Interaction between the oligomycin sensitivity conferring protein and the F0 sector of the mitochondrial adenosinetriphosphatase complex: cooperative effect of the F1 sector

Beef heart mitchondrial oligomycin sensitivity conferring protein (OSCP) labeled with [14C]-N-ethylmaleimide ([14C]OSCP) at the only cysteine residue, Cys-118, present in the sequence [Ovchinnikov, Y. A., Modyanov, N. N., Grinkevich, V. A., Aldanova, N. A., Trubetskaya, O. E., Nazimov, I.V., Hundal, T., & Ernster, L. (1984) FEBS Lett. 166, 19-22] exhibits full biological activity in a reconstituted F0-F1 system [Dupuis, A., Issartel, J. P., Lunardi, J., Satre, M., & Vignais, P. V. (1985) Biochemistry 24, 728-733]. The binding parameters of [14C]OSCP with respect to the F0 sector of submitochondrial particles largely depleted of F1 and OSCP (AUA particles) have been explored. In the absence of added F1, a limited number of high-affinity OSCP binding sites were detected in the AUA particles (20-40 pmol/mg of particles); under these conditions, the low-affinity binding sites for OSCP were essentially not saturable. Addition of F1 to the particles promoted high-affinity binding for OSCP, with an apparent Kd of 5 nM, a value 16 times lower than the Kd relative to the binding of OSCP to F1 in the absence of particles. Saturation of the F1 and OSCP binding sites of AUA particles was attained with about 200 pmol of both F1 and OSCP added per milligram of particles. The oligomycin-dependent inhibition of F1-ATPase bound to AUA particles was assayed as a function of bound OSCP. At subsaturating concentrations of F1, the dose-effect curves were rectilinear until inhibition of ATPase activity by oligomycin was virtually complete, and maximal inhibition was obtained for an OSCP to F1 ratio of 1 (mol/mol).(ABSTRACT TRUNCATED AT 250 WORDS)     

Interactions between the oligomycin sensitivity conferring protein (OSCP) and beef heart mitochondrial F1-ATPase. 2. Identification of the interacting F1 subunits by cross-linking

Interactions between oligomycin sensitivity conferring protein (OSCP) and subunits of beef heart mitochondrial F1-ATPase have been explored by cross-linking at an OSCP/F1 molar ratio close to 1 to ensure specific high-affinity binding of OSCP to F1 [see Dupuis et al. [Dupuis, A., Issartel, J.-P., Lunardi, J., Satre, M., & Vignais, P.V. (1985) Biochemistry (preceding paper in this issue)]]. Cross-links between F1 subunits and OSCP were established by means of two zero length cross-linkers, 1-[3-(dimethylamino)propyl]-3-ethylcarbodiimide and N-(ethoxycarbonyl)-2-ethoxydihydroquinoline. The cross-linked products were separated by sodium dodecyl suflate-polyacrylamide gel electrophoresis. Coomassie blue staining revealed two cross-linked products of Mr 75 000 and 80 000 which could result from the binding of OSCP to the alpha and beta subunits of F1. Definite identification of the cross-linked products was achieved by chemical labeling with specific radiolabeled reagents and by blotting on nitrocellulose filters followed by immunocharacterization with anti-alpha, anti-beta, and anti-OSCP antibodies. OSCP was found to cross-link with the alpha and beta subunits of F1.     

Heterologous expression, purification, and biochemistry of the oligomycin sensitivity conferring protein (OSCP) from yeast.

Yeast Saccharomyces cerevisiae oligomycin sensitivity conferring proteins (OSCP) have been expressed in Escherichia coli. Heterologous expression results in production of a protein that is identical to yeast mature OSCP, including the absence of the initiating methionine residue. Yeast OSCP expressed in E. coli has been purified to homogeneity and it is able to reconstitute oligomycin-sensitive ATPase using purified F1- and F1/OSCP-depleted membranes (electron transport particles (ETP). Binding of F1 to ETP is dependent on the addition of OSCP. Binding studies using 35S-OSCP indicated that OSCP binds to ETP with a Kd of 200 nM and a capacity of 420 pmol/mg particle protein, whereas OSCP does not interact with F1 in the absence of ETP. These data indicate that yeast OSCP must first form a specific complex with F0, which then binds F1 forming the functional complex. To identify functional domains in yeast OSCP, two deletion mutants have been made. Antibodies directed to these deletion products do not inhibit OSCP-dependent binding of F1 to ETP. However, antibodies directed against the last one-third of OSCP greatly reduce the oligomycin sensitivity of the reconstituted ATPase. These data suggest that OSCP is involved in a functional role in energy transduction or proton translocation and serves a structural role in the yeast mitochondrial ATP synthase.     

Isolation and properties of OSCP and an F1-ATPase binding protein from rat liver mitochondria - evidence against OSCP as the linking "stalk" between F1 and the membrane.

Oligomycin Sensitivity Conferral Protein (OSCP) and an F₁-ATPase Binding Protein were isolated from F₁-depleted rat liver mitochondrial membrane. Their molecular weights on polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate and urea were 22,500 and 8,500 respectively. When incubated with liver TUA (trypsin, urea and ammonia-treated) submitochondrial particles, the binding protein was effective in the binding of F₁ to the particles with the resultant particle-bound ATPase activity not oligomycin sensitive. When OSCP was then incubated with the reconstituted membrane-bound ATPase, its activity became oligomycin sensitive. These results suggest that, first; the binding protein, but not OSCP, connects F₁-ATPase to the membrane of rat liver mitochondria and maybe to the “stalk”, if indeed there is a stalk in mitochondrial membrane ATPase complex; and second; the function of OSCP is solely to render the ATPase activity sensitive to oligomycin and other similar inhibitors.     

A fluorescent derivative of the oligomycin-sensitivity conferring protein (acrylodan-OSCP). Evidence for polarity changes in the environment of CYS118 of OSCP upon binding to mitochondrial F1

The fluorescent probe, 6-acryloyl-2-dimethylaminonaphtalene (acrylodan) was reacted with the oligomycin-sensitivity conferring protein (OSCP). Acrylodan bound covalently to the single cysteinyl residue of the protein. Acrylodan-OSCP was fully competent in conferring oligomycin sensitivity to the mitochondrial F0-F1 ATPase complex. The fluorescence emission peak of acrylodan-OSCP was blue-shifted compared to that of an acrylodan-mercaptoethanol adduct, which means that acrylodan experiences a hydrophobic environment in OSCP. Binding of acrylodan-OSCP to the isolated F1 was accompanied by a red shift of fluorescence. It was achieved in less than 1 s at 25 degrees C. The titration curve revealed one high affinity OSCP binding site per F1. Acrylodan-OSCP appears to be an interesting tool for studying the dynamics of structural changes within the mitochondrial ATPase complex.     

ATP synthase complex from bovine heart mitochondria: the oligomycin sensitivity conferring protein is essential for dicyclohexyl carbodiimide-sensitive ATPase.

The requirement of bovine heart mitochondrial oligomycin sensitivity conferring protein (OSCP) in conferring dicyclohexylcarbodiimide (DCCD)-sensitivity to membrane-bound F1 was investigated by using OSCP-depleted membrane fraction (UF0) of ATP synthase. The ATPase activity of UF0-F1 was completely insensitive to DCCD while that of UF0-F1-OSCP was inhibited 95% by 16 microM DCCD. Both UF0-F1 and UF0-F1-OSCP complexes bound 5 nmol [14C]DCCD/mg UF0, and all the radioactivity was found to be associated with the DCCD-binding proteolipid. The data suggest that OSCP may be necessary for transmitting not only energy-linked signals, but also signals induced by F0 inhibitory ligands in mitochondrial energy transduction.     

Efficient reconstitution of mitochondrial energy-transfer reactions from depleted membranes and F1-ATPase as a function of the amount of bound oligomycin sensitivity-conferring protein (OSCP)

Pig heart mitochondrial membranes depleted of F1 and OSCP by various treatments were analyzed for their content in alpha and beta subunits of F1 and in OSCP using monoclonal antibodies. Membrane treatments and conditions of rebinding of F1 and OSCP were optimized to reconstitute efficient NADH- and ATP-dependent proton fluxes, ATP synthesis and oligomycin-sensitive ATPase activity. F1 and OSCP can be rebound independently to depleted membranes but to avoid unspecific binding of F1 to depleted membranes (ASUA) which is not efficient for ATP synthesis, F1 must be rebound before the addition of OSCP. The rebinding of OSCP to depleted membranes reconstituted with F1 inhibits the ATPase activity of rebound F1, while it restores the ATP-driven proton flux measured by the quenching of ACMA fluorescence. The rebinding of OSCP also renders the ATPase activity of bound F1 sensitive to uncouplers. The rebinding of OSCP alone or F1 alone, does not modify the NADH-dependent proton flux, while the rebinding of both F1 and OSCP controls this flux, inducing an inhibition of the rate of NADH oxidation. Similarly, oligomycin, which seals the F0 channel even in the absence of F1 and OSCP, inhibits the rate of NADH oxidation. OSCP is required to adjust the fitting of F1 to F0 for a correct channelling of protons efficient for ATP synthesis. All reconstituted energy-transfer reactions reach their optimal value for the same amount of OSCP. This amount is consistent with a stoichiometry of two OSCP per F1 in the F0-F1 complex.     

Titration of the binding sites for the oligomycin-sensitivity conferring protein in beef heart submitochondrial particles

The binding parameters of the oligomycin-sensitivity conferring protein (OSCP) in inside-out particles from beef heart mitochondria have been tested by means of two assays, the oligomycin-sensitive ATP-Pi exchange, and the oligomycin-sensitive ATP hydrolysis. The total number of OSCP binding sites in A particles was equal to 220 pmol/mg particle protein. Each mole of ATPase active site was able to bind 1.1 +/- 0.5 mol OSCP with Kd 1.7 nM.     

Interaction of F1-ATPase, from ox heart mitochondria with its naturally occurring inhibitor protein. Studies using radio-iodinated inhibitor protein

The ox heart mitochondrial inhibitor protein may be iodinated with up to 0.8 mol 125I per mol inhibitor with no loss of inhibitory activity, with no change in binding affinity to submitochondrial particles, and without alteration in the response of membrane-bound inhibitor to energisation. Tryptic peptide maps reveal a single labelled peptide, consistent with modification of the single tyrosine residue of the protein. A single type of high-affinity binding site (Kd=96 . 10 (-9)M) for the inhibitor protein has been measured in submitochondrial particles. The concentration of this site is proportional to the amount of membrane-bound F1, and there appears to be one such site per F1 molecule. The ATp hydrolytic activity of submitochondrial particles is inversely proportional to the occupancy of the high-affinity binding site for the inhibitor protein. No evidence is found for a non-inhibitory binding site on the membrane or on other mitochondrial proteins. In intact mitochondria from bovine heart, the inhibitor protein is present in an approx. 1:1 ratio with F1. Submitochondrial particles prepared by sonication of these mitochondria with MgATP contain about 0.75 mol inhibitor protein per mol F1, and show about 25% of the ATPase activity of inhibitor-free submitochondrial particles. Additional inhibitor protein can be bound to these particles to a level of 0.2 mol/mol F1, with consequent loss of ATPase activity. If MgATP is omitted from the medium, or inhibitors of ATP hydrolysis are present, the rate of combination between F1 and its inhibitor protein is very much reduced. The equilibrium level of binding is, however, unaltered. These results suggest the presence of a single, high-affinity, inhibitory binding site for inhibitor protein on membrane-bound F1. The energisation of coupled submitochondrial particles by succinate oxidation or by ATP hydrolysis results in both the dissociation of inhibitor protein into solution, and the activation of ATP hydrolysis. At least 80% of the membrane-bound F1-inhibitor complex responds to this energisation by participating in a new equilibrium between bound and free inhibitor protein. This finding suggests that a delocalised energy pool is important in promoting inhibitor protein release from F1. Dissipation of the electrochemical gradient by uncouplers, or the binding of oligomycin or efrapetin effectively blocks energised release of the inhibitor protein. Conversely, the addition of aurovertin or adenosine 5'--[beta, lambda--imido]triphosphate enhances energy-driven release. The mode of action of various inhibitors on binding and energised release of the protein inhibitor is discussed.     

A study of the dicyclohexylcarbodiimide-binding component of the mitochondrial ATPase complex from beef heart

1. The binding of [14C]-dicyclohexylcarbodiimide to membrane proteins of beef heart mitochondria has been investigated using dodecylsulphate/polyacrylamide gel electrophoresis. Upon incubation of submitochondrial particles with low concentrations of dicyclohexylcarbodiimide (5 nmol/mg protein) radioactivity was incorporated into three components with apparent molecular weights of 30000, 18000 and less than 6500. Only the two smaller components were found to be extracted into chloroform/methanol. The same two components were labelled when the isolated ATPase complex or a reconstituted F0F1 system was incubated with low concentrations of dicyclohexylcarbodiimide. High concentrations of dicyclohexylcarbodiimide (20-100 nmol/mg protein) resulted in binding to several mitochondrial proteins. 2. The maximal amount of dicyclohexylcarbodiimide which can bind to submitochondrial particles, the isolated ATPase complex, and the reconstituted F0F1 system was found to exceed the amount required for maximal inhibition of the ATPase activity by several-fold. The distribution of the bound [14C]dicyclohexylcarbodiimide between the different dicyclohexylcarbodiimide-binding components was investigated as a function of dicyclohexylcarbodiimide concentration. The smallest and largest components revealed a high affinity for dicyclohexylcarbodiimide-binding which paralleled the inhibition of ATPase activity. The intermediate component had a markedly lower affinity for dicyclohexylcarbodiimide-binding. 3. The larger dicyclohexylcarbodiimide-binding component of the isolated ATPase complex can be converted into the smaller component by treatment of the ATPase complex with performic acid. Partial conversion can also be achieved by extraction of the band from the dodecylsulphate-polyacrylamide gel after electrophoresis, followed by re-electrophoresis. The observations suggest that the larger component may be an oligomer of the smaller one. 4. Using concentrations of oligomycin and dicyclohexylcarbodiimide which were equal to or greater than those required for maximal inhibition of the ATPase activity, oligomycin was found to diminish the binding of [14C]dicyclohexylcarbodiimide to both dicyclohexylcarbodiimide-binding components of the isolated ATPase complex.     

ATP synthase complex from beef heart mitochondria. Role of the thiol group of the 25-kDa subunit of Fo in the coupling mechanism between Fo and F1

In order to assess the role of thiol groups in the Fo part of the ATP synthase in the coupling mechanism of ATP synthase, we have treated isolated Fo, extracted from beef heart Complex V with urea, with thiol reagents, primarily with diazenedicarboxylic acid bis-(dimethylamide) (diamide) but also with Cd2+ and N-ethylmaleimide. FoF1 ATP synthase was reconstituted by adding isolated F1 and the oligomycin-sensitivity-conferring-protein (OSCP) to Fo. The efficiency of reconstitution was assessed by determining the sensitivity to oligomycin of the ATP hydrolytic activity of the reconstituted enzyme. Contrary to Cd2+, incubation of diamide with Fo, before the addition of F1 and OSCP, induced a severe loss of oligomycin sensitivity, due to an inhibited binding of F1 to Fo. This effect was reversed by dithiothreitol. Conversely, if F1 and OSCP were added to Fo before diamide, no effect could be detected. These results show that F1 (and/or OSCP) protects Fo thiols from diamide and are substantiated by the finding that the oligomycin sensitivity of ATP hydrolysis activity of isolated Complex V was also unaltered by diamide. Gel electrophoresis of FoF1 ATP synthase, reconstituted with diamide-treated Fo, revealed that the loss of oligomycin sensitivity was directly correlated with diminution of band Fo 1 (or subunit b). Concomitantly a band appeared of approximately twice the molecular weight of subunit Fo 1. As this protein contains only 1 cysteine residue (Walker, J. E., Runswick, M. J., and Poulter, L. (1987) J. Mol. Biol. 197, 89-100), the effect of diamide is attributed to the formation of a disulfide bridge between two of these subunits. These results offer further evidence for the proposal, based on aminoacid sequence and structural analysis, that subunit Fo 1 of mammalian Fo is involved in the binding with F1 (Walker et al. (1987]. N-Ethylmaleimide affects oligomycin sensitivity to a lesser extent than diamide, suggesting that the mode of action of these reagents (and the structural changes induced in Fo) is different.     

Effect of the natural ATPase inhibitor on the binding of adenine nucleotides and inorganic phosphate to mitochondrial F1-ATPase

(1) Incubation of the beef heart mitochondrial ATPase, F1 with Mg-ATP was required for the binding of the natural inhibitor, IF1, to F1 to form the inactive F1-IF1 complex. When F1 was incubated in the presence of [14C]ATP and MgCl2, about 2 mol 14C-labeled adenine nucleotides were found to bind per mol of F1; the bound 14C-labeled nucleotides consisted of [14C]ADP arising from [14C]ATP hydrolysis and [14C]ATP. The 14C- labeled nucleotide binding was not prevented by IF1. These data are in agreement with the idea that the formation of the F1-IF1 complex requires an appropriate conformation of F1. (2) The 14C-labeled adenine nucleotides bound to F1 following preincubation of F1 with Mg-[14C] ATP could be exchanged with added [3H]ADP or [3H]ATP. No exchange occurred between added [3H]ADP or [3H]ATP and the 14 C-labeled adenine nucleotides bound to the F1-IF1 complex. These data suggest that the conformation of F1 in the isolated F1-IF1 complex is further modified in such a way that the bound 14C-labeled nucleotides are no longer available for exchange. (3) 32Pi was able to bind to isolated F1 with a stoichiometry of about 1 mol of Pi per mol of F1 (Penefsky, H.S. (1977) J. Biol. Chem. 252, 2891-2899). There was no binding of 32Pi to the F1-IF1 complex. Thus, not only the nucleotides sites, but also the Pi site, are masked from interaction with external ligands in the isolated F1-IF1 complex.     

Mitochondrial ATP synthase complex. Membrane topography and stoichiometry of the F0 subunits.

The topography of the subunits of the membrane sector F0 of the ATP synthase complex in the bovine mitochondrial inner membrane was studied with the help of subunit-specific antibodies raised to the F0 subunits b, d, 6, F6, A6L, OSCP (oligomycin-sensitivity-conferring protein), and N,N' -dicyclohexylcarbodiimide (DCCD)-binding proteolipid and to the ATPase inhibitor protein (IF1) as an internal control. Exposure of F0 subunits in inverted and right-side-out inner membranes was investigated by direct antibody binding as well as by susceptibility of these subunits to degradation by various proteases as monitored by gel electrophoresis of the membrane digests and immunoblotting with the subunit-specific antibodies. Results show that subunits b, d, F6, A6L (including its C-terminal end) and OSCP were exposed on the matrix side. Sufficient masses of these subunits to recognize antibodies or undergo proteolysis were not exposed on the cytosolic side. This was also the case for subunit 6 and the DCCD-binding proteolipid on either side of the inner membrane. Quantitative immunoblotting in which bound radio-activity from [125I]protein A was employed to estimate the concentration of an antigen in a sample allowed the determination of the stoichiometry of several F0 subunits and IF1 relative to F1-ATPase. Results showed that per mol of F1 there are in bovine heart mitochondria 1 mol each of d, OSCP, and IF1, and 2 mol each of b and F6. Subunit 6 and the DCCD-binding proteolipid could not be quantitated, because the former transferred poorly to nitrocellulose and the latter's antibody did not bind [125I]protein A.     

Proteins required for the binding of mitrochondrial 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 muM. 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.     

Photolabeling of mitochondrial F1-ATPase by an azido derivative of the oligomycin-sensitivity conferring protein

An azido derivative of the oligomycin sensitivity conferring protein (OSCP) was prepared by alkylation with the bifunctional reagent p-azido phenacyl bromide. Azido-OSCP was fully biologically active in the dark. Upon photoirradiation of a mixture of beef heart mitochondrial F1-ATPase and azido-OSCP, the resulting covalent photoproducts were separated by polyacrylamide gel electrophoresis in the presence of Na dodecyl sulfate and characterized by an immunochemical procedure. OSCP was found to react with the alpha and the beta subunits of F1 with strong preference for the alpha subunit.     

ATP synthase complex from bovine heart mitochondria. Passive H+ conduction through F0 does not require oligomycin sensitivity-conferring protein

Oligomycin sensitivity-conferring protein (OSCP) is a water-soluble subunit of bovine heart mitochondrial H(+)-ATPase (F1-F0). In order to investigate the requirement of OSCP for passive proton conductance through mitochondrial F0, OSCP-depleted membrane preparations were obtained by extracting purified F1-F0 complexes with 4.0 M urea. The residual complexes, referred to as UF0, were found to be deficient with respect to OSCP, as well as alpha, beta, and gamma subunits of F1-ATPase, but had a full complement of coupling factor 6 as judged by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and Western blotting techniques. These UF0 complexes had no intrinsic ATPase activity and were able to bind nearly the same amount of F1-ATPase in the presence of either OSCP or NH4+ ions alone, or a combination of the two. However, the preparations exhibited an absolute dependency on OSCP for conferral of oligomycin sensitivity to membrane-bound ATPase. The passive proton conductance in UF0 proteoliposomes was measured by time-resolved quenching of 9-amino-6-chloro-2-methoxyacridine or 9-aminoacridine fluorescence following a valinomycin-induced K(+)-diffusion potential. The data clearly establish that OSCP is not a necessary component of the F0 proton channel nor is its presence required for conductance blockage by the inhibitors oligomycin or dicyclohexylcarbodiimide. Furthermore, OSCP does not prevent or block passive H+ leakage. Comparisons of OSCP with the F1-F0 subunits from Escherichia coli and chloroplast lead us to suggest that mitochondrial OSCP is, both structurally and functionally, a hybrid between the beta and delta subunits of the prokaryotic systems.     

Structural and functional characterization of subunits of the F0 sector of the mitochondrial F0F1-ATP synthase.

Proteolytic digestion of F1-depleted submitochondrial particles (USMP), reconstitution with isolated subunits and titration with inhibitors show that the nuclear-encoded PVP protein, previously identified as an intrinsic component of bovine heart F0 (F01) (Zanotti, F. et al. (1988) FEBS Lett. 237, 9-14), is critically involved in maintaining the proper H+ translocating configuration of this sector and its correct binding to the F1 catalytic moiety. Trypsin digestion of USMP, under conditions leading to cleavage of the carboxyl region of the PVP protein and partial inhibition of transmembrane H+ translocation, results in general loss of sensitivity of this process to F0 inhibitors. This is restored by addition of the isolated PVP protein. Trypsin digestion of USMP causes also loss of oligomycin sensitivity of the catalytic activity of membrane reconstituted soluble F1, which can be restored by the combined addition of PVP and OSCP, or PVP and F6. Amino acid sequence analysis shows that, in USMP, modification by [14C] N,N'-dicyclohexylcarbodiimide of subunit c of F0 induces the formation of a dimer of this protein, which retains the 14C-labelled group. Chemical modification of cysteine-64 of subunit c results in inhibition of H+ conduction by F0. The results indicate that proton conduction in mitochondrial F0 depends on interaction of subunit c with the PVP protein.     

Studies on polypeptide composition, hydrolytic activity and proton conduction of mitochondrial FoF1 H+ ATPase in regenerating rat liver

A study of the FoF1 ATPase complex of mitochondria isolated from regenerating rat liver following partial (70%) hepatectomy is presented. As we have previously reported, ATPase activity in submitochondrial particles prepared from regenerating rat liver 24 h following partial hepatectomy was depressed by 75% with respect to controls (submitochondrial particles from sham-operated animals). Polyacrylamide gel electrophoresis and immunodecoration using an antibody raised against isolated bovine heart F1 sector of the FoF1 ATPase indicated a substantial decrease in F1 content in the mitochondrial membrane from regenerating rat liver. Proton conduction by the FoF1 ATPase complex was studied by following the anaerobic relaxation of the transmembrane proton gradient (delta mu H+) generated by succinate-driven respiration. In control rat-liver submitochondrial particles containing the FoF1 moiety of the ATPase complex, anaerobic relaxation of delta mu H+ showed biphasic kinetics, whilst the same process in particles derived from regenerating rat liver exhibited monophasic kinetics and was significantly more rapid. Oligomycin and N,N-dicyclohexyl carbodiimide [(cHxN)2C] inhibited proton conductance by the F1-Fo ATPase complex in submitochondrial particles from both control and regenerating rat liver. Binding of [14C](cHxN)2C and immunodecoration using an antibody raised against bovine heart oligomycin-sensitivity-conferring protein (OSCP) indicated no difference in the content of either the (cHxN)2C binding protein or OSCP between control and regenerating rat-liver mitochondrial membranes. The results reported show that the structural and functional integrity of the Fo-F1 ATPase of rat liver is severely perturbed during regeneration.     

Oligomycin sensitivity-conferring protein (OSCP) of beef heart mitochondria. Internal sequence homology and structural relationship with other proteins

Structural analysis of oligomycin sensitivity-conferring protein (OSCP) revealed repeating sequences (residues 1-89, 105-190) suggesting an evolution of the protein by gene duplication. In addition to the reported homology with the delta-subunit of Escherichia coli F1ATPase, OSCP also shows a certain homology with the b-subunit of E. coli F0 and the ADP/ATP carrier of mitochondria.     

Oligomycin sensitivity-conferring protein (OSCP) of mitochondrial ATP synthase. The carboxyl-terminal region of OSCP is essential for the reconstitution of oligomycin-sensitive H(+)-ATPase.

Studies to establish the structure/function relationships of oligomycin sensitivity-conferring protein (OSCP) of mitochondrial ATP synthase were carried out using genetic engineering and biochemical approaches. A full-length cDNA clone encoding OSCP was isolated from a bovine heart cDNA library, and the mature form of OSCP was expressed in Escherichia coli using plasmid expression vector pKP1500. Recombinant OSCP was found to accumulate in the cytoplasmic inclusion bodies, by virtue of which the recombinant protein could be purified to greater than 85% purity by simple low speed centrifugation of cell lysates. Recombinant OSCP was found to be indistinguishable from OSCP isolated from mitochondria with respect to (i) apparent molecular mass on sodium dodecyl sulfate gel electrophoresis, (ii) immunological reactivity to anti-OSCP serum, (iii) biological activity in restoring oligomycin-sensitive ATPase and Pi-ATP exchange activities to OSCP-depleted ATP synthase complexes, and (iv) insensitivity of the biological activity to sulfhydryl-directed alkylating reagents. The amino-terminal sequence of the recombinant protein revealed that the initiating methionine was not removed by E. coli, although that apparently did not affect protein folding or its biological activity. Data on nested deletion mutations starting from the carboxyl terminus in OSCP demonstrated that, in each instance, the mutant form was expressed and the protein product was sequestered in cytoplasmic inclusion bodies, similar to the wild-type form. However, none of the variants, including the one in which only the last 10 residues were deleted, was able to restore cold-stable oligomycin-sensitive ATPase or Pi-ATP exchange activity in OSCP-depleted complexes. Taken together, these data suggest that amino acid residues 181-190 (or some of the residues in this region) in the OSCP sequence may be important for OSCP-F1 interactions.