Theoretical phosphorylation rates after addition of a small amount of glucose to intact ascites tumor cells

Changes were measured in glycolytic and respiratory rates during the entire period of glycolysis and respiratory inhibition after addition of 0.08 or 0.15 mM glucose to Ehrlich ascites carcinoma cells in 54 mM phosphate buffer (pH 7.3) at 37°. Glycolytic products fully accounted for the glucose utilized.

Theoretical rates of glycolytic ATP synthesis were calculated from the rates of accumulation of glycolytic products, and rates of oxidative phosphorylation were calculated from respiratory rates, assuming a P:O ratio of 3.0. The maximum in the glycolytic phosphorylation rate curve preceded the minimum in the respiratory phosphorylation rate curve. As a consequence, the total phosphorylation rate curve was biphasic, first rising above, then falling below, and finally returning to the initial, pre-glucose rate. The area under the early rise approximately equalled the area above the later dip and corresponded to between 1 and 2 μmoles of ATP/ml cells. The low rate of change in the ATP content of the cells indicated that most of the change in phosphorylation rate represented changes in both ATP synthesis and ATP utilization.

It is hypothesized that ATP synthesized by glycolysis is more readily available to the ATP-utilizing systems. On addition of glucose, ATP is shifted from a respiratory to a glycolytic reservoir and a period of more rapid ATP utilization associated with a decrease in the level of endogenous substrates involved in the ATP-utilizing reactions ensues; after cessation of glycolysis, the process is reversed, and ATP utilization is slowed for a period while the endogenous substrates increase again.     

Effects of ATP reduction on the pattern of force development and myosin light chain phosphorylation in intact arterial smooth muscle

The effect of reduction of ATP content on phosphorylation of the 20 kDa light chain of myosin (MLC) and force development in intact carotid arterial smooth muscle was investigated. With reduction of ATP to 23% of control by treatment with 2-deoxyglucose there was reduction in basal, in peak and 30 min MLC phosphorylation during contraction (P less than 0.001). The rate of force development was reduced, but maximal force was the same as control. By treatment with 50 microM iodoacetate, the resting ATP content was unchanged but fell to 22% after 30 min contraction. Basal MLC phosphorylation was the same as control, but peak (P less than 0.001) and 30 min phosphorylation were lower (P less than 0.005), even though the rate and magnitude of force development were greater. The results indicate that neither rate nor magnitude of force development correlate with MLC phosphorylation. Basal and initial MLC phosphorylation may play a cooperative role in contractile function.     

Character and reasons for change in mitochondrial ATP content during auto-oscillation of ion currents]

The changes in the adenosine triphosphate content in the course of ionic flux oscillations in mitochondria were estimated by using the chemiluminescence method. The ATP concentration changes were shown to be of cyclic character; the oscillations in the ATP content were shifted by 180 degrees C against those of K+ fluxes. The oligomycin-induced oxidative phosphorylation blocking changed (but did not eliminate) the oscillational character of the ATP content in mitochondrial suspensions. It was concluded that substrate phosphorylation is the source of ATP under conditions of oxidative phosphorylation inhibition. Incubation of mitochondria in the presence of exogenous ATP led to suppression of ionic flux oscillations.     

Inhibitory analysis as an approach to investigation of regulation of ATP and pyrophosphate biosynthesis in mitochondria

The effect of respiration rate on the content and accumulation of ATP and PPi in rat liver mitochondria was studied. It was found that the syntheses of ATP and PPi occur at different respiration rates. It was assumed that the respiration rate can determined the formation of ATP or PPi via oxidative phosphorylation. A possible mechanism of this effect is discussed.     

Thyroid Status Is a Key Regulator of Both Flux and Efficiency of Oxidative Phosphorylation in Rat Hepatocytes

Thyroid status is crucial in energy homeostasis, but despite extensive studies the actual mechanism by which it regulates mitochondrial respiration and ATP synthesis is still unclear. We studied oxidative phosphorylation in both intact liver cells and isolated mitochondria from in vivo models of severe not life threatening hyper- and hypothyroidism. Thyroid status correlated with cellular and mitochondrial oxygen consumption rates as well as with maximal mitochondrial ATP production. Addition of a protonophoric uncoupler, 2,4-dinitrophenol, to hepatocytes did not mimic the cellular energetic change linked to hyperthyroidism. Mitochondrial content of cytochrome oxidase, ATP synthase, phosphate and adenine nucleotide carriers were increased in hyperthyroidism and decreased in hypothyroidism as compared to controls. As a result of these complex changes, the maximal rate of ATP synthesis increased in hyperthyroidism despite a decrease in ATP/O ratio, while in hypothyroidism ATP/O ratio increased but did not compensate for the flux limitation of oxidative phosphorylation. We conclude that energy homeostasis depends on a compromise between rate and efficiency, which is mainly regulated by thyroid hormones.     

Method for measuring ATP production in isolated mitochondria: ATP production in brain and liver mitochondria of Fischer-344 rats with age and caloric restriction

The production of ATP is vital for muscle contraction, chemiosmotic homeostasis, and normal cellular function. Many studies have measured ATP content or qualitative changes in ATP production, but few have quantified ATP production in vivo in isolated mitochondria. Because of the importance of understanding the energy capacity of mitochondria in biology, physiology, cellular dysfunction, and ultimately, disease pathologies and normal aging, we modified a commercially available bioluminescent ATP determination assay for quantitatively measuring ATP content and rate of ATP production in isolated mitochondria. The bioluminescence assay is based on the reaction of ATP with recombinant firefly luciferase and its substrate luciferin. The stabilities of the reaction mixture as well as relevant ATP standards were quantified. The luminescent signals of the reaction mixture and a 0.5 microM ATP standard decreased linearly at rates of 2.16 and 1.39% decay/min, respectively. For a 25 microM ATP standard, the luminescent signal underwent a logarithmic decay, due to intrinsic deviations from the Beer-Lambert law. Moreover, to test the functionality of isolated mitochondria, they were incubated with 1 and 5 mM oligomycin, an inhibitor of oxidative phosphorylation. The rate of ATP production in the mitochondria declined by 34 and 83%, respectively. Due to the sensitivity and stability of the assay and methodology, we were able to quantitatively measure in vivo the effects of age and caloric restriction on the ATP content and production in isolated mitochondria from the brain and liver of young and old Fischer-344 rats. In both tissues, neither age nor caloric restriction had any significant effect on the ATP content or the rate of ATP production. This study introduces a highly sensitive, reproducible, and quick methodology for measuring ATP in isolated mitochondria.     

Hexokinase of rat brain mitochondria: relative importance of adenylate kinase and oxidative phosphorylation as sources of substrate ATP, and interaction with intramitochondrial compartments of ATP and ADP

Interactions between intramitochondrial ATP-generating, ADP-requiring processes and ATP-requiring, ADP-generating phosphorylation of glucose by mitochondrially bound hexokinase (ATP:D-hexose 6-phosphotransferase, EC 2.7.1.1) have been investigated using well-coupled mitochondria isolated from rat brain. ADP generated by mitochondrially bound hexokinase was more effective at stimulating respiration than was ADP generated by hexokinase dissociated from the mitochondria, and pyruvate kinase was less effective as a scavenger of ADP generated by the mitochondrially bound hexokinase than was the case with ADP generated by the dissociated enzyme. These results indicate that ADP generated by the mitochondrially bound enzyme is at least partially sequestered and directed toward the mitochondrial oxidative phosphorylation apparatus. Under the conditions of these experiments, the maximum rate of ATP production by oxidative phosphorylation was approximately 10-fold greater than the maximum rate of ATP generation by the adenylate kinase reaction. Moreover, during periods of active oxidative phosphorylation, adenylate kinase made no detectable contribution to ATP production. Thus, adenylate kinase does not represent a major source of ATP for hexokinase bound to actively phosphorylating brain mitochondria. With adenylate kinase as the sole source of ATP, a steady state was attained in which ATP formation was balanced by utilization in the hexokinase reaction. In contrast, when oxidative phosphorylation was the source of ATP, a steady state rate of Glc phosphorylation was attained, but it was equivalent to only about 40-50% of the rate of ATP production and thus there was a continued net increase in ATP concentration in the system. Rates of Glc phosphorylation with ATP generated by oxidative phosphorylation exceeded those seen with equivalent levels of exogenously added ATP. Moreover, at total ATP concentrations greater than approximately 0.2 mM, hexokinase bound to actively phosphorylating mitochondria was unresponsive to continued slow increases in ATP levels; acute increase in ATP (by addition of exogenous nucleotide) did, however, result in increased hexokinase activity. The relative insensitivity of mitochondrially bound hexokinase to extramitochondrial ATP suggested dependence on an intramitochondrial pool (or pools) of ATP during active oxidative phosphorylation. Two intramitochondrial compartments of ATP were identified based on their selective release by inhibitors of electron transport or oxidative phosphorylation. These compartments were distinguished by their sensitivity to inhibitors and the kinetics with which they were filled with ATP generated by oxidative phosphorylation. Exogenous glycerol kinase competed effectively with mitochondrially bound hexokinase for extramitochondrial ATP, with relatively low levels of glycerol kinase completely inhibiting phosphorylation of Glc.(ABSTRACT TRUNCATED AT 400 WORDS)     

The contribution of adenine nucleotide loss to ischemia-induced impairment of rat kidney cortex mitochondria.

Adenine nucleotides and respiration were assayed with rat kidney mitochondria depleted of adenine nucleotides by pyrophosphate treatment and by normothermic ischemia, respectively, with the aim of identifying net uptake of ATP as well as elucidating the contribution of adenine nucleotide loss to the ischemic impairment of oxidative phosphorylation. Treatment of rat kidney mitochondria with pyrophosphate caused a loss of adenine nucleotides as well as a decrease of state 3 respiration. After incubation of pyrophosphate-treated mitochondria with ATP, Mg2+ and phosphate, the content of adenine nucleotides increased. We propose that kidney mitochondria possess a mechanism for net uptake of ATP. Restoration of a normal content of matrix adenine nucleotides was related to full recovery of the rate of state 3 respiration. A hyperbolic relationship between the matrix content of adenine nucleotides and the rate of state 3 respiration was observed. Mitochondria isolated from kidneys exposed to normothermic ischemia were characterized by a decrease in the content of adenine nucleotides as well as in state 3 respiration. Incubation of ischemic mitochondria with ATP, Mg2+ and phosphate restored the content of adenine nucleotides to values measured in freshly-isolated mitochondria. State 3 respiration of ischemic mitochondria reloaded with ATP recovered only partially. The rate of state 3 respiration increased by ATP-reloading approached that of uncoupler-stimulated respiration measured with ischemic mitochondria. These findings suggest that the decrease of matrix adenine nucleotides contributes to the impairment of ischemic mitochondria as well as underlining the occurrence of additional molecular changes of respiratory chain limiting the oxidative phosphorylation.     

Transient state kinetic studies of phosphorylation by ATP and Pi of the calcium-dependent ATPase from sarcoplasmic reticulum.

The ATPase of the sarcoplasmic reticulum is phosphorylated by ATP in the presence of Ca2+. A rapid phosphorylation was observed when the enzyme was preincubated with Ca2+ prior to the addition of 0.1 or 1 mM ATP. The rate of phosphorylation was decreased when Ca2+ was omitted from the preincubation medium and added with ATP when the reaction was started. The rate of phosphorylation by ATP was further decreased when Pi was included in the preincubation medium without Ca2+. In this case, the enzyme was phosphorylated by Pi during the preincubation. When Ca2+ and ATP were added, a burst of phosphorylation by ATP was observed in the initial 16 ms. In the subsequent incubation intervals, the phosphorylation by ATP was synchronous with the hydrolysis of the phosphoenzyme formed by Pi. The rate of hydrolysis of the phosphoenzyme formed by Pi was measured when either the Pi concentration was decreased 10 fold, or when Ca2+, ATP or ATP plus Ca2+ was added to the medium. Upon the single addition of Ca2+, the time for half-maximal decay was in the range 500--1000 ms. In all other conditions it was in the range 70--90 ms.     

Effect of 2,4-dinitrophenol on the rat liver respiratory activity and ATP content after hypothermic storage and following reperfusion

The influence of oxidative phosphorylation uncoupler 2,4-dinitrophenol (DNP) presence in preserving solution on the rat liver respiratory activity and ATP content after 18 h of hypothermic storage (HS) and following normothermic reperfusion (NR) was investigated. DNP presence on the HS stage led to decrease of ATP level as compared with the control. After DNP removal during NR the gradual recovery of oxidative phosphorylation coupling occurred. This fact resulted in improvement of mitochondrial functional state (V4 respiration rate decrease, respiratory control and ATP level increase).     

Regulation of steady state level of phosphoenzyme and ATP synthesis in sarcoplasmic reticulum vesicles during reversal of the Ca2+ pump.

The role of the Ca2+ concentration gradient in ATP synthesis and membrane phosphorylation by Pi was investigated in sarcoplasmic reticulum vesicles isolated from rabbit skeletal muscle. The Pi concentration required to attain 50% of the maximal membrane phosphorylation varies significantly in the pH range of 5.5 to 4.5, the optimal being at pH 6.0. In the pH range of 6.0 to 7.0, this concentration of Pi was 4- to 10-fold higher in empty vesicles than in vesicles loaded with calcium phosphate, i.e. having transmembrane Ca2+ concentration gradient. ATP, ADP, and Ca2+ inhibit the membrane phosphorylation by Pi, the inhibition being greater at pH 7.0 than at pH 6.0. The pH profile for ATP synthesis shows a higher optimum than for membrane phosphorylation. The optimum pH for synthesis, but not for phosphorylation depends on whether the vesicles were previously loaded with calcium phosphate or with calcium oxalate. Addition of Ca2+ to the assay medium inhibits the extent of membrane phosphorylation and the rate of ATP synthesis to different extents. Evidence is presented that the rate of membrane phosphorylation by Pi is higher than the rate by which the phosphoprotein transfers its pohsphate to ADP for the ATP synthesis.     

Interaction of mitochondrially bound rat brain hexokinase with intramitochondrial compartments of ATP generated by oxidative phosphorylation and creatine kinase.

Previous work led to the conclusion that, during oxidative phosphorylation, mitochondrially bound hexokinase (ATP:D-hexose 6-phosphotransferase, EC 2.7.1.1) from rat brain was dependent on intramitochondrially compartmented ATP as substrate. The present study demonstrated that, when oxidative phosphorylation was functioning concurrently, mitochondrial creatine kinase could also generate intramitochondrial ATP serving as substrate for hexokinase. In the absence of concurrent oxidative phosphorylation, the kinetics of glucose phosphorylation with ATP generated by creatine kinase were not consistent with the supply of ATP from a saturable intramitochondrial compartment as formed during oxidative phosphorylation. Evidence for intramitochondrially compartmented ATP, generated by creatine kinase, was obtained; this was distinct from compartmented ATP generated by oxidative phosphorylation in terms of kinetics of generation of the compartment and its capacity, sensitivity to release by carboxyatractyloside, and sensitivity to disruption by digitonin. That oxidative phosphorylation did induce a dependence on intramitochondrial ATP as a substrate was further indicated by the observation that, although the initial rate of glucose phosphorylation by mitochondrial hexokinase depended on the extramitochondrial concentration of ATP present at the time oxidative phosphorylation was initiated, a final steady state rate of glucose phosphorylation was attained that was independent of extramitochondrial ATP levels. These and previous results emphasize the probable importance of nucleotide compartmentation in regulation of cerebral glycolytic and oxidative metabolism.     

Bioenergetic response of isolated nerve terminals of rat brain to osmotic swelling

The swelling of nerve terminals of rat brain in a hypotonic medium (230 mOsm) induced the potential-independent entrance of 45Ca2+ into synaptosomes and intrasynaptosomal mitochondria that changed the energy status of synaptosomes, the rate of O2 consumption and the content of ATP being decreased. The ratio ATP/ADP decreased from 6.5 +/- 0.26 (310 mOsm medium) to 3.1 +/- 0.18 (the medium 230 mOsm). Studies on the equilibrium distribution of K+ (86Rb+) and [3H]TPP+ showed that contents of these cations in the nerve terminals were virtually the same on incubation in both iso- and hypotonic media. This indicated that the swelling did not damage intrasynaptosomal mitochondria and plasma membranes of the synaptosomes. The inhibition of oxidative phosphorylation increased twofold the rate of glycolysis. The incubation of synaptosomes in calcium-free medium (230 mOsm) in the presence of EGTA (1 mM) prevented the inhibition of oxidative phosphorylation and synthesis of ATP by the osmotic swelling. Ruthenium Red (10 microM) in the medium 230 mOsm inhibited the entrance of 45Ca2+ into the intrasynaptosomal mitochondria and normalized the oxidative phosphorylation to the control level (310 mOsm medium). The decrease in the energy potential of synaptosomes induced by the hypoosmotic shock is suggested to be associated with the increase in Ca2+ content in the cytoplasm, its transport into the mitochondria, and the inhibitory effect on oxidative phosphorylation.     

Control of respiration and oxidative phosphorylation in isolated rat liver cells

NAD(P)H fluorescence, mitochondrial membrane potential and respiration rate were measured and manipulated in isolated liver cells from fed and starved rats in order to characterize control of mitochondrial respiration and phosphorylation. Increased mitochondrial NADH supply stimulated respiration and this accounted for most of the stimulation of respiration by vasopressin and extracellular ATP. From the response of respiration to NADH it was estimated that the control coefficient over respiration of the processes that supply mitochondrial NADH was about 0.15-0.3 in cells from fed rats. Inhibition of the ATP synthase with oligomycin increased the mitochondrial membrane potential and decreased respiration in cells from fed rats, while the uncoupler carbonyl cyanide p-trifluoromethoxyphenylhydrazone had the opposite effect. There was a unique relationship between respiration and membrane potential irrespective of the ATP content of the cells indicating that phosphorylation potential controls respiration solely via phosphorylation (rather than by controlling NADH supply). From the response of respiration to the mitochondrial membrane potential (delta psi M) it was estimated that the control coefficients over respiration rate in cells from fed rats were: 0.29 by the processes that generate delta psi M, 0.49 by the process of ATP synthesis, transport and consumption, and 0.22 by the processes that cycle protons across the inner mitochondrial membrane other than via ATP synthesis (e.g. the passive proton leak). Control coefficients over the rate of mitochondrial ATP synthesis were 0.23, 0.84 and -0.07, respectively, by the same processes. The control distribution in cells from starved rats was similar.     

ATP pools and transients in the blue-green alga,Anabaena cylindrica

Anabaena cylindrica grown in steady state continuous culture has an extractable ATP pool, measured on the basis of the luciferin-luciferase assay of 165±35 nmoles ATP mg chla ^-1. This pool is maintained by a dynamic balance between the rate of ATP synthesis and the rate of ATP utilization. Phosphorylating mechanisms which can maintain the pool in the short term are total photophosphorylation, cyclic photophosphorylation and oxidative phosphorylation. The alga can maintain its ATP pool by switching rapidly from one of these phosphorylating mechanisms to another depending on the environmental conditions. At each switch-over there is a transient drop in the ATP pool for a few seconds. On switching to conditions where only substrate level phosphorylation operates, the ATP pool falls immediately, but takes several hours to recover. The apparent rates of ATP synthesis by total photophosphorylation and by cyclic photophosphorylation are both much higher (210±30 and 250±13 moles ATP mg chla ^-1 h^-1 respectively) than the apparent rate of ATP synthesis by oxidative phosphorylation (22±3 moles ATP mg chla ^-1 h^-1). In long term experiments the ATP pool is maintained when total photophosphorylation is operating. It cannot be maintained in the long term by cyclic photophosphorylation alone in the absence of photosystem II activity or endogenous carbon compounds, or by oxidative phosphorylation in the absence of endogenous carbon compounds. Measurements of ATP, ADP and AMP show that the total pool of adenylates is similar in the light and in the dark in the short term. There is only limited production of ATP under dark anaerobic conditions when glycolysis and substrate phosphorylation can operate which suggests that these processes are of limited significance in providing ATP in Anabaena cylindrica.Abbreviations ADP adenosine 5-diphosphate - AMP adenosine 5-monophosphate - ATP adenosine 5-triphosphate - CCCP carbonyl cyanide m-chlorophenyl hydrazone - DCMU 3-(3,4-dichlorophenyl)1,1-dimethyl urea - HEPES N-2-hydroxyethylpiperazine-N-2-ethane sulfonic acid - PEP phosphoenolpyruvate     

Metabolic control over the oxygen consumption flux in intact skeletal muscle: in silico studies

It has been postulated previously that a direct activation of all oxidative phosphorylation complexes in parallel with the activation of ATP usage and substrate dehydrogenation (the so-called each-step activation) is the main mechanism responsible for adjusting the rate of ATP production by mitochondria to the current energy demand during rest-to-work transition in intact skeletal muscle in vivo. The present in silico study, using a computer model of oxidative phosphorylation developed previously, analyzes the impact of the each-step-activation mechanism on the distribution of control (defined within Metabolic Control Analysis) over the oxygen consumption flux among the components of the bioenergetic system in intact oxidative skeletal muscle at different energy demands. It is demonstrated that in the absence of each-step activation, the oxidative phosphorylation complexes take over from ATP usage most of the control over the respiration rate and oxidative ATP production at higher (but still physiological) energy demands. This leads to a saturation of oxidative phosphorylation, impossibility of a further acceleration of oxidative ATP synthesis, and dramatic drop in the phosphorylation potential. On the other hand, the each-step-activation mechanism allows maintenance of a high degree of the control exerted by ATP usage over the ATP turnover and oxygen consumption flux even at high energy demands and thus enables a potentially very large increase in ATP turnover. It is also shown that low oxygen concentration shifts the metabolic control from ATP usage to cytochrome oxidase and thus limits the oxidative ATP production. respiration rate; parallel activation; oxidative phosphorylation; metabolic control analysis; flux control coefficient; muscle contraction     

The relation between the action potential duration,the increase in resting tension,and ATP content during metabolic inhibition in guinea pig ventricular muscles

To investigate whether the action potential duration (APD) or resting tension was dependent on global ATP content, and whether they were preferentially dependent on glycolytic ATP, APD and resting tension were measured under various metabolic inhibition with corresponding measurement of ATP content in guinea pig ventricular muscles. Oxidative phosphorylation was inhibited by either hypoxic perfusion, the perfusion of sodium cyanide, or 2,4-dinitrophenol. Glycolysis was blocked by the perfusion of iodoacetic acid, and hypoxia with variable glycolytic activities was achieved by hypoxic perfusion in the presence of glucose (5, 10, and 50 mM). APD began to decrease when ATP content decreased to less than 3 mM/kg w.w. from the control level of 4.35 mM/kg w.w. APD shortened significantly and resting tension increased steeply, when ATP content decreased below 1 mM/kg w.w. The dependence of APD and the increase in resting tension on ATP content was not affected by the mode of metabolic block, that is, the inhibition of glycolysis and/or oxidative phosphorylation. Though other factors can affect APD and resting tension, we found no evidence of functional ATP compartmentation, with respect to APD and the increase in resting tension during metabolic inhibition.     

Contribution of the translocator of adenine nucleotides and the ATP synthase to the control of oxidative phosphorylation and arsenylation in liver mitochondria

The regulation of the rate of mitochondrial oxidative phosphorylation and arsenylation was studied at two external free Ca2+ concentrations. The rate of arsenate-stimulated respiration in absence of added ADP was not affected by external 10(-9) and 10(-6) M Ca2+ levels or carboxyatractyloside, while state 3 respiration was profoundly modified. In addition, the kinetic analysis showed that the rate of arsenylation in the presence of ADP was more efficient (Vm/Km ratio 3.5 times higher) in the catalytic process than phosphorylation. Therefore, this suggests that the activity of the ATP/ADP carrier is importantly controlled by Ca2+. The evaluation of the control in phosphorylation showed that the flux-control coefficients (Ci) exerted by the ATP/ADP carrier (ranged between 0.23 and 0.48) and the ATP synthase (0.05-0.57) were modified in a reciprocal way by Ca2+ and Pi concentrations. This suggests that these two enzymes are coupling sequentially through a common intermediate, the intramitochondrial ATP/ADP ratio. Other important steps controlling phosphorylation were the b-c1 complex (Ci = 0.30) and the cytochrome oxidase (Ci = 0.23) but they were not modified by Ca2+. It was also found that the main step controlling arsenylation was the ATP synthase (Ci = 0.74). The increment in the inorganic arsenate concentration induced a diminution in the control exerted by the ATP synthase (from 0.73 to 0.56). The results suggest that Ca2+ and Pi (or inorganic arsenate) could be regulated by ATP synthesis through an activating effect on ATP/ADP carrier and/or ATP synthase.     

The effect of ATP on the malate regulation of oxidative phosphorylation in brain mitochondria

Malate was studied for its effect on the oxidative phosphorylation rate in the rat brain mitochondria in the presence and absence of ATP, succinate being used as a substrate of the respiration. It has been found that malate in the 0.05-0.4 mM concentration range increases the oxidation phosphorylation rate. ATP inhibiting oxidative phosphorylation intensifies the malate stimulation. The malate 0.8 mM concentration removes the inhibiting action of ATP. The regulatory effects of malate and ATP are supposed to be realized at the adenine nucleotide translocator step.