncouplers of oxidative phosphorylation and sulfhydryl reagents. The mutant strains accumulated succinate into the cells against a concentration gradient when suitable energy sources were supplied.

Presence of glucose in the medium strongly repressed the formation of the succinate transport system. The optimum pH for the succinate uptake was between 7.8 and 8.0.     

Alterations of the Respiratory System of Neurospora crassa by the mi-1 Mutation

The respiratory mechanism of the cytochrome-defective mi-1 mutant of Neurospora crassa was partially characterized and compared with that of the wild type. Both systems of electron transport were linked to oxidative phosphorylation and showed similar characteristics with respect to substrates and components. The system operating in the cytochrome-deficient mi-1 mutant showed no characteristic alpha absorption bands of cytochromes a or b and was very unstable in vitro. The possibility that this system may be an altered form of the normal cytochrome electron transport chain which occurs in the wild type is discussed.     

Cytoplasmically inherited respiratory deficiency of a mouse fibroblast line which is resistant to rutamycin.

Mouse fibroblasts resistant to the drug rutamycin were isolated and found also to be respiratory deficient. These cells produce large amounts of lactic acid, and oxygen consumption data indicate that the first complex of the electron transport chain, NADH-coenzyme Q reductase, is defective. Levels of rotenone-sensitive NADH-cytochrome c reductase and pyruvate decarboxylase of the pyruvate dehydrogenase complex are markedly depressed in the mutant cells. Other components of the electron transport chain appear to be fully functional. The mutant cells were enucleated and fused with another cell line, and the resulting cybrid demonstrated a similar pattern of respiratory deficiency as did the original mutant. These results indicate that this defect in respiration is a cytoplasmically inherited characteristic in this cell line.     

Electron transport and oxidative stress in Zymomonas mobilis respiratory mutants

The ethanol-producing bacterium Zymomonas mobilis is of great interest from a bioenergetic perspective because, although it has a very high respiratory capacity, the respiratory system does not appear to be primarily required for energy conservation. To investigate the regulation of respiratory genes and function of electron transport branches in Z. mobilis, several mutants of the common wild-type strain Zm6 (ATCC 29191) were constructed and analyzed. Mutant strains with a chloramphenicol-resistance determinant inserted in the genes encoding the cytochrome b subunit of the bc (1) complex (Zm6-cytB), subunit II of the cytochrome bd terminal oxidase (Zm6-cydB), and in the catalase gene (Zm6-kat) were constructed. The cytB and cydB mutants had low respiration capacity when cultivated anaerobically. Zm6-cydB lacked the cytochrome d absorbance at 630 nm, while Zm6-cytB had very low spectral signals of all cytochromes and low catalase activity. However, under aerobic growth conditions, the respiration capacity of the mutant cells was comparable to that of the parent strain. The catalase mutation did not affect aerobic growth, but rendered cells sensitive to hydrogen peroxide. Cytochrome c peroxidase activity could not be detected. An upregulation of several thiol-dependent oxidative stress-protective systems was observed in an aerobically growing ndh mutant deficient in type II NADH dehydrogenase (Zm6-ndh). It is concluded that the electron transport chain in Z. mobilis contains at least two electron pathways to oxygen and that one of its functions might be to prevent endogenous oxidative stress.     

Antimycin-insensitive mutants of Candida utilis II. The effects of antimycin on Cytochrome b.

1. Cytochrome b-562 is more reduced in submitochondrial particles of mutant 28 during the aerobic steady-state respiration with succinate than in particles of the wild type. When anaerobiosis is reached, the reduction of cytochrome b is preceded by a rapid reoxidation in the mutnat. A similar reoxidation is observed in the wild type in the present of low concentrations of antimycin. 2. In contrast to the wild type, inhibition of electron transport in the mutant has a much higher antimycin titre than effects on cytochromes b (viz., aerobic steady-state reduction; reduction in the presence of substrate, cyanide and oxygen; the 'red shift' and lowering of E'-o of cytochrome b-562). Moreover, the titration curve of electron transport is hyperbolic whereas the curves for the reduction are sigmoidal. The conclusion is, that in both mutant and wild type, the actions of antimycin on electron transport and cytochromes b are separable. 3. The red shift in the mutant is more extensive than in the wild type. 4. Cytochrome b-558 and cytochrome b-566 (that absorbs in mutant and wild type at 564.5 nm) do not respond simultaneously to addition of antimycin, indicating that they are two separate cytochromes. 5. The difference between the effect of antimycin on electron transport and cytochromes b reduction is also found in intact cells of the mutant. 6. A model is suggested for the wild-type respiratory chain in which (i) the cytochromes b lie, in an uncoupled system, out of the main electron-transfer chain, (ii) antimycin induces a conformation change in QH-2-cytochrome c reductase resulting in effects on cytochrome b and inhibition of electron transport, (iii) a second antimycin-binding site with low affinity to the antibiotic is present, capable of inhibiting electron transport.     

Impairment of glutamate transport and increased vulnerability to oxidative stress in neuroblastoma SH-SY5Y cells expressing a Cu,Zn superoxide dismutase typical of familial amyotrophic lateral sclerosis

Human neuroblastoma SH-SY5Y cells transfected with either familial amyotrophic lateral sclerosis-typical G93A mutant or wild-type copper/zinc superoxide dismutase were compared to untransfected cells in term of glutamate transport. Vmax of glutamate uptake was reduced in mutant cells, with no change in Km. No difference in EAAT1, EAAT2 and EAAT3 glutamate transporter mRNAs and immunoreactive proteins was found, suggesting that one or more transporters are functionally inactivated, possibly due to increased oxidative stress induced by the G93A mutation. Mutant cells showed a marked sensitivity to oxidants, resulting in a more pronounced reduction of glutamate uptake. Short-term antioxidant treatment did not reverse the impairment of glutamate uptake in G93A cells. Interestlingly, N-acetylcysteine was partially effective in preventing glutamate uptake reduction due to exogenous oxidative insults. Since the inhibition of the EAAT2 transporter subtype had no effect on glutamate re-uptake in this model, our study suggests an impaired function of the EAAT1/3 transporter subtypes, possibly due to oxidative inactivation, in the presence of mutant copper/zinc superoxide dismutase. Therefore, this model might prove to be a valuable tool to study the effects of mutant copper/zinc superoxide dismutase associated with amyotrophic lateral sclerosis on glutamate transport in neuronal cells, without the specific contribution of glial cells. These findings might lead to the identification of new therapeutic strategies aimed at preventing the damage associated with ALS.     

Oxidative phosphorylation in a yeast mutant lacking α-ketoglutarate dehydrogenase activity

The effect of α-ketoglutarate deficiency on the oxidative phosphorylation in yeast mitochondria was studied. By determining the properties of electron transport and energy transduction systems of mutant mitochondria it was found that the lack of α-ketoglutarate dehydrogenase activity in mitochondria does not result in any functional defect in the oxidative phosphorylation system.     

Gene mutation eliminating antimycin A-tolerant electron transport in Ustilago maydis

A class of mutants of Ustilago maydis selected on a fungitoxic oxathiin lack of antimycin A-tolerant respiratory system which is present in wild-type cells. This system provides, directly or indirectly, for considerable resistance to antimycin A because growth of mutant cells lacking the system is much more sensitive to the antibiotic than that of the wild type. Antimycin A-sensitive O(2) uptake and growth is found in half of the progeny from crosses of mutant to wild type. All antimycin A-sensitive segregants are somewhat more resistant to oxathiins than the antimycin A-resistant segregants. The respiration of the mutant is strongly inhibited by cyanide and azide at concentrations which stimulate respiration of the wild type. Respiration of both mutant and wild type is about equally inhibited by rotenone. It appears that the mutation alters some component of the respiratory system located between the rotenone inhibition site and the antimycin A inhibition site that permits shift of electron transport to an alternate terminal oxidase when the normal electron transport pathway is blocked.     

Antimycin-insensitive mutants of Candida utilis. II. The effects of antimycin on cytochrome b

1. Cytochrome b-562 is more reduced in submitochondrial particles of mutant 28 during the aerobic steady-state respiration with succinate than in particles of the wild type. When anaerobiosis is reached, the reduction of cytochrome b is preceded by a rapid reoxidation in the mutant. A similar reoxidation is observed in the wild type in the presence of low concentrations of antimycin.

2. In contrast to the wild type, inhibition of electron transport in the mutant has a much higher antimycin titre than effects on cytochromes b (viz., aerobic steadystate reduction; reduction in the presence of substrate, cyanide and oxygen; the ‘red shift’ and lowering of E′₀ of cytochrome b-562). Moreover, the titration curve of electron transport is hyperbolic whereas the curves for the reduction are sigmoidal. The conclusion is, that in both mutant and wild type, the actions of antimycin on electron transport and cytochromes b are separable.

3. The red shift in the mutant is more extensive than in the wild type.

4. Cytochrome b-558 and cytochrome b-566 (that absorbs in mutant and wild type at 564.5 nm) do not respond simultaneously to addition of antimycin, indicating that they are two separate cytochromes.

5. The difference between the effect of antimycin on electron transport and cytochromes b reduction is also found in intact cells of the mutant.

6. A model is suggested for the wild-type respiratory chain in which (i) the cytochromes b lie, in an uncoupled system, out of the main electron-transfer chain, (ii) antimycin induces a conformation change in QH₂-cytochrome c reductase resulting in effects on cytochrome b and inhibition of electron transport, (iii) a second antimycinbinding site with low affinity to the antibiotic is present, capable of inhibiting electron transport.     

Higher plant-like fluorescence induction and thermoluminescence characteristics in cyanobacterium, Spirulina mutant defective in PQH2 oxidation by cytb6/f complex

Characterization of the photosynthetic electron transport in a mutant of Spirulina platensis, generated by chemical mutagenesis, demonstrated that the electron transfer from the plastoquinone (PQ) to cytochrome b6/f was slowed. Thermoluminescence (TL) measurements suggested the presence of reversed energy flow via PQ, which resulted in an emergence of the plant-like after-glow TL band at 45 degrees C that could be enhanced by the transthylakoidal pH gradient and could be eliminated by an uncoupler, FCCP. The localization of the changes in the electron transport of the mutant cells measured by various methods revealed that the re-oxidation of the PQ pool is hampered in the mutant compared to the wild-type cells. The reduction in energy migration was localized between PQ and PS I reaction centers.     

Inactivation of Aspartic Transcarbamylase in Sporulating Bacillus subtilis: Demonstration of a Requirement for Metabolic Energy

The aspartic transcarbamylase (ATCase) activity of Bacillus subtilis cells disappears rapidly from stationary-phase cells prior to sporulation. ATCase activity does not appear in the culture fluid during the stationary phase; hence the enzyme appears to be inactivated in the cells. The enzyme is inactivated normally in two different mutants lacking proteases; the activity is very stable in crude extracts of cells or in the culture fluid. These results suggest that ATCase is not inactivated by the general proteolysis that occurs in sporulating bacteria. The inactivation of ATCase can be completely inhibited after it has begun by oxygen starvation or addition of fluoroacetate. Inhibitors of oxidative phosphorylation and electron transport also interrupt the inactivation of ATCase. The inactivation of ATCase is very slow in two mutant strains that are deficient in enzymes of tricarboxylic acid cycle. Addition of gluconate to stationary cultures of the mutant strains, which is known to restore depleted adenosine 5'-triphosphate pools in these bacteria, also restores inactivation of ATCase. These experiments support the conclusion that the generation of metabolic energy is necessary for the inactivation of ATCase in stationary cells. ATCase activity is stable in growing cells in which ATCase synthesis is repressed by addition of uracil; the enzyme is inactivated normally, however, when such cells cease growing.     

Quinones in long-lived clk-1 mutants of Caenorhabditis elegans

Ubiquinone (UQ) (coenzyme Q) is a lipophilic redox-active molecule that functions as an electron carrier in the mitochondrial electron transport chain. Electron transfer via UQ involves the formation of semiubiquinone radicals, which causes the generation of superoxide radicals upon reaction with oxygen. In the reduced form, UQ functions as a lipid-soluble antioxidant, and protects cells from lipid peroxidation. Thus, UQ is also important as a lipophilic regulator of oxidative stress. Recently, a study on long-lived clk-1 mutants of Caenorhabditis elegans demonstrated that biosynthesis of UQ is dramatically altered in mutant mitochondria. Demethoxy ubiquinone (DMQ), that accumulates in clk-1 mutants in place of UQ, may contribute to the extension of life span. Here we elucidate the possible mechanisms of life span extension in clk-1 mutants, with particular emphasis on the electrochemical property of DMQ. Recent findings on the biochemical function of CLK-1 are also discussed.     

Inactivation of the extrinsic subunit of photosystem II, PsbU, in Synechococcus PCC 7942 results in elevated resistance to oxidative stress

PsbU is a subunit of the extrinsic complex attached to the core of photosystem II. A PsbU-mutant of Synechococcus PCC 7942 was isolated based on its elevated resistance to externally applied oxidative stress. PsbU-mutant exhibits fast rates of degradation of the photosystem II core protein, D1, under sub-saturating as well as high-light conditions. While forward electron transfer is not affected, back electron flow is severely impaired in the mutant. We suggest that impairment of psbU results in production of reactive-oxygen-species, which trigger antioxidative mechanisms even under standard growth conditions. Accordingly, when challenged with external oxidative stress, these cells are more resistant than wild type cells.     

Mitochondrial Respiratory Electron Carriers Are Involved in Oxidative Stress during Heat Stress in Saccharomyces cerevisiae

In the present study we sought to determine the source of heat-induced oxidative stress. We investigated the involvement of mitochondrial respiratory electron transport in post-diauxic-phase cells under conditions of lethal heat shock. Petite cells were thermosensitive, had increased nuclear mutation frequencies, and experienced elevated levels of oxidation of an intracellular probe following exposure to a temperature of 50 degrees C. Cells with a deletion in COQ7 leading to a deficiency in coenzyme Q had a much more severe thermosensitivity phenotype for these oxidative endpoints following heat stress compared to that of petite cells. In contrast, deletion of the external NADH dehydrogenases NDE1 and NDE2, which feed electrons from NADH into the electron transport chain, abrogated the levels of heat-induced intracellular fluorescence and nuclear mutation frequency. Mitochondria isolated from COQ7-deficient cells secreted more than 30 times as much H(2)O(2) at 42 as at 30 degrees C, while mitochondria isolated from cells simultaneously deficient in NDE1 and NDE2 secreted no H(2)O(2). We conclude that heat stress causes nuclear mutations via oxidative stress originating from the respiratory electron transport chains of mitochondria.     

Deletion of Von Willebrand A Domain Containing Protein (VWA8) raises activity of mitochondrial electron transport chain complexes in hepatocytes

VWA8 (Von Willebrand A Domain Containing Protein 8) is a AAA+ ATPase that is localized to the mitochondrial matrix and is widely expressed in highly energetic tissues. Originally found to be higher in abundance in livers of mice fed a high fat diet, deletion of the VWA8 gene in differentiated mouse AML12 hepatocytes unexpectedly produced a phenotype of higher mitochondrial and nonmitochondrial oxidative metabolism, higher ROS (reactive oxygen species) production mainly from NADPH oxidases, and increased HNF4a expression. The purposes of this study were first, to determine whether higher mitochondrial oxidative capacity in VWA8 null hepatocytes is the product of higher capacity in all aspects of the electron transport chain and oxidative phosphorylation, and second, the density of cristae in mitochondria and mitochondrial content was measured to determine if higher mitochondrial oxidative capacity is accompanied by greater cristae area and mitochondrial abundance. Electron transport chain complexes I, II, III, and IV activities all were higher in hepatocytes in which the VWA8 gene had been deleted using CRISPR/Cas9. A comparison of abundance of proteins in electron transport chain complexes I, III and ATP synthase previously determined using an unbiased proteomics approach in hepatocytes in which VWA8 had been deleted showed agreement with the activity assays. Mitochondrial cristae, the site where electron transport chain complexes are located, were quantified using electron microscopy and stereology. Cristae density, per mitochondrial area, was almost two-fold higher in the VWA8 null cells (P < 0.01), and mitochondrial area was two-fold higher in the VWA8 null cells (P < 0.05). The results of this study allow us to conclude that despite sustained, higher ROS production in VWA8 null cells, a global mitochondrial compensatory response was maintained, resulting in overall higher mitochondrial oxidative capacity.     

Reconstitution of oxidative phosphorylation and the adenosine triphosphate-dependent transhydrogenase activity by a combination of membrane fractions from uncA? and uncB? mutant strains of Escherichia coli K12

1. Membrane preparations from both uncA(-) and uncB(-) mutant strains of Escherichia coli K12, in which electron transport is uncoupled from phosphorylation, were fractionated by washing with a low-ionic-strength buffer. The fractionation gave a ;5mm-Tris wash' and a ;membrane residue' from each strain. This technique, applied to membranes from normal cells, separates the Mg(2+),Ca(2+)-stimulated adenosine triphosphatase activity from the membrane-bound electron-transport chain and the non-energy-linked transhydrogenase activity. 2. Reconstitution of both oxidative phosphorylation and the ATP-dependent transhydrogenase activity was obtained by a combination of the ;membrane residue' from strain AN249 (uncA(-)) with the ;5mm-Tris wash' from strain AN283 (uncB(-)). 3. Valinomycin plus NH(4) (+) inhibited oxidative phosphorylation both in membranes from a normal strain of E. coli and in the reconstituted membrane system derived from the mutant strains. 4. The electron-transport-dependent transhydrogenase activity was located in the membrane residue and was de-repressed in both the mutant strains. 5. The spatial and functional relationships between the proteins specified by the uncA and uncB genes and the transhydrogenase protein are discussed.