Effect of palmitate on energy coupling in lymphocyte mitochondria

In the presence of 0.1 micrograms/ml of oligomycin, DNP (40-60 microM) increases lymphocyte respiration 10-fold and more. Palmitate taken at the same concentration stimulates the respiration of isolated mitochondria (1-2 mg prot/ml) in the presence of 1 mg/ml of BSA and the respiration of lymphocytes (10(8) cells/ml). When BSA and EGTA are absent in mitochondria isolation media, the mitochondrial respiration does not increase after DNP or ADP addition. Lymphocyte preparations are mostly distinguished by mitochondrial morphology in the presence of the uncoupler; they differ less by changes in dis-C3-(5) fluorescence after addition of 5-10 microM DNP and only insignificantly by the stimulation of respiration by DNP and palmitate. These results may be explained by the increase in the uncoupler-induced permeability of mitochondria for K+ and by partial transformation of delta psi m into delta pH in some cells, which may increase the cell resistance to damaging influences.     

Ion transport by heart mitochondria. Retention and loss of energy coupling in aged heart mitochondria

The retention and loss of energy-coupling reactions in isolated beef heart mitochondria have been examined under anaerobic conditions using suspending media chosen to mimic the intracellular milieu. In long-term incubations at 37 °C, a loose coupling develops which can be controlled by adding serum albumin. This lesion closely resembles that produced by addition of free fatty acids which has been described in previous studies. Shorter incubation times produce an increased susceptibility to hydrogen peroxide which is characterized by elevated ATPase activity, increased permeability to monovalent cations, and increased proton ejection on transition from the anaerobic to the aerobic state. This peroxide sensitivity is prevented by chelators such as EGTA and appears to involve a time-dependent release of metal ions. Of the metabolites which are known to increase in concentration in the ischemic heart cell, Na⁺, P₁, lactate, and H⁺ all promote swelling of isolated heart mitochondria and contribute to a decline in energy coupling. The relationship of these results to the pathological deterioration of mitochondria in ischemic heart tissue is discussed.     

Control of energy transformation of mitochondria. Analysis by a quantitative model

A mathematical model of control of energy transformation in mitochondria is presented. The considered processes are: the proton translocation by the respiratory chain, the production of ATP by ATPase, the translocation of adenine nucleotides and of phosphate by their translocators, and a passive backflow of protons through the mitochondrial membrane. The mathematical equations expressing the steady-state kinetics of these processes and the relations between them were derived on the basis of current experimental data. The model predicts fairly well the values of the proton electrochemical gradient, of the ATP/ADP ratios within and outside mitochondria and of the distribution of phosphate between both compartments in different metabolic states of mitochondria. From the general agreement of model computations with experimental data, it is suggested that the electron flux through the respiratory chain is immediately controlled by the energy back-pressure of the proton electrochemical gradient, that the ATPase reaction is near equilibrium in phosphorylating mitochondria but that the adenine nucleotide exchange across the mitochondrial membrane requires some loss of energy. The latter is caused by an inhibition of the translocator by ATP from the outer side or by ADP from the inner side depending on the actual ATP/ADP in both compartments. It explains that no fixed relation exists between the rate of respiration and the phosphorylation state of extramitochondrial adenine nucleotides. The relation is modified by the concentration of phosphate and by intramitochondrial energy utilization.     

Effects of photodynamic action on energy coupling of Ca2+ uptake in liver mitochondria

In mitochondria isolated from rat liver, incubated in the presence of 6 X 10(-3) mM hematoporphyrin and irradiated with UV light at 365 nm, respiration, oxidative phosphorylation and Ca2+ uptake were measured in order to determine the respective photosensitivity of these functions. Irradiation with increasing doses produces uncoupling of oxidative phosphorylation followed by inhibition of Ca2+ uptake and finally arrest of respiration. Ca2+ uptake stimulated by the addition of ATP was also studied in mitochondria uncoupled by irradiation which were still able to concentrate Ca2+ aerobically. Anaerobic Ca2+ uptake driven by ATP hydrolysis was found to be similar in control and in irradiated mitochondria, suggesting a different photosensitivity for the ATPase as compared to the ATP-synthase activity.     

Chloride-dependent restoration of coupling by oligomycin in rat liver mitochondria.

In rat liver mitochondria suspended in KC1 medium, oligomycin interfered with the effect of uncouplers on energy conservation. It antagonized the effect of uncouplers that are weak acids (2,4-dinitrophenol etc.), but enhanced that of the lipid-penetrating cation NN-dimethyl-N'N'-dibenzylammonium. Oligomycin caused none of the above effects when Br- or NO-/3 was substituted for C1- as the major anionic species in the assay medium. The concentration of oligomycin that exerted the above-mentioned effects was lower than that necessary for the inhibition of energy transfer, but was in the range that induced C1- permeation through the cristae membrane. The possible connexion between the effect of oligomycin on C1- permeation and its interference with the action of uncouplers is discussed.     

Effect of diphtheria toxin fragment A on energy coupling in mitochondria. Studies on mouse liver mitoplasts

The effect of intact diphtheria toxin and of its fragment A on protein synthesis in mouse liver mitoplasts (digitonin-treated mitochondria) was studied. Fragment A inhibited protein synthesis in intact mitoplasts to the same extent as the uncoupler, carbonylcyanidep-trifluoromethoxyphenylhydrazone, but similar effects were not observed in lyzed mitoplasts. Intact diphtheria toxin was without effect in either case.Fragment A strongly stimulated mitochondrial ATPase activity. At concentrations which efficiently inhibited mitochondrial protein synthesis and stimulated ATPase activity, fragment A had no effect on the intramitochondrial concentration of nicotin-amide adenine dinucleotides. Moreover, it did not catalyze ADP ribosylation of mitochondrial proteins. The results indicate that the effects observed did not involve the NAD⁺-glycohydrolase activity of fragment A.[¹²⁵I]-Labelled fragment A was bound to mitoplasts to about the same extent as the labelled intact diphtheria toxin.The present results suggest that fragment A of diphtheria toxin is capable of inhibiting the energy coupling in mitoplasts, thereby inhibiting protein synthesis. The detailed mechanism of the uncoupling and its possible physiological significance remains to be elucidated     

Competitive inhibition of hexokinase isoenzymes by mercurials.

A difference in the mode of inhibition of hexokinase [EC 2.7.1.1] isoenzymes by p-chloromercuribenzenesulfonate was confirmed with respect to glucose between two Type I isoenzyme preparations purified from the kidney and spleen of rat. Essentially the same difference was observed when galactose was used as the substrate in place of glucose, as the kidney Type I isoenzyme was inhibited in a competitive manner while the spleen counterpart was inhibited in a non-competitive manner by sulfhydryl inhibitor. Both the Type I isoenzymes, however, were competitively inhibited by other mercurial sulfhydryl inhibitors, methyl and butyl mercuric chlorides. On the other hand, the Type II hexokinase isoenzymes purified from the muscle, heart, and spleen were all inhibited competitively by p-chloromercuribenzenesulfonate with respect to glucose. The mechanism of competitive inhibition of the hexokinase isoenzymes by sulfhydryl inhibitors was discussed in view of the difference in the mode of action of the mercurials with different isoenzymes.     

On the localized coupling of respiration and phosphorylation in mitochondria

This paper is an overview of the theoretical and experimental studies performed in our laboratory to answer the question whether there exist conditions where the hypothetical mechanism of the localized coupling of respiration and phosphorylation postulated by R. Williams in 1961 operates. These studies were undertaken to verify the earlier suggestion that mitochondria may exist in two structural and functional states. Correspondingly, there are two operation modes of oxidative phosphorylation, one of which corresponds to the Williams' mechanism of localized coupling and the other, to the Mitchell's mechanism of delocalized coupling. The paper considers the principle of the energy conservation of oxidative reactions in mitochondrial membranes in the form of the thermodynamic potential of hydrogen ions (Deltamusol) lacking, in part, the solvation shell. We present experimental evidence for the existence of the mechanism of localized coupling and describes the conditions favorable for its implementation. The experiments described in this paper show that the aforementioned models for proton coupling are not necessarily alternative. A conclusion is made that, depending on the particular conditions, either localized or delocalized coupling mechanisms of oxidative phosphorylation may come into operation.     

Control of choline oxidation by rat-liver mitochondria

The steady-state concentrations of choline and its reaction products in intact rat-liver mitochondria were determined under different conditions. From these measurements, it is concluded that in a sucrose medium choline dehydrogenation and betaine aldehyde dehydrogenation are the rate-limiting steps in overall choline oxidation under “State-3” or uncoupled conditions, respectively.Ageing of the mitochondria leads to changes in the mitochondrial membrane, resulting in a markedly different pattern of oxidation products. This finding explains why rotenone inhibits oxygen uptake with choline as substrate in fresh but not in aged mitochondria.