Raloxifene affects fatty acid oxidation in livers from ovariectomized rats by acting as a pro-oxidant agent.

Estrogen deficiency accelerates the development of several disorders including visceral obesity and hepatic steatosis. The predisposing factors can be exacerbated by drugs that affect hepatic lipid metabolism. The aim of the present work was to determine if raloxifene, a selective estrogen receptor modulator (SERM) used extensively by postmenopausal women, affects hepatic fatty acid oxidation pathways. Fatty acids oxidation was measured in the livers, mitochondria and peroxisomes of ovariectomized (OVX) rats. Mitochondrial and peroxisomal ß-oxidation was inhibited by raloxifene at a concentration range of 2.5-25 µM. In perfused livers, raloxifene reduced the ketogenesis from endogenous and exogenous fatty acids and increased the ß-hydroxybutyrate/acetoacetate ratio. An increase in ¹4CO2 production without a parallel increase in the oxygen consumption indicated that raloxifene caused a diversion of NADH from the mitochondrial respiratory chain to another oxidative reaction. It was found that raloxifene has a strong ability to react with H2O2 in the presence of peroxidase. It is likely that the generation of phenoxyl radical derivatives of raloxifene in intact livers led to the co-oxidation of NADH and a shift of the cellular redox state to an oxidised condition. This change can perturb other important liver metabolic processes dependent on cellular NADH/NAD⁺ ratio.

Anti-hiperglycemic effect of Quassia amara (Simaroubaceae) in normal and diabetic rats / Efeito anti-hiperglicêmico de Quassia amara (Simaroubaceae) em ratos normais e diabéticos

The anti-hyperglycemic effect of wood powder of Quassia amara (QA) was evaluated in normal and in alloxan diabetes-induced rats. After a 12 h fast and glycemic check, the animals were orally given 0.9% of saline (control group), metformin (500 mg/kg) or QA (200 mg/kg) and, 30 minutes later, they received an oral glucose dose (1g/kg). The blood glucose level was measured after 30, 60, 90 and 120 minutes. From the oral glucose dose, QA showed anti-hyperglycemic effects, similar to metformin, only in the diabetic animals (p<0.01) when compared to the control group. Although the anti-hyperglycemic mechanism of action of QA was not investigated, a mechanism similar to metformin can be suggested, since both presented similar results for the conditions tested, that is, normal and diabetic rats. It is believed that the use of QA in diabetics could help to control the blood glucose levels and be useful as an alternative therapy.

O efeito anti-hiperglicemiante do pó do lenho de Quassia amara (QA) foi avaliado em ratos normais e diabéticos aloxana induzidos. Após jejum de 12 horas e verificação da glicemia, os animais receberam administração oral de salina 0.9% (grupo controle), metformina (500 mg/kg) ou QA (200 mg/kg) e 30 minutos depois carga oral de glicose (1g/kg). A glicemia foi medida nos próximos 30, 60, 90 e 120 minutos. A partir da carga oral de glicose, a QA mostrou efeito anti-hiperglicemiante, similar a metformina, somente nos animais diabéticos (p<0.01) quando comparados ao grupo controle. Embora o mecanismo de ação anti-hiperglicemiante da QA não tenha sido investigado, podemos sugerir um mecanismo semelhante à metformina, visto que ambos apresentaram resultados similares nas duas condições testadas, ou seja, animais normais e diabéticos. Acredita-se que o uso de QA, em diabéticos, possa auxiliar no controle da glicemia e servir como terapia alternativa.

Action of quercetin on glycogen catabolism in the rat liver.

1. The influence of quercetin on glycogen catabolism and related parameters was investigated in the isolated perfused rat liver and subcellular systems. 2. Quercetin stimulated glycogenolysis (glucose release). This effect was already evident at a concentration of 50 microM maximal at 300 microM and declined at higher concentrations. Quercetin also stimulated oxygen consumption, with a similar concentration dependence. 3. Lactate production from endogenous glycogen (glycolysis) was diminished by quercetin without significant changes in pyruvate production. 4. Quercetin did not inhibit glucose transport into cells but decreased intracellular sequestration of [5-(3)H]glucose under conditions of net glucose release. 5. In isolated mitochondria, quercetin diminished the energy transduction efficiency. It also inhibited several enzymatic activities, e.g. the K(+)-ATPase/Na(+)-ATPase of plasma membrane vesicles and the glucose 6-phosphatase of isolated microsomes. 6. No significant changes of the cellular contents of AMP, ADP and ATP were found. The cellular content of glucose 6-phosphate, however, was increased (3.12-fold). 7. Some of the effects of quercetin (glycogenolysis stimulation) can be attributed to its action on mitochondrial energy metabolism, as, for example, uncoupling of oxidative phosphorylation. However, the multiplicity of the effects on several enzymatic systems certainly produces an intricate interplay that also generates complex and apparently contradictory effects.

The uncoupling effect of the nonsteroidal anti-inflammatory drug nimesulide in liver mitochondria from adjuvant-induced arthritic rats.

The aim of the present study was to evaluate the changes caused by adjuvant-induced arthritis in liver mitochondria and to investigate the effects of the nonsteroidal anti-inflammatory drug nimesulide. The main alterations observed in liver mitochondria from arthritic rats were: higher rates of state IV and state III respiration with beta-hydroxybutyrate as substrate; reduced respiratory control ratio and impaired capacity for swelling dependent on beta-hydroxybutyrate oxidation. No alterations were found in the activities of NADH oxidase and ATPase. Nimesulide produced: (1) stimulation of state IV respiration; (2) decrease in the ADP/O ratio and in the respiratory control ratio; (3) stimulation of ATPase activity of intact mitochondria; (4) inhibition of swelling driven by the oxidation of beta-hydroxybutyrate; (5) induction of passive swelling due to NH(3)/NH(4)+ redistribution. The activity of NADH oxidase was insensitive to nimesulide. Mitochondria from arthritic rats showed higher sensitivity to nimesulide regarding respiratory activity. The results of this work allow us to conclude that adjuvant-induced arthritis leads to quantitative changes in some mitochondrial functions and in the sensitivity to nimesulide. Direct evidence that nimesulide acts as an uncoupler was also presented. Since nimesulide was active in liver mitochondria at therapeutic levels, the impairment of energy metabolism could lead to disturbances in the liver responses to inflammation, a fact that should be considered in therapeutic intervention.

Effects of norepinephrine on the metabolism of fatty acids with different chain lengths in the perfused rat liver.

The effects of norepinephrine on ketogenesis in isolated hepatocytes have been reported as ranging from stimulation to inhibition. The present work was planned with the aim of clarifying these discrepancies. The experimental system was the once-through perfused liver from fasted and fed rats. Fatty acids with chain lengths varying from 8-18 were infused. The effects of norepinephrine depended on the metabolic state of the rat and on the nature of the fatty acid. Norepinephrine clearly inhibited ketogenesis from long-chain fatty acids (stearate > palmitate > oleate), but had little effect on ketogenesis from medium-chain fatty acids (octanoate and laureate). With palmitate the decrease in oxygen uptake was restricted to the substrate stimulated portion; with stearate, the decrease exceeded the substrate stimulated portion; with oleate, oxygen uptake was transiently inhibited. Withdrawal of Ca2+ attenuated the inhibitory effects. 14CO2 production from [1-14C]oleate was inhibited. Net uptake of the fatty acids was not affected by norepinephrine. In livers from fed rats, oxygen uptake and ketogenesis from stearate were only transiently inhibited. The conclusions are: (a) in the fasted state norepinephrine reduces ketogenesis and respiration by means of a Ca2+-dependent mechanism; (b) the degree of inhibition varies with the chain length and the degree of saturation of the fatty acids; (c) norepinephrine favours esterification of the activated long-chain fatty acids in detriment to oxidation; (d) in the fed state the stimulatory action of norepinephrine on glycogen catabolism induces conditions which are able to reverse inhibition of ketogenesis and oxygen uptake.

The hemodynamic effects of diltiazem in the isolated perfused rat liver are Ca(2+)-dependent.

AIMS/BACKGROUND: Diltiazem reduces systemic blood pressure by decreasing the vascular smooth muscle tone. In the liver however, diltiazem seems to cause vasoconstriction, as evidenced by increases in portal pressure. The questions raised by this observation are concerned with a) the site of action of diltiazem (large vessels or sinusoids), b) the formation of permeability barriers and c) the role of Ca2+. The experiments in the present study should provide an answer to these questions. METHODS: The experimental system was the hemoglobin-free perfused rat liver. The multiple-indicator dilution technique was employed with simultaneous injection of [14C]sucrose and [3H]water. Mean transit times and distribution spaces were calculated from the normalized outflow profiles. RESULTS: Calcium alone did not affect the hemodynamics of the liver. Diltiazem, however, changed several hemodynamic parameters when Ca2+ was present, but it was inactive in the absence of this cation. The hemodynamic effects of 500 microM diltiazem were: a) diminution of the transit time through the large vessels (t(o)) and, consequently, of the accessible vascular space (66.9%); b) diminution of the mean transit time of [14C]sucrose (tsuc) and, consequently, of the accessible sinusoidal space (28.1%); c) diminution of the mean transit time of tritiated water (twater) and, consequently, of the accessible cellular space (68.9%); d) diminution of the cellular to extracellular space ratio (theta) from 1.42 +/- 0.05 to 0.46 +/- 0.11. CONCLUSIONS: The linear superposition of the tritiated water and labeled sucrose curves, predicted by Goresky's model, could be optimized even when the curves were obtained with diltiazem + Ca2+, indicating that the distribution of both tracers was still flow-limited. The hemodynamic effects of diltiazem seem to be restricted to a vasoconstriction of the great vessels, an action which was strictly dependent on Ca2+. At the concentration of 500 microM, the effects of diltiazem were pronounced to the point of excluding completely about 2/3 of the liver parenchyma from the microcirculation, as indicated by the observed reduction in the accessible cell space. The sinusoids that were still supplied with perfusion fluid suffered considerable distension (2.19 fold) because the whole perfusate flow was deviated into the remaining 1/3 microcirculatory units. Diltiazem did not seem to induce the formation of intrahepatic shunts or diffusion barriers in the liver.

The role of Ca2+ and hemodynamics in the action of diltiazem on hepatic energy metabolism.

Diltiazem causes vasoconstriction in the liver when present at high concentrations, an action that is strictly Ca2+-dependent. Diltiazem is also active on energy metabolism. This toxic action could be partly a consequence of hemodynamic effects. In the absence of Ca2+, the hemodynamic effects are no longer present and, consequently, Ca2+-free experiments are useful for distinguishing between hemodynamics-dependent and hemodynamics-independent effects. The experimental system used was the hemoglobin-free perfused rat liver from fed and fasted rats. Diltiazem was infused at various concentrations in the presence and absence of Ca2+. Several metabolic parameters were measured: lactate and pyruvate production (glycolysis), glycogenolysis, oxygen uptake, gluconeogenesis, and the cellular levels of lactate, pyruvate, glucose, AMP, ADP, and ATP. The effects of diltiazem can be divided into three groups: (1) Effects that are strictly dependent on the Ca2+-mediated hemodynamic action. This group comprises inhibition of oxygen uptake at all concentrations (50-500 micromol/L) inhibition of lactate, pyruvate, and glucose release at high concentrations; the decrease in cellular ATP; the increase in cellular AMP; and the cellular accumulation of glucose and lactate. (2) Effects that are independent of the hemodynamic action. The most relevant effect of this type is inhibition of gluconeogenesis. (3) Effects that are influenced by Ca2+ but are independent of the hemodynamic effects. This is the typical case of lactate and glucose release from endogenous glycogen, whose stimulation by low diltiazem concentrations is more pronounced in the presence of Ca2+ than in its absence.

Effects of fusaric acid on rat liver mitochondria.

The effects of fusaric acid on hepatic energy metabolism were measured. Three experimental systems were employed: (a) Intact rat liver mitochondria; (b) freeze-thawing disrupted mitochondria; and (c) the isolated perfused rat liver. Fusaric acid affects mitochondrial energy metabolism by at least three modes of action: (1) Inhibition of succinate-dehydrogenase (in the 10(-3)-10(-2) M range); (2) inhibition of oxidative phosphorylation (in the 10(-5)-10(-4) M range); and (3) inhibition of alpha-ketoglutarate-dehydrogenase (in the 10(-5)-10(-4) M range). The inhibition of oxidative phosphorylation seems to be the result of a direct action on the ATP-synthase/ATPase without significant inhibition of the ATP/ADP exchange. In the isolated perfused rat liver, fusaric acid inhibits oxygen uptake and gluconeogenesis from pyruvate, the latter being strictly dependent on intramitochondrially generated ATP. The effects of fusaric acid on rat liver mitochondria are similar to those reported previously for maize root mitochondria. However, except for the action on succinate-dehydrogenase, rat liver mitochondria are approximately two orders of magnitude more sensitive than maize root mitochondria.

The role of hemodynamics in the action of diltiazem on hepatic fatty acid metabolism.

The hemodynamic effects of diltiazem in the liver are strictly Ca2+ -dependent Consequently, Ca2+ -free perfusion can be used for investigating the metabolic effects of diltiazem without interference by hemodynamics. Livers were perfused with Krebs/Henseleit-bicarbonate buffer (pH 7.4). For performing Ca2+ -free perfusion the cation was omitted from the perfusion fluid and the cellular pools were exhausted by repeated phenylephrine infusions. Three conditions were investigated with and without Ca2+ : (1) substrate-free perfusion fluid; (2) 0.3 mM [1-(14)C]octanoate infusion; (3) 0.3 mM [1-(14)C]palmitate infusion. The following results were obtained: 1. Oxygen uptake stimulation caused by octanoate and palmitate was abolished by 500 microM diltiazem in the presence of Ca2+; in the absence of Ca2+ there was no inhibition (octanoate) or it was much smaller (palmitate); 2. The 14CO2 production was inhibited in the presence of Ca2+; in the absence of Ca2+ there was no inhibition (palmitate) or even stimulation (octanoate). 3. Ketogenesis from endogenous sources, from palmitate and from octanoate was inhibited by diltiazem in the presence as well as in the absence of Ca2+. The beta-hidroxybutyrate/acetoacetate ratio was diminished in the presence and in the absence of Ca2+ . It was concluded that inhibition of fatty acid oxidation by diltiazem depends partly on the Ca2+ -dependent hemodynamic effects and partly on a Ca2+ -independent action on some enzymatic system.

Metabolic effects of trifluoperazine in the liver and the influence of calcium.

The effects of trifluoperazine on hepatic cell metabolism were investigated using isolated perfused rat liver. The following effects of trifluoperazine were found: (1) trifluoperazine inhibited oxygen uptake, the site of action being the mitochondria. Half-maximal inhibition occurred at concentrations around 50 microM; with 100 microM trifluoperazine the effect was already maximal. When Ca2+ was withdrawn from the perfusion medium and the intracellular Ca2+ pools were exhausted, the inhibitory action on respiration was no longer observable. The reintroduction of Ca2+ restored inhibition. (2) Glycogenolysis and glycolysis were not significantly affected during the infusion of trifluoperazine. After stopping trifluoperazine infusion, however, glycogenolysis (glucose release) experienced a transitory stimulation. (3) Gluconeogenesis from lactate as the carbon source was inhibited by trifluoperazine. This inhibition was approximately proportional to the inhibition of oxygen uptake. Withdrawal of Ca2+ diminished, but it did not eliminate, inhibition of gluconeogenesis. (4) Ketogenesis was also inhibited in parallel with the inhibition of oxygen uptake. Withdrawal of Ca2+ from the perfusion fluid also abolished this action. (5) The effects of trifluoperazine were reverted very slowly when its infusion was stopped. The recovery of oxygen uptake at 50 min after cessation of the infusion was only 30%. Uptake of the substance was very fast. Absence of Ca2+ did not affect uptake. It was concluded that inhibition of mitochondrial energy metabolism is one of the most prominent effects of trifluoperazine in the liver. The fact that this inhibition depends on Ca2+ is unique.

Effects of the nonsteroidal anti-inflammatory drug piroxicam on rat liver mitochondria.

1. The effects of piroxicam, a nonsteroidal anti-inflammatory drug, on rat liver mitochondria were investigated in order to obtain direct evidence about a possible uncoupling effect, as suggested by a previous work with the perfused rat liver. 2. Piroxicam increased respiration in the absence of exogenous ADP and decreased respiration in the presence of exogenous ADP, the ADP/O ratios and the respiratory control ratios. 3. The ATPase activity of intact mitochondria was increased by piroxicam. With 2,4-dinitrophenol uncoupled mitochondria, inhibition was observed. The ATPase activity of freeze-thawing disrupted mitochondria was insensitive to piroxicam. 4. Swelling driven by the oxidation of several substrates and safranine uptake induced by succinate oxidation were inhibited. 5. The results of this work represent a direct evidence that piroxicam acts as an uncoupler, thus, decreasing mitochondrial ATP generation.

Effects of the nonsteroidal anti-inflammatory drug piroxicam on energy metabolism in the perfused rat liver.

1. The actions of piroxicam, a nonsteroidal and noncarboxylic anti-inflammatory drug, on the metabolism of the isolated perfused rat liver were investigated. The main purpose was to verify if piroxicam is also active on glycogenolysis and energy metabolism, as demonstrated for several carboxylic nonsteroidal anti-inflammatories. 2. Piroxicam increased oxygen consumption in livers from both fed and fasted rats. 3. Piroxicam increased glucose release and glycolysis from endogenous glycogen (glycogenolysis). 4. Gluconeogenesis from lactate plus pyruvate was inhibited. 5. The action of piroxicam on oxygen consumption was blocked by antimycin A, but not by atractyloside. 6. The action of piroxicam in the perfused rat liver metabolism seems to be a consequence of its action on mitochondria. 7. It can be concluded that inhibition of energy metabolism and stimulation of glycogenolysis are not specific properties of carboxylic nonsteroidal anti-inflammatory drugs.