Isolation of totally inverted submitochondrial particles by sonication of beef heart mitochondria

A novel procedure for isolating totally inverted preparations of submitochondrial particles by sonication of beef heart mitochondria is described. The procedure involves only differential centrifugation in 0.25 M sucrose containing 0.15 M KCl. The submitochondrial particles have 96% of their cytoplasmic face cytochromec-binding sites sequestered within the particles. Mild sonication exposes cytochromec-binding sites to the medium. The oligomycin-sensitive ATPase of sonic-derived submitochondrial particles, like that of electron transport particles, is inhibited 98% by exogenous isolated ATPase inhibitor protein. NADH oxidase activity in these particles is inhibited by oligomycin. The respiratory control index (uncoupled rate/oligomycin-inhibited rate) is approximately 3.4 and can be increased by washing the particles with medium containing bovine serum albumin.     

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.     

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.     

Respiration driven C1- uptake by submitochondrial particles

Both Mg2+ and oligomycin are required for the establishment of a membrane potential and the uptake of Cl- in submitochondrial particles prepared from rat liver. The effect of oligomycin is considered to be due to blocking of H+ conduction through exposed F0 channels of the ATPase complex whereas Mg2+ may more directly affect the anion-conducting channel.     

Oxidative phosphorylation in pea cotyledon submitochondrial particles

Mitochondria and submitochondrial particles (SMP) from pea cotyledons were shown to catalyze oxidative phosphorylation as measured by ³²Pi uptake into phosphate esters. ATP synthesis was sensitive to the electron transport inhibitor KCN, the uncoupler carbonyl cyanide m-chlorophenylhydrazone, and the coupling factor inhibitor oligomycin. Experiments with the adenine nucleotide translocator inhibitor atractyloside indicated the SMP were inside-out. Mersalyl completely inhibited ATP synthesis by SMP, and a separate experiment indicated that mersalyl has a direct effect on the ATPase complex. The kinetics of ATP synthesis indicated a high affinity for phosphate (K_m = 0.18 millimolar). ADP kinetics gave a biphasic curve with K_m values of about 4.8 and 160 micromolar. O₂ uptake and ATP synthesis had a pH maximum of 7.6 while the ratio of micromoles phosphate esterified to microatoms O₂ taken up was highest at pH 7.2. Sodium chloride inhibited both ATP synthesis and O₂ uptake but stimulated the ATPase reaction. The SMP also catalyzed a slow ATP-phosphate exchange reaction.     

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.