Mechanistic stoichiometry of mitochondrial oxidative phosphorylation.

P/O ratios of rat liver mitochondria were measured with particular attention to systematic errors. Corrections for energy loss during oxidative phosphorylation were made by measurement of respiration as a function of mitochondrial membrane potential. The corrected values were close to 1, 0.5, and 1 at the three coupling sites, respectively. These values are consistent with recent measurements of mitochondrial proton transport.

Information content of amino acid residues in putative helix VIII of the lac permease from Escherichia coli.

Mutants in putative helix VIII of lactose permease that retain the ability to accumulate lactose were created by cassette mutagenesis. A mutagenic insert encoding amino acid residues 259-278 was synthesized chemically by using reagents contaminated with 1% each of the other three bases and ligated into a KpnI/BclI site in the lacY gene in plasmid pGEM-4. Mutants that retain transport activity were selected by transforming a strain of Escherichia coli containing a wild-type lacZ gene, but deleted in lacY, with the mutant library and identifying colonies that transport lactose on indicator plates. Sequencing of the mutated region in lacY in 129 positive colonies reveals 43 single amino acid mutations at 26 sites and 26 multiple mutations. The variable amino acid positions are largely on one side of the putative alpha-helix, a stripe opposite Glu269. This mutable stripe of low information content is probably in contact with the membrane phospholipids.

Studies on the electron transfer pathway, topography of iron-sulfur centers, and site of coupling in NADH-Q oxidoreductase.

Electron transfer activities and steady state reduction levels of Fe-S centers of NADH-Q oxidoreductase were measured in mitochondria, submitochondrial particles (ETPH), and complex I after treatment with various reagents. p-Chloromercuribenzenesulfonate destroyed the signal from center N-4 (gx = 1.88) in ETPH but not in mitochondria, showing that N-4 is accessible only from the matrix side of the inner membrane. N-Bromosuccinimide also destroyed the signal from N-4 but without inhibiting rotenone-sensitive electron transfer to quinone, suggesting a branched pathway for electron transfer. Diethylpyrocarbonate caused oxidation of N-3 and N-4 in the steady state without changing N-1, suggesting N-1 is before N-3 and N-4. Difluorodinitrobenzene and dicyclohexylcarbodiimide inhibited oxidation of all Fe-S centers and tetranitromethane inhibited reduction of all Fe-S centers. Titrations of the rate of superoxide (O2-) generation in rotenone-treated submitochondrial particles were similar with the ratio [NADH]/[NAD] and that of 3-acetyl pyridine adenine nucleotide in spite of different midpoint potentials of the two couples. On reaction with inhibitors the inhibition of O2- formation was similar to that of ferricyanide reductase rather than quinone reductase. The rate of O2- formation during ATP-driven reverse electron transfer was 16% of the rate observed with NADH. The presence of NAD increased the rate to 83%. The results suggest that bound, reduced nucleotide, probably E-NAD., is the main source of O2- in NADH dehydrogenase. The effect of ATP on the reduction levels of Fe-S centers in well-coupled ETPH was measured by equilibrating with either NADH/NAD or succinate/fumarate redox couples. With NADH/NAD none of the Fe-S centers showed ATP induced changes, but with succinate/fumarate all centers showed ATP-driven reduction with or without NAD present. The effect on N-2 was smaller than that on N-1, N-3, and N-4. These observations indicate that the major coupling interaction is between N-2 and the low potential centers, N-1, N-3, and N-4. Possible schemes of coupling in this segment are discussed.

Decrease in glucose transport activity of Friend erythroleukemia cell caused by dimethylsulfoxide, a differentiation-inducing reagent.

A transport system for D-glucose was found in a Friend erythroleukemia cell line, T-3-C1-2-O and was characterized as a facilitated diffusion system. D-Glucose transport activity showed a half-saturation concentration of 2.2 mM and was inhibited by mercuric ions, cytochalasin B, phloretin, and stilbestrol, but was not strongly inhibited by phloridzin. Transport of 3-O-methyl-D-glucose was faster than D-glucose and the intracellular concentration of the sugar was found to reach the concentration in the assay medium. The treatment of cells with a differentiation-inducing reagent, dimethylsulfoxide(Me2SO), for 24 h caused a marked decrease in glucose transport activity due to a decrease in Vmax. In an induction-insensitive Friend cell line, T-3-K-1, D-glucose transport activity was low in untreated cells and Me2SO treatment did not cause a significant decrease in transport activity. The results obtained in this study indicate that the decrease in glucose transport activity is not due to the direct effect of Me2SO on transport activity, but is associated with the induction of differentiation. By immunoblotting cell lysates of T-3-C1-2-O cells using antibody to human erythrocyte glucose transporter, a single major band having a molecular weight of 52,000 was detected, which may be a glucose transporter in Friend cells.

The glucose transporter of mammalian cells.

The glucose transporter is now identified but may have modifications or other subunits that control its activity. The kinetics and inhibitor binding studies are consistent with the carrier model with different degrees of asymmetry and a single binding site that varies in specificity depending on the conformation of the protein. The physical structure could actually be quite different from the usual diagrams (rocking bananas), however, and could function as a monomer or higher oligomer. The binding site, or filter, that gives specificity could be in the middle as usually depicted; alternatively it could be entirely on the cytoplasmic side, where the protein is trypsin sensitive, and hydrophobic helices could span the membrane forming a simple channel. Possible restrictions on structures in the membrane from the hydrophobic nature of transmembrane segments of membrane proteins (62) may favor a globular domain outside the membrane as the binding site. Such speculations will have to await more structural information about the transporter.

Effect of membrane potential and pH gradient on electron transfer in cytochrome oxidase.

Steady-state spectra of cytochrome oxidase in phospholipid vesicles were obtained by using hexaammineruthenium(II) and ascorbate as reductants. Cytochrome a was up to 80% reduced in the steady state in coupled vesicles. Upon addition of nigericin or acetate, which decrease delta pH, resulting in an increase in delta psi, cytochrome a became more oxidized in the steady state with no change in the rate of respiration. On the other hand, uncouplers or valinomycin plus nigericin, which lower both delta psi and delta pH, stimulated respiration 2-8-fold and also lowered the steady-state level of reduction of cytochrome a. These experiments indicate that electron transfer between cytochromes a and a 3 is sensitive primarily to the pH gradient. Studies with the reconstituted and the soluble enzyme at various pH values indicated that the pH on the matrix side of the membrane, rather than delta pH, controlled the steady-state level of reduced cytochrome a. Hexaammineruthenium(II) substituted for cytochrome c in measurements of proton pumping by cytochrome oxidase. Dicyclohexylcarbodiimide, which eliminated proton pumping by cytochrome oxidase, decreased the effect of ionophores on the steady-state level of reduced cytochrome a.

Energetics of ATP-driven reverse electron transfer from cytochrome c to fumarate and from succinate to NAD in submitochondrial particles.

The maximum Gibbs free energies of reverse electron transfer from succinate to NAD+ and from cytochrome c to fumarate driven by ATP hydrolysis in submitochondrial particles from beef heart were measured as a function of the Gibbs free energy of ATP hydrolysis. The ratio of the energies delta G'redox/delta G'ATP was 1.40 from succinate to NAD+ and 0.89 from cytochrome c to succinate. The ratio, equivalent to a thermodynamic P/2e-ratio, was dependent on whether the electrochemical proton gradient was primarily a membrane potential or a pH gradient for the cytochrome c to fumarate reaction. The results are consistent with H+/ATP = 3 for F1 ATPase, H+/2e- = 4 for NADH-CoQ reductase, and H+(matrix)/2e- = 2 for succinate-cytochrome c reductase.

Insulin-induced translocation of intracellular glucose transporters in the isolated rat adipose cell.

Three techniques have now been used to demonstrate that insulin stimulates glucose transport in isolated rat adipose cells through the translocation of glucose transporters from a large intracellular pool to the plasma membrane. By using a specific D-glucose-inhibitable cytochalasin B-binding assay, most of the basal cell's transporters are found associated with a low-density microsomal membrane fraction. However, although Golgi marker enzyme activities are also enriched in this fraction, their distributions over all fractions do not parallel that of the transporters. In response to insulin, more than half of the intracellular transporters are translocated to the plasma membranes without a corresponding redistribution of marker enzyme activities. Furthermore, although the Kd of the transporters in the plasma membranes remains constant at approximately 100 nM, that of the intracellular transporters decreases from approximately 140 to approximately 100 nM. Nevertheless, transport activity is reconstitutable from, and an affinity-purified rabbit IgG against the purified human erythrocyte transporter cross-reacts with a 45,000-dalton band in, both plasma membranes and the low-density microsomal membrane fraction in proportion to the number of glucose transporters determined by cytochalasin B binding. Thus, intracellular glucose transporters in the rat adipose cell appear to be 1) localized to a unique membrane species, 2) either compartmentalized in two distinguishable pools or processed during their cycling to the plasma membrane in response to insulin, but fully functional and indistinguishable when reconstituted into liposomes, and 3) immunologically similar to the human erythrocyte glucose transporter.

Non-ohmic proton conductance of mitochondria and liposomes.

Direct measurements of the proton/hydroxyl ion flux across rat liver mitochondria and liposome membranes are reported. H+/OH- fluxes driven by membrane potential (delta psi) showed nonlinear dependence on delta psi both in mitochondria and in liposomes whereas delta pH-driven H+/OH- flux shows linear dependence on delta pH in liposomes. In the presence of low concentrations of a protonophore the H+/OH- flux was linearly dependent on delta psi and showed complex dependence on delta pH. The nonlinearity of H+/OH- permeability without protonophore is described by an integrated Nernst- Plank equation with trapezoidal energy barrier. Permeability coefficients depended on the driving force but were in the range 10(-3) cm/s for mitochondria and 10(-4)-10(-6) cm/s for liposomes. The nonlinear dependence of H+/OH- flux on delta psi explains the nonlinear dependence of electrochemical proton gradient on the rate of electron transport in energy coupling systems.

Measurement of the electrochemical proton gradient in submitochondrial particles.

The pH gradient and membrane potential of submitochondrial particles from bovine heart were estimated by the uptake of [14C]ethylamine and [36Cl]perchlorate, using filtration through a glass fiber prefilter and Millipore filter without washing to separate the vesicles from the medium. An external volume probe of [3H] sucrose was also used. Internal volume of the vesicles was measured by the extent of uptake of glucose, which equilibrates slowly across the membrane. The electrochemical potential gradient of H+ (delta micro H+) calculated from uptake of ethylamine and perchlorate, assuming the ions taken up were free in solution inside the vesicles, was 23 to 24 kJ/mol of H+ (240-250 mV) during respiration in the absence of ATP. The ratio of the free energy of ATP synthesis (delta GATP) to delta micro H+ was 2.2 to 2.3 during oxidative phosphorylation and only slightly higher during ATP hydrolysis indicating that the H+-translocating ATPase is close to equilibrium under both conditions. The nonintegral ratio suggests there is a systematic error in the measurement of delta micro H+. The value of delta micro H+ calculated from ion uptake could be too high if some of the ions taken up are bound to the membrane or concentrated into the electric double layer at the inner membrane-water interface. The effects of vesicle volume (varied osmotically) and permeant ions (which affect internal ionic strength and pH) on the ratio of delta GATP to delta micro H+ suggested that ion association with the membrane in fact caused significant overestimation of delta micro H+. Association of ethylammonium and perchlorate ions with unenergized submitochondrial particles was measured by centrifugation, in the presence of a high concentration of impermeant salt to minimize association with the external surface. The results were used to estimate the extent of binding during the ion uptake assays, and delta micro H+ was recalculated taking this binding into account. The resulting values were between 19 and 20 kJ/mol of H+ (197-207 mV) during respiration in the absence of ADP, and the ratio of delta GATP to delta micro H+ was about 3 during oxidative phosphorylation.

Proton transport by cytochrome c oxidase from the thermophilic bacterium PS3 reconstituted in liposomes.

Cytochrome oxidase from the thermophilic bacterium PS3 which contains three types of polypeptide subunits are reconstituted into liposomes by a freeze-thaw technique. The reconstituted enzyme caused acidification of the medium during cytochrome c oxidation with a stoichiometry of up to 0.8 H+/e. Uptake of K+ ions in the presence of valinomycin occurred with a stoichiometry between 1.5 and 2 K+/e. Dicyclohexylcarbodiimide inhibited the acidification and decreased the stoichiometry of K+ ion uptake to about 1 K+/e. This bacterial oxidase thus appears to be a proton pump with properties similar to the mitochondrial enzyme.

Kinetic properties of the reconstituted glucose transporter from human erythrocytes.

The kinetic parameters of D-glucose transport in liposomes reconstituted with the purified glucose transporter were determined. Net uptake and efflux both had Km values of 0.7 to 1.2 mM and Vmax values of 1.6 mumol/mg of protein/min. Equilibrium exchange had a Km of 35 mM and a Vmax of 50 mumol/mg of protein/min. By separating the liposomes from unreconstituted protein using density centrifugation, the Vmax of exchange was increased to 86 mumol/mg of protein/min, about 3 times that of the erythrocyte membrane. Trypsin, which inhibits erythrocyte glucose transport only from the cytoplasmic side, inhibited reconstituted transport activity about 40% when added externally. With internal treatment as well, the inhibition was about 80%. This suggests that the reconstituted transporter is oriented about equally in both directions. Antibody prepared against the purified transporter inhibits transport to a maximum of about 50%, also indicating a scrambled orientation. External trypsin treatment decreased the Km for uptake and increased the Km for efflux, consistent with asymmetric kinetic parameters for the two faces of the transporter. However, the calculated Km values are lower than those reported for erythrocytes. Phloretin and diethylstilbestrol inhibit the reconstituted transporter. However, they bind to liposomes, producing anomalous results under some experimental conditions. When this binding is taken into account, phloretin inhibits completely and symmetrically. The binding accounts for the apparent asymmetric effects of phloretin reported by others. The inhibitory effects of mercuric ions are consistent with action at two classes of binding sites. Treatment with trypsin increases the sensitivity to Hg2+, indicating that the more sensitive site is on the external face of the transporter.

Binding of cytochalasin B to human erythrocyte glucose transporter.

Cytochalasin B, a potent inhibitor of D-glucose transport systems, binds to the glucose transporter purified from human erythrocytes as described previously [Kasahara, M., & Hinkle, P. C. (1977) J. Biol. Chem. 252, 7384]. The transporter binds 9.2 +/- 1.3 nmol of cytochalasin B/mg of protein with a dissociation constant of 0.18 microM. The binding is competitively inhibited by D-glucose (Ki = 43 mM). Phloretin, diethylstilbestrol, maltose, 6-O-propyl-D-galactose, propyl beta-D-glucopyranoside, and dithiothreitol were also linear competitive inhibitors of cytochalasin B binding. The propyl sugars have been shown to inhibit transport from either the plasma or cytoplasma side of the membrane, respectively. The binding of cytochalasin B to the isolated transporter was inhibited by both propyl sugars.

Immunological identification of the human erythrocyte glucose transporter.

A rabbit antibody against the human erythrocyte glucose transporter was purified by affinity chromatography and used to determine the distribution of transporter on polyacrylamide gels after electrophoresis in sodium dodecyl sulfate. Fresh erythrocyte ghosts showed transporter only at the broad 55,000 Mr band, as did the isolated transporter. HeLa cell plasma membranes showed a similar band of crossreacting material at Mr 55,000. The amount of crossreacting material in human erythrocyte ghosts and in plasma membranes from human HeLa cells and mouse L-1210 cells was determined in an enzyme-linked immunosorbent assay which gave results consistent with the extent of glucose-reversible binding of cytochalasin B.

The phosphorus/oxygen ratio of mitochondrial oxidative phosphorylation.

The transport of ATP out of mitochondria and uptake of ADP and Pi into the matrix are coupled to the uptake of one proton (Klingenberg, M., and Rottenberg, H. (1977) Eur. J. Biochem. 73, 125--130). According to the chemiosmotic hypothesis of oxidative phosphorylation this coupling of nucleotide and Pi transport to proton transport implies that the P/O ratio for the synthesis and transport of ATP to the external medium is less than the P/O ratio for the synthesis of ATP inside mitochondria. A survey of previous determinations of the P/O ratio of intact mitochondria showed little convincing evidence in support of the currently accepted values of 3 with NADH-linked substrates and 2 with succinate. We have measured P/O ratios in rat liver mitochondria by the ADP pulse method and by 32 Pi esterification, measuring oxygen uptake with an oxygen electrode, and find values close to 2 with beta-hydroxybutyrate as substrate and 1.3 with succinate as substrate in the presence of rotenone to inhibit NADH oxidation. These values were largely independent of pH, temperature, Mg2+ ion concentration, Pi concentration, ADP pulse size, or amount of mitochondria used. We suggest that these are the true values of the P/O ratio for ATP synthesis and transport by mitochondria, and that previously reported higher values resulted from errors in the determination of oxygen uptake and the use of substrates which lead to ATP synthesis by succinate thiokinase.