Studies on the mechanism of inhibition of the mitochondrial electron transport by antimycin. II. Antimycin as an allosteric inhibitor

1. Pretreatment of sub-mitochondrial particles with cholate results in a change in the curve describing inhibition by antimycin of the succinate-cytochrome c reductase from sigmoidal towards linear. This effect of cholate is reversed by partial removal of the cholate by dialysis, either in the absence or presence of antimycin.

2. Treatment with cholate has the same action on the sigmoidal effect curve of antimycin on the reducibility of cytochrome b. This is also reversed by dialysis.

3. The effect of antimycin on the displacement to the red of the -band of ferrocytochrome b, measured in the presence of succinate, NADH or reduced ubiquinone Q-2, is also described by a sigmoidal curve that is changed to a linear one by addition of cholate.

4. Linear displacement curves are obtained with menaquinol or Na₂S₂O₄.

5. It is proposed that antimycin is an allosteric inhibitor of the respiratory chain. This allosteric effect should be distinguished from the effect of antimycin on the “conformation stability” of Complex III.     

Studies on the mechanism of inhibition of the mitochondrial electron transport by antimycin. IV. Effect of surface-active agents on the antimycin-inhibition curve and availability of sulfhydryl groups of the heart muscle preparation

1. Pretreatment of submitochondrial particles with anionic detergents, such as deoxycholate and dodecyl sulfate, results in a change in the curve describing inhibition by antimycin of the succinate-cytochrome c reductase from sigmoidal towards linear.

2. On treatment of the preparation with either nonionic (Triton X-100 or Tween 80) or cationic (Cetavlon) detergents, the sigmoidal inhibition curve is retained. However, the preparation preincubated with Tween 80 is one half as sensitive to antimycin as the untreated one despite the fact that the activity of the preparation is not affected by this detergent.

3. In the presence of the anionic detergents, much higher amounts of sulfhydryl groups of the preparation are titratable by 5,5′-dithiobis(2-nitrobenzoic acid) than those of the control preparation. Addition of antimycin is without effect.

4. Preincubation of the preparation with Cetavlon results in only a small increase in the amount of sulfhydryl groups, whereas the nonionic detergents are without effect on the sulfhydryl content of the preparation.

5. The results indicate that the anionic detergents at the concentration transforming the antimycin-inhibition curve from sigmoidal towards linear result in a rapid increase of the sulfhydryl content of the heart-muscle preparation.     

The reaction of antimycin with a cytochrome b preparation active in reconstitution of the respiratory chain

1. Succinate-cytochrome c reductase activity was reconstituted by incubating a mixture of succinate dehydrogenase, cytochrome c₁, ubiquinone-10, phospholipid and a preparation of cytochrome b, made by the method of .

2. Preparations of cytochrome b active in reconstitution contained 5–28% native cytochrome b, as adjudged by reducibility with succinate in the reconstituted preparation and by lack of reaction with CO. Preparations of cytochrome b containing no native cytochrome b according to this criterion were inactive in reconstitution.

3. With a fixed amount of cytochrome b, the activity of the reconstituted preparation increased with increasing amounts of cytochrome c₁ until a ratio of about 2b (total): 1c₁ (allowing for the cytochrome c₁ present in the cytochrome b preparation) was reached.

4. The amount of antimycin necessary for maximal inhibition of the reconstituted enzyme is a function of the amount of the cytochrome b and is independent of the amount of cytochrome c₁. It is equal to about one half the amount of native cytochrome b.

5. Preparations of intact or reconstituted succinate-cytochrome c reductase or of cytochrome b completely quench the fluorescence of added antimycin, until an amount of antimycin equal to onehalf the amount of native cytochrome b present was added. Antimycin added in excess of this amount fluoresces with normal intensity. The quenching is only partial in the presence of Na₂S₂O₄. Denatured cytochrome b does not quench the fluorescence.

6. Since preparations of cytochrome b active in reconstitution contained cytochrome c₁ in an amount exceeding one half the amount of native cytochrome b present in the preparation, there is no evidence that native cytochrome b has been resolved from cytochrome c₁. The stimulatory action of cytochrome c₁ may be due to the restoration of a damaged membrane conformation.

7. Based on the assumption that the bc₁ segment of the respiratory chain contains 2b:1c₁:1 antimycin-binding sites, the specific quenching of antimycin fluorescence by binding to cytochrome b enables an accurate determination of the absorbance coefficients of cytochromes b and c₁. These are 25.6 and 20.1 mM⁻¹×cm⁻¹ for the wavelength pairs 563–577 nm and 553–539 nm, respectively, in the difference spectrum reduced minus oxidized.     

Antimycin-insensitive mutants of Candida utilis. II. The effects of antimycin on cytochrome b

1. Cytochrome b-562 is more reduced in submitochondrial particles of mutant 28 during the aerobic steady-state respiration with succinate than in particles of the wild type. When anaerobiosis is reached, the reduction of cytochrome b is preceded by a rapid reoxidation in the mutant. A similar reoxidation is observed in the wild type in the presence of low concentrations of antimycin.

2. In contrast to the wild type, inhibition of electron transport in the mutant has a much higher antimycin titre than effects on cytochromes b (viz., aerobic steadystate reduction; reduction in the presence of substrate, cyanide and oxygen; the ‘red shift’ and lowering of E′₀ of cytochrome b-562). Moreover, the titration curve of electron transport is hyperbolic whereas the curves for the reduction are sigmoidal. The conclusion is, that in both mutant and wild type, the actions of antimycin on electron transport and cytochromes b are separable.

3. The red shift in the mutant is more extensive than in the wild type.

4. Cytochrome b-558 and cytochrome b-566 (that absorbs in mutant and wild type at 564.5 nm) do not respond simultaneously to addition of antimycin, indicating that they are two separate cytochromes.

5. The difference between the effect of antimycin on electron transport and cytochromes b reduction is also found in intact cells of the mutant.

6. A model is suggested for the wild-type respiratory chain in which (i) the cytochromes b lie, in an uncoupled system, out of the main electron-transfer chain, (ii) antimycin induces a conformation change in QH₂-cytochrome c reductase resulting in effects on cytochrome b and inhibition of electron transport, (iii) a second antimycinbinding site with low affinity to the antibiotic is present, capable of inhibiting electron transport.     

Oxidoreduction of cytochrome b in the presence of antimycin

1. The effect of oxidizing equivalents on the redox state of cytochrome b in the presence of antimycin has been studied in the presence and absence of various redox mediators.

2. The antimycin-induced extra reduction of cytochrome b is always dependent on the initial presence of an oxidant such as oxygen. After removal of the oxidant this effect remains or is partially (under some conditions even completely) abolished depending on the redox potential of the substrate used and the leak through the antimycin-inhibited site.

3. The increased reduction of cytochrome b induced by oxidant in the presence of antimycin involves all three spectroscopically resolvable b components (b-562, b-566 and b-558.

4. Redox mediators with an actual redox potential of less than 100–170 mV cause the oxidation of cytochrome b reduced under the influence of antimycin and oxidant.

5. Redox titrations of cytochrome b with the succinate/fumarate couple were performed aerobically in the presence of cyanide. In the presence of antimycin two b components are separated potentiometrically, one with an apparent midpoint potential above 80 mV (at pH 7.0), outside the range of the succinate/fumurate couple, and one with an apparent midpoint potential of 40 mV and an n value of 2. In the absence of antimycin cytochrome b titrates essentially as one species with a midpoint potential of 39 mV (at pH 7.0) and n = 1.14.

6. The increased reducibility of cytochrome b induced by antimycin plus oxidant is considered to be the result of two effects: inhibition of oxidation of ferrocytochrome b by ferricytochrome c₁ (the effect of antimycin), and oxidation of the semiquinone form of a two-equivalent redox couple such as ubiquinone/ubiquinol by the added oxidant, leading to a decreased redox potential of the QH₂/QH^• couple and reduction of cytochrome b.     

The binding of aurovertin to mitochondria, and its effect on mitochondrial respiration

1. The fluorescence of aurovertin increases about 100-fold on binding to sub-mitochondrial particles.

2. The mitochondrial ATPase (F₁) binds one mole aurovertin/mole F₁ with a dissociation constant of 6·10⁻⁸ M.

3. The fluorescence of mitochondrion-bound aurovertin is maximal during State-3 respiration and is partially quenched on anaerobiosis, addition of respiratory inhibitor, oligomycin or uncoupler, or transition to State 4. This quenching is still present when the binding site is saturated with aurovertin, showing that the quantum yield of fluorescence is lowered.

4. Aurovertin is bound co-operatively to State-3 mitochondria.

5. The curve relating inhibition of State-3 respiration to aurovertin concentration is more sharply sigmoidal than the binding curve.

6. An analysis of the binding and inhibition data leads to the conclusion that aurovertin induces a conformation change in the binding site on F₁ in two ways: (i) directly by acting as an allosteric effector of an oligomeric system, (ii) indirectly by inhibiting State-3 respiration which changes the allosteric constant of the oligomeric system.

7. The concentration of the aurovertin-binding site in both rat-liver and rat-heart mitochondria is about the same as that of the antimycin-binding and oligomycin-binding sites.     

Inhibition of peroxisomal fatty acyl-CoA oxidase by antimycin A.

Peroxisomal fatty acyl-CoA oxidase was inhibited by micromolar concentrations of antimycin A, an inhibitor of mitochondrial respiration. The inhibition was observed with all three substrates tested, i.e. palmitoyl-CoA, trihydroxycoprostanoyl-CoA and hexadecanedioyl-CoA. The peroxisomal D-amino acid oxidase was also inhibited by antimycin, but the peroxisomal L-alpha-hydroxyacid oxidase and uric acid oxidase and the mitochondrial monoamine oxidase were not. The degree of inhibition of acyl-CoA oxidase by antimycin was strongly dependent on the amount of cellular protein present in the assay mixture: at a fixed antimycin concentration, the inhibition was gradually lost with increasing protein concentrations. At a fixed cellular protein concentration in the assay mixtures, the mitochondrial oxidation of glutamate or palmitoylcarnitine was inhibited at antimycin concentrations that were much lower than those required for the inhibition of fatty acyl-CoA oxidase. Our results, nevertheless, demonstrate that antimycin A must be used with caution, when it is added to homogenates or subcellular fractions in order to distinguish between mitochondrial and peroxisomal fatty acid oxidation.     

On the nature of electron and energy transport in mitochondria. I. Multiple inhibition of mitochondrial respiration

1. A series of eight classical respiratory-chain inhibitors was studied. The slopes of State-3 respiratory rate versus dose plots are convex for antimycin, 2-n-heptyl-4-hydroxyquinoline-N-oxide (HOQNO), rotenone and sulfide, and concave for malonate, Amytal, cyanide and azide.

2. Plots of ADP: O ratio versus dose indicate uncoupling effects at higher concentrations of antimycin, HOQNO, cyanide and azide. On the other hand, sulfide and rotenone have no effect on the phosphorylating efficiency. Malonate increases the ADP: O ratio.

3. Two inhibitors can be combined in such a way that the total inhibition should be equal to the inhibition caused by the single inhibitors if each inhibitor affects respiration independently (additivity of inhibition). In practice, however, antagonism and synergism are also found.

4. Additivity of combined inhibition occurs where both inhibitors act on the same enzyme.

5. Antagonism is observed where the two inhibitors act on different enzymes of the same chain.

6. Synergism is found where the two inhibitors act on enzymes in different branches of a forked chain. This turns into normal additivity when the electron flow through both branches is made equal.

7. The results are compatible with the hypothesis that respiratory enzymes are arranged in chains. The possibility that the chains may be cross-linked or branched is discussed.     

Proteins required for the binding of mitochondrial ATPase to the mitochondrial inner membrane

1. Isolated F₁ (mitochondrial ATPase) binds to urea-treated submitochondrial particles suspended in sucrose/Tris/EDTA with a dissociation constant of 0.1 μM.

2. About one-third of the F₁ and the oligomycin-sensitivity conferring protein (OSCP) are lost during preparation of submitochondrial particles prepared at high pH (A particles). None is lost from particles treated with trypsin (T particles).

3. After further treatment with alkali of urea-treated particles, binding of F₁ requires the addition of OSCP. Maximum binding is reached when both OSCP and Fc₂ are added. The concentration of F₁-binding sites in the presence of both OSCP and Fc₂ is about the same as that in TU particles.

4. After further extraction with silicotungstate of urea- and alkali-treated particles, OSCP no longer induces binding of F₁, unless Fc₂ is also present. Fc₂ induces binding in the absence of OSCP but with a lower binding constant and, in contrast to results under all the other conditions studied in this paper, the ATPase activity is oligomycin insensitive.

5. It is tentatively concluded that OSCP is the binding site for F₁ and Fc₂ is the binding site for OSCP.     

Respiration-dependent uncoupler-stimulated ATPase activity in castor bean endosperm mitochondria and submitochondrial particles

1. The uncoupler-stimulated ATPase activity of castor bean endosperm mitochondria and submitochondrial particles has been studied. The rate of ATP hydrolysis catalyzed by intact mitochondria was slow and little enhanced by addition of uncouplers at the concentration required for uncoupling the oxidative phosphorylation. ATPase activity was stimulated at higher concentrations of uncouplers.

2. 1-Anilinonaphthalene 8-sulfonate fluorescence was decreased when the mitochondria were oxidizing succinate. Carbonylcyanide-p-trifluoromethoxyphenylhydrazone and antimycin reversed the succinate-induced fluorescence diminution. ATP did not induce the fluorescence response.

3. The addition of succinate, NADH or ascorbate/N,N,N′,N′-tetramethyl-p-phenylenediamine as electron donor induced high ATPase activity in the presence of low concentrations of uncouplers. Stimulating effect of uncouplers was completely abolished by further addition of antimycin.

4. Submitochondrial particles were prepared by sonication. The particles catalyzed a rapid hydrolysis of ATP and carbonylcyanide-p-trifluoromethoxyphenylhydrazone at 10^-8 M did not stimulate the ATPase activity. Addition of succinate induced uncoupler-stimulated ATPase activity. The effect of succinate was completely abolished by further addition of antimycin.

5. The treatment of submitochondrial particles by trypsin or high pH also induced uncoupler-stimulated ATPase activity.

6. The above results were interpreted to indicate that ATPase inhibitor regulated the back-flow reaction of mitochondrial oxidative phosphorylation.     

Studies on the mechanism of electron trasport in the bc1-segment of the respiratory chain in yeast. III. Isolation and characterization of an antimycin resistant mutant ANT 8 in Schizosaccharomyces pombe.

1. A mutant (ANT 8) of Schizosaccharomyces pombe which shows resistance to antimycin both in vivo and in vitro is characterized biochemically and genetically. 2. In crosses of ANT 8 with auxotrophic strains, resistance to antimycin segregates 2:2 indicating that resistance is conferred by a single nuclear gene. Diploids heterozygous for the resistance gene, however, show segregation of the resistance and sensitivity during mitosis. Possible reasons for this segregation are discussed. 3. Compared with the wild type, the NADH oxidase of ANT 8 requires 13 times as much antimycin for 95% inhibition. After addition of ubiquinone-3, electron transport which is less sensitive to antimycin is found only in the mutant. 4. The resistance of the mutant ANT 8 si due to the much weaker binding of antimycin to mitochondria. As in the wild type, two antimycin binding sites can be separated by binding studies. From the inhibition curves it is evident that binding of antimycin to oxidized mitochondrial particles does not correspond with its inhibitory effect on the partly reduced enzyme in kinetic studies. 5. The peak of the b-cytochrome absorbing at 560.2 nm at 77 degrees K in the wild type is shifted to 561 nm in the mutant. 6. A special preparation method for mutant mitochondrial particles is described, yielding highly active enzymes and CO-insensitive cytochromes. 7. The results are discussed with reference to the components in our model of the respiratory chain, which may be responsible for this type of resistance.     

The acceptor specificity of flavins and flavoproteins. III. Flavoproteins

1. The specificity of flavoproteins towards acceptors has been rather neglected, but an attempt is here made to construct a comparative table of acceptor specificities of those flavoprotein enzymes for which data exist.

2. The acceptor specificity of reduced flavin groups, when combined with apoenzyme proteins, is quite different from that of the same flavin groups in the free state (see Part II). Free flavins react very rapidly with a wide range of acceptors, but the same groups combined as flavoproteins have a severely restricted range of action.

3. There are remarkable differences between different flavoproteins. Nearly every flavoprotein fails altogether to react with at least one, and often several, of the acceptors, giving a specificity pattern which is different in each case. There seems to be no general acceptor for flavoproteins.

4. The effect of combination of a flavin with a particular apoenzyme is to inhibit specifically the reaction of the flavin with particular acceptors with which it would react very rapidly in the absence of the apoenzyme.

5. Each apoenzyme produces its own distinctive pattern of inhibitions. The degree of inhibition is often very high; the table shows over 50 cases of specific inhibitions that are essentially complete. Some of these are very difficult to explain.

6. There is no obvious parallelism between any acceptor and any other in its pattern of reactivity with a series of different flavoproteins.

7. In a few cases combination with apoenzyme specifically accelerates the reaction of the flavin with particular acceptors, so that the flavoprotein is oxidized faster than the free flavin.

8. Possible correlations are discussed between the effects of apoenzymes on the reactivity of flavins with acceptors and a number of special known features of different apoenzymes, but no adequate explanation of the differences in specificity has emerged.

9. In view of the interesting nature of the effects, a plea is made for a more intensive study of the acceptor side of flavoprotein specificity.     

Binding of HQNO to beef-heart sub-mitochondrial particles

1. The fluorescence spectra of HQNO (2-n-heptyl-4-hydroxyquinoline-N-oxide) in water at pH 7.5 show an emission maximum at 480 nm and an excitation maximum at 355 nm.2. The fluorescence is enhanced by binding to bovine serum albumin, and is completely quenched by binding to sub-mitochondrial particles of beef heart.3. Binding experiments reveal specific binding of HQNO to sub-mitochondrial particles with a dissociation constant of 64 nM and, depending on the protein concentration, a considerable amount of aspecific binding.4. The concentration of specific binding sites for HQNO is identical with that of antimycin-binding sites. Furthermore, the presence of antimycin prevents the binding of HQNO and antimycin releases HQNO from its binding site.5. The binding of HQNO is not sensitive to the redox state of the respiratorychain components.6. Inhibition of electron transfer by HQNO is caused by binding to the specific binding site.7. The relation between inhibition of NADH or succinate oxidation and saturation of the binding site is hyperbolic.8. The increase in the reduction level of cytochrome b on addition of HQNO in the presence of succinate and oxygen, either in the presence or absence of cyanide, does not parallel the inhibition of overall electron transfer.9. All data can be quantitatively described and analysed using the model for electron transfer proposed by Wikström and Berden in 1972 (Wikström, M. K. F. and Berden, J. A. (1972) Biochim. Biophys. Acta 283, 403–420).     

Quinone interaction with the respiratory chain-linked NADH dehydrogenase of beef heart mitochondria. II. Duroquinone reductase activity

1. Enzymatic reduction of 2,3,5,6-tetramethyl-1,4-benzoquinone (duroquinone) by NADH can be used in an assay procedure for the NADH dehydrogenase. The reduction of this quinone occurs in the region of the electron transport system between the primary dehydrogenase and the cytochrome system as defined by the almost complete loss of reductase activity following piericidin A treatment.

2. Duroquinone reduction can be distinguished from ubiquinone 2 reduction by the marked inhibition of the former following phospholipase C, poly- -lysine, or chloroquine diphosphate treatment. In addition, duroquinone reduction requires the presence of endogenous ubiquinone 10 specifically whereas ubiquinone 2 reduction does not require the presence of endogenous quinone. These observations are consistent with the nonequivalency of the reduction sites of duroquinone and ubiquinone 2.

3. Duroquinol can be utilized as an electron donor for the energy-linked reduction, of NAD⁺. Duroquinol reduction of NAD⁺ is dependent upon the presence of ATP, is inhibited by oligomycin, carbonyl cyanide p-trifluoro methoxyphenylhydrazone and piericidin A, and is not inhibited by antimycin A at levels which inhibit electron transport.

4. Duroquinone reduction as well as ubiquinone 2 reduction are inhibited almost completely by phospholipase A, p-chloromercuribenzoate, o-phenanthroline, and Triton X100 treatments.     

Properties and function of the respiratory chain of freshwater mussel spermatozoa in relation to motility

1. The spermatozoa of the freshwater mussel (Hyriopsis schlegelii) contain cytochromes aa₃, b and c, flavoproteins and nicotinamide nucleotides in molar ratios of 1.0:0.9:1.8:1.8:8.7. Cytochrome c₁ is not detectable even at liquid-N₂ temperature, but a c₁-like cytochrome with an -band at 550 mμ is found at liquid-N₂ temperature in a cell preparation from which cytochrome c is completely removed.

2. The near-ultraviolet difference spectrum of whole cells reveals an absorption peak at 315 mμ with a shoulder around 350 mμ.

3. Both the endogenous respiration and motility of spermatozoa are completely blocked by 0.2 mM CN⁻ and by 0.2 μM antimycin A. 2,4-Dinitrophenol and pentachlorophenol completely inhibit motility at the maximal stimulation of respiration. Rotenone strongly inhibits NADH oxidase of spermatozoa, although it has no effect on the respiration of whole cells.

4. It is concluded that the motility of mussel spermatozoa is tightly coupled to respiration, and the respiratory chain phosphorylating process is the only energy-supplying system for motility.     

Study of electrogenic electron transfer steps in chromatophore membrane of Chromatium vinosum by the response of merocyanin dye

1. Electrogenic steps in photosynthetic cyclic electron transport in chromatophore membrane of Chromatium vinosum were studied by measuring absorption changes of added merocyanin dye and of intrinsic carotenoid.

2. The change in dye absorbance was linear with the membrane potential change induced either by light excitation or by application of diffusion potential by adding valinomycin in the presence of K⁺ concentration gradient.

3. It was estimated that chromatophore membrane became 40–60 mV and 110–170 mV inside positive upon single and multiple excitations with single-turnover flashes, respectively, from the responses of the dye and the carotenoid.

4. Electron transfers between cytochrome c-555 or c-552 and reaction center bacteriochlorophyll dimer (BChl₂) and between BChl₂ and the primary electron acceptor were concluded to be electrogenic from the redox titration of the dye response.

5. No dye response which corresponded to the change of redox level of cytochrome b was observed in the titration curve. Addition of antimycin A slightly decreased the dye response.

6. The dye response was decreased under phosphorylating conditions.

7. From the results obtained localization of the electron transfer components in chromatophore membrane is discussed.     

The Influence of Seasonal Variation on Oxidative Phosphorylation in Sub-mitochondrial Particles Prepared from Jerusalem Artichoke Tubers

A method for the preparation of sub-mitochondrial particlesfrom Jerusalem artichoke tubers by sonication is described.The particles carried out a rapid oxidation of NADH, succinate,and ascorbate saturated with N',N',N,N-tetramethylphenylenediamine(TMPD). The difference spectrum (dithionite reduced minus oxidized)of sub-mitochondrial particles was similar to that of wholemitochondria. In the autumn phosphorylation accompanied electrontransport only when supernatant from the preparation procedurewas added to the sub-mitochondrial particles in the presenceof magnesium. In the winter and spring there was a decreasein the effect of supernatant on phosphorylation, and the sub-mitochondrialparticles alone synthesized ATP during substrate oxidation.It is suggested that the reconstitution of phosphorylation inJerusalem artichoke sub-mitochondrial particles is essentiallysimilar to that observed in beef heart electron transport particles,but that phosphorylation in the former is subject to seasonalvariations.     

Studies of mitochondrial calcium movements using chlorotetracycline

1. The association of calcium with isolated rat liver mitochondrial membranes under various metabolic conditions was monitored using the fluorescent chelate probe, chlorotetracycline. Chlorotetracycline fluorescence increased markedly during energized calcium uptake in the absence of a permeant anion. Uncoupler and a respiratory chain inhibitor caused a rapid decrease in chlorotetracycline fluorescence when added either before or after calcium. During calcium uptake experiments concentrations of calcium exceeding 100 μM caused a transient fluorescence increase followed by an extensive decrease in fluorescence.

2. Changes in the chlorotetracycline-associated fluorescence of the mitochondrial suspensions were correlated with the uptake of exogenous ⁴⁵Ca. A positive correlation was observed between fluorescence and energized ⁴⁵Ca uptake in the absence of permeant anions. Addition of the permeant anion, phosphate, caused an extensive decrease in chlorotetracycline fluorescence but an enhanced uptake of exogenous ⁴⁵Ca.

3. The interaction of endogenous mitochondrial calcium with the fluorescent chelate probe was studied under a number of experimental conditions using mitochondria labeled during preparation with ⁴⁵Ca. Endogenous ⁴⁵Ca was lost rapidly from the mitochondria upon treatment with uncoupler, antimycin A, and A23187. Potassium phosphate and EGTA had no effect on the endogenous calcium as measured by either the ⁴⁵Ca content of the mitochondria or the fluorescence of the probe.

4. Mitochondria treated with antimycin A lost most of their endogenous ⁴⁵Ca within 3 min; subsequent energization of the mitochondria resulted in a partial uptake of the released ⁴⁵Ca but caused nearly a complete return of the chlorotetracycline fluorescence to the original level. Addition of phosphate did not change the fluorescence level but resulted in an almost complete accumulation of the ⁴⁵Ca previously released.

5. Following this energized uptake of ⁴⁵Ca, EGTA, p-trifluoromethoxyphenyl hydrazone of carbonyl cyanide, A23187 and calcium chloride all caused a nearly complete loss of the ⁴⁵Ca from the mitochondria and, with the exception of calcium chloride, caused an extensive decrease in the fluorescence level. Hence, the apparent location and/or properties of the endogenous calcium in this rat liver mitochondrial system were altered significantly by manipulation of the energetic state of the mitochondrial membrane.     

Evidence for a lipid dependence of mitochondrial nicotinamide nucleotide transhydrogenase

1. The lipid dependence of mitochondrial nicotinamide nucleotide transhydrogenase from beef heart was investigated. With submitochondrial particles digestion of phospholipids by phospholipases A and C led to a partial inhibition that could not be readily reversed by phospholipids.

2. Extraction of neutral lipids including ubiquinone from lyophilized submitochondrial particles with pentane did not inhibit the transhydrogenase, whereas further extraction with water/acetone led to a complete and apparently irreversible inhibition.

3. A partially purified preparation of transhydrogenase, depleted of lipids (and inactivated) by treatment with cholate and ammonium sulphate, was reactivated by various purified phospholipids but not by detergents or triacylglycerols.

4. It is concluded that mitochondrial transhydrogenase, catalyzing the non-energy-linked transhydrogenase reaction, requires phospholipids specifically for its catalytic activity and not as dispersing agents. A mixture of phospholipids appears to fulfill this requirement better than the individual phospholipids.     

Studies on the biochemical basis of susceptibility and resistance of the housefly to fluoroacetate

1. Administration of fluoroacetate to sensitive houseflies in amounts close to the L.D.₅₀ range (0.25–0.3 μg/fly) brought about a prompt elevation of their citrate content. With about 10-fold higher doses of fluoroacetate a concurrent increase of both citrate and pyruvate levels took place in the fly tissues.

2. Incubation of sarcosomes of the sensitive housefly strain in the presence of oxidizable substrates and fluoroacetate resulted in accumulation of citrate, inhibition of respiration and uncoupling of oxidative phosphorylation. The magnitude of the effects varied considerably with the different substrates used, being particularly pronounced with pyruvate and malate and inappreciable with succinate and -glycerophosphate.

3. The respiratory inhibition induced by a brief exposure in the cold of housefly sarcosomes to fluoroacetate, persisted after the sarcosomes had been washed free from fluoroacetate. The toxic effect of fluoroacetate on the respiratory chain could be prevented by an excess of simultaneously added acetate.

4. The susceptibility of the respiratory function of the sarcosomes to fluoroacetate inhibition was abolished by sonication. The unresponsiveness of the sonicated sarcosomes to fluoroacetate was attended by a loss of their respiratory chain phosphorylation activity.

5. Sarcosomes derived from a partially resistant housefly strain, when incubated in the presence of fluoroacetate, failed to accumulate citrate, but displayed the characteristic respiratory-inhibition response. Sarcosomes from a highly resistant strain showed no impairment of their functional capacity by fluoroacetate. However, all the different housefly strains tested proved to be equally sensitive to the deleterious effect of fluorocitrate on sarcosomal respiration.

6. The possible biochemical mechanisms underlying the toxicity of fluoroacetate in the housefly are considered with particular reference to the altered response of the target systems exhibited by the fluoroacetate-resistant strains.