Lipogenesis in liver, lung and adipose tissue of rats fed with oleoylanilide

Fatty acid conjugates of xenobiotics

In this review, we discuss the formation and toxicity of fatty acid conjugates of xenobiotics. Conjugates formed in vivo and in vitro and those detected as contaminants are reviewed. Due to the lipophilic nature of these conjugates, they may accumulate in various body organs and cause toxic manifestations. In vivo formation of these fatty acid conjugates appears to be catalyzed by enzyme(s). Fatty acid ethyl esters are the most widely studied esters and have been implicated in the onset or pathogenesis of myocardial and pancreatic diseases in alcoholics. In experimental animals, studies on 2-chloroethyl linoleate, palmitoylpentachlorophenol and oleoyl and linoleoyl anilides clearly indicate that lipid conjugates of xenobiotics are involved in target organ toxicity. These findings warrant further detailed studies to isolate and identify other fatty acid conjugates and to evaluate their toxicity. Thorough toxicokinetic and metabolic studies are also needed to identify putative toxic agents. Identifying these agents could help in understanding the mechanism of pathogenesis associated with lipid conjugation. Finally fatty acid conjugates of drugs (prodrugs), have been shown to have increased half-lives and long-lasting dose-response. Thus these conjugates may be useful for enhancing the therapeutic potential of drugs and should be explored further.

Development of pancellular toxicity in guinea pig lung by ingestion of oleylanilide

Toxic oil syndrome (TOS), characterized by widespread thromboembolism, vasculotoxicity, and ARDS, develops in humans ingesting denatured edible oils. The mechanism(s) involved in targeted vasculocentric damage in this multi-system disorder is not known. Oleylanilide (OA) was synthesized and fed to male, young adult guinea pigs by gavage for 30 days at doses of 35, 50, and 100 mg/kg/day in groups of six animals each respective to weight. Controls were fed olive oil. Oleylanilide fed animals gained less weight than controls. At the end of experiment, right lungs were inflation fixed in appropriate fixative for histology and transmission electron microscopy (TEM) and left lungs were frozen at -70 degrees C for biochemical analyses. The activity of glycerophosphate acyltransferase (GAT) and cholinephosphotransferase (CPT), two key enzymes involved in phospholipid biosynthesis, were decreased in lung due to OA ingestion. All doses of OA induced marked perivascular and peribronchoiolar monocytic infiltrates that often formed prominent nodules; segmental vascular smooth muscle cell proliferation and derangement of myocytic polarity, subendothelial foamy infiltrates, and edema; nuclear pyknosis and dropout in vascular and bronchial targetoid myocytes; and denudation of bronchiolar epithelial cells. Alveoli contained large numbers of monocytes, macrophages, red cells, edema, and debris. Transmission electron microscopy showed type I cell cytoplasmic ballooning and disintegration of type I cell; contracted and blebbed endothelial cells, fibrin thrombi in capillaries, intracellular megalamellar bodies in type II cells, and surfactant lamellae; and liposomes and fine granular precipitates within alveoli, and contraction and lift off of bronchiolar epithelial cells. Monocytes, mast cells, and eosinophils infiltrated bronchial walls. Furthermore, there was deposition of electron dense particles on the surface of the alveolar wall.(ABSTRACT TRUNCATED AT 400 WORDS)

Toxic effects of fatty acid anilides on the oxygen defense systems of guinea pig lungs and erythrocytes

Toxic oil syndrome (TOS) is caused by ingestion of denatured edible oils. Even though the etiology and pathogenesis of this disease are not fully known, it is quite clear that generation of free radicals caused by ingestion of fatty acid anilides is responsible for the pathogenetic mechanism in many TOS patients. Fatty acid anilides may also alter the free radical status of lungs and erythrocytes; this possibility may shed some light on understanding toxic oil syndrome. The present study describes the effects of oral administration of fatty acid anilides on the activities of major enzymes involved in the oxygen defense systems of lungs and erythrocytes. Feeding fatty acid anilides caused an increase in the superoxide dismutase (SOD) activity in erythrocytes, whereas it caused a decrease in the SOD activity in lungs. GSH-Px activity was not significantly changed in erythrocytes but was decreased in lungs. Although the activity of catalase was increased only by a higher dose in the erythrocytes, it was not affected in the lung at any dosage. Even though the ingestion of fatty acid anilides caused an increase in the SOD activity in the erythrocytes and a decrease in the SOD activity in the lungs, there was an increase in the lipid peroxidation in both cases. The increase in lipid peroxidation in erythrocytes is probably caused by the accumulation of H2O2, and that in the lungs is due to the accumulation of superoxide anion.

Effects of linoleic and oleic acid anilides on prostacyclin synthesis and fibrinolytic profile of human endothelial cells in culture: relevance to the toxic oil syndrome

We evaluated the effects of fatty-acid anilides (FAA) on prostacyclin (PGI2) synthesis and on the fibrinolytic properties of human umbilical vein endothelial cells. Preincubation of endothelial cells with oleic- and linoleic-anilides (OAA and LAA, respectively) resulted in a time- and concentration-dependent inhibition of ionophore A23187- and thrombin-induced PGI2 synthesis. However, no significant effects of FAA on arachidonic acid-induced PGI2 synthesis were found, except with 1000 microM LAA which inhibited cyclooxygenase activity after 24 h. In general terms, OAA showed similar inhibitory effects on PGI2 production as did LAA, but with a shifted time course, since the production of PGI2 at 24 h for OAA was similar to that observed for LAA at 2 h. The release of labeled arachidonic acid from cell membranes was significantly reduced (75-85%), after 24 h, with both FAA. The effect of 100 microM LAA on thrombin-induced PGI2 production was rapid (within 15 min) and irreversible after 60 min. The recovery of PGI2 synthesis after LAA treatment was blocked by cycloheximide, suggesting a decrease of phospholipase(s) activity or cessation of enzyme synthesis. Moreover, this reduced PGI2 synthesis was not associated with [3H]adenine release. Our data indicate that FAA induce a significant impairment of stimulated PGI2 synthesis and arachidonic acid release in endothelial cells, acting primarily as inhibitors of phospholipase(s) rather than of cyclooxygenase. Finally, both LAA and OAA induce an anti-fibrinolytic activity in these cells where major changes are observed in the plasminogen activator inhibitor and the urine-type plasminogen activator.

Lysosomal enzyme activities in liver and sera from guinea pigs fed oil related to the toxic oil syndrome

beta-N-Acetylglucosaminidase and beta-galactosidase activities were determined in serum and liver from guinea pigs fed "toxic oil" (related to cases of TOS) under different experimental conditions. The results obtained were compared with those of guinea pigs fed non "toxic oil" (case-unrelated oil; controls 1) and animals fed no oil (controls 2). In serum, both activities were significantly increased after all treatments with case-related oil as compared with controls 1 and 2. In the liver, beta-galactosidase activity did not show significant differences in any of the treatments when compared with controls 2. However, NAG activity decreased significantly after 7 days of treatment with non-heated oil--either case-related or not--when compared with controls 2; it also decreased significantly after 28 days of treatment with heated case-unrelated oil, both with respect to controls 2 and the animals fed case-related oil. Liver weights tended to increase in the animals fed oil--toxic or not--with respect to those of the livers from untreated animals. Morphologically, a slight vacuolization of the hepatocytes was observed in some of the samples from the treated animals.

Toxic oil syndrome: a study of renal function in guinea pigs fed toxic oil

1. Comparative studies of beta-N-acetylglucosaminidase (NAG, EC 3.2.1. 52) and beta-galactosidase (EC 3.2.1. 23) activities, protein concentration and creatinine clearance, were carried out in urine and kidney from guinea pigs treated with "toxic oil", orally administered under different conditions, related to controls. 2. Enzyme activities did not vary significantly in urine with any of the studied conditions of oil administration. By contrast, in kidney, beta-D-galactosidase disclosed a significant increase in all the treatments studied when compared to controls without treatment. 3. Urinary protein excretion, creatinine concentration and creatinine clearance were significantly greater in treated animals than in controls after 4 weeks of treatment. 4. Relative kidney weight (g/100 g body wt), was significantly lower in animals treated for 28 days with previously heated oil.

Influence of fatty acid anilides present in toxic oils on the metabolism of exogenous arachidonic acid in cultured human endothelial cells

The effect of fatty acid anilides (FAA) on the exogenous arachidonic acid (AA) metabolism and toxicity of isolated human endothelial cells was studied to clarify their possible role in the etiology of toxic oil syndrome. Confluent cells were incubated with and without linoleic acid anilide (LAA), oleic acid anilide (OAA) and two unrelated samples for 2-24 h prior to the addition of [l-14C]AA alone or with calcium ionophore A-23187. The eicosanoids produced were analyzed by RP-HPLC. A dual stimulatory and inhibitory effect on the conversion of exogenous AA as a function of preincubation time with anilides (100 and 1000 microM) was observed. Treated cells significantly increased (1-3-fold) the production of the main cyclooxygenase-derived prostanoids (6-keto-PGF1 alpha and PGF2 alpha) formed by these cells, with a maximum stimulatory effect after 2-3 h, only when AA was used alone. However, afterwards a time- and dose-dependent decrease in prostanoid formation was observed with LAA (P < 0.05 at 24 h), either in the absence or presence of ionophore A-23187 in the incubation mixture. This inhibitory effect on cyclooxygenase was not observed with OAA, which still stimulate after 24 h of treatment. The changes in prostanoid synthesis were not followed with a parallel release in the lactate dehydrogenase activity in the medium (except with unrelated samples). Moreover, anilide treatment increased the appearance of cytosolic lipid droplets or vacuoles after 2 and 5 h of contact with LAA and OAA, respectively. From these results, it was suggested that anilides impair prostanoid synthesis in endothelial cells; their stimulatory effect could be explained by an unspecific effect on cell membrane, not related to cell toxicity and the inhibitory effect by an inhibition of the cyclooxygenase activity. These observations further contribute to our understanding of the possible role of anilides in the etiology of the toxic oil syndrome.

Rates of utilization of intravenous oleylanilide administered chronically to the rat

The constant injection of [14C]oleylanilide into the vena cava of Wistar rats for 7 days with osmotic minipumps was used to estimate tissue distribution of chronically administered anilides. The largest concentrations of the anilide were found in the brown adipose tissue; all other tissues showed much lower proportions. When anilide distribution was expressed as nmol/g lipid, the high concentration of the compound in the brown adipose tissue contrasted with its very low presence in the white adipose tissue; all other tissues showed intermediate concentrations. Anilide-treated rats consumed more food and lost more weight than did controls; their energy balance showed higher energy inefficiency. The results suggest a possible effect of anilides on the thermogenic pathway of the rat brown adipose tissue. In addition, there was a large individual variability in the proportions of anilide present in all tissues, from as little as 0.3% of the total anilide injected in some animals to 6% in others.

The toxic oil syndrome (TOS, 1981): from the disease towards a toxicological understanding of its chemical aetiology and mechanism

In Spain early in May 1981, 20,000 people became ill with a severe acute respiratory illness. The eosinophilia and subsequent myalgia, scleroderma and muscle wasting indicated a unique disease entity. Epidemiological evidence linked the disease with the consumption of oils containing "refined" aniline denatured rape seed oil. Ten years after the explosive appearance of this disease (approximately 350 deaths and over 1000 in the chronic phase) the clinical and pathological description is now well established. The aetiological agent(s) in the food oil are unknown and the mechanism(s) of pathogenesis are uncertain. There is no experimental animal model. A new disease, Eosinophilia Myalgia Syndrome (EMS) which appeared late in 1989 in the USA, is due to the consumption of impure 1-tryptophan. There may be similarities between the diseases and the aetiological agents for TOS and EMS: possibilities for future research will be discussed. Underlying the time lag for solution of this problem is a lack of knowledge of the basic biology involved.

Synergistic vascular toxicity and fatty acid anilides in the toxic oil syndrome

The underlying etiology of the toxic oil syndrome may be related to any of several toxic contaminants. The hypothesis is made that two or more toxic compounds may act synergistically to cause vascular damage in the toxic oil syndrome. To support this hypothesis, previous studies are reviewed concerning the remarkable synergistic toxic action of allylamine and beta-aminopropionitrile on the media of blood vessels. Although these toxins are not directly related to the toxic oil syndrome, this previous experimental work emphasizes the possibility that unexplored synergistic actions may be important. Furthermore, the hypothesis that contaminating fatty acid anilides in toxic oil undergo alterations during cooking is supported by high pressure liquid chromatographic analysis. The theoretic metabolism of fatty acid anilides is discussed. Recent data concerning the toxic actions of the anilides of oleic and linoleic acid are given. These data suggest that these anilides induce immunologic alterations that may be similar to those seen in the toxic oil syndrome. In addition, the heated anilides appear to have increased toxicity, supporting the concept that the use of toxic oil in cooking may increase its toxicity.

Persistence of respiratory abnormalities four years after the onset of toxic oil syndrome

We studied a random sample of 436 subjects with TOS aged 18 to 60 years, to assess the prevalence of respiratory involvement four years after onset of the syndrome. Clinical evaluation together with chest roentgenograms, electrocardiogram and functional respiratory tests were carried out. Respiratory involvement occurred in 390 (89.4 percent) individuals and was the most common abnormality detected, followed by neurological disorders in 289 (66.3 percent), osteoarticular symptoms in 171 (39.2 percent), psychiatric disorders in 96 (22 percent), hepatic involvement in 91 (20.9 percent), and sclerodermatous sequelae in 89 (20.4 percent). Among patients with respiratory involvement, dyspnea and cough were the most common complaints. Decreased VC was observed in 151 (34.6 percent) patients and reduced transfer factor of CO in 95 (21.8 percent) patients. Airway obstruction and alveolar hypoventilation were observed only in nine (2.1 percent) patients. Six (1.4 percent) patients suffered from pulmonary artery hypertension.

Association of changes in lysophosphatidylcholine metabolism and in microsomal membrane lipid composition to the pulmonary injury induced by oleic acid

Alterations in the lipid composition of lung microsomal membranes occur in oleic acid-induced respiratory distress. The marked decrease in the phosphatidylcholine/lysophosphatidylcholine molar ratio could be related with an altered metabolism of lysophosphatidylcholine in these membranes. Results revealed that the activity of phospholipase A increased whereas that of acyl-CoA:lysophosphatidylcholine acyltransferase decreased. Microsomal lysophospholipase activity remained unchanged. On the other hand, the microsomal enzyme system involved in the de novo synthesis of diacylglycerol was impaired, and cholinephosphotransferase activity was lowered. These changes in the activity of some membrane-bound enzymes were not caused by changes in the membrane lipid fluidity since lipid structural order parameter (SDPH) did not change and neither did the major factors on which the fluidity depends. The possible significance of microsomal lipid alterations in the pathogenesis of respiratory distress induced by oleic acid is discussed.

Microsomal membrane fluidity and phosphatidylcholine synthesis in rabbit lung under high oxygen tension

Phosphatidylcholine metabolism and membrane fluidity were studied in microsomes isolated from rabbit lung, which had been exposed to high oxygen tension for 30 min. In these microsomes the incorporation of [3H]-palmitate into phosphatidylcholine increased whereas the incorporation of [14C]-glycerol and [14C]-choline from CDP-[methyl-14C]-choline remained unchanged in comparison to the control microsomes. The enhanced [3H]-palmitate incorporation may be explained by an increase of the specific activity of acyl-CoA:lysophosphatidylcholine acyltransferase which was measured in microsomes from hyperoxic lung. Although microsomal parameters influencing membrane fluidity, such as the cholesterol/phospholipid molar ratio, unsaturation degree of phospholipid acyl chains and lipid/protein ratio, are altered after oxygen treatment in vivo, no change of fluorescence polarization (PDPH) and lipid structural order parameter (SDPH) could be measured. Probably, the membrane maintains its fluidity by counteracting effects on different factors on which the fluidity depends.

Lyso-phosphatidylcholine is implicated in thioacetamide-induced liver necrosis

Thioacetamide is a weak hepatocarcinogen. To determine whether alterations in lysophosphatidylcholine are implicated in thioacetamide-induced hepatic necrosis, rats were injected i.p. with this agent (50 mg/Kg body weight per day) or diluent for 1, 3, 8 and 30 days. Serum catalytic activities of aminotransferases were determined. Incorporation of (32P)-orthophosphate into hepatic lysophosphatidylcholine was also evaluated in animals killed 75 minutes or 13 hours after isotope administration. Results demonstrate that: A significant increase in hepatic lysolecithin concentration occurs when a maximum level of serum aminotransferases is present. An increase of (32P)-orthophosphate radioactive incorporation in lysolecithin was observed at the two assayed labelling periods, which suggest an activation of phospholipase A. The radioactivity present in lysolecithin after 13 h isotope injection showed a close correlation with serum level of aminotransferases. From these results it can be deduced that lysolecithin is implicated in TAA-induced necrosis and may be generated by increase in either phospholipase A activity and/or synthesis.

Effects of consuming toxic oils and oleoanilides on fat digestibility and adipose tissue composition of rats

An oil implicated in the Spanish "toxic syndrome" was studied for its effect on fat digestibility and adipose-tissue composition in rats. The effects produced by the mixture of oils and those induced by the presence of oleoanilides were assessed separately. For 4 wk, Wistar rats were fed diets containing either a mixture of oils similar to that constituting the toxic oil, the same mixture of oils supplemented with oleoanilides, or the toxic oil (which also contained oleoanilides) and were then compared with a group fed olive oil. Food consumption fluctuated sharply in the group fed the toxic oil, falling significantly in the last week of the study. The digestibility coefficient of the various fats was similar, although the rats fed the toxic oil did absorb less fat because of the lower intake. The nitrogen content of the periovarian adipose tissue was highest in the rats fed the toxic oil, and the adipose-tissue fatty acids most affected by this treatment were linoleic and linolenic acid. The delta-9 desaturase activity, measured in terms of the C16:1/C16:0 and C18:1/C18:0 ratios, was significantly less in the group fed the toxic oil, which suggests functional modifications of the adipocyte related to lipogenesis.

Lipid alterations in liver and kidney induced by normobaric hyperoxia: correlations with changes in microsomal membrane fluidity

The effects of normobaric hyperoxia on both microsomal membrane fluidity and mechanism of phospholipid synthesis in rabbit liver and kidney have been studied. Hyperoxia induces in both organs an impairment of de novo synthesis of glycerolipids which could be due to an inactivation of acyltransferase activities involved in the initial formation of phosphatidic acid. The ability to replace phospholipid fatty acids by reacylation mechanism decreases slightly in the hyperoxic kidney, while it does not change in the hyperoxic liver. Concerning the effect of high arterial pO2 on microsomal membrane fluidity, the hyperoxic liver shows a more fluid environment within the membrane core of microsomes; however, no difference was shown in that of microsomal membrane core of hyperoxic kidney. An insight into the lipid composition of microsomes indicates that liver microsomal membranes have lower cholesterol content and higher unsaturation degree of phospholipid fatty acids, whereas hyperoxic kidney microsomes become more saturated and did not show any difference in their cholesterol content. In both hyperoxic liver and kidney microsomes, phospholipid content decreases in agreement with the depression of phosphatidic acid biosynthesis. These results are discussed in relation to the values of microsomal membrane microviscosity obtained.

Membrane regulation of liver and lung microsomes under low oxygen tension

A highly monitorized animal model has been developed for the study of the influence of low oxygen tension on lipid composition, microviscosity and regulation of enzyme activities involved in the phospholipid synthesis of hepatic and pulmonary microsomes. Microviscosity decreased in liver microsomes whereas no difference was shown in that of microsomal membrane core of hypoxemic lung. Nevertheless, phospholipid and cholesterol content of both liver and lung membranes changed significantly. Microsomal membranes of hypoxemic liver increased the unsaturation degree of fatty acids, whereas hypoxemic lung membranes become more saturated, mainly due to the increase of palmitic acid. The adaptive response of lung was confirmed by the high increase of the deacylation-reacylation mechanism.

The microviscosity of liver plasma membranes of rats fed with oleoylanilide

Oleoylanilide was administered orally to groups of rats according to different patterns. Oleoylanilide was perfused at different concentrations through rat liver. Oleoylanilide was added to isolated hepatocytes. Oleoylanilide was added to plasma-membrane preparations. Membrane preparations were obtained after experiments performed in vivo and perfusion experiments and, by using 1,6-diphenylhexa-1,3,5-triene as fluorescence probe, the fluorescence polarization parameter was measured, from which the microviscosity (eta) was calculated. In all cases the microviscosity decreased markedly. Addition of oleoylanilide to hepatocyte preparations and to isolated membranes produced the same effect, increasing the fluidity of the membranes. These data suggest that oleoylanilide partitions into the membrane, disordering some lipid interactions.

Substrate selectivity of lysophosphatidylcholine: lysophosphatidylcholine acyltransferase from rabbit lung

The influence of both polar group and acyl chain of lysophospholipids on the lysophosphatidylcholine: lysophosphatidylcholine acyltransferase from rabbit lung was studied. Both, transacylase and hydrolase activities of this enzyme, utilize selectively 1-[1-14C]palmitoyl-sn-glycero-3-phosphocholine when compared with 1-[9,10-3H2]palmitoyl-sn-glycero-3-phosphoethanolamine. Transacylase activity is more selective for lysophosphatidylcholine as acyl acceptor than as acyl donor. The amount of dipalmitoylphosphatidylcholine/min/mg protein synthesized from mixed lysophosphatidylcholine/lysophosphatidylethanolamine micelles does not change with increasing molar percentages of lysophosphatidylethanolamine in the mixture and is similar to that formed with pure lysophosphatidylcholine micelles. Transacylation reaction takes place preferentially with long and saturated acyl chains whereas hydrolysis reaction does more efficiently with longer acyl chains, independently of their insaturation degree.

Effect of fatty acid anilides on the generation of arachidonic acid by human polymorphonuclear leukocytes

The addition of oleoylanilide or linoleylanilide to human polymorphonuclear leukocytes induces a time- and dose-dependent generation of arachidonic acid. Half-maximal effect is caused by a dose of 0.2 mg linoleylanilide/ml. Fatty acid anilides also produce a time- and dose-dependent inhibition of the synthesis of triacylglycerol. Half-maximal effect is caused by 1 microgram linoleylanilide/ml. These results indicate that fatty acid anilides, which have been found in the illegal cooking oil which intoxicated thousands of Spaniards, alter lipid metabolism in human polymorphonuclear leukocytes.