ATP synthesis by myosin during pH-jump

It has been shown that a fast increase in pH of myosin solution leads to ATP formation de novo from ADP and Pi (about one ATP molecule per one myosin molecule). The obligatory condition for ATP synthesis was that the value of pH 7.9-8.0 should be crossed in the course of pH-jump. The data obtained are explained in terms of the concept of conformational relaxation in enzyme catalysis.     

pH-jump-induced ADP phosphorylation in mitochondria

Mitochondria, uncoupled by aging or by freeze-thaw treatment, are able to synthesize ATP from ADP and P_i after a fast increase (but not decrease) in the external pH. The maximal ATP yield (approx. 2.5 ATP molecules / electron-transport chain per pH jump) can be obtained under the following conditions: (1) the pH change during the jump must exceed 0.7 pH units; (2) in the course of this change, the pH of the mitochondrial suspension must cross the pH 8.1–8.3 value. This pH-jump-induced ATP synthesis is completely inhibited by oligomycin.     

Involvement of a non-proton pump factor (possibly Donnan-type equilibrium) in maintenance of an acidic pH in lysosomes.

Change of the internal pH of isolated lysosomes was measured with fluorescein isothiocyanate-dextran. In buffer of pH 7.0, isolated lysosomes had an acidic pH of about 5.5, which decreased to pH 5.2 on addition of ATP. Addition of bafilomycin inhibited the acidification by H(+)-ATPase and resulted in an increase of the internal pH to 5.5 due to passive diffusion of protons across the lysosomal membrane. However, no further alkalization was observed. The acidic pH (pH 5.5) of isolated lysosomes could be maintained for at least 48 h in the absence of ATP, but increased gradually to pH 5.9-6.4 upon incubation with monovalent cations (K+ or Na+), amines, or ionophores. These results suggest that a non-proton pump factor (possibly Donnan equilibrium) is involved in maintaining the acidic pH of isolated lysosomes.     

Uncoupling effect of the general anesthetic 2,6-diisopropylphenol in isolated rat liver mitochondria.

2,6-Diisopropylphenol, a general anesthetic, was previously reported to reduce the transmembrane electrical potential in isolated rat liver mitochondria without affecting the rate of ATP production. This effect appeared to contrast with the generally accepted chemiosmotic mechanism for oxidative phosphorylation. In this study we further examined the influence of 2,6-diisopropylphenol on the production of ATP by isolated mitochondria and we studied its effect on the permeability of the inner mitochondrial membrane to protons. In order to clarify the effects of 2,6-diisopropylphenol on mitochondrial ATP production the activities of the adenine nucleotide translocator and the ATP synthetase were evaluated. The results obtained indicate that the depression of the transmembrane electrical potential elicited by 2,6-diisopropylphenol decreased the activity of the ATP synthetase (as expected in the chemiosmotic model for energy coupling), but not that of the adenine nucleotide translocator. The decrease of the ATP synthetase activity, however, did not result in an apparent inhibition of the overall rate of ATP production in isolated mitochondria due to the rate-limiting effect of the adenine nucleotide translocator in this process. Moreover 2,6-diisopropylphenol was found to increase the permeability to protons of the inner mitochondrial membrane; this effect became more marked as the pH of the incubation medium was increased, demonstrating that it involved the dissociated form of 2,6-diisopropylphenol. These observations suggested that 2,6-diisopropylphenol affected oxidative phosphorylation by acting as a mild protonophore and that its effectiveness was limited by the low fraction of phenol dissociated at near-physiological pH.     

Variable stoichiometry in reconstituted shark Na,K-ATPase engaged in uncoupled efflux

In liposomes with reconstituted shark Na,K-ATPase produced to contain no internal K+ or Na+ addition of external Na+ and ATP induce an uncoupled Na+ efflux on inside-out oriented pumps which is electrogenic and accompanied by hydrolysis of ATP (Cornelius, F. (1989) Biochem. Biophys. Res. Commun. 160, 801-807). At saturating cytoplasmic Na+ the net-charge translocated per ATP molecule split is compatible with a coupling ratio of Nacyt transported per ATP split of 3:1 at pH greater than or equal to 7.0. However, this ratio decreases to 1.5:1 below pH 7.0. At non-saturating cytoplasmic Na+ the 3:1 stoichiometry is attained at pH 7.0-7.5, whereas outside this range of pH the net-charge translocated per ATP molecule split decreases.     

The plasma membrane H(+)-ATPase from yeast. Effects of pH, vanadate and erythrosine B on ATP hydrolysis and ATP binding.

The H(+)-ATPase from the plasma membrane of Saccharomyces cerevisiae was isolated and purified. The rate of ATP hydrolysis and ATP binding was measured as a function of pH and the effect of the vanadate and erythrosine B inhibitors was investigated. The pH dependence of the rate of ATP hydrolysis forms a bell-shaped curve with a maximum at pH 6 and half-maximal rates at pH 5.0 and 7.4. Only the pH dependence between pH 6 and pH 7.6 is reversible. Above pH 7.6 and below pH 5.5, denaturation of the isolated enzyme is observed. The rate of ATP binding shows the same pH dependency as that of ATP hydrolysis. Both pH dependencies can be described by the dissociation of a monovalent acidic group with a pK of 7.4. It is concluded that the enzyme must be protonated before ATP binding. Vanadate does not inhibit ATP binding, ADP release or Pi release at concentrations where complete inhibition of ATP hydrolysis is observed. It is concluded that vanadate inhibits a step of the reaction cycle which occurs after Pi release. In contrast, erythrosine B inhibits ATP binding and thus affects the first step of the reaction cycle.     

Photophosphorylation associated with synchronous turnovers of the electron-transport carriers in chloroplasts

Two saturating single-turnover flashes spaced 100 ms apart are sufficient to achieve ATP formation in isolated chloroplast thylakoids. Two turnovers of the electron carriers result in the accumulation of about 7 nmol H⁺ / mg chlorophyll. Under the same conditions (i.e., ΔG_ATP = 38 kJ/mol) a solitary flash is inadequate to produce ATP. The electron flux from the third or any subsequent flash is coupled to ATP formation as efficiently as is observed in continuous light (i.e., ) and produces 0.8 molecules of ATP per coupling factor on each turnover. The yield of ATP per flash increases with declining temperature being largest near 4°C, the lowest value tested. The number of H⁺ accumulated per flash is independent of temperature so the greater yields of ATP near 4°C indicate that fewer H⁺ are existing the membrane via nonproductive pathways. The yield of ATP per flash near 4°C is largely independent of flash frequency between 1 and 30 Hz. When the formation of an electrical potential difference is prevented by adequate amounts of valinomycin and potassium the accumulated effects of about eight flashes are required before ATP formation is achieved (i.e., about 26 nmol H⁺/mg chlorophyll), indicating an average ΔpH/flash in excess of 0.3 units. In the presence of the exchange carrier nigericin, the electrical component of the driving force for ATP formation is enhanced at the expense of the ΔpH. In this case, ATP formation is efficiently coupled to electron flux only at flash frequencies rapid enough to allow a summation of the electrical field. These results clearly demonstrate that any processes which are prerequisites for ATP synthesis (i.e., activation of coupling factor or generation of Δp) are fulfilled by a remarkably small number of charge separations.     

The involvement of stromal ATP in maintaining the pH gradient across the chloroplast envelope in the light

The possible involvement of ATP in maintaining the pH gradient across the chloroplast envelope membrane was investigated by simultaneously measuring the stromal ATP concentration and the pH of the stroma and intrathylakoid spaces in intact isolated chloroplasts. Addition of exogenous ATP in the dark increased stromal pH by 0.3–0.4 pH units and increased the pH gradient across the thylakoid membrane by a similar amount. In the dark, dihydroxyacetone phosphate plus oxaloacetate increased stromal ATP to levels equal to those obtained in illuminated chloroplasts, but stromal pH was only increased by 0.1–0.3 pH units compared to an increase of 0.8–1.0 units in the light. The energy-transfer inhibitor, phlorizin, decreased stromal ATP in illuminated chloroplasts almost to dark levels, but did not decrease stromal pH. Inorganic pyrophosphate and an analog of ATP were used to exchange endogenous adenine nucleotides out of chloroplasts, and this also decreased the stromal ATP to dark levels without decreasing stromal pH in the light. Addition of 15–20 μM 3-(3′,4′-dichlorophenyl)-1,1-dimethylurea (DCMU) reduced both the stromal pH and ATP content of illuminated chloroplasts to dark levels but lower concentrations of DCMU preferentially decreased stromal pH. It is concluded that the pH gradient across the chloroplast envelope is unlikely to be maintained by an electrogenic proton pump driven by ATP hydrolysis. Photosynthetic electron transport is required to maintain the pH gradients across both the chloroplast thylakoid and chloroplast envelope membranes.     

Ligand-modulation of the stability of the glucose transporter GLUT 1

The glucose transporter GLUT 1 was isolated from human erythrocytes and reconstituted into endogenous membrane lipids. Results from thermal denaturation studies, using differential scanning calorimetry, indicate that the thermal denaturation temperature of GLUT 1 is significantly lower in the presence of ATP. The lowering of this transition temperature is very dependent on pH. At more acidic pH, ATP has a greater effect of lowering the thermal denaturation temperature of the protein. For example, with 4.8 mM ATP, the denaturation endotherm is lowered by over 10 degrees at pH 4.3, whereas at pH 7.4, ATP does not alter this transition temperature. However, a change in pH alone, in the absence of ATP, has very little effect on the denaturation temperature. Both glucose and salt partially reverse the lowering of the temperature of thermal denaturation caused by ATP. Studies of acrylamide quenching of the Trp residues of GLUT 1 indicate that at neutral pH, ATP increases the Stern-Volmer quenching constant, while glucose lowers it. The results indicate that ATP binds to GLUT 1 and destabilizes the native structure, leading to a lowering of the thermal denaturation temperature and an increase in acrylamide quenching. The effects of ATP are reversed in part by glucose and are also partly electrostatic in nature.     

Properties of phosphoribulokinase from Thiobacillus neapolitanus

Partially purified preparations of ribulose-5-phosphate kinase (specific activity, 50 to 125 mumoles per min per mg of protein) were employed in a series of kinetic experiments in the presence of several concentrations of H(+), Mg(2+), adenosine triphosphate (ATP), and phosphoenolpyruvate (PEP). The pH optimum of the enzyme was found to be 7.9; at this pH and above, response of the enzyme to variations in ATP concentration was hyperbolic, exhibiting a K(m) of 7 x 10(-4)m ATP. At pH values below the optimum the response to ATP was sigmoidal, as it was throughout the entire pH range in the presence of PEP at a concentration greater than 5 x 10(-4)m. In the presence of PEP the pH optimum shifted to pH 8.4. In contrast, phosphoribulokinase from spinach exhibited hyperbolic responses throughout its pH range with no inhibition caused by PEP. Thiobacillus neapolitanus phosphoribulokinase was inhibited by PEP in a sigmoidal manner; however, in the presence of suboptimal concentrations of Mg(2+) the addition of PEP caused significant stimulation of activity. It is postulated that the enzyme consists of interacting subunits with several sites on the enzyme for binding ATP and with several separate sites binding PEP. It is suggested that PEP functions as a regulator of CO(2) fixation when the organism is under conditions of unlimited concentrations of substrate and CO(2).     

On the mechanisms of ATP-induced and succinate-induced redistribution of cations in isolated rat liver cells

1. The ability of external ATP to induce calcium uptake in isolated rat liver cells was further characterized. Stimulation of calcium uptake was specific for ATP, other nucleotides or ATP metabolites had no comparable effect. ATP was dephosphorylated while stimulating calcium uptake, but there was no stoichiometry between ATP hydrolysis and calcium uptake nor did dephosphorylation depend on calcium concentration. ATP acted from outside and was dephosphorylated by an ecto-ATPase of the cells. 2. In addition to its direct action, ATP enhanced succinate-dependent calcium uptake in a cooperative fashion. This is best explained by different sites of action. ATP increases cell membrane permeability while succinate stimulates uptake into mitochondria. 3. ATP was able to lower Na+ and K+ gradients and the pH gradient between cells and incubation medium. Increasing calcium concentration counteracted this effect though calcium uptake was then stimulated. 4. Succinate alone did not affect monovalent cation gradients but raised the pH gradient. It partially counteracted the ATP effects on these gradients. 5. Since catecholamine-like actions of ATP may be mediated by an increase in cytoplasmic calcium concentration, the action of extracellular ATP can be taken as a model to study the role of calcium as a transmitter of hormone actions. From interdependence between ATP-stimulated and succinate-stimulated calcium uptake, conclusions can be drawn on the resulting cytoplasmic calcium concentration and its effect on plasma membrane permeability.     

Purification and properties of adductor muscle phosphofructokinase from the oyster, Crassostrea virginica. The aerobic/anaerobic transition: role of arginine phosphate in enzyme control.

Phosphofructokinase from oyster (Crassostrea virginica) adductor muscle occurs in a single electrophorectic form at an activity of 8.1 mumol of product formed per minute per gram wet weight. The enzyme was purified to homogeneity by a novel method involving extraction in dilute ethanol and subsequent precipitation with polyethylene glycol. Oyster adductor phosphofructokinase has a molecular weight of 3400000 +/- 20000 as measured by Sephadex gel chromatography. Mg2+ or Mn2+ can satisfy the divalent ion requirement while ATP, GTP, or ITP can serve as phosphate donors for the reaction. Oyster adductor phosphofructokinase displays hyperbolic saturation kinetics with respect to all substrates (fructose 6-phosphate, ATP, and Mg2+) at either pH 7.9 OR PH 6.8. The Michaelis constant for fructose 6 phosphate at pH 6.8, the cellular pH of anoxic oyster tissues, is 3.5 mM. In the presence of AMP, by far the most potent activator and deinhibitor of the enzyme, this drops to 0.70 mM. Many traditional effectors of phosphofructokinase including citrate, NAD(P)H,Ca2+, fructose 1,6-bisphosphate, 3-phosphoglycerate, ADP, and phosphoenolpyruvate do not alter enzyme activity when tested at their physiological concentrations. Monovalent ions (K +, NH4+) are activators of the enzyme. ATP and arginine phosphate are the only compounds found to inhibit the adductor enzyme. The inhibitory action of both can be reversed by physiological concentrations of AMP(0.2- 1.0mM) and to a lesser extent by high concentrations of Pi (20 mM) and adenosine 3' :5'-monophosphate (0.1 mM). The two inhibitors exhibit very different pH versus inhibition profiles. The Ki (ATP) decreases from 5.0 mM to 1.3 mM as the pH decreases from 7.9 to 6.8, whereas the Ki for arginine phosphate increases from 1.3 mM to 4.5 mM for the same pH drop. Of all compounds tested, only AMP, within its physiological range, activated adductor phosphofructokinase significantly at low pH values. The kinetic data support the proposal that arginine phosphate, not ATP or citrate, is the most likely regulator of adductor phosphofructokinase in vivo under aerobic, high tissue pH, conditions. In anoxia, the depletion of arginine phosphate reserves and the increase in AMP concentrations in the tissue, coupled with the increase in the Ki for arginine phosphate brought about by low pH conditions, serves to activate phosphofructokinase to aid maintenance of anaerobic energy production.     

Postillumination adenosine triphosphate synthesis in Rhodospirillum rubrum chromatophores. I. Conditions for maximal yields.

The very low level of postillumination ATP synthesis in chromatophores was markedly stimulated when permeant anions (thiocyanate or perchlorate) or permeant cations (potassium in the presence of valinomycin) were added to the light stage. Although these compounds stimulated also light-induced proton uptake in chromatophores the pH dependence of both photoreactions was different. Proton uptake peaked at pH 6.5 while the amount of postillumination ATP was maximal when the light stage was carried out around pH 7.7. The increased yield of ATP at the more alkaline pH could not be explained by a slower decay of the high energy state at this pH, since the decay rate was faster at pH 7.7 than at pH 6.5. The proton concentration gradient which is maintained across the chromatophore membrane in the light was also found to increase when the external pH was raised from 6.0 to 8.0. Only a minimal amount of postillumination ATP was formed when this gradient was below 2.1 pH units, but above this value the ATP yield rose steeply as a function of the increasing pH gradient. In light of these results it is suggested that in order to obtain a high yield of postillumination ATP synthesis in chromatophores two conditions are required: the particles have to be loaded with a sufficient number of protons and a light-induced pH gradient above a certain threshold value has to be maintained across their membrane. The low yield of postillumination ATP in chromatophores and the increase obtained by adding permeating ions, is thus explained by similar variations in the extent of the pH gradient, which exceeded the threshold value only in the presence of the permeating ions.     

Influence of the redox state and the activation of the chloroplast ATP synthase on proton-transport-coupled ATP synthesis/hydrolysis

The membrane-bound ATP synthase from chloroplasts can occur in different redox and activation states. In the absence of reductants the enzyme usually is oxidized and inactive, E^ox_i. Illumination in the presence of dithiothreitol leads to an active, reduced enzyme, E^red_a. If this form is stored in the dark in the presence of dithiothreitol an inactive, reduced enzyme E^red_i is formed. The rates of ATP synthesis and ATP hydrolysis catalyzed by the different enzyme species are measured as a function of ΔpH (Δψ = 0 mV). The ΔpH was generated with an acid-base transition using a rapid-mixing quenched flow apparatus. The following results were obtained. (1) The oxidized ATP synthase catalyzes high rates of ATP synthesis, v^ox_max = 400 ATP per CF₀F₁ per s. The half-maximal rate is obtained at ΔpH = 3.4. (2) The active, reduced ATP synthase catalyzes high rates of ATP synthesis, v^red_max = 400 ATP per CF₀F₁ per s. The half-maximal rate is obtained at ΔpH = 2.7. It catalyzes also high rates of ATP hydrolysis v^red_max = −90 ATP per CF₀F per s at ΔpH = 0. (3) The inactive species (both oxidized and reduced) catalyze neither ATP synthesis nor ATP hydrolysis. The activation/inactivation of the reduced enzyme is completely reversible. (4) The activation of the reduced, inactive enzyme is measured as a function of ΔpH by measuring the rate of ATP hydrolysis catalyzed by the active species. Half-maximal activation is observed at ΔpH = 2.2. (5) On the basis of these results a reaction scheme is proposed relating the redox reaction, the activation and the catalytic reaction of the chloroplast ATP synthase.     

Determination of the free-energy coupling between ATP and an affinity label attached to rabbit muscle phosphofructokinase

The smallest enzymatically active form of rabbit muscle phosphofructokinase is a tetramer of four identical or nearly identical monomers. The enzyme is inhibited by ATP, and this inhibition by ATP is relieved by the activating adenine nucleotides adenosine cyclic 3',5'-phosphate, AMP, and ADP. Each monomer contains one binding site specific for the inhibitor ATP and another site specific for the activating adenine nucleotides. The enzyme can also be activated by covalently labeling the activating adenine nucleotide binding sites with the affinity label 5'-[p-(fluorosulfonyl)benzoyl]adenosine. These activator binding sites on the enzyme have been covalently labeled to various degrees, ranging from an average value of less than one label per tetramer to four labels per tetramer, and the free-energy coupling, delta Gxy, between the covalently bound affinity label and ATP binding at the inhibitory site was determined. For enzyme preparations containing four labels per tetramer, delta Gxy is approximately 1 kcal/mol at pH 6.95 and 25 degrees C. A very significant free-energy coupling is observed in those preparations containing an average of one label per tetramer and less, and the change in delta Gxy in going from native tetramers to ones containing an average of two labels per tetramer is twice as great as the change in delta Gxy observed in going from tetramers containing an average of two labels per tetramer to ones containing four labels per tetramer, suggesting that modification of the final two monomers in the tetramer contributes much less to the antagonistic effect on ATP binding than does modification of the first two monomers in the tetramer.     

Interconversion of two distinct states of active CF0-CF1 (chloroplast ATPase complex) in chloroplasts

Chloroplast ATPase complex is activated by illumination in the presence or absence of dithiothreitol. ATPase complex which has been activated without dithiothreitol catalyzes ATP hydrolysis which is insensitive to stimulation by NH4Cl and is highly sensitive to medium pH. Addition of dithiothreitol during illumination results in an increase in the stimulating effect of NH4Cl on ATP hydrolysis and a decrease in pH sensitivity of ATP hydrolysis. With increasing time in the dark, the ability of NH4Cl to stimulate ATP hydrolysis decreases and the effect of pH on the ATP hydrolysis increases. The onset of resistance to NH4Cl stimulation and the increase in sensitivity to pH are accelerated by ADP and the acceleration is inhibited by Pi. ATP hydrolysis restores NH4Cl sensitivity and renders the activity more resistant to pH. These results suggest that active chloroplast ATPase complex converts its state reversibly from the NH4Cl-insensitive and highly pH-sensitive one to the NH4Cl-sensitive and relatively pH-insensitive one. The conversion from the former to the latter requires both sulfhydryl compound and energy.     

Adenine nucleotide transport in sonic submitochondrial particles. Kinetic properties and binding of specific inhibitors.

1. A procedure for preparation of sonic submitochondrial particles competent for adenine nucleotide transport is described. ADP or ATP transport was assayed, in the presence of oligomycin, in a saline medium made of 0.125 M KCl, 1 mM EDTA, 10 mM 4-morpholinopropane sulfonic acid buffer, pH 6.5. 2. Sonic particles transport ADP and ATP by an exchange diffusion process. Externally added ADP (or ATP) is exchanged with internal ADP and ATP with a stoichiometry of one to one. The V value for ADP transport 5 degrees C was between 2 and 3 nmol/min per mg protein. 3. The transport system in sonic particles is specific for ADP and ATP. It is strongly dependent on temperature. The activation energy between 0 and 9 degrees C is approx. 35 kcal/mol. The optimum pH is 6.5, 4, Like in intact mitochondria, externally added ADP is transported into sonic particles faster at a given concentration than externally added ATP. The V value for ADP transport is 1.5-2 times higher than the V value for ATP transport. 5. The transition from the energized to the deenergized state in sonic particles results in a decrease of the pH gradient across the membrane (internal pH less than external pH) and in a 2-4 fold increase in the Km value for ATP. This latter effect is opposite that found for transport of added ATP in intact mitochondria (Souverijn, J.H.M., Huisman, L.A., Rosing J. and Kemp, Jr., A. (1973) Biochim. Biophys. Acta 305, 185-198). Energization has no effect on the V value of ATP transport in sonic particles. 6. In contrast to intact mitochondria, inhibition of ADP transport in sonic particles by bongkrekic acid does not have any lag-time and does not depend on pH. The inhibition caused by bongkrekic acid is a mixed type inhibition with a Ki value of 1.2 micronM. Atractyloside and carboxyatractyloside do not inhibit ADP transport in sonic particles, unless the particles have been preloaded with these inhibitors during the sonication. 7. Palmityl-CoA added to sonic particles inhibits efficiently ADP transport. The mixed type inhibition found with palmityl-CoA has a Ki value of 1.6 micronM. 8. [3H]Bongkrekic acid binds to sonic particles readily and with high affinity. Bongkrekic acic binding to sonic particles does not depend on pH and it has a saturation plateau, corresponding approximately to 1.3 mol of site per mol of cytochrome a. The number of [3H]atracytloside binding sites is much lower (one-fifth of the bongkrekic acid). External carboxyatractyloside does not compete with [3H]bongkrekic acid for binding to sonic particles. However, when carboxyatractyloside is present inside the particles, it inhibits the binding of [3H]bongkrekic acid.     

Factors affecting the development of the capacity for ATP formation in isolated chloroplasts

Full development of the capacity for ATP formation in isolated thylakoid membranes coincides with the beginning of illumination. Indeed, the yield of ATP per ms of illumination is about twice as great during the first 15 ms of high-intensity illumination as it is thereafter. The presence of valinomycin and K⁺ prevents the formation of a membrane potential (as indicated by the obliteration of most of the change in absorbance at 518 nm) and at the same time delays the formation of the capacity for ATP synthesis for many milliseconds. Presumably, phosphorylation is initially dependent on a rapidly formed membrane potential, whereas after a delay a ΔpH sufficient to drive ATP formation forms. The actual duration of this delay depends on the phosphoryl group transfer potential (i.e., ΔG_ATP) of the ATP-synthesizing reaction. If the delay in the presence of valinomycin and K⁺ represents the time required to develop a ΔpH capable of driving phosphorylation by itself, then the effect of ΔG_ATP on the duration of the delay suggests that the onset of phosphorylation is determined by the magnitude of the electrochemical potential of protons and not by factors affecting the activation of the coupling factor enzyme. The initial ATP formation, which is almost entirely dependent on the electrical potential, should not be affected by the electrically neutral exchange of cations catalyzed by nigericin. When the external pH is 7.0 this seems to be true, since the ATP synthesis which is initially sensitive to valinomycin and K⁺ is largely insensitive to nigericin and K⁺. However, when the external pH is 8.0 the response to nigericin is exactly the opposite and the ATP formation which is sensitive to valinomycin is also abolished by nigericin. These data suggest that there may be either an energetic requirement for both a ΔpH and membrane potential at alkaline pH or a non-energetic requirement for a minimum proton activity in the initiation of phosphorylation.     

Quantitative analysis of the kinetics of end-dependent disassembly of RecA filaments from ssDNA.

On linear single-stranded DNA, RecA filaments assemble and disassemble in the 5' to 3' direction. Monomers (or other units) associate at one end and dissociate from the other. ATP hydrolysis occurs throughout the filament. Dissociation can result when ATP is hydrolyzed by the monomer at the disassembly end. We have developed a comprehensive model for the end-dependent filament disassembly process. The model accounts not only for disassembly, but also for the limited reassembly that occurs as DNA is vacated by disassembling filaments. The overall process can be monitored quantitatively by following the resulting decline in DNA-dependent ATP hydrolysis. The rate of disassembly is highly pH dependent, being negligible at pH 6 and reaching a maximum at pH values above 7. 5. The rate of disassembly is not significantly affected by the concentration of free RecA protein within the experimental uncertainty. For filaments on single-stranded DNA, the monomer kcat for ATP hydrolysis is 30 min-1, and disassembly proceeds at a maximum rate of 60-70 monomers per minute per filament end. The latter rate is that predicted if the ATP hydrolytic cycles of adjacent monomers are not coupled in any way.     

Enzymatic activities and ATP-induced fluorescence enhancement of myosin from fast and slow skeletal and cardiac muscles.

The maximal ATP-induced enhancement of fluorescence and the dependence of this enhancement on ATP concentration were determined for myosins from fast and slow skeletal and cardiac muscle of the rabbit. With myosins from slow and cardiac muscle modifications in the preparative procedure and chromatography on DEAE-Sephadex were required to obtain preprations which were free of actin, which exhibited the maximal fluorescence enhancement and which bound two moles of ATP per mole of myosin. Since the fluorescence enhancement of cardiac and slow muscle myosins is labile at slightly alkaline pH, it was also necessary to minimize incubation at pH greater than 7 in order to attain the maximal enhancement. With fast muscle myosin the changes in preparative procedure, together with chromatography, led to a 50 to 100% increase in the steady-state rate of ATP hydrolysis and fluorescence enhancement, without changing the maximal binding of ATP. From a comparison of the rate of steady-state hydrolysis of ATP with the rate of decay of the enhanced fluorescence, it appears that for all three myosins, both ATP binding sites have the same enzymatic activity, the steady-state rate per site being slower for cardiac and slow muscle myosins than for fast muscle myosin.