Triclabendazole protects yeast and mammalian cells from oxidative stress: identification of a potential neuroprotective compound

The Prestwick and NIH chemical libraries were screened for drugs that protect baker’s yeast from sugar-induced cell death (SICD). SICD is triggered when stationary-phase yeast cells are transferred from spent rich medium into water with 2% glucose and no other nutrients. The rapid, apoptotic cell death occurs because reactive oxygen species (ROS) accumulate. We found that triclabendazole, which is used to treat liver flukes in cattle and man, partially protects against SICD. Characterization of triclabendazole revealed that it also protects yeast cells from death induced by the Parkinson’s disease-related protein alpha-synuclein (α-syn), which is known to induce the accumulation of ROS.     

Revisiting the Crabtree/Warburg effect in a dynamic perspective: a fitness advantage against sugar-induced cell death

The mechanisms behind the Warburg effect in mammalian cells, as well as for the similar Crabtree effect in the yeast Saccharomyces cerevisiae, are still a matter of debate: why do cells shift from the energy-efficient respiration to the energy-inefficient fermentation at high sugar concentration?

This review reports on the strong similarities of these phenomena in both cell types, discusses the current ideas, and provides a novel interpretation of their common functional mechanism in a dynamic perspective. This is achieved by analysing another phenomenon, the sugar-induced-cell-death (SICD) occurring in yeast at high sugar concentration, to highlight the link between ATP depletion and cell death.

The integration between SICD and the dynamic functioning of the glycolytic process, suggests that the Crabtree/Warburg effect may be interpreted as the avoidance of ATP depletion in those conditions where glucose uptake is higher than the downstream processing capability of the second phase of glycolysis. It follows that the down-regulation of respiration is strategic for cell survival allowing the allocation of more resources to the fermentation pathway, thus maintaining the cell energetic homeostasis.     

A study of the Crabtree effect in Novikoff ascites-hepatoma cells

Novikoff ascites-hepatoma cells show no Crabtree effect on the addition of glucose to tumour-cell suspensions, and convert a significant part of the added glucose into glycogen. Treatment of the cells with 2-deoxyglucose or glucose in the presence of iodoacetate inhibits respiration and decreases glycogen synthesis from glucose. Short-term experiments indicate a slight inhibition of glucose uptake for a brief period, due either to ATP accumulation in the mitochondria or to glucose 6-phosphate-mediated inhibition of hexokinase. Utilization of glucose metabolites and ATP for glycogen synthesis appears to remove inhibition of glucose uptake, and perhaps accounts for the absence of respiratory inhibition, by relieving a deficiency of ADP for the mitochondria. Decreased respiration in the presence of 2-deoxyglucose or glucose in the presence of iodoacetate could be due to the change in mitochondrial structure or permeability, caused by the significant loss of adenine nucleotides.     

Oxygen-dependent regulation of in vivo replication of simian virus 40 DNA is modulated by glucose

Simian virus 40 (SV40)-infected CV1 cells exposed to hypoxia show an inhibition of viral replication. Reoxygenation after several hours of hypoxia results in new initiations followed by a nearly synchronous round of SV40 replication. In this communication, we examined the effect of glucose on inhibition of viral DNA replication under hypoxia. We found that glucose stimulated SV40 DNA replication under hypoxia in two different ways. First, the rate of DNA synthesis, i.e. the fork propagation rate, increased. This effect seemed to be mediated by inhibition of mitochondrial respiration by glucose (Crabtree effect). Inhibition of mitochondrial respiration probably resulted in a higher intracellular oxygen concentration and an activation of oxygen-dependent ribonucleotide reductase, which provides the precursors for DNA synthesis. This glucose effect was consequently strongly dependent on the strength of hypoxia and the extent of intracellular respiration; hypoxic gassing with 10 ppm instead of 200-400 ppm O(2) or treatment of hypoxic cells with a mitochondrial uncoupler (carbonyl cyanide m-chlorophenylhydrazone) reduced the glucose effect on replication, whereas antimycin A, an inhibitor of respiration, increased it. The second effect of glucose concerned initiation, i.e. stimulation of unwinding of the viral origin. This effect was not influenced by the strength of hypoxia or the extent of cellular respiration and seemed, therefore, not to be mediated through a Crabtree effect. No evidence for a direct correlation between the cellular ATP concentration and the extent of SV40 replication under hypoxia was found. The effect of glucose on replication under hypoxia was not restricted to SV40-infected CV1 cells but was also detectable in HeLa cells. This suggests it to be a mechanism of more general validity.     

Glucose and phosphate inhibit respiration and oxidative metabolism in cultured hamster eight-cell embryos: evidence for the "crabtree effect"

The development of hamster eight-cell embryos is inhibited by glucose in culture medium containing inorganic phosphate (Pi). This is hypothetically attributed to the "Crabtree effect," in which enhanced glycolysis inhibits respiratory activity and oxidative metabolism. To examine this hypothesis, oxygen consumption of hamster eight-cell embryos was measured using a microelectrode. A two- to three-fold decrease in oxygen consumption was observed in embryos cultured with glucose and Pi. Oxidizable substrates and intermediates of the Krebs cycle supported embryo development only in the absence of glucose and Pi; Krebs cycle inhibitors (fluoroacetate and arsenite) arrested embryo development. Under anaerobic conditions, pyruvate and lactate did not support embryo development. Inhibition of both respiration and oxidative activity in cultured hamster embryos by glucose and Pi is consistent with the existence of a Crabtree effect and indicates that the metabolic properties of preimplantation embryonic cells differ markedly from those of most somatic cells and resemble some cancer cells.     

Change in energy metabolism of ascites cancer cells with a decrease in pH]

In Hank's balanced salt solution EL-4 ascites thymoma cells possessed endogenous respiration which was sufficient for the maintenance of their ATP level: pH decrease down to 6.0 had no effect either on endogenous respiration or the ATP level. Glucose had no influence on the respiration of EL-4 cells but inhibited that of Ehrlich ascites carcinoma (EAC) cells by 40% (Crabtree effect); respiration of the both cell lines was strongly (4-fold) inhibited after simultaneous addition of glucose, lactate and pH decrease. EL-4 cells had no endogenous glycolysis; EAC cells showed a low level of glycolysis only after pH decrease. Glucose addition led to activation of glycolysis (both inhibited 2-fold after a decrease of pH down to 6.0. The respiration inhibition at pH 7.3 and 6.0 caused no decrease of ATP depletion when glucose was present in the medium; this result may be due to suppression of ATP consumption. Incubation of EL-4 cells under respiration and glycolysis deficiency conditions resulted in a sharp ATP depletion; pH decrease delayed this depletion.     

The microbiol metabolism of C1 compounds. Oxidative phosphorylation in membrane preparations of Pseudomonas AM1

A method is described for preparation of membrane vesicles (diameter 80nm) capable of respiration-linked ATP synthesis. Vesicles prepared from succinate-grown bacteria oxidized NADH, succinate and ascorbate plus NNN'N'-tetramethylphenylenediamine; vesicles prepared from methanol-grown bacteria also oxidized methanol and formaldehyde, but they were otherwise identical. The uncoupling agent carbonyl cyanide chlorophenylhydrazone and the adenosine triphosphatase inhibitor dicyclohexylcarbodi-imide both inhibited ATP synthesis, whereas they had no effect on the rate of respiration. Rotenone inhibited ATP synthesis and respiration with NADH as substrate; antimycin A inhibited with succinate as substrate, and cyanide inhibited with all substrates. P/O ratios were usually 0.7-1.3 with NADH, 0.6-1.0 with succinate and 0.2-0.6 with reduced NNN'N'-tetramethylphenylenediamine or methanol as respiratory substrate. When 2,6-dichlorophenol-indophenol was used as an alternative electron acceptor to O(2) (NADH as donor) the P/2e ratio was 1.65. Although these P/O ratios are minimum values, because they do not take into account unknown amounts of uncoupled O(2) consumption, they are consistent with previous proposals [O'Keeffe & Anthony (1978) Biochem, J.170, 561-567] based on measurements of proton translocation in whole cells. The results also confirm that methanol dehydrogenase and cytochromes c and a/a(3) are arranged so that the first step in methanol oxidation is coupled to synthesis of ATP.     

Respiration of mitochondria isolated from differentiated and undifferentiated HT29 colon cancer cells in the presence of various substrates and ADP generating systems

1. Oxygen consumption was investigated in two cultured subpopulations of either undifferentiated (Glc+ cells) or differentiated (Glc- cells) HT29 colon cancer cells and in the corresponding isolated mitochondria. In Glc+ cells, a decrease of the respiration is induced by the presence of glucose (Crabtree effect), whereas it is not the case in Glc- cells. 2. The oxidative phosphorylation rate of Glc- mitochondria is found to be much higher than that of Glc+ mitochondria, due to a higher efficiency to oxidize glutamine, glutamate, 2-oxoglutarate, succinate or malate. 3. In both types of mitochondria, respiration can be supported by the ADP formed by adenylate kinase or nucleotide diphosphate kinase, and, although to a lesser extent in Glc- mitochondria, by hexokinase. 4. Glc+ cells are characterized by a low respiration capacity and a high glycolytic flux leading to the Crabtree effect. Glc- cells are characterized by a better correlation between a moderate glycolytic flux and a high respiratory capacity.     

Interrelationship of carbohydrate metabolism and alkaline phosphatase synthesis in Bacillus licheniformis 749/c.

Membrane-bound alkaline phosphatase of Bacillus licheniformis 749/c is derepressed by glucose in complex and chemically defined media. In the presence of lactate, pyruvate, or succinate the synthesis is repressed. The lactate repression neither affects total protein synthesis nor inhibits penicillinase synthesis. Thus, carbon sources specifically influence alkaline phosphatase synthesis. Although variations in the inorganic phosphate content of the growth media directly affect alkaline phosphatase synthesis, the intracellular inorganic and total phosphate pools appear to be unrelated to its repression or derepression. During lactate repression there is preferential incorporation of lactate molecules into glycogen, whereas no such incorporation could be detected from glucose. Net glycogen synthesis remains the same in glucose- or lactate-grown cells. It is postulated that, in phosphate-deficient growth medium, gluconeogenic metabolism regulates alkaline phosphatase synthesis.     

Energy metabolism of isolated rat thymus cells

The energy metabolism of rat thymus cells has been investigated using preparations of isolated cells obtained by mechanical treatment of whole organs. The addition of glycolytic substrates such as glucose, pyruvate and lactate stimulates the endogenous respiration of these cells by 50%. On the other hand, succinate, glutamate and malate do not produce any effect. Oligomycin (10 mug/ml) inhibits both endogenous and glucose stimulated respiration by about 40%; 2, 4-DNP (50 muM) increases by 100% glucose induced respiration. The results obtained by using mitochondrial and glycolytic inhibitors as well as aminoxyacetic acid (AOA) and following pyridine nucleotides redox changes, support the idea that in thymus cells glucose is able to induce a great enhancement of O2 consumption both by raising the level of endogenous pyruvate and feeding the mitochondrial respiratory chain with cytosolic reducing equivalents, through an active malate-aspartate shuttle. Thymus cells exhibit a high Pasteur effect (74%). Both AOA and 2,4 DNP are able to stimulate aerobic lactate accumulation by 200% and 100% respectively, indicating that either the redox or phosphate potential do influence the rate of aerobic glycolysis in isolated thymus cells. Similar experiments are also reported on other cells with well known biochemical characteristics.     

Mode of Action of the Antibiotic Siccanin on Intact Cells and Mitochondria of Trichophyton mentagrophytes

Siccanin at 3 mug/ml completely inhibited the growth of Trichophyton mentagrophytes. The primary site of action of siccanin on T. mentagrophytes is succinate dehydrogenase in the terminal electron transport system. At a concentration of siccanin giving 50% inhibition of growth (0.3 mug/ml), respiration of intact cells was inhibited more strongly than any other cellular functions tested, including the syntheses of cellular ribonucleic acid, deoxyribonucleic acid, phospholipid, protein, and cell wall fractions. In addition, at the same concentration siccanin did not cause any detectable damage in the permeability of the cells. Furthermore, the oxidation of succinate in mitochondrial preparation is more sensitive to the antibiotic than respiration in intact cells. Oxidation of other substrates tested was less sensitive to siccanin than that of succinate. The antibiotic inhibited both phosphorylation and oxidation, without causing changes in the P:O ratio. Siccanin at 0.03 mug/ml, which caused 50% inhibition of succinate oxidation in mitochondria, had effect neither on the exchange reaction between inorganic phosphate (P(i)) and adenosine triphosphate (ATP) nor on that between adenosine diphosphate and ATP. An ATP phosphohydrolase activity was also insensitive to the antibiotic. At very high concentrations, however, the antibiotic slightly inhibited the P(i)-ATP exchange reaction. From those results, it was concluded that siccanin inhibits fungal growth by inhibiting the respiratory electron transport system.     

Effects of varying the carbon source limiting growth on yield and maintenance characteristics of Escherichia coli in continuous culture.

The magnitudes of Yo (grams [dry weight] formed per gram of atom O) and mo, the maintenance respiration (milligram-atoms of O per gram [dry weight] per hour), of Escherichia coli B have been determined by growing the organism in aerobic continuous culture limited by a number of different substrates. The value found were as follows: glucose--tyo = 12.5, mo = 0.9; glucose plus 2.7 mM cyclic adenosine 3',5'-monophosphate (cAMP)--Yo = 31.2, mo = 9.3; galactose--Yo = 13.2, mo = 1.8; mannitol--Yo = 20.1, mo = 6.1; L-glutamate--Yo = 25.5, mo = 17.7; glycerol--Yo = 14.9, mo = 10.0; succinate--Yo = 11.2, mo = 12.1; and acetate--Yo = 14.7, mo = 25.4. During growth in anaerobic continuous culture with limiting glucose YATP was found to be 10.3 g (dry weight)/mol of adenosine 5'-triphosphate (ATP) and m ATP was 18.9 mmol of ATP/g (dry weight) per h. The aerobic growth yields of cells growing on glucose, glucose plus cAMP, mannitol, and glutamate were consistent with the hypothesis that carbohydrates partially repress oxidative phosphorylation, but the yields of cells growing on glycerol, succinate, acetate, and galactose were all lower than expected. We conclude that, like the efficiency of oxidative phosphorylation, both the maintenance respiration and the amount of ATP necessary to serve maintenance processes are determined by the identity of the growth substrates. Yields smaller than expected may be explained by the absence of respiratory control exerted by phosphate acceptors.     

Effect of ATP translocation on citrulline and oxaloacetate synthesis by isolated rat liver mitochondria.

The possibility that the availability of ATP may affect the rate of synthesis of carbamoyl phosphate (measured as citrulline) by carbamoyl phosphate synthase (ammonia) was studied using respiring isolated rat liver mitochondria incubated with added ADP, with hexokinase, glucose, and ATP, or with atractylate, in order to enhance or prevent the efflux of mitochondrial ATP. The effects of these agents were compared with those on oxaloacetate synthesis from pyruvate. Addition of hexokinase, glucose, and ATP to isolated mitochondria resulted in an inhibition of citrulline synthesis which was proportional to the amounts of glucose 6-phosphate formed; under these conditions, matrix ATP and ATP/ADP tended to decrease. The addition of increasing amounts of ADP also resulted in proportional inhibition of citrulline synthesis, but in this case the matrix content of ATP and ADP increased, and ATP/ADP decreased very slightly. In the presence of atractylate, citrulline synthesis was maximal despite a 30% decrease in matrix ATP and ATP/ADP. These effects were observed whether pyruvate, succinate, glutamate, or β-OH-butyrate was used as the respiratory substrate. ADP, the hexokinase system, and atractylate had qualitatively similar but much less pronounced effects on oxaloacetate synthesis from pyruvate. Within the limits of variation observed in these experiments, the rate of synthesis of citrulline appears not to be affected by the matrix content of total ATP, total ADP, or by ATP/ADP. It is affected, however, by the velocity of translocation of ATP into the extramitochondrial medium. These findings suggest that carbamoyl phosphate synthase (ammonia) may be loosely associated with the mitochondrial inner membrane, and may compete for ATP with the ATP-ADP translocator to an extent determined by the extramitochondrial demands for ATP.     

Isolation and characterization of adult rat hearts cells.

Adult rat heart muscle cells were isolated after simultaneous perfusion of multiple (two to eight) hearts with buffered salt solutions containing collagenase and hyaluronidase. Yields (35 to 50% of ventricular weight with approximately 70% viability) are quantitatively suitable for metabolic studies. Viability has been determined by the ability of intact cells to exclude trypan blue and the inability of intact cells to oxidize exogenous succinate. Micrographs show that the fine structure of the isolated cells is well ordered. Cell concentrations of glycogen, glucose 6-phosphate, citrate, and various enzymes were similar to those of intact heart. ATP and creatine phosphate concentrations were lower than in whole hearts. Adenosine 3′,5′-monophosphate concentrations were somewhat elevated. Deoxyribonucleic acid was lower than in whole tissue. The isolated cells retain certain metabolic control mechanisms. The uncoupler of oxidative phosphorylation, 2,4-dinitrophenol, increased oxygen consumption severalfold, whereas exogenous ADP had no effect on respiration. Under anaerobic conditions the rates of glucose utilization and lactate production were faster than in the presence of oxygen, indicating retention of the Pasteur effect. The addition of glucose and insulin caused a decrease in oxygen uptake or the Crabtree effect. Exogenously added pyruvate decreased glycolytic flux and produced a pronounced increase in intracellular citrate and glucose 6-phosphate. Isoproterenol stimulated adenylate cyclase activity of the isolated cells at the same concentrations effective with intact heart preparations. Isoproterenol and glucagon caused the activation of phosphorylase. The cells deteriorated as a function of incubation time, as indicated by a decrease in ATP content and a loss of lactate dehydrogenase into the medium. Cell deterioration was greatly accelerated by Ca²⁺ at concentrations greater than 10^?5m.     

Lysosomal acid proteinase of rabbit liver

1. The interference mechanism of carbonyl cyanide m-chlorophenylhydrazone with the respiratory process and with phosphorylation coupled to respiration has been investigated in resting cells of Escherichia coli. 2. Preincubation of the cells with carbonyl cyanide m-chlorophenylhydrazone in the absence of substrate caused strong inhibition of succinate oxidation. The inactivation of the respiratory system proved to be time-dependent and temperature-dependent and could be arrested by adding the substrate. Inhibition of incorporation of ³²P into acid-soluble organic phosphate esters exceeded the inhibition of oxygen uptake. 3. In contrast with succinate, the rate of oxidation of glucose was increased by carbonyl cyanide m-chlorophenylhydrazone. The sensitivity of other substrates to the inhibitor was less than that of succinate. 4. Various observations are described in support of the view that respiratory inhibition induced by carbonyl cyanide m-chlorophenylhydrazone is a result of its interference with ATP synthesis. The capacity of a given substrate to increase intracellular ATP concentration appeared to be directly related to its resistance to inhibition. In cell-free extracts carbonyl cyanide m-chlorophenylhydrazone still suppressed ³²P incorporation but had no effect on respiration. 5. Carbonyl cyanide m-chlorophenylhydrazone-induced stimulation of glucose oxidation and the acceleration of succinate oxidation by ADP or AMP in cells rendered permeable to nucleotides are tentatively interpreted as an indication that a certain part of respiration in E. coli is under phosphate-acceptor-mediated control.     

Kinetic control of mitochondrial ATP synthesis

In order to gain a clearer understanding of the kinetic control of ATP synthesis, rat liver and rat heart mitochondria were incubated under conditions that resulted in various rates of net ATP synthesis or ATP hydrolysis. Radiolabeled phosphate was included in the incubation media, and exchange rates between phosphate and ATP were determined as a function of rates of net ATP synthesis. Since ATP synthase is a highly reversible enzyme, the catalyzed reaction was expected to approach equilibrium especially at low rates of respiration and net ATP synthesis. Thus ADP + Pi V1 in equilibrium V2 ATP. If V1 is the rate of incorporation of radiolabeled phosphate into ATP, then net ATP synthesis (or hydrolysis) is V1 - V2. Since V1 and V1 - V2 could be measured, it was possible to calculate V2. V1 doubled in the transition from zero to maximal net ATP synthesis, whereas V2 decreased by over 90% when the rate of ATP synthesis was high due to high-media ADP. In heart mitochondria at 37 degrees C when respiration increased from 104 +/- 10 to 842 +/- 51 nanoatoms of O2/(min X mg), incorporation of [33P]phosphate into ATP (V1) increased from 1,100 +/- 60 to 1,978 +/- 121 and V2 decreased from 1,100 to near zero. These data demonstrate that mitochondrial ATP synthesis does not occur near equilibrium under physiological conditions and relatively high rates of ATP synthesis. A reaction with a high ratio of forward to reverse flux is obviously not near equilibrium. The important most sensitively controlled reaction appears to be V2, ATP hydrolysis. Possible mechanisms of kinetic control of V2 are discussed.(ABSTRACT TRUNCATED AT 250 WORDS)     

Triosephosphates as intermediates of the Crabtree effect

An increase in glucose concentration in the medium rapidly decreases respiration rate in many cell types, including tumor cells. The molecular mechanism of this phenomenon, the Crabtree effect, is still unclear. It was shown earlier that adding the intermediate product of glycolysis fructose-1,6-bisphosphate to isolated mitochondria suppresses their respiration. To study possible roles of glycolytic intermediates in the Crabtree effect, we used a model organism, the yeast Saccharomyces cerevisiae. To have the option to rapidly increase intracellular concentrations of certain glycolytic intermediates, we used mutant cells with glycolysis blocked at different stages. We studied fast effects of glucose addition on the respiration rate in such cells. We found that addition of glucose affected cells with deleted phosphoglycerate mutase (strain gpm1-delta) more strongly than ones with inactivated aldolase or phosphofructokinase. In the case of preincubation of gpm1-delta cells with 2-deoxyglucose, which blocks glycolysis at the stage of 2-deoxyglucosephosphate formation, the effect of glucose addition was absent. This suggests that triosephosphates are intermediates of the Crabtree effect. Apart from this, the incubation of gpm1-delta cells in galactose-containing medium appeared to cause a large increase in their size. It was previously shown that galactose addition did not have any short-term effect on respiration rate of gpm1-delta cells and, at the same time, strongly suppressed their growth rate. Apparently, the influence of increasing triosephosphate concentration on yeast physiology is not limited to the activation of the Crabtree effect.     

Transport protein synthesis in non-growing yeast cells

Addition of a metabolizable substrate (glucose, ethanol and, to a degree, trehalose) to non-growing baker's yeast cells causes a boost of protein synthesis, reaching maximum rate 20 min after addition of glucose and 40–50 min after ethanol or trehalose addition. The synthesis involves that of transport proteins for various solutes which appear in the following sequence: H⁺, l-proline, sulfate, l-leucine, phosphate, α-methyl-d-glucoside, 2-aminoisobutyrate. With the exception of the phosphate transport system, the K_t of the synthesized systems is the same as before stimulation. Glucose is usually the best stimulant, but ethanol matches it in the case of sulfate and exceeds it in the case of proline. This may be connected with ethanol's stimulating the synthesis of transport proteins both in mitochondria and in the cytosol while glucose acts on cytosolic synthesis alone. The stimulation is often repressed by ammonium ions (leucine, proline, sulfate, H⁺), by antimycin (proline, trehalose, sulfate, H⁺), by iodoacetamide (all systems tested), and by anaerobic preincubation (leucine, proline, trehalose, sulfate). It is practically absent in a respiration-deficient petite mutant, only little depressed in the op₁ mutant lacking ADP/ATP exchange in mitochondria, but totally suppressed (with the exception of transport of phosphate) in a low-phosphorus strain. The addition of glucose causes a drop in intracellular inorganic monophosphate by 30%, diphosphate by 45%, ATP by 70%, in total amino acids by nearly 50%, in transmembrane potential (absolute value) by about 50%, an increase of high-molecular-weight polyphosphate by 65%, of total cAMP by more than 100%, in the endogenous respiration rate by more than 100%, and a change of intracellular pH from 6.80 to 7.05. Ethanol caused practically no change in ATP, total amino acids, endogenous respiration, intracellular pH or transmembrane potential; a slight decrease in inorganic monophosphate and diphosphate and a sizeable increase in high-molecular-weight polyphosphate. The synthesis of the various transport proteins thus appears to draw its energy from different sources and with different susceptibility to inhibitors. It is much more stimulated in facultatively aerobic species (Saccharomyces cerevisiae, Endomyces magnusii) than in strictly aerobic ones (Rhodotorula glutinis, Candida parapsilosis) where an inhibition of transport activity is often observed after preincubation with metabolizable substrates.     

The phosphorus/oxygen ratio of mitochondrial oxidative phosphorylation.

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

Fatty acids revert the inhibition of respiration caused by the antidiabetic drug metformin to facilitate their mitochondrial β-oxidation

While metformin has been widely used to treat type 2 diabetes for the last fifty years, its mode of action remains unclear. Hence, we investigated the short-term alterations in energy metabolism caused by metformin administration in 3T3-L1 adipocytes. We found that metformin inhibited mitochondrial respiration, although ATP levels remained constant as the decrease in mitochondrial production was compensated by an increase in glycolysis. While AMP/ATP ratios were unaffected by metformin, phosphorylation of AMPK and its downstream target acetyl-CoA carboxylase augmented. The inhibition of respiration provoked a rapid and sustained increase in superoxide levels, despite the increase in UCP2 and superoxide dismutase activity. The inhibition of respiration was rapidly reversed by fatty acids and thus respiration was lower in treated cells in the presence of pyruvate and glucose while rates were identical to control cells when palmitate was the substrate. We conclude that metformin reversibly inhibits mitochondrial respiration, it rapidly activates AMPK without altering the energy charge, and it inhibits fatty acid synthesis. Mitochondrial β-oxidation is facilitated by reversing the inhibition of complex I and, presumably, by releasing the inhibition of carnitine palmitoyltransferase. This article is part of a Special Issue entitled: 17th European Bioenergetics Conference (EBEC 2012).