Role of intramitochondrial pH in the energetics and regulation of mitochondrial oxidative phosphorylation.

The dependence of ATP synthesis coupled to electron transfer from 3-hydroxy-butyrate (3-OH-B) to cytochrome c on the intramitochondrial pH (pHi) was investigated. Suspensions of isolated rat liver mitochondria were incubated at constant extramitochondrial pH (pHe) with ATP, ADP, Pi, 3-OH-B, and acetoacetate (acac) (the last two were varied to maintain [3-OH-B]/[acac] constant), with or without sodium propionate to change the intramitochondrial pH. Measurements were made of the steady-state water volume of the mitochondrial matrix, transmembrane pH difference, level of cytochrome c reduction, concentration of metabolites and rate of oxygen consumption. For each experiment, conditions were used for which transmembrane pH was near maximal and minimal values and the measured extramitochondrial [ATP], [ADP], and [Pi] were used to calculate log[ATP]/[ADP][Pi]. When [3-OH-B]/[acac] and [cyt c2+]/[cyt c3+] were constant, and pHi was decreased from approx. 7.7 to 7.2, log [ATP]/[ADP][Pi] at high pHi was significantly (P less than 0.02) greater than at low pHi. The mean slope (delta log [ATP]/[ADP][Pi] divided by the change in pHi) was 1.08 +/- 0.15 (mean +/- S.E.). This agrees with the slope of 1.0 predicted if the energy available for ATP synthesis is dependent upon the pH at which 3-hydroxybutyrate dehydrogenase operates, that is, on the pH of the matrix space. The steady-state respiratory rate and reduction of cytochrome c were measured at different pHi and pHe values. Plots of respiratory rate vs.% cytochrome c reduction at different intra- and extramitochondrial pH values indicated that the respiratory rate is dependent upon pHi and not on pHe. This implies that the matrix space is the source of protons involved in the reduction of oxygen to water in coupled mitochondria.     

Kinetics of Pi-Pi exchange in rat liver mitochondria. Rapid filtration experiments in the millisecond time range

Phosphate-phosphate exchange through the inorganic phosphate (Pi) carrier of rat liver mitochondria was investigated by a new rapid filtration technique, which does not require the use of transport inhibitors to stop the reaction and offers high time resolution (starting from 10 ms), thus allowing kinetic measurements on a fine time scale even at room temperature. At approximately 22 degrees C, isotopic equilibrium of [32P]Pi is achieved within 0.8-2.5 s--depending on the Pi concentration--and an initial linear phase, lasting for 400-500 ms, is observed. Complete inhibition of Pi exchange by an excess (33 nmol/mg) of mersalyl, a well-known organomercurial inhibitor, required 200 ms, pointing to the insufficiency of this reagent for effective inhibitor stop. On the other hand, investigation of the effect of mersalyl (allowed to react with mitochondria for at least 20 s) on the initial rate of Pi exchange supports earlier observations on the protective effect of this inhibitor; i.e., up to 3 nmol of mersalyl/mg of protein does not decrease the transport rate whereas these low concentrations protect approximately 50% of the transport capacity from irreversible inactivation by N-ethylmaleimide. In nonrespiring mitochondria, at pH 7.3, Pi exchange exhibited a Km of 1.6 mM and a Vmax of 3.0 mumol min-1 (mg of mitochondrial protein)-1. The increase of the membrane potential without any concomitant change of delta pH had no significant influence on the kinetic parameters. The maximal velocity of Pi transport is significantly higher than the maximal velocity of all the other components of oxidative phosphorylation at comparable temperatures. The possible physiological significance of this excess capacity is discussed.     

Intravesicular pH changes in submitochondrial particles induced by monovalent cations: relationship to the Na+/H+ and K+/H+ antiporters

The fluorescence of internalized fluorescein isothiocyanate dextran has been used to monitor the intravesicular pH of submitochondrial particles (SMP). Respiring SMP maintain a steady-state delta pH (interior acid) that results from the inwardly directed H+ flux of respiration and an opposing passive H+ leak. Addition of K+, Na+, or Li+ to SMP results in a shift to a more alkaline interior pH (pHi) in both respiring and nonrespiring SMP. The K+-dependent change in pHi, like the K+/H+ antiport in intact mitochondria, is inhibited by quinine and by dicyclohexylcarbodiimide. The Na+-dependent reaction is only partially inhibited by these reagents. Both the Na+- and the K+-dependent pH changes are sensitive to amiloride derivatives. The Km for both Na+ and K+ is near 20 mM whereas that for Li+ is closer to 10 mM. The K+/H+ exchange reaction is only slightly inhibited by added Mg2+, but abolished when A23187 is added with Mg2+. The passive exchange is optimal at pHi 6.5 with either Na+ or K+, and cannot be detected above pHi of 7.2. Both the Na+/H+ and the K+/H+ exchange reactions are optimal at an external pH of 7.8 in respiring SMP (pHi 7.1). Valinomycin stimulates the K+-dependent pH change in nonrespiring SMP, as does nigericin. It is concluded that SMP show K+/H+ antiport activity with properties distinct from those of Na+/H+ antiport. However, the properties of the K+/H+ exchange do not correspond in all respects to those of the antiport in intact mitochondria. Donnan equilibria and parallel uniport pathways for H+ and cations appear to contribute to cation-dependent pH changes in SMP.     

Reconstruction of steady state in cell-free systems. Interactions between glycolysis and mitochondrial metabolism: regulation of the redox and phosphorylation states

A reconstituted "open" system comprising respiring mitochondria and actively glycolyzing muscle extract was devised for studies of vectorially mediated interactions. Glycogen particles were the substrate for the glycolyzing enzymes. Purified soluble (F1) ATPase was added in varying quantities to establish a range of energetic steady states. The data generally confirm our recent conclusions (Wu and Davis, (1981) Arch. Biochem. Biophys. 208, 85-89) on the relative efficacy of the adenine nucleotides and their ratios, and of inorganic phosphate on flux through rate-controlling steps of glycolysis. When mitochondrial ATP synthesis was blocked, glycolytic flux was relatively rapid, and the lactate/pyruvate ratio increased with time to values up to greater than 300. If functional mitochondria were present, glycolytic flux was very strongly suppressed, provided the energy state (ATP/ADP) was high, and the phosphate concentration[Pi] was low. Adenine nucleotide control of glycolysis was to a large extent lost when the steady-state ATP/ADP was below about 10, or if [Pi] was elevated. In the two-phase system containing respiring mitochondria and components of the malate-aspartate shuttle, the ATP/ADP and both extra- and intramitochondrial NAD+/NADH ratios were maintained constant, and to various perturbable levels with varying energy load (ATPase). The gradient in reduction potentials attained values (delta Gredox) of up to about 2.5 kcal. The extramitochondrial redox state was not positively correlated with the external phosphorylation potential ([ATP]/[ADP] X [Pi]). The following conclusions are drawn on the basis of the present data, together with other reports (Davis, Bremer, and Akerman (1980) J. Biol. Chem. 255, 2277-2283) and (Klingenberg and Rottenberg (1977) Eur. J. Biochem. 73, 125-130): (a) the gradient in reduction potential is driven by the membrane potential (delta psi), mediated by the electrogenic glutamate-aspartate exchange, and the poise or set point of this gradient is a function of delta psi; and (b) the gradient of ATP/ADP ratios across the membrane is also driven principally by delta psi, mediated by the electrogenic ATP-ADP exchange. Hence, segregation of phosphorylation and reduction potentials is linked through a mutually shared electrical driving force.     

Estimation of the pH gradient and donnan potential in de-energized heart mitochondria

The transmembrane pH gradient maintained by nonrespiring, uncoupled heart mitochondria has been estimated using the distribution of methylamine and of 5,5-dimethyl-2,4-oxazolidinedione (DMO) and compared with the delta pH reported by the fluorescent probe 2,7-biscarboxyethyl-5(6)-carboxyfluorescein (BCECF). Under these conditions the protonmotive force approaches zero and the membrane potential (delta psi) should equal 59 delta pH (P. Mitchell and J. Moyle (1969) Eur. J. Biochem. 7, 471-484). The delta pH reported by DMO corresponds closely to that estimated by BCECF and is consistent with a Donnan potential of no greater than about -30 mV (interior negative) for nonenergized mitochondria in a sucrose medium. This potential appears to result from the presence of immobile negative charges in the matrix and is eliminated by addition of 10 to 25 mM KCl. Measurements of delta pH using the methylamine and of delta tsi using the distribution of 42K+ in the presence of valinomycin result in an apparent overestimation of these parameters due to binding of these components to negative sites on the membrane. Increasing ionic strength decreases this contribution of surface potential, but significant binding can still be detected in 100 mM KCl. These studies suggest that 42K+ (or 86Rb+) is far from an ideal probe for measuring delta tsi in respiring mitochondria and may significantly overestimate this parameter, especially in sucrose media.     

Special features of Pi transport in pig heart and rat liver mitochondria as revealed by 6,6'-dithiodinicotinic acid (CPDS).

CPDS (6,6'-dithiodinicotinic acid), a non permeant thiol agent which affects several mitochondrial functions in a way different to that of mersalyl [18-19] revealed striking differences between the phosphate translocating systems of pig heart and rat liver mitochondria. Pi entry was measured either by swelling in 0.12 M ammonium phosphate or by rapid centrifugation in 32Pi medium. Pi efflux was measured after preloading of mitochondria with 32Pi, by exchange against Pi or malate; the "ATP-FCCP" system has been tested previously [19]. In pig heart mitochondria, Pi entry seems to proceed exclusively via the Pi/OH- carrier; CPDS completely inhibits this transport and the energy-linked functions. In contrast n-butyl-malonate does not affect the Pi-entry and the energy-linked functions. The Pi efflux is not affected either by CPDS or mersalyl, which do not produce a swelling in the "ATP-uncoupler system". In rat liver mitochondria, CPDS inhibits only the Pi/OH- carrier; both CPDS and n-butylmalonate are necessary to inhibit completely Pi entry. CPDS as well as mersalyl provokes a swelling in the presence of the "APT-uncoupler system". The results suggest two distinct functions of phosphate transport in both types of mitochondria.     

The ATP-Mg/Pi carrier of rat liver mitochondria catalyzes a divalent electroneutral exchange.

Net transport of ATP-Mg or ADP in exchange for phosphate in isolated rat liver mitochondria has been shown to be an electroneutral process mediated by the ATP-Mg/Pi carrier. We compared the steady state distribution ratios of phosphate, ATP-Mg, and ADP at a pH of 7.4 to determine whether the divalent or monovalent form of these anions is the transported substrate. The log of the divalent ATP-Mg distribution ratio (in/out) approached the log of the divalent phosphate distribution ratio (approximately 0.85), which was approximately twice the value of the delta pH (approximately 0.40) across the inner mitochondrial membrane. This steady state relationship held under several different conditions, e.g. when the medium ATP concentration was varied or if the phosphate gradient was modified by partial uncoupling with the proton ionophore, carbonyl cyanide p-trifluoromethoxyphenylhydrazone. Unidirectional ADP efflux in exchange for external ADP or ATP-Mg was stimulated by an increase in matrix H+. The log of the trivalent ADP distribution ratio (approximately 1.20) approached 3 times the value of delta pH. All these data are consistent with the model of an electroneutral exchange of divalent phosphate (HPO2-4) for divalent ATP-Mg (ATP-Mg2-) or for divalent protonated ADP (HADP2-). We conclude that this transport mechanism accounts for the adenine nucleotide concentration gradient that normally exists between the matrix and external medium.     

A novel method to differentiate between ping-pong and simultaneous exchange kinetics and its application to the anion exchanger of the HL60 cell.

We have developed a new test to differentiate between ping-pong and simultaneous mechanisms for tightly coupled anion exchange. This test requires the use of a dead-end reversible noncompetitive inhibitor. As an example, we have applied the test to the anion exchanger of the HL60 cell using the salicylic acid derivative 3,5-diiodosalicylic acid (DIS), which reversibly inhibits HL60 cell Cl/Cl exchange. The concentration of DIS that causes 50% inhibition (ID50) increased only slightly as either intra- or extracellular chloride was increased, indicating that DIS inhibits HL60 anion exchange in a noncompetitive manner. In agreement with this observation, plots of the slope of the Dixon plot as a function of 1/[Clo] or 1/[Cli] were fit with straight lines with nonzero intercepts, indicating that DIS does not compete with either of the substrates ([Clo] and [Cli]). The secondary Dixon slope test is based on the fact that, for a dead-end inhibitor such as DIS, the slope of the Dixon plot slope vs. 1/[Cli] (secondary Dixon slope or SDS) is independent of extracellular Cl when the exchange mechanism follows ping-pong kinetics. Similarly, the SDS calculated from a plot as a function of 1/[Clo] is also independent of intracellular Cl for a ping-pong exchanger. In contrast to this prediction, we found that for DIS inhibition of Cl/Cl exchange in HL60 cells the slope of the Dixon plot slope vs. 1/[Cli] decreased by a factor of 2.5-fold when [Clo] was increased from 1 to 11 mM (P < 0.0001). This change in the SDS rules out ping-pong kinetics, but is consistent with a simultaneous model of Cl/Cl exchange in which there are extra- and intracellular anion binding sites, both of which must be occupied by suitable anions in order to allow simultaneous exchange of the ions.     

Ornithine/phosphate antiport in rat kidney mitochondria. Some characteristics of the process

[14C]Ornithine uptake by rat kidney mitochondria has been investigated according to the stop inhibitor method by using praseodimium chloride as an inhibitor. The existence of an ornithine/Pi exchange was found occurring with 1:1 stoichiometry. Both uptake and efflux follow first-order kinetics with a k of 2.4 min-1. Uptake increases with increasing pH. The activation energy for the process is 58.6 kJ/mol and Q10 is 2.6. Ornithine/Pi exchange is electrical and energy-dependent, as suggested by the sensitivity of the process to the ionophores valinomycin and nigericin. Measurements both of proton movement across the mitochondrial membrane and of membrane potential strongly suggest that ornithine uptake into mitochondria is driven by the electrochemical proton gradient via the dependent ornithine/Pi translocator and delta pH-dependent Pi carrier.     

Functional relationship between the ADP/ATP-carrier and the F1-ATPase in mitochondria.

1. The distribution of labeled and unlabeled adenine-nucleotides inside and outside mitochondria was followed after addition of [14C]ADP to rat liver mitochondria. Two types of mitochondria were used: 1, respiring mitochondria which were carrying out oxidative phosphorylation and which had been replenished in ATP by incubation in a medium supplemented with succinate and phosphate; 2, non-respiring mitochondria which had been partially depleted of ATP by incubation in a medium supplemented with rotenone and phosphate. During the first minute following addition of [14C]ADP to the respiring mitochondria, the pre-existing intramitochondrial (internal) [12C]ATP was released into the medium and replaced by newly synthesized [14C]ATP. No [14C]ADP accumulated in the mitochondria. It is suggested that extramitochondrial (external) ADP entering respiring mitochondria in exchange for internal ATP is phosphorylated to ATP before its complete release in the matrix space. In non-respiring mitochondria, the entry of [14C]ADP into the mitochondria was accompanied by the appearance in the external space of [12C]ADP and [12C]ATP, with a marked predominance of [12C]ADP. Thus in non-respiring mitochondria, the residual internal ATP is dephosphorylated to ADP in the inner membrane before being released outside the mitochondria. 2. When mitochondria were incubated with glutamate, ADP and [32P]phosphate, the [32P]ATP which accumulated in the matrix space became rapidly labeled in both the P gamma and P beta groups of the ATP, due to the presence of a transphosphorylation system in the mitochondrial matrix. The [32P]ATP which accumulated outside the mitochondria was also labeled in the P beta group, although less rapidly than the internal ATP. Our data show that a large fraction (75-80%) of the ATP produced by phosphorylation of added ADP within the inner mitochondrial membrane is released into the matrix space before being transported out from the mitochondria; only a small part (20-25%) is released directly outside the mitochondria without penetrating the matrix space. 3. In respiring and phosphorylating mitochondria, the value of the Km of the ADP-carrier for external ADP was 2-4 times lower than its value in non-respiring and non-phosphorylating mitochondria. 4. The above experimental data are discussed with reference to the topological and functional relationships between the ADP-carrier and the oxidative phosphorylation complex in the inner mitochondrial membrane. They strongly suggest that the ADP-carrier comes to the close neighbourhood of the ATP synthetase on the matrix side of the inner membrane.     

Evidence from 18O exchange measurements for steps involving a weak acid and a slow chemical transformation in the mechanism of phosphorylation of the gastric H+, K+-ATPase by inorganic phosphate

Phosphorylation of the gastric H,K-ATPase by Pi has been studied by measuring the P18Oj16O4-j distribution as a function of time at different H+, K+, and [18O]Pi concentrations. The advantage of isotope exchange measurements is that the P18Oj16O4-j distribution depends on the relative rates of HOH loss to form the phosphoenzyme intermediate and Pi dissociation from the enzyme. Therefore, 18O exchange is a sensitive probe of mechanism. K+ increases the exchange rate (v(ex] but does not affect the partition coefficient (Pc) that determines the P18Oj16O4-j distribution. Conversely, H+ inhibits exchange. A single Pc describes the data at every pH, but the value increases from 0.04 at pH 8 to 0.64 at pH 5.5. Vex depends hyperbolically on [Pi]0. Km for Pi does not depend on pH, and Pc does not depend on [Pi]0. Individual rate constants in the phosphorylation mechanism are estimated. Formation of the E.Pi complex that looses HOH is 1-2 orders of magnitude slower at pH 5.5 than at pH 8 and is not diffusion controlled. The observed change in Pc with pH is compatible with catalysis occurring by a different mechanism when a group with pKa = 7.2 is protonated. Slower than diffusion-controlled formation of the E.Pi complex that splits out HOH is evidence for a relatively slow, unimolecular chemical transformation involving an additional intermediate in the phosphorylation mechanism, such as a protein conformational change.     

Phosphate transport in rat-liver mitochondria

1. The kinetics of the efflux of P_i and malate as well as the relationship between P_i transport and intra- and extramitochondrial pH changes were studied in rat-liver mitochondria in the presence of rotenone and oligomycin at different pH's.

2. At high pH a fast efflux of P_i from the mitochondria occurs in the first few seconds, followed by a slow re-entry of P_i into the mitochondria. Under the same conditions the exit of malate shows a time lag of 2–4 sec. The exit of malate coincides with the re-entry of P_i.

3. In the presence of butylmalonate the exit of endogenous P_i is coupled with a concomitant alkalinization of the mitochondrial matrix space, as calculated from the distribution of 5,5-[¹⁴C]dimethyloxazolidine-2,4-dione.

4. The stoicheiometry of the P_i-hydroxyl exchange was found to be 1:1.

5. The kinetics of P_i transport are consistent with previous observations that there is a direct exchange between OH⁻ and P_i, but not between OH⁻ and malate. The equilibrium distribution of H₂PO₄⁻ and OH⁻ deviates from the Donnan distribution. This may be explained by assuming a pH-dependent binding of P_i in the mitochondria.     

Bioenergetic studies of mitochondrial oxidative phosphorylation using 31phosphorus NMR

The relationship between phosphorylation ratio [( ATP])/[ADP][Pi], phosphocreatine (PCr)/Pi, and ATPase activity was determined for isolated rat heart mitochondria, and the use of phosphorylation ratio and/or PCr/Pi as bioenergetic indices (Chance, B., Eleff, S., Leigh, J. S., Sokolow, D., and Sapega, A. (1981) Proc. Natl. Acad. Sci. U.S.A. 78, 6714-6718) was evaluated. Isolated rat heart mitochondria were suspended at low concentration (0.5-2.0 mg of protein/ ml) in oxygenated KCl/sucrose/4-(2-hydroxyethyl)-1-piperazineethanesulfonic acid medium at 25 degrees C and pyruvate, malate, PCr, ATP, Pi, and Mg2+ were added. Changes in extramitochondrial phosphorus compounds were followed by 31P NMR. The ATPase activity was varied by the addition of potato apyrase. It was found that the logarithm of steady state PCr/Pi decreased linearly with increasing ATPase rate with a PCr/Pi intercept of 32.8 at 0 ATPase rate. The log phosphorylation ratio was also linearly related to the ATPase rate with an extrapolated maximum value of 6.87 at 0 ATPase rate, corresponding to a phosphorylation ratio of 7.41 X 10(6) M(-1) and a delta GATP of -16.3 kcal. The phosphorylation ratio in these experiments (for state 4 respiration) was greater by 1 or 2 orders of magnitude than previously reported for either isolated mitochondria or for whole tissue.     

Theoretical analysis of distribution of [18O]Pi species during exchange with water. Application to exchanges catalyzed by yeast inorganic pyrophosphatase

A theoretical analysis has been derived which allows the analytical calculation of the complete distribution of 18O-labeled Pi species expected to occur during medium Pi equilibrium HOH exchange of [18O]Pi and to be produced by intermediate Pi equilibrium HOH exchange during net hydrolysis of [18O]PPi or other labeled phosphate compounds. The observed distributions with catalysis by yeast inorganic pyrophosphatase are found to agree closely with the theoretical values indicating that the exchange reaction can be adequately described by a unique value of the partitioning of bound Pi between release from the enzyme versus formation of bound PPi with loss of an oxygen to the water. The limitations on the exclusion of other mechanisms are discussed. The extent of this partitioning does change, however, under some experimental conditions. At low pH, with activation by Mg2+ or Mn2+, the relative rate of release of Pi is found to increase. The extent of exchange is also dependent on the nature of the activating metal, being greatest with Co2+. During PPi hydrolysis with PPi in excess over Mg2+, a shift to lower extents of exchange is observed.     

Stoichiometry of H+-linked dopamine transport in chromaffin granule ghosts

A proton-translocating adenosinetriphosphatase in adrenal medullary chromaffin granule ghosts can generate either a membrane potential (inside positive) or a pH gradient (inside acid). Dopamine uptake occurs in response to both the membrane potential and the pH gradient. The natural logarithm of the dopamine concentration gradient [In (Din/Dout)] is linearly related to the membrane potential with a slope of F/(RT). This dependence is not affected by the pH of the medium. In (Din/Dout) is linearly dependent on In ([H+]in/[H+]out) with a slope of 2. These results indicate that dopamine is taken up via an exchange diffusion or antiport mechanism. The stoichiometry of this exchange is two H+/dopamine cation and is independent of pH.     

The transport of L-cysteinesulfinate in rat liver mitochondria.

1. The mechanism of L-cysteinesulfinate permeation into rat liver mitochondria has been investigated. 2. Mitochondria do not swell in ammonium or potassium salts of L-cysteinesulfinate in all the conditions tested, including the presence of valinomycin and/or carbonylcyanide p-trifluoromethoxyphenylhydrazone. 3. The activation of malate oxidation by L-cysteinesulfinate is abolished by aminooxyacetate, an inhibitor of the intramitochondrial aspartate aminotransferase, it is not inhibited by high concentrations of carbonylcyanide p-trifluoromethoxyphenylhydrazone (in contrast to the oxidation of malate plus glutamate) and it is decreased on lowering the pH of the medium. 4. All the aspartate formed during the oxidation of malate plus L-cysteinesulfinate is exported into the extramitochondrial space. 5. Homocysteinesulfinate, cysteate and homocysteate, which are all good substrates of the mitochondrial aspartate aminotransferase, are unable to activate the oxidation of malate. Homocysteinesulfinate and homocysteate have no inhibitory effect on the L-cysteinesulfinate-induced respiration, whereas cysteate inhibits it competitively with respect to L-cysteinesulfinate. 6. In contrast to D-aspartate, D-cysteinesulfinate and D-glutamate, L-aspartate inhibits the oxidation of malate plus L-cysteinesulfinate in a competitive way with respect to L-cysteinesulfinate. Vice versa, L-cysteinesulfinate inhibits the influx of L-aspartate. 7. Externally added L-cysteinesulfinate elicits efflux of intramitochondrial L-aspartate or L-glutamate. The cysteinesulfinate analogues homocysteinesulfinate, cysteate and homocysteate and the D-stereoisomers of cysteinesulfinate, aspartate and glutamate do not cause a significant release of internal glutamate or aspartate, indicating a high degree of specificity of the exchange reactions. External L-cysteinesulfinate does not cause efflux of intramitochondrial Pi, malate, malonate, citrate, oxoglutarate, pyruvate or ADP. The L-cysteinesulfinate-aspartate and L-cysteinesulfinate-glutamate exchanges are inhibited by glisoxepide and by known substrates of the glutamate-aspartate carrier. 8. The exchange between external L-cysteinesulfinate and intramitochondrial glutamate is accompanied by translocation of protons across the mitochondrial membrane in the same direction as glutamate. The L-cysteinesulfinate-aspartate exchange, on the other hand, is not accompanied by H+ translocation. 9. The ratios delta H+/delta glutamate, delta L-cysteinesulfinate/delta glutamate and delta L-cysteinesulfinate/delta aspartate are close to unity. 10. It is concluded that L-cysteinesulfinate is transported by the glutamate-aspartate carrier of rat liver mitochondria. The present data suggest that the dissociated form of L-cysteinesulfinate exchanges with H+-compensated glutamate or with negatively charged aspartate.     

Regulatory behavior of Escherichia coli aspartate transcarbamylase altered by site-specific mutation of Tyr240----Phe in the catalytic chain

Isotopic exchange kinetics at chemical equilibrium have been used to identify changes in the regulatory properties of aspartate transcarbamylase (ATCase) caused by site-specific mutation of Tyr240----Phe (Y240F) in the catalytic chain. With both wild-type and the mutant enzymes, ATP activates both [14C]Asp in equilibrium N-carbamyl-L-aspartate (C-Asp) and the [32P]carbamyl phosphate (C-P) in equilibrium Pi exchanges. In contrast, with wild-type enzyme, CTP inhibits both exchanges, but with Y240F mutant enzyme CTP inhibits Asp in equilibrium C-Asp exchange and activates C-P in equilibrium Pi exchange. The bisubstrate analog N-(phosphonacetyl-L-aspartate), PALA, activates Asp in equilibrium C-Asp at a lower concentration with the Y240F enzyme, but the extent of activation is decreased, relative to wild-type enzyme. PALA activation of C-P in equilibrium Pi observed with wild-type enzyme disappears completely with the Y240F mutant enzyme. Analysis of perturbations of exchange rates by ATP and CTP were carried out by systematic methods plus computer-based simulations with the ISOBI program. These analyses indicate that (a) ATP increases the rates of association and dissociation for both C-P and Asp, but (b) CTP differentially increases the rate of C-P association to a greater degree than dissociation, but also decreases the rates for Asp association and dissociation in equal proportion. In addition, Arrhenius plots for Y240F ATCase suggest that ATP and CTP act by different mechanisms: ATP increases Vmax (decreases delta G not equal to) uniformly at all temperatures, whereas CTP does not alter either Vmax (delta G not equal to) or the Arrhenius slope (delta H not equal to).     

Dependence of mitochondrial oxidative phosphorylation on activity of the adenine nucleotide translocase

The coupled reactions of electron transport and ATP synthesis for the first two sites of mitochondrial oxidative phosphorylation have been previously reported to be near equilibrium in isolated respiring pigeon heart (Erecińska, M., Veech, R. L., and Wilson, D. F. (1974) Arch. Biochem. Biophys. 160, 412-421) and rat liver mitochondria (Forman, N. G., and Wilson, D. F. (1982) J. Biol. Chem. 257, 12908-12915). Measurements are presented in this paper which demonstrate that the same relationship exists for both forward and reverse electron transport in rat heart mitochondria. This conclusion implies that adenine nucleotide translocation, a partial reaction of the system, is also near equilibrium, contrasting with proposals that the translocase is rate-limiting for oxidative phosphorylation. To resolve this controversy, the respiratory rates of suspensions of isolated rat liver and rat heart mitochondria were controlled by varying either the added [ATP]/[ADP][Pi] ratios ratios or [ADP] (by varying hexokinase in a regenerating system). Titrations with carboxyatractyloside, a high affinity inhibitor of the translocase which is noncompetitive with ADP, were carried out to assess the dependence of the respiratory rate on translocase activity. Plots of respiratory rate versus [carboxyatractyloside] were all strongly sigmoidal. In liver mitochondria, 40%-70% and in heart mitochondria 66% of the sites could be blocked with carboxyatractyloside before a 10% decrease in the respiratory rate was observed. Further analysis showed that liver and heart mitochondria have translocase/cytochrome a ratios of 1.52 and 3.20, respectively, and that at 23 degrees C the maximal turnover numbers for the translocases were 65 s-1 and 23 s-1. In all states of controlled respiration (no added inhibitor), a substantial excess of translocase activity was present, suggesting that the translocase was not normally rate-limiting in oxidative phosphorylation.     

Radiosensitivity of parenchymal hepatocytes as a function of oxygen concentration

To investigate the mechanism(s) of hepatocyte radioresistance (D0 2.7 Gy), the radiosensitivities of respiring (37 degrees C) and nonrespiring (0 degrees C) hepatocytes were determined as a function of oxygen concentration. Fischer 344 female rat hepatocytes were isolated by liver perfusion, equilibrated in Leibowitz-15 media with different oxygen tensions, and exposed to 60Co radiation at either 37 or 0 degrees C. Cell survival and DNA single-strand breaks were used as the biological end points of radiosensitivity. The K value for respiring hepatocytes (37 degrees C) was 14.3 +/- 0.5 mm Hg O2 (18.8 +/- 0.7 mumol O2/liter), demonstrating that the K value for freshly isolated parenchymal hepatocytes is significantly greater than those previously obtained for cultured cells. In contrast, the K value for nonrespiring hepatocytes (0 degree C) is 1.4 +/- 0.4 mm Hg O2 (3.7 +/- 1.0 mumol O2/liter) indicating that hepatocyte respiration results in a plasma membrane-to-nucleus oxygen gradient of approximately 12.9 +/- 0.6 mm Hg (15.1 +/- 1.2 microns O2/liter). The hypothesis that the hepatic nucleus typically resides in a hypoxic condition, although the liver is uniformly perfused with well-oxygenated blood, is supported by (1) the nonradom perinuclear distribution of the mitochondria, (2) the high cellular respiration rate, and (3) the large intracellular oxygen diffusion distance in hepatocytes (25 microns diameter).     

Gluconeogenesis in the kidney cortex. Flow of malate between compartments

1. Kidney-cortex slices from starved rats were incubated with l-[U-(14)C]lactate or l-[U-(14)C]malate plus unlabelled acetate and the specific radioactivity of the glucose formed was determined. In parallel experiments the specific radioactivity of the glucose formed from [1-(14)C]acetate plus unlabelled l-lactate and l-malate was determined. 2. By analytical methods the major products formed from the substrates were measured. The glucose formed was purified by paper chromatography for determination of specific radioactivity. 3. The specific radioactivity of the glucose formed from l-[U-(14)C]lactate agrees with predictions of a model based on interaction of the gluconeogenic and the oxidative pathways. 4. The specific radioactivity of the glucose formed from l-[U-(14)C]malate agrees with the predicted value if rapid malate exchange between the cytosol and mitochondria is assumed. 5. The rate of malate exchange between compartments was estimated to be rapid and at least several times the rate of glucose formation. 6. The specific radioactivity of the glucose formed from [1-(14)C]acetate plus unlabelled l-lactate or l-malate agrees with the predictions from the model, again assuming rapid malate exchange between compartments. 7. Malate exchange between compartments together with reversible malate dehydrogenase activity in the mitochondria and cytosol also tends to equilibrate isotopically the NADH pool in these compartments. (3)H from compounds such as l-[2-(3)H]lactate, which form NAD(3)H in the cytosol, appears in part in water; and (3)H from dl-beta-hydroxy[3-(3)H]butyrate, which forms NAD(3)H in the mitochondria, appears in part in glucose, largely on C-4.