Evidence supporting the identity of beef heart mitochondrial chloroform-released adenosine triphosphatase (ATPase) with coupling factor I

Highly purified mitochondrial chloroform-released beef heart ATPase had molecular weight 330 000, five bands (α, β, γ, δ, ε) in sodium dodecyl sulfate gel electrophoresis and could restore the oxidative-phosphorylation function of A particles. Maximal inhibition (90%) of the enzyme by N,N′-dicyclohexylcarbodiimide was achieved at a molar ratio of inhibitor to protein of 30 : 1. Chloroform introduced into an aqueous solution of beef heart coupling factor I protected it from cold inactivation.     

Evidence supporting the identity of beef heart mitochondrial chloroform-released adenosine triphosphatase (ATPase) with coupling factor I.

Highly purified mitochondrial chloroform-released beef heart ATPase had molecular weight 330 000, five bands (alpha, beta, gamma, delta, epsilon) in sodium dodecyl sulfate gel electrophoresis and could restore the oxidative-phosphorylation function of A particles. Maximal inhibition (90%) of the enzyme by N,N'-dicyclohexylcarbodiimide was achieved at a molar ratio of inhibitor to protein of 30 : 1. Chloroform introduced into an aqueous solution of beef heart coupling factor I protected it from cold inactivation.     

Mg2+-induced ADP-dependent inhibition of the ATPase activity of beef heart mitochondrial coupling factor F1.

Incubation of F₁ in the presence of Mg²⁺ results in a pronounced lag in its ATPase activity measured with the ATP-regenerating system. A decrease of the initial rate of ATPase induced by Mg²⁺ is also observed when free nucleotides were separated from the enzyme by Sephadex gel filtration. No inhibition is observed when F₁ treated to remove tightly bound nucleotides was preincubated in the presence of Mg²⁺. Mg²⁺-induced inhibition of ATPase activity of nucleotide-depleted F₁ can be restored by an addition of low concentrations of ADP. In all cases the inhibited ATPase can be activated by the ADP-removing system /phosphoenol pyruvate + pyruvate kinase/. It is concluded that i/ Mg²⁺-induced inhibition of the ATPase activity of F₁ is due to the formation of an inactive F₁. ADP complex; and ii/ unusual inhibition of oligomycin-sensitive ATPase by ADP /Fitin et al., Biochem. Biophys. Res. Communs. 1979, $\text{86}$, 434/ is directed to F₁ component of the complete mitochondrial ATPase system.     

Visualization of mitochondrial coupling factor F1(ATPase) by freeze-drying

It is known that the negatively stained preparations of inner mitochondrial membrane display characteristic ∼9 nmF ₁ (ATPase) knobs projecting from the matrix surface. Freeze-etch studies have reported the absence of such knobs from the “etched” surface of the inner mitochondrial membranes. We have demonstrated their presence on the surface of SMP (submitochondrial particles) prepared by freeze-drying for transmission electron microscopy. This identification has been substantiated by comparison with the freeze-dried TU particles (trypsin-urea treated SMP) that are devoid ofF ₁ (ATPase). It has been suggested that a layer of water molecules is strongly adsorbed to the surface of SMP and does not sublime during normal freeze-“etching.”     

A circular dichroism study of mitochondrial transhydrogenase from beef heart.

This paper describes a circular dichroism (CD) spectroscopy study of purified proton-pumping nicotinamide nucleotide transhydrogenase from beef heart. The CD spectrum obtained was used to estimate the content of secondary structures of the purified enzyme and suggests the presence of 40-45% alpha-helical structure and long, possibly membrane-spanning alpha-helices. The spectrum was essentially unaffected by the absence or presence of transhydrogenase substrates, suggesting that the catalytic and proton-translocating activities of the enzyme occur without major rearrangements at the level of secondary structures.     

Visualization of mitochondrial coupling factor F1(ATPase) by freeze-drying.

It is known that the negatively stained preparations of inner mitochondrial membrane display characteristic approximately 9 nm F1 (ATPase) knobs projecting from the matrix surface. Freeze-etch studies have reported the absence of such knobs from the "etched" surface of the inner mitochondrial membranes. We have demonstrated their presence on the surface of SMP (submitochondrial particles) prepared by freeze-drying for transmission electron microscopy. This identification has been substantiated by comparison with freeze-dried TU particles (trypsin-urea treated SMP) that are devoid of F1 (ATPase). It has been suggested that a layer of water molecules is strongly adsorbed to the surface of SMP and does not sublime during normal freeze-"etching."     

Crystallographic study of beef liver catalase

An orthorhombic form of beef liver catalase crystals has been examined by X-ray diffraction and electron microscopy. The space group is P2₁2₁2₁ with $\text{a = 89}\text{A}\text{?}\text{, b = 140}\text{A}\text{?}\text{, and}\text{c = 231}\text{A}\text{?}$. Electron micrographs show the presence of broad channels arrayed in a hexagonal manner. The solvent content of these orthorhombic crystals is considerably less than that for previously reported trigonal crystals of beef liver catalase although the packing arrangement appears to be virtually the same, suggesting a possible symmetry transition upon dehydration.     

Substructure of F1-ATPase (BF1 factor) from Micrococcus lysodeikticus

Summary Dimethyl suberimidate and dithiobis (succinimidyl propionate) have been used to explore the nearest neighbor relationship of the subunits (, , and by decreasing molecular weight) of F₁-ATPase or BF₁ factor of Micrococcus lysodeikticus. Cross-linking with the two diimido esters inhibited the ATPase activity but this inhibition never exceeded 50% of the initial value. The cross-linking pattern of this BF₁ factor, as revealed by sodium dodecyl sulfate gel electrophoresis, shows a relative low proportion of high molecular weight aggregates which move slowly than the heaviest subunit (). They are resolved as three components of molecular weights 200,000, 130,000 and 100,000 in 5% acrylamide gels, plus an additional component (mol. wt 80,000) identified in 10% acrylamide gels. The other aggregate bands represent cross-linking products of the smaller subunits ( and ) that may travel to the conventional position of the heavier subunits.The subunit composition of the aggregate bands has been determined through the reversion of dithiobis (succinimidyl propionate) cross-linking of the BF₁ factor by dithiothreitol and analysis in second dimension by gel electrophoresis. The results indicate that subunit can cross-link with itself and with each of the other subunits except . The subunit is also able to cross-link with itself and with the other subunits although to a minor extent than , and that ₂ aggregates are present. These results represent a specific pattern of cross-linking for this BF₁ factor as compared to other F₁ coupling factors. It suggests a certain asymmetry in the spatial organization of the major subunits of M. lysodeikticus F₁-ATPase where the subunit must play a central role. A subunit stoichiometry _{3 3 2 2} is proposed for whole F₁-ATPase which leads to a molecular weight 440,000 consistent with the 430,000 value estimated by sedimentation equilibrium at low speed. A tentative structural model of M. lysodeikticus BF₁ factor is derived from these data. The significance of the results in relation to the possible generalization of the molecular architecture of F₁ factors is discussed.     

Electron microscopy of beef heart mitochondrial F1-ATPase

The quaternary structure of isolated and membrane-bound F1-ATPase (submitochondrial particles) has been studied by electron microscopy. A model of the molecule has been proposed: six protein masses are arranged in two layers approximately at the vertices of a triangular antiprism. Computer averaging of the images showed that the frontal view of the molecule can be approximately characterized by mirror plane symmetry.     

Subunit structures of purified beef mitochondrial cytochromebc 1 complex from liver and heart

The existence of tissue-specific isozymes of cytochromec oxidase has been widely documented. We have now studied if there are differences between subunits of mitochondrialbc ₁ complexes isolated from liver and heart. For this purpose, we have developed a method for the purification of an active ubiquinol-cytochromec oxidoreductase from adult bovine liver that includes solubilization of submitochondrial particles with deoxycholate, ammonium acetate fractionation, resolubilization with dodecyl maltoside, and ion exchange chromatography. The electrophoretic pattern of the liver preparation showed the presence of 11 subunits, with apparent molecular weights identical to the ones reported for the heart complex. Western blot analysis and isoelectric focusing followed by two-dimensional gels ofbc ₁ complexes from liver and heart were compared, and no qualitative differences were observed. In addition, the high-molecular-weight subunits of the purified complexes from both tissues, subunits I, II, V, and VI, were isolated by PAGE in the presence of Coomasie Blue and subjected to limited proteolysis and to chemical digestion with cyanogen bromide and BNPS-skatol, and the peptide patterns were compared. Finally, two of the small-molecular-weight subunits from the liver complex were isolated (subunits VII and X), partially analyzed by amino terminal sequencing, and found to be identical with the reported sequence of their heart counterparts. The data suggest that, in contrast to the case of cytochromec oxidase,bc ₁ complexes from liver and heart do not exhibit tissue-specific differences.     

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.     

Crystallization of coupling factor 1 (CF1) from spinach chloroplast.

Spinach chloroplast coupling factor (CF₁) was crystal-lized at 20°C from 0.05 M TRIS-PO₄, containing 4 mM ATP, 15mM KCl, 1.0 mM EDTA and 1.80 M (NH₄)₂SO₄, at pH 7.8. Some unit cell parameters were determined by electron microscopy and by X-ray diffraction. The cube shaped crystals have a tetragonal lattice, a = b = 135 Å, c = 280 Å with eight molecules per unit cell; possible space group P422 or P4₂2₁2, hence half a molecule in the asymmetric unit. Crystals grown at pH 7.5 in the absence of ATP have an orthorhombic lattice, a = 125 Å, b = 145 Å, c = 169 Å (C222₁), eight molecules per unit cell.     

Interaction of Mg+2 with beef heart mitochondrial ATPase (F1).

The soluble mitochondrial ATPase, F₁, can be slowly inactivated by incubation with Mg⁺² in a manner consistent with the observations of Moyle and Mitchell $\text{(}\text{FEBS}\text{Lett}\text{.}\text{56}$, 55 (1975)). This inhibition results in a low initial rate of ATP hydrolysis upon addition to an ATPase assay medium of F₁ which has been incubated with Mg⁺². This inhibition, however, is completely reversible by Mg·ATP in a time dependent process and results in the rate of ATP hydrolysis increasing during the ATPase assay to reach control levels after 30 sec. The length of the lag is independent of the F₁ concentration in the ATPase assay and the lag is also completely reversed by subsequent incubation with excess EDTA before assay.F₁ is unstable if incubated with EDTA in the absence of free nucleotides or Mg⁺². The rate of inactivation increases with decreasing protein concentration until a limiting rate is reached at high dilution. Mg⁺² in excess of the EDTA or 50 μM ADP stabilize the F₁ against the inactivation but cannot reverse prior denaturation.     

High-affinity metal-binding site in beef heart mitochondrial F1ATPase: an EPR spectroscopy study

The high-affinity metal-binding site of isolated F(1)-ATPase from beef heart mitochondria was studied by high-field (HF) continuous wave electron paramagnetic resonance (CW-EPR) and pulsed EPR spectroscopy, using Mn(II) as a paramagnetic probe. The protein F(1) was fully depleted of endogenous Mg(II) and nucleotides [stripped F(1) or MF1(0,0)] and loaded with stoichiometric Mn(II) and stoichiometric or excess amounts of ADP or adenosine 5'-(beta,gamma-imido)-triphosphate (AMPPNP). Mn(II) and nucleotides were added to MF1(0,0) either subsequently or together as preformed complexes. Metal-ADP inhibition kinetics analysis was performed showing that in all samples Mn(II) enters one catalytic site on a beta subunit. From the HF-EPR spectra, the zero-field splitting (ZFS) parameters of the various samples were obtained, showing that different metal-protein coordination symmetry is induced depending on the metal nucleotide addition order and the protein/metal/nucleotide molar ratios. The electron spin-echo envelope modulation (ESEEM) technique was used to obtain information on the interaction between Mn(II) and the (31)P nuclei of the metal-coordinated nucleotide. In the case of samples containing ADP, the measured (31)P hyperfine couplings clearly indicated coordination changes related to the metal nucleotide addition order and the protein/metal/nucleotide ratios. On the contrary, the samples with AMPPNP showed very similar ESEEM patterns, despite the remarkable differences present among their HF-EPR spectra. This fact has been attributed to changes in the metal-site coordination symmetry because of ligands not involving phosphate groups. The kinetic data showed that the divalent metal always induces in the catalytic site the high-affinity conformation, while EPR experiments in frozen solutions supported the occurrence of different precatalytic states when the metal and ADP are added to the protein sequentially or together as a preformed complex. The different states evolve to the same conformation, the metal(II)-ADP inhibited form, upon induction of the trisite catalytic activity. All our spectroscopic and kinetic data point to the active role of the divalent cation in creating a competent catalytic site upon binding to MF1, in accordance with previous evidence obtained for Escherichia coli and chloroplast F(1).     

Pre-steady-state kinetics of beef heart mitochondrial ATPase

The pre-steady-state kinetics of beef heart mitochondrial ATPase (F1) were examined. F1 was found to exhibit hysteretic behavior when hydrolyzing ATP. The hysteretic property was expressed as an activation process which occurred when the enzyme was mixed with its substrate, MgATP. Many catalytic turnovers were required before the activation was complete. The lag in hydrolysis increased hyperbolically as the concentration of enzyme increased. Passage of F1 through Sephadex G25 eliminated the activation process. Several kinetically distinct possibilities for explaining these data, including multiple nucleotide dissociations, enzyme conformational changes, and regulatory site interactions, are discussed. The enzyme was apparently able to recognize nucleotide in a noncatalytic manner, as evidenced by the fact that F1 preincubated with ADP in the absence of substrate achieved partial activation (smaller lag times) before being introduced to substrate. ADP is also a time-dependent inhibitor, exhibiting a slow hysteretic inhibition in addition to immediate competitive inhibition.     

Metal-nucleotide structural characteristics during catalysis by beef heart mitochondrial F1

This study examined the nature of the metal-nucleotide complexes which serve as substrates, products, and intermediates in the beef heart mitochondrial ATPase reaction. The two methods employed involved the use of phosphorothioate ATP analogs as substrates in the presence of Mg2+ or Cd2+ and the use of substitution inert Cr X ATP complexes (the isolated diastereomers of the bidentate complexes) along with the newly synthesized Cr X ITP complexes as inhibitors of both the F1-ATPase and F1-ITPase activities. Little stereoselectivity was observed in the inhibition of F1-ATPase and F1-ITPase activities by the isolated diastereomers of beta,gamma-bidentate CrATP, while the inhibition by the delta,alpha,beta-bidentate CrADP diastereomer was greater than that of the lambda epimer. gamma-Monodentate CrITP was a weak inhibitor of both the ATPase and ITPase activities, whereas beta,gamma-bidentate CrITP failed to show any inhibition at all up to a concentration of 3.2 mM. When adenosine 5'-O-(2-thiotriphosphate) (ATP beta S) was used as the substrate, (VmSp]/(Vm(Rp] with Mg2+ present was 2.7 at 31 degrees C and 3.5 at 13 degrees C. The (Vm/Km(Sp]/(Vm/Km(Rp] ratios with Mg2+ present were 15.3 at 31 degrees C and 73.3 at 13 degrees C. With Cd2+ present, the (Vm(Sp]/(Vm(Rp] ratios were 0.81 and 0.65 at 31 and 13 degrees C, respectively. The (Vm/Km(Sp]/(Vm/Km(Rp] ratios with Cd2+ present were 1.17 at 31 degrees C and 1.34 at 13 degrees C. The large activation energy observed for the isomers of CdATP beta S was not observed for MgATP beta S, MgATP, or CdATP. The Vm for Cd adenosine 5'-O-thiotriphosphate (ATP gamma S) hydrolysis was the largest of all the metal-phosphorothioate nucleotide complexes, while that for MgATP gamma S was the smallest. The results are interpreted in terms of a catalytic model for F1-catalyzed nucleotide hydrolysis describing metal-nucleotide chelation during the reaction.     

Mechanism of ATP synthesis by mitochondrial ATP synthase from beef heart

Previous studies of the rate constants for the elementary steps of ATP hydrolysis by the soluble and membrane-bound forms of beef heart mitochondrial F₁ supported the proposal that ATP is formed in high-affinity catalytic sites of the enzyme with little or no change in free energy and that the major requirement for energy in oxidative phosphorylation is for the release of product ATP.The affinity of the membrane-bound enzyme for ATP during NADH oxidation was calculated from the ratio of the rate constants for the forward binding step (k ₊₁) and the reverse dissociation step (k _–1).k _–1 was accelerated several orders of magnitude by NADH oxidation. In the presence of NADH and ADP an additional enhancement ofk _–1 was observed. These energy-dependent dissociations of ATP were sensitive to the uncoupler FCCP.k ₊₁ was affected little by NADH oxidation. The dissociation constant (K _d ATP) increased many orders of magnitude during the transition from nonenergized to energized states.     

Structural studies of mitochondrial coupling factor 1 using tyrosine fluorescence

The absorbance and fluorescence spectral properties of mitochondrial F1-ATPase confirm that this protein does not contain tryptophan residues and therefore its fluorescence is due to tyrosines. The 36% increase in the fluorescence and the almost 100% increase in quantum yield upon denaturation of the protein suggest that a considerable number of tyrosyl residues have a very low quantum yield in the native enzyme. Quenching experiments using iodide indicate that all of the fluorophores are quenched and also all of them with the same quenching constant. These observations are interpreted as confirmatory of what has been found with several other proteins whose fluorescence originates from tyrosyl residues, where the buried tyrosines fluoresce with a much lower quantum yield than those which are exposed. ATP added to F1 previously depleted of loosely bound nucleotides changes the quenching constant of iodide and the quantum yield and this is interpreted to be due to a conformational change induced by the binding of the nucleotide to the enzyme. Addition of 2-mercaptoethanol decreases, although slightly, the polarization of the fluorescence. However, SDS addition gives a much bigger decrease. Hence disulphide bridges are less important for the tertiary structure of the protein than hydrophobic interactions, hydrogen bonding or other forces. Nevertheless the conformational change induced by reduction of disulphide bridges is detected in iodide quenching experiments and the change of the quantum yield of the enzyme.     

Tightly bound magnesium in mitochondrial adenosine triphosphatase from beef heart.

Tightly bound magnesium was found in soluble, purified ATPase (F1) from beef heart mitochondria in the amount of 1 mol/mol of F1. Iron, zinc, cobalt, manganese, calcium, sodium, copper, and potassium were not tightly bound at stoichiometric levels. Removal of magnesium by chelating agents caused loss of ATPase activity. Removal of tightly bound nucleotide by gel filtration in 50% glycerol- or 60 mM K2SO4-containing buffers did not remove magnesium. Cold dissociation did release magnesium when complete denaturation was accomplished. The results suggest that magnesium is an integral part of F1, that it is required for activity, and that magnesium and nucleotides are tightly bound at separate sites. The idea that the tightly bound nucleotides are not complexed with cations suggests certain structural requirements at their binding sites which might account for the unusual properties of the sites.