Endogenous ubiquinol prevents protein modification accompanying lipid peroxidation in beef heart submitochondrial particles

This article is a study of the relationship between lipid peroxidation and protein modification in beef heart submitochondrial particles, and the protective effect of endogenous ubiquinol (reduced coenzyme Q) against these effects. ADP-Fe^3· and ascorbate were used to initiate lipid peroxidation and protein modification, which were monitored by measuring TBARS and protein carbonylation, respectively. Endogenous ubiquinone was reduced by the addition of succinate and antimycin. The parameters investigated included extraction and reincorporation of ubiquinone, and comparison of the effect of ubiquinol with those of various antioxidant compounds and enzymes, as well as the iron chelator EDTA. Under all conditions employed there was a close correlation between lipid peroxidation and protein carbonylation, and the inhibition of these effects by endogenous ubiquinol. SDS-PAGE analysis revealed a differential effect on individual protein components and its prevention by ubiquinol. Conceivable mechanisms behind the observed oxidative modifications of membrane phospholipids and proteins and of the role of ubiquinol in preventing these effects are considered.     

Titration of the binding sites for the oligomycin-sensitivity conferring protein in beef heart submitochondrial particles

The binding parameters of the oligomycin-sensitivity conferring protein (OSCP) in inside-out particles from beef heart mitochondria have been tested by means of two assays, the oligomycin-sensitive ATP-Pi exchange, and the oligomycin-sensitive ATP hydrolysis. The total number of OSCP binding sites in A particles was equal to 220 pmol/mg particle protein. Each mole of ATPase active site was able to bind 1.1 +/- 0.5 mol OSCP with Kd 1.7 nM.     

Calorimetric studies of lipid phase transitions in native and heat-denatured membranes of beef heart submitochondrial particles

The lipids in beef heart submitochondrial particles undergo a broad reversible endothermic phase change centered at about −10°C. Following protein denaturation, a new reversible transition centered at about 20°C appears. The extracted lipids from these membranes exhibit thermal behavior that is essentially identical to the lipid transition in the intact membrane after protein denaturation. A role for this latent pool of higher-melting lipids is proposed.     

Organization and function of cytochromeb and ubiquinone in the cristae membrane of beef heart mitochondria

The arrangement and function of the redox centers of the mammalianbc ₁ complex is described on the basis of structural data derived from amino acid sequence studies and secondary structure predictions and on the basis of functional studies (i.e., EPR data, inhibitor studies, and kinetic experiments). Two ubiquinone reaction centers do exist—a QH₂ oxidation center situated at the outer, cytosolic surface of the cristae membrane (Q₀ center), and a Q reduction center (Q _i center) situated more to the inner surface of the cristae membrane. The Q₀ center is formed by theb-566 domain of cytochromeb, the FeS protein, and maybe an additional small subunit, whereas the Q _i center is formed by theb-562 domain of cytochromeb and presumably the 13.4kDa protein (QP-C). The Q binding proteins are proposed to be protein subunits of the Q reaction centers of various multiprotein complexes. The path of electron flow branches at the Q₀ center, half of the electrons flowing via the high-potential cytochrome chain to oxygen and half of the electrons cycling back into the Q pool via the cytochromeb path connecting the two Q reaction centers. During oxidation of QH₂, 2H⁺ are released to the cytosolic space and during reduction of Q, 2H⁺ are taken up from the matrix side, resulting in a net transport across the membrane of 2H⁺ per e^– flown from QH₂ to cytochromec, the H⁺ being transported across the membrane as H (H⁺ + e^–) by the mobile carrier Q. The authors correct their earlier view of cytochromeb functioning as a H⁺ pump, proposing that the redox-linkedpK changes of the acidic groups of cytochromeb are involved in the protonation/deprotonation processes taking place during the reduction and oxidation of Q. The reviewers stress that cytochromeb is in equilibrium with the Q pool via the Q _i center, but not via the Q₀ center. Their view of the mechanisms taking place at the reductase is a Q cycle linked to a Q-pool where cytochromeb is acting as an electron pump.     

Effect of the protonmotive force on ATP-linked processes and mobilization of the bound natural ATPase inhibitor in beef heart submitochondrial particles

In an attempt to determine whether the natural ATPase inhibitor (IF₁) plays a role in oxidative phosphorylation, the time course of ATP synthesis and ATP hydrolysis in inside-out submitochondrial particles from beef heart mitochondria either possessing IF₁ (Mg-ATP particles) or devoid of IF₁ (AS particles) was investigated and compared to movements of IF₁, as assessed by an isotopic assay. The responses of the above reactions to preincubation of the particles in aerobiosis with NADH or succinate were as follows: (1) The few seconds lag that preceded the steady-rate phase of ATP synthesis was shortened and even abolished both in Mg-ATP particles and AS particles. The rate of ATP synthesis in the steady state was independent of the length of the lag. (2) ATPase was slowly activated, maximal activation being obtained after a 50-min preincubation; there was no direct link between the development of the protonmotive force (maximal within 1 sec) and ATPase activation. (3) Bound IF₁ was slowly released; the release of bound IF₁ as a function of the preincubation period was parallel to the enhancement of ATPase activity; the maximal amount of IF₁ released was a small fraction of the total IF₁ bound to the particles (less than 20%). (4) The double reciprocal plots of the rates of ATP and ITP hydrolysis vs. substrate concentrations that were curvilinear in the absence of preincubation with a respiratory substrate became linear after aerobic preincubation with the substrate. The data conclusively show that only ATPase activity in submitochondrial particles is correlated with the release of IF₁, and that the total extent of IF₁ release induced by respiration is limited. On the other hand, the kinetics of ATPase in control and activated particles are consistent with the existence of two conformations of the membrane-bound F₁-ATPase, directed to ATP synthesis or ATP hydrolysis and distinguishable by their affinity for IF₁.     

Mechanistic and phenomenological features of proton pumps in the respiratory chain of mitochondria

Various direct, indirect (kinetic and thermodynamic), and combined mechanisms have been proposed to explain the conversion of redox energy into a transmembrane protonmotive force (p) by enzymatic complexes of respiratory chains. The conceptual evolution of these models is examined. The characteristics of thermodynamic coupling between redox transitions of electron carriers and scalar proton transfer in cytochromec oxidase and its possible involvement in proton pumping is discussed. Other aspects dealt with in this paper are: (i) variability of H⁺/e ^– stoichiometries, in cytochromec oxidase and cytochromec reductase and its mechanistic implications; (ii) possible models by which the reduction of dioxygen to water at the binuclear heme-copper center of protonmotive oxidases can be directly involved in proton pumping. Finally a unifying concept for proton pumping by the redox complexes of respiratory chain is presented.     

Oxidation of reduced triphosphopyridine nucleotide by submitochondrial particles from beef heart

Submitochondrial particles prepared from beef heart are capable of oxidizing TPNH, in the absence of added DPN, at a rate of approximately 50 nmoles/min × mg protein at 30°. TPNH oxidation by these particles occurs through the respiratory chain as evidenced from TPNH-induced reduction of the cytochromes and the inhibitory effects of rotenone, piericidin A, amytal, antimycin A and cyanide. The latter studies have indicated that the site of TPNH interaction with the respiratory chain is on the substrate side of the rotenone-piericidin block and close to that of DPNH.     

Some properties of mitochondria, mitoplasts and submitochondrial particles of different polarities from plant tissues

Irrespective of the starting material, i.e. washed mitochondria, purified mitochondria or mitoplast from Solanum tuberosum L., submitochondrial particles of well-defined polarities can be generated by French press treatment in low-salt medium or by sonication in high-salt medium. The first treatment will result in submitochondrial particles which are more than 80% right-side-out (right-side-out particles), the second in submitochondrial particles that are more than 80% inside-out (inside-out particles). The isoelectric point (pI = 4.0) of the inside-out particles measured by cross-partition is distinctly different from the isoelectric points of the other mitochondrial membranes which exhibit pI values between 4.5 and 4.7. The surface charge density measured by 9-aminoacridine fluorescence varies in the same order from −27 mC · m⁻² for Percoll-purified mitochondria to −51 mC · m⁻² for both right-side-out and inside-out particles. Even though the charge densities for the two surfaces of the inner membrane are similar, inside-out particles are much more negatively charged at pH 7.0, since they are 6-times larger. These results clearly demonstrate that it is possible to obtain submitochondrial particles of various polarities and sizes which in turn constitute valuable tools for the study of lateral and transverse asymmetry of the inner mitochondrial membrane.     

Interaction of aurovertin with submitochondrial particles,deficient in ATPase inhibitor

1. Binding of aurovertin to submitochondrial particles deficient in ATPase inhibitor is accompanied by an enhancement of the fluorescence by at least 100-fold.2. This change in fluorescence proceeds in three phases. The slowest change may be due to a conformational change in F₁, induced by the antibiotic bound during the rapid phases, giving rise to an increase in the quantum yield of the bound fluorochrome.3. Phosphate and ATP quench the fluorescence of the particle-aurovertin complex and ADP enhances it; the rate and extent of these changes are dependent on the availability of free Mg²⁺.4. There is at least one binding site on the submitochondrial particles, where ATP, ADP and phosphate can bind reversibly and for which these ligands compete. These interactions are dependent on the availability of free Mg²⁺ and are partly sensitive to oligomycin.5. Binding studies reveal two binding sites for aurovertin on inhibitor-free particles, one with high affinity and one with a lower affinity. Ligands such as phosphate and ATP decrease both the quantum yield and the affinity of the particles for aurovertin. They also increase the total concentration of binding sites, and affect the relative contribution of weak and strong binding sites.6. A model is presented in which changes of the aurovertin fluorescence reflect conformational changes of the ATPase induced by its ligands.     

Cation requirement for the reconstitution of oligomycin-sensitive ATPase by means of soluble F1-ATPase and F1-depleted submitochondrial particles

Bovine heart submitochondrial particles depleted of F₁ by treatment with urea (‘F₁-depleted particles’) were incubated with soluble F₁-ATPase. The binding of F₁ to the particles and the concomitant conferral of oligomycin sensitivity on the ATPase activity required the presence of cations in the incubation medium. NH⁺₄, K⁺, Rb⁺, Cs⁺, Na⁺ and Li⁺ promoted reconstitution maximally at 40–74 mM, guanidinium⁺ and Tris⁺ at 20–30 mM, and Ca²⁺ and Mg²⁺ at 3–5 mM. The particles exhibited a negative ζ-potential, as determined by microelectrophoresis, and this was neutralized by mono- and divalent cations in the same concentration range as that needed to promote F₁ binding and reconstitution of oligomycin-sensitive ATPase. It is concluded that the cations act by neutralizing negative charges on the membrane surface, mainly negatively charged phospholipids. These results are discussed in relation to earlier findings reported in the literature with F₁-depleted thylakoid membranes and with submitochondrial particles depleted of both F₁ and the coupling proteins F₆ and oligomycin sensitivity-conferring protein.     

Methionine-oxidized horse heart cytochrome c. III. Ascorbate reduction and the methionine-80-sulfur-iron linkage

The ascorbate reduction of the CT-cytochromes—two chemically generated forms of horse heart cytochrome c, F^III and F^II, with both methionines, 80 and 65, as methionine sulfoxides, no iron-sulfur linkage, and potentiometric and physiological oxidoreduction properties distinct from those of the native protein and one another (J. Pande et al., 1987)—has been investigated using a stopped-flow technique. The reaction was monitored at 550 nm, and studies were conducted in 10 mM phosphate +0.17 M NaCl buffer,pH 7.4. Both CT-cytochromes are reduced by triphasic profiles, a faster and an intermediate ascorbate-dependent reaction and a slow, ascorbate-independent process. Both CT-cytochromes contain three molecular forms in slow equilibrium, two reducing directly by reaction with ascorbate and a third through conversion to one of the reducible forms. Like the reaction of the native protein, the ascorbate dependence of both the rapid and the intermediate process is nonlinear, approaching saturation values at high concentrations. The ascorbate profiles of the pseudo-first-order reduction constants are typical of the model for the reduction reaction of the unmodified protein, binding followed by a first-order reduction reaction (Myer et al., 1980; Myer and Kumar, 1984), but with distinct kinetic parameters, the first-order reduction constants and the protein-ascorbate stability constants. It has been concluded that the functional-conformational differences between the two CT-cytochromes are not operational to any significant extent in the reduction reaction with ascorbate. The methionine-80-sulfur-iron linkage of the protein is not a crucial requirement for the ascorbate reduction of the protein. The mechanism of the reaction in the main is also insensitive to the replacement of Met-80-S from heme coordination and/or the associated conformational-oxidoreduction properties of the protein. Of the two aspects of the reaction, the efficiency of the electron-transfer reaction and the stability of the ascorbate dianion-protein complex, the former is dependent on the integrity of the structural-conformational state of the molecule.     

Electron transfer between cytochromec and cytochromec peroxidase

The reaction between cytochromec (CC) and cytochromec peroxidase (CcP) is a very attractive system for investigating the fundamental mechanism of biological electron transfer. The resting ferric state of CcP is oxidized by hydrogen peroxide to compound I (CMPI) containing an oxyferryl heme and an indolyl radical cation on Trp-191. CMPI is sequentially reduced to CMPII and then to the resting state CcP by two molecules of CC. In this review we discuss the use of a new ruthenium photoreduction technique and other rapid kinetic techniques to address the following important questions: (1) What is the initial electron acceptor in CMPI? (2) What are the true rates of electron transfer from CC to the radical cation and to the oxyferryl heme? (3) What are the binding domains and pathways for electron transfer from CC to the radical cation and the oxyferryl heme? (4) What is the mechanism for the complete reaction under physiological conditions?