ATP- and phosphate-induced configurational changes of submitochondrial particles

Light scattering was employed to monitor configurational changes of submitochondrial particles. Such changes were induced by ATP but not by analogues of this nucleotide. Mg²⁺ in an equimolar concentration to ATP enhanced the effect of the nucleotide. The ATP-induced changes were inhibited by oligomycin and uncouplers. Atractyloside was effective as an inhibitor only when loaded within the particles. The ATP-induced changes were decreased by phosphate. The effect of phosphate was partially inhibited by mersalyl. Sodium phosphate and ammonium phosphate were more effective than potassium phosphate.

The observed changes in light scattering were due to (a) events involved in energization and de-energization of the membrane, and (b) events concerning transport over the particulate membrane.

The changes were specific for adenine nucleotides and phosphate.     

Respiratory changes induced by guanidines and cations in submitochondrial particles

Alkylguanidines inhibit the respiration of submitochondrial particles oxidizing NADH, while hydrophilic guanidines stimulate the rate of oxygen uptake. Regardless of the effect that a guanidine exerts on respiration, all guanidines tested inhibited the stimulatory action of K⁺ on the oxygen uptake of submitochondrial particles. It was found also that octylguanidine modified the Arrhenius plot of respiration of the particles. These findings suggest that alkylguanidines exert their action through the interaction of the alkyl chain with a hydrophobic region in the membrane and also through the interaction of the guanidine moiety with a certain locus in the membrane.The results of studies made on the effect of a wide variety of cations on the respiration of submitochondrial particles may be explained on the assumption that in the inner membrane of the mitochondria exists a negatively charged surface or region with which cations can interact. These results also suggest that the stimulation or inhibition of respiration induced by a given cation depends on the ease with which it can move within this hypothetical negative region.     

Variable proton conductance of submitochondrial particles.

The relationship between the rate of substrate oxidation and the protonmotive force (electrochemical proton gradient) generated by bovine heart submitochondrial particles has been examined. Unexpectedly, oxidation of succinate generated a higher protonmotive force than the oxidation of NADH, although the rate of proton translocation across the membrane was inferred to be considerably lower with succinate as substrate. The data suggest that the flow of electrons through site 1 of the respiratory chain may increase the conductance of the mitochondrial membrane for protons. Upon reduction of the rate of succinate oxidation by titration with malonate, the protonmotive force remained essentially constant until the extent of inhibition was greater than 75%. The general conclusion from this work is that a constant passive membrane conductance for protons cannot be assumed.     

Energy coupling in lysolecithin-treated submitochondrial particles.

Mitochondria isolated from mung bean hypocotyls, possessing a significant level of cyanide and antimycin A — resistant respiration $\text{via}$ an alternate pathway, were assayed for hydrogen peroxide production by yeast cytochrome $\text{c}$ peroxidase compound II formation. Rates of antimycin A — insensitive hydrogen peroxide production of 0.7–3 nmol/mg/min were observed which were too low to account for the observed oxygen consumption $\text{via}$ the alternate pathway. However, further investigations revealed the presence of significant levels of catalase, peroxidase and hydrogen donor to peroxidase, even in gradient purified mitochondria and these could easily utilize any hydrogen peroxide produced by the alternate pathway. Similar experiments performed upon submitochondrial particles demonstrated a rate of H₂O₂ production which could easily account for the net electron flux through the alternate pathway. From these results, we postulate that the alternate pathway reduces oxygen only partially to hydrogen peroxide, and that the peroxidase and catalase activities of the mitochondria prevent its accumulation.     

Mechanism of acridine uptake by submitochondrial particles.

Acridines were compared regarding their ability to be taken up by submitochondrial particles under energized conditions. pH dependence of uptake was explored, and it was found that acridines fell into three classes independently of their pK_a value: acridines which are not taken up, acridines taken up at all pH values, and acridines taken up only at alkaline pH. Partition measurements between H₂O and chloroform phase showed a similar pattern, and affinity for the organic phase seemed to parallel uptake. Acridines which are taken up by submitochondrial particles at acidic pH under energized conditions despite a high pK_a value could also be extracted into chloroform at acidic pH, thus implying that the dye's uncharged form has a high affinity for the organic phase. By supplementing the aqueous medium with lipophilic anions, the dye may also be extracted in its charged form. The data support a mechanism for acridine uptake in which diffusion of the uncharged form across the membranes is an obligatory step. Some previously reported inhibitory anion effects on uptake may be explained by ion pair formation, which allows release of the accumulated charged form.     

Carnitine transport in submitochondrial particles and reconstituted proteoliposomes.

Influx and efflux measurements of carnitine with submitochondrial particles lead to the conclusion that carnitine can cross the inner mitochondrial membrane by either facilitated diffusion or more rapidly by a carnitine-carnitine exchange. Both, the facilitated diffusion and the exchange are inhibited by N-ethylmaleimide or mersalyl at low concentrations. Reconstituted particles prepared from liposomes and either submitochondrial particles or an octyl β-glucoside-solubilized preparation were active in catalyzing carnitine-carnitine exchange.     

Tightly-bound ATP and ADP in reconstituted submitochondrial particles.

Soluble beef-heart mitochondrial ATPase (F₁) which was depleted of tightly bound nucleotide was reconstituted with depleted submitochondrial particles and oligomycin-sensitivity conferring protein. A correlation was noted between the recovery of energy-transduction capability and the reloading of tightly bound nucleotide. Reconstituted membrane-bound F₁ contained both ATP and ADP tightly bound; the total (ATP and ADP) was tentatively calculated to be around 3.6 moles per mole membrane-bound F₁.     

Adriamycin stimulated superoxide formation in submitochondrial particles.

Adriamycin (doxorubicin), an anticancer agent, stimulated the formation of superoxide in submitochondrial particles isolated from bovine heart. Superoxide formation was detected by oxygen uptake, by the cooxidation of epinephrine to adrenochrome and by the reduction of acetylated cytochrome c. These processes were sensitive to superoxide dismutase (SOD). Rotenone-insensitive oxidation of NADH by the mitochondrial respiratory chain in the presence of oxygen caused the formation of approx 4 nmol of superoxide per min/mg of protein. Adriamycin at a concentration of 400 micron stimulated the rate of superoxide formation 6-fold to 25 nmol.min-1.mg-1, but this was not a maximum rate. Approximately 50 micron adriamycin was estimated to be sufficient for obtaining one-half maximal stimulation. Hydrogen peroxide accumulated as a final reaction product. Measurements of the relative catalase activity of blood-free tissues of rabbits and rats indicated that heart contained 2 to 4% of the catalase activity of liver or kidney. An enhanced production of superoxide and hydrogen peroxide and the relatively low catalase content of heart tissue may be factors in the cardiotoxicity induced by adriamycin chemotherapy if a similar reaction occurs in vivo.