无机磷影响叠氮钠对ATP合成酶合成活性的抑制

利用ADP和放射性磷直接合成ATP的方法,研究了无机磷(P_i)和叠氮钠对猪心线粒体ATP合成酶（F₁F_O-ATPase）ATP合成活性的影响.结果发现无机磷除作为合成ATP的底物参与F₁F_O-ATPase的合成反应外,还对F₁F_O-ATPase的合成活性呈现抑制作用,在1 mmol/L ADP存在时,随着P_i浓度由0.01～10 mmol/L增加,抑制合成作用越来越强.与叠氮钠在低浓度时(小于1 mmol/L)只抑制ATP水解,不影响ATP合成的观点不同.实验结果显示0.1 mmol/L叠氮钠表观激活F₁F_O-ATPase的ATP合成活性,且激活程度与反应体系中所加P_i的浓度呈负相关.当固定P_i浓度（0.1 mmol/L）后,随着叠氮钠浓度的增加表观激活程度也在变化,叠氮钠与磷浓度相等时表观激活程度最大,直至叠氮钠浓度接近0.5 mmol/L时,开始呈现表观抑制现象,叠氮钠浓度高于1 mmol/L之后,就出现解偶联现象.     

Possible mechanism of ATP formation in energy-transforming biological membranes

An "elementary act" of ATP formation from ADP and Pi in energy-transducing organels (mitochondria, chloroplasts and chromatophores) can be realized without closed membrane vesicles, pieces of membranes and F0-component of H+ATPase. The "elementary act" is initiated by a rather fast deprotonation of several acid groups of the coupling factor F1 (or CF1), this process leads to structurally non-equilibrium state of the enzyme due to the appearance of "additional" negative charges in unchanged protein globula. The endergonic step of ATP synthesis, i. e. release of tightly-bound ATP into the aqueous medium, occurs during conformational relaxation of the non-equilibrium state of H+ATPase. Closed membrane vesicles are necessary for a cyclic return of the enzyme to the initial state with protonized functional groups, this provides multiple synthesis of ATP under the steady state and quasi-stationary conditions. The energetical aspects and details of possible schemes of ATP synthesis initiated by artificial electrochemical gradient of protons, as well as ATP formation during oxidative and photophosphorylation are discussed here.     

Inhibitors of the slow stage of proton transfer in the link connecting respiration with mitochondrial phosphorylation]

Electrophilic agents--derivatives of carbonic acids--are found to inhibit respiration, ATP synthesis and reverse electrone transport in intact mitochondria. The inhibition of respiration and ATPase was observed in intact mitochondria at 3 and 3u states (by Chance). Inhibitors concentrations, which caused 50% inhibition, were approximately the same. Sharp decrease of the effect of electrophilic inhibitors on respiration and ATPase activity in mitochondria and submitochondrial particles with substantially impaired coupling system was observed. The following conclusions are drawn on the basis of the data obtained: 1) electrophilic inhibitor attack the coupling site of respiration and ATP synthesis in mitochondria; 2) the reaction of the proton transport from the respiration proton pump to ATP synthetase is one of the slowest steps of the process of ATP-synthesis in mitochondria. A scheme of working the coupling system is suggested which includes the step of proton lateral diffusion.     

Brown adipose tissue mitochondria: modulation by GDP and fatty acids depends on the respiratory substrates

The UCP1 [first UCP (uncoupling protein)] that is found in the mitochondria of brown adipocytes [BAT (brown adipose tissue)] regulates the heat production, a process linked to non-shivering thermogenesis. The activity of UCP1 is modulated by GDP and fatty acids. In this report, we demonstrate that respiration and heat released by BAT mitochondria vary depending on the respiratory substrate utilized and the coupling state of the mitochondria. It has already been established that, in the presence of pyruvate/malate, BAT mitochondria are coupled by faf-BSA (fatty-acid-free BSA) and GDP, leading to an increase in ATP synthesis and mitochondrial membrane potential along with simultaneous decreases in both the rates of respiration and heat production. Oleate restores the uncoupled state, inhibiting ATP synthesis and increasing the rates of both respiration and heat production. We now show that in the presence of succinate: (i) the rates of uncoupled mitochondria respiration and heat production are five times slower than in the presence of pyruvate/malate; (ii) faf-BSA and GDP accelerate heat and respiration as a result and, in coupled mitochondria, these two rates are accelerated compared with pyruvate/malate; (iii) in spite of the differences in respiration and heat production noted with the two substrates, the membrane potential and the ATP synthesized were the same; and (iv) oleate promoted a decrease in heat production and respiration in coupled mitochondria, an effect different from that observed using pyruvate/malate. These effects are not related to the production of ROS (reactive oxygen species). We suggest that succinate could stimulate a new route to heat production in BAT mitochondria.     

Effect of catecholamine depletion on oxidative energy metabolism in rat liver, brain and heart mitochondria; use of reserpine

Regulation of mitochondrial functions in vivo by catecholamines was examined indirectly by depleting the catecholamines stores by reserpine treatments of the experimental animals. Reserpine treatment resulted in decreased respiratory activity in liver and brain mitochondria with the two NAD+-linked substrates: glutamate and pyruvate + malate with succinate ATP synthesis rate decreased in liver mitochondria only. With ascorbate + TMPD system, the ADP/O ratio and ADP phosphorylation rate decreased in brain mitochondria. For the heart mitochondria, state 3 respiration rates decreased for all substrates. In the liver mitochondria basal ATPase activity decreased by 51%, but in the presence of Mg2+ and/or DNP increased significantly. In the brain and heart mitochondria ATPase activities were unchanged. The energy of activation in high temperature range increased liver mitochondrial ATPase while in brain mitochondria reserpine treatment resulted in abolishment in phase transition. Total phospholipid (TPL) content of the brain mitochondria increased by 22%. For the heart mitochondria TPL content decreased by 19% and CHL content decreased by 34%. Tissue specific differential effects were observed for the mitochondrial phospholipid composition. Liver mitochondrial membranes were more fluidized in the reserpine-treated group. The epinephrine and norepinephrine contents in the adrenals decreased by 68 and 77% after reserpine treatment.     

ATPase complex and oxidative phosphorylation in chloramphenicol-induced megamitochondria from mouse liver.

1. Functional properties of the ATPase complex are investigated in megamitochondria isolated from livers of weanling mice fed a diet containing 2% chloramphenicol, as an inhibitor of mitochondrial protein synthesis. 2. Whereas the specific activity of ATPase remains unchanged in chloramphenicol-induced megamitochondria, about 40% of the enyzme activity is resistant to inhibition by oligomycin, triethyltin or venturicidin. It is concluded that the ATPase complex lacks one or more components whose synthesis or accumulation is dependent on mitochondrial translation. The inhibitor-resistant ATPase portion appears tightly bound to the mitochondrial membrane. 3. Respiratory chain phosphorylation is tightly coupled in isolated megamitochondria. ATP synthesis and ATP-Pi exchange are diminished by 40%, as compared to control mitochondria, but both processes are sensitive to oligomycin, triethyltin or venturicidin. 4. The decrease in ATP synthesis and ATP-Pi exchange in megamitochondria correlates quite well with the emergence of inhibitor-resistant ATPase. 5. The following electron transport activities in the megmitochondria are reduced: NADH-cytochrome c reductase, by 60%, cytochrome oxidase, by 80%; the amount of antimycin required to gain complete inhibition of the bc1-segment is diminished by more than 50%. On the other hand succinate dehydrogenase activity is increased by 50%. 6. Chloramphenicol-induced megamitochondria appear to be a useful system for studying the role of mitochondrial translation in the assembly of mammalian mitochondria.     

Control of adenine nucleotide metabolism in hepatic mitochondria from rats with ethanol-induced fatty liver

Male rats developed fatty liver after being fed on an ethanol-containing diet for 31 days. Liver mitochondria from these animals catalysed ATP synthesis at a slower rate when compared with mitochondria from pair-fed control rats (control mitochondria), and demonstrated lowered respiratory control with succinate as substrate, owing to a decrease in the State-3 respiratory rate. Respiration in the presence of uncoupler was comparable in mitochondria from both groups of rats. Translocation of both ATP and ADP was decreased in mitochondria from ethanol-fed rats, with ADP uptake being lowered more dramatically by ethanol feeding. Parameters influencing adenine nucleotide translocation were investigated in mitochondria from ethanol-fed rats. Experiments performed suggested that lowered adenine nucleotide translocation in these mitochondria is not the result of inhibition of the translocase by either long-chain acyl-CoA derivatives or unesterified fatty acids. Analysis of endogenous adenine nucleotides in these mitochondria revealed lowered ATP concentrations, but no decrease in total adenine nucleotides. In experiments where the endogenous ATP in these mitochondria was shifted to higher concentrations by incubation with oxidizable substrates or defatted bovine serum albumin, the rate of ADP translocation was increased, with a linear correlation being observed between endogenous ATP concentrations and the rate of ADP translocation. The depressed ATP concentration in mitochondria from ethanol-fed rats suggests that the ATP synthetase complex is replenishing endogenous ATP at a slower rate. The lowered ATPase activity of the ATP synthetase observed in submitochondrial particles from ethanol-fed animals suggests a decrease in the function of the synthetase complex. A decrease in the rate of ATP synthesis in mitochondria from ethanol-fed rats is sufficient to explain the decreased ADP translocation and State-3 respiration.     

The effect of respiration substrates on the ATPase activity of uncoupled mitochondria

Mg-dependent ATPase activity in aging uncoupled mitochondria is 30% reduced by 2 mM of succinate. The results show that redox state of mitochondria electron-transport chain affects the activity and apparently modifies the structure of the enzyme performing ATP synthesis and hydrolysis.     

The insensitivity to uncouplers of testis mitochondrial ATPase

Albumin-free testis mitochondrial ATPase activity failed to be stimulated by either 2,4-dinitrophenol (DNP) or carbonyl cyanide rho-trifluoromethoxyphenylhydrazone (FCCP). DNP scarcely enhanced the state 4 respiration and mitochondria proved to be poorly coupled. When 1% bovine serum albumin was added to the isolation medium, DNP or FCCP stimulated ATPase nearly twofold and the dose-response curves for the uncouplers on the QO2 reached a plateau at five- to sixfold. The DNP coupling index (q) also showed a 30-40% improvement. A dose-response curve for oligomycin on the rate of [gamma-32P]ATP synthesis showed a stimulation of ATP synthase activity by 10-100 ng inhibitor/mg protein, suggesting a possible blockade of "open" F0 channels. In the albumin preparation oligomycin inhibited ATP synthesis in the range 10-100 ng/mg protein. Since testis ATPase is known to be loosely bound to the membrane, an effect of albumin, improving tightness in the interaction of the F1 and the F0 sectors of the ATPase, is suggested.     

Deficiency of uncoupler-stimulated adenosine triphosphatase activity in yeast mitochondria

Oligomycin-sensitive ATPase activity was studied in isolated yeast mitochondria. The protonophore CCCP, at a concentration which completely inhibited ATP synthesis, induced only a low rate of hydrolysis of externally added ATP, and the extent of hydrolysis was dependent upon phosphate (Pi) concentration. CCCP promoted hydrolysis of intramitochondrial ATP. However, hydrolysis of externally added ATP was total in a medium containing potassium phosphate plus valinomycin. Without ionophores, ATPase activity was only observed at high external pH or with detergent-treated mitochondria. Under state 4 conditions, external ATP had access to the catalytic nucleotide site of ATPase as shown by 32Pi-ATP exchange experiments. These results are discussed in terms of a limitation of the translocase-mediated ATP/ADP exchange in uncoupled mitochondria.     

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.     

Adenine nucleotide translocation in liver mitochondria of hypothyroid rats.

In measurements using a disc filtration method, liver mitochondria obtained from hypothyroid rats translocate external ADP at 0 °C via the atractyloside-sensitive carrier much more slowly than do mitochondria from normal rats, confirming the findings of Portnay et al. (Biochem. Biophys. Res. Commun. 55, 17, 1973). The hypothyroid mitochondria contain 60% more ATP + ADP than do mitochondria from normals, but the excess nucleotides are not exchangeable and so do not contribute to translocation. A decrease in the first-order rate constant accounts for the decreased velocity. Neither a decrease in the number of translocator sites nor changes in ADP phosphorylation or ATPase activity seem to account for the abnormal kinetics of translocation. Although the filtration method limits the maximal translocation rate observed in normal mitochondria at temperatures above 17 °C that induce a fluid membrane state, no such transition is seen in mitochondria from hypothyroid rats up to 35 °C, indicating that the translocator is in an altered environment in hypothyroidism. Injecting a hypothyroid rat once with l-thyroxine corrects the abnormal compartmentation and produces a temperature-rate relationship like that in normal mitochondria in 3 days, a period which would accommodate the hormone actions reported on translation, membrane phospholipid synthesis, or fatty acid desaturation.     

Effect of long-chain fatty acyl-CoA on mitochondrial and cytosolic ATP/ADP ratios in the intact liver cell.

The effect of long-chain acyl-CoA on subcellular adenine nucleotide systems was studied in the intact liver cell. Long-chain acyl-CoA content was varied by varying the nutritional state (fed and starved states) or by addition of oleate. Starvation led to an increase in the mitochondrial and a decrease in the cytosolic ATP/ADP ratio in liver both in vivo and in the isolated perfused organ as compared with the fed state. The changes were reversed on re-feeding glucose in liver in vivo or on infusion of substrates (glucose, glycerol) in the perfused liver, respectively. Similar changes in mitochondrial and cytosolic ATP/ADP ratios occurred on addition of oleate, but, importantly, not with a short-chain fatty acid such as octanoate. It is concluded that long-chain acyl-CoA exerts an inhibitory effect on mitochondrial adenine nucleotide translocation in the intact cell, as was previously postulated in the literature from data obtained with isolated mitochondria. The physiological relevance with respect to pyruvate metabolism, i.e. regulation of pyruvate carboxylase and pyruvate dehydrogenase by the mitochondrial ATP/ADP ratio, is discussed.     

Characterization of rat liver mitochondria depleted of inner membrane components by chloramphenicol treatment of regenerating rat liver.

The maximal decline of adenosine triphosphate phosphohydrolase (ATPase; EC 3.6.1.3) in mitochondria from regenerating rat liver on treatment with chloramphenicol occurs between 48 and 72 h after partial hepatectomy. The depleted mitochondria are well coupled, exhibiting a respiratory control ratio of about 7 with succinate. These mitochondria are fully sensitive to rutamycin for the inhibition of succinate state 3 respiration. In frozen-thawed mitochondria there is a 60% reduction in ATPase activity, and of this remaining ATPase activity only 50% is sensitive to rutamycin. The titers for release of succinate state 4 respiration and ATPase activity by 5-Cl, 3-tert-butyl, 2′-Cl, 4′-NO₂-salicylanilide are decreased, and the efficiency of the uncoupler is increased. The antimycin titer for inhibition of succinate state 3 respiration is decreased. In all cases where a decrease in activity or titer was observed it is about the same (50%), suggesting inhibition at a common site for these parameters.     

ATPase complex and oxidative phosphorylation in chloramphenicol-induced megamitochondria from mouse liver

1. 1. Functional properties of the ATPase complex are investigated in megamitochondria isolated from livers of weanling mice fed a diet containing 2% chloramphenicol, as an inhibitor of mitochondrial protein synthesis.

2. 2. Whereas the specific activity of ATPase remains unchanged in chloramphenicol-induced megamitochondria, about 40% of the enzyme activity is resistant to inhibition by oligomycin, triethyltin or venturicidin. It is concluded that the ATPase complex lacks one or more components whose synthesis or accumulation is dependent on mitochondrial translation. The inhibitor-resistant ATPase portion appears tightly bound to the mitochondrial membrane.

3. 3. Respiratory chain phosphorylation is tightly coupled in isolated megamitochondria. ATP synthesis and ATP-P_i exchange are diminished by 40%, as compared to control mitochondria, but both processes are sensitive to oligomycin, triethyltin or venturicidin.

4. 4. The decrease in ATP synthesis and ATP-P_i exchange in megamitochondria correlates quite well with the emergence of inhibitor-resistant ATPase.

5. 5. The following electron transport activities in the megamitochondria are reduced: NADH-cytochrome c reductase, by 60%, cytochrome oxidase, by 80%; the amount of antimycin required to gain complete inhibition of the bc₁-segment is diminished by more than 50%. On the other hand succinate dehydrogenase activity is increased by 50%.

6. 6. Chloramphenicol-induced megamitochondria appear to be a useful system for studying the role of mitochondrial translation in the assembly of mammalian mitochondria.

Binding of an intrinsic ATPase inhibitor to the F(1)FoATPase in phosphorylating conditions of yeast mitochondria

Yeast mitochondrial ATP synthase has three regulatory proteins; ATPase inhibitor, 9K protein, and 15K protein. A mutant yeast lacking these three regulatory factors was constructed by gene disruption. Rates of ATP synthesis of both wild-type and the mutant yeast mitochondria decreased with decrease of respiration, while their membrane potential was maintained at 170-160 mV under various respiration rates. When mitochondrial respiration was blocked by antimycin A, the membrane potential of both types of mitochondria was maintained at about 160 mV by ATP hydrolysis. ATP hydrolyzing activity of F(1)FoATPase solubilized from normal mitochondria decreased in proportion to the rate of ATP synthesis, while the activity of the mutant F(1)FoATPase was constant regardless of changes in the rate of phosphorylation. These observations strongly suggest that F(1)FoATPase in the phosphorylating mitochondria is a mixture of two types of enzyme, phosphorylating and non-phosphorylating enzymes, whose ratio is determined by the rate of respiration and that the ATPase inhibitor binds preferentially to the non-phosphorylating enzyme.     

The Membrane-Bound Forms of the Mitochondrial ATPase of Turnip (Brassica napus L.) and Mung Bean (Phaseolus aureus): Characterization and Investigation of Factors Controlling Activity

Isolated intact plant mitochondria, including those from turnipand mung bean, show low endogenous Mg²⁺-ATPase activity and,unlike mammalian mitochondria, lack significant uncoupler-stimulatedATPase activity. In contrast, the rates of respiration-drivenATP synthesis are comparable to those in mammalian mitochondria,suggesting the presence of an ATPase inhibitor. Disruption ofintact turnip mitochondria only results in limited increasesin ATPase activity, indicating that a permeability barrier toATP transport is not primarily responsible for the low endogenousactivity. The ATPase activity of turnip mitochondria and membraneparticles can be increased up to 50-fold when assayed underoptimum conditions. Time-dependent increases in activity inducedby ageing, exposure to salts and trypsin treatment, are allconsistent with an inhibitor protein being responsible for thelow endogenous activity and lack of uncoupler-stimulation. TheATPase activity of particles under optimum conditions and afterageing is sufficient to account for the rates of ATP synthesis.After activation, turnip mitochondrial ATPase activity is similarto the mammalian enzyme in inhibitor sensitivity, pH optimum,bivalent cation requirement, and sensitivity to ‘activatinganions’. In mung bean mitochondria, a permeability barrierto ATP is only partly responsible for the low endogenous ATPaseactivity, together with the inhibitory factor. On the basisof variation in the relative Ca²⁺ and Mg²⁺ -ATPase activitiesafter various treatments, a Ca²⁺-regulatory site which affectsATPase activity is proposed to exist in the F₁ATPase complex. Key words: Plant mitochondrial ATPase, calcium/magnesium -ATPase, inhibitor+ nucleotide specificity, cation/anion effects     

Effect of Ca ions on the transmembrane electric potential, synthesis and hydrolysis of ATP in brain mitochondria

The transmembrane potential (delta psi) of rabbit brain mitochondria was measured with the fluorescent dye dis--C2--5. During oxidative phosphorylation a fall in delta psi in the order of 20% was observed. In the presence of inhibitors of ATP synthesis, there was a good correlation between the fall in delta psi and the ADP-stimulated increase in respiration rate. The influence of endogenous calcium on the energetic metabolism of mitochondria was studied by measuring the changes of delta psi. An amount of 12 nmol Ca2+/mg protein cause half-inhibition of the ATP synthesis rate; 50 nmol/mg completely inhibits oxidative phosphorylation. The effect of the Ca2+ load on the ATPase activity of intact mitochondria was studied. It was found that endogenous calcium inhibits in a similar degree synthesis and hydrolysis of ATP. It was shown that both Ca ATP and Mg ATP can serve as a substrate for the mitochondrial ATPase.     

Lipid protein interactions in mitochondria. VII. A comparison of the effects of lipid removal and lipid perturbation of the kinetic properties of mitochondrial ATPase.

We investigated the kinetics of mitochondrial ATPase in bovine heart mitochondria and submitochondrial particles upon treatment with phospholipase A2, or upon addition of n-butanol to perturb the lipid protein interactions. The changes observed are the following: (1) Lipid removal or perturbation with butanol is accompanied by loss of ATPase activity with decrease of both V and of the KM for ATP. (2) There are changes of activation energy of ATPase activity at temperatures above the discontinuity normally observed for membrane-bound enzymes in mitochondria. In particular, butanol abolishes the discontinuity, and induces a constant activation energy of about 32 kcal/mol in the range 8--37 degrees C. (3) Butanol modifies the pH dependence of ATPase shifting the pH optimum from around 10 to less alkaline values. The optimum for Mg2+ concentrations is increased by the solvent. (4) Treatment with phospholipase A2 results in a removal of oligomycin-sensitive ATPase, whereas butanol addition prevents oligomycin inhibition of ATPase. (5) In beef heart mitochondria, a spin-labelled analog of the inhibitor, dicyclohexyl carbodiimide, did not show any change in environment upon butanol addition, unlike that found in mitochondria from Saccharomyces cerevisiae.     

Ethidium bromide inhibits mitochondrial phosphorylating oxidation.

Ethidium bromide, in addition to combination with mitochondrial nucleic acids, is a phosphorylation inhibitor during glutamate and succinate respiration by mitochondria. Exhaustive washing of ethidium bromide-treated mitochondria did not relieve the inhibition nor significantly decrease the amount of bound dye. Dialysis against a cation exchange resin at 3 degrees for 17 hr removed about 97% of bound dye. This restored phosphorylating capacity to that of untreated mitochondria which had also been dialyzed against the resin. Since state 3 respiration was diminished and state 4 was unaffected by the presence of the acridine dye, and since neither swelling of mitochondria nor release of latent ATPase was observed, then ethidium bromide was not an electron transport inhibitor nor an uncoupler of oxidative phosphorylation. Inhibition of metabolic processes by ethidium bromide may be due in part to depressed generation of mitochondrial ATP.