A relationship between toxicity and chemical nature

The maximum allowable concentration of any chemical substance can be estimated with some degree of confidence solely on the basis of the chemical groups and structure it contains. The derivation of this methodology from the U. S. Dept. of Labor Occupational Health and Environmental Control Air Contaminants List (1972) is described.     

Relationship between exercise-induced changes in serum and hepatic cholesterol metabolism in rats

The purpose of the present study was to determine the effects of exercise training on serum cholesterol level and hepatic cholesterol metabolism in rats. Twenty-four male Wistar strain rats, aged 6 weeks, were assigned to one of three experimental groups; control (n = 8), exercised 20 minutes a day (E20, n = 8), and exercised 60 minutes a day (E60, n = 8). Rats were sacrificed after ten weeks exercise. The levels of serum total cholesterol and HDL-cholesterol in the group E20 and group E60 were lower than that of control, 8% and 24% (p less than 0.01) for the total cholesterol and 10% and 24% (p less than 0.05) for the HDL-cholesterol, respectively. The activity of HMG-CoA reductase in liver microsome was significantly higher in the group E60 than that of control. The hepatic microsomal HMG-CoA reductase activity was negatively related to serum total (r = -0.62, p less than 0.01) and HDL (r = -0.58, p less than 0.01) cholesterol levels. From these results, we concluded that the enhancement of the cholesterol metabolism in the liver by exercise is a major course of the exercise-induced change in serum cholesterol of Wistar rats.     

Metabolism of ochratoxin B and its possible effects upon the metabolism and toxicity of ochratoxin A in rats

A metabolic product was formed from ochratoxin B by rat liver microsomal fractions in the presence of NADPH. It was isolated from the incubation mixture by extraction, thin-layer chromatography, high-pressure liquid chromatography, and crystallization. On the basis of mass and nuclear magnetic resonance spectroscopy, the structure is suggested to be 4-hydroxyochratoxin B. The Km for the formation of 4-hydroxyochratoxin B was determined, and the hydroxylation of ochratoxin A was not altered by the presence of ochratoxin B. Rats were given ochratoxin A or B, or a mixture of both intraperitoneally. The ratios of the three metabolites, ochratoxin A, (4R)-4-hydroxyochratoxin A, and ochratoxin alpha, excreted in the urine did not change in the presence of ochratoxin B. Ochratoxin B was metabolized to 4-hydroxyochratoxin B and ochratoxin beta, but in a different ratio than for the ochratoxin A metabolites. When given intraperitoneally, ochratoxin beta was excreted within 24 h. In rats treated with ochratoxin A alone, the food intake was reduced by 50%, and histologically severe lesions, degeneration, and necrosis were observed in the proximal tubules. When ochratoxin A and B given in combination, the animals were clinically unaffected and histologically there was only slight damage of proximal tubules. These observations indicate that ochratoxin B considerably reduces the toxic effects of ochratoxin A.     

Overview of coenzyme A metabolism and its role in cellular toxicity

Coenzyme A (CoASH) has a clearly defined role as a cofactor for a number of oxidative and biosynthetic reactions in intermediary metabolism. Formation of acyl-CoA thioesters from organic carboxylic acids activates the acid for further biotransformation reactions and facilitates enzyme recognition. Xenobiotic carboxylic acids can also form CoA-thioesters, and the resulting acyl-CoA may contribute to the compound's toxicity. Generation of an unusual or poorly-metabolized acyl-CoA from a xenobiotic may lead to cellular metabolic dysfunction through several types of mechanisms including: (1) inhibition of key metabolic enzymes by the acyl-CoA; (2) sequestration of the total cellular CoA pool as the unusual acyl-CoA; (3) physical-chemical effects of the acyl-CoA; and (4) sequestration and depletion of carnitine as the acyl group is transformed from the acyl-CoA to form the corresponding acylcarnitine. Many of these toxicities are similar to sequelae observed in the inherited organic acidurias in which endogenously-generated acyl-CoAs accumulate secondary to an enzymopathy. Insights into the cellular mechanisms of xenobiotic acyl-CoA accumulation have been derived from model systems developed to understand organic acidemias, such as the methylmalonyl-CoA accumulation of the methylmalonic acidurias. The relevance of acyl-CoA accretion to human pathophysiology has now been well established, and identification of the relevant mechanism of toxicity can allow implementation of strategies to minimize the metabolic injury. Additionally, recognition of the potential for acyl-CoA mediated xenobiotic injury should result in improved rational drug design and earlier recognition of such toxicity when it develops.     

Relationship between the level of serum L-tryptophan and its hepatic uptake and metabolism in rats with carbon tetrachloride-induced liver cirrhosis

Summary In the serum of rats with liver cirrhosis induced by 12-week intermittent carbon tetrachloride (CCl₄) injection, free L-tryptophan (Trp) levels increased with decreases in total Trp, albumin-bound Trp, and albumin levels. In the serum of the cirrhotic rats, there were no changes in the ratio of albumin-bound Trp to albumin and the level of free fatty acids which are known to weaken the binding of Trp to albumin. In the liver of the cirrhotic rats, there were increases in protein and free Trp (i.e., non-protein Trp) contents and a decrease in total tryptophan 2,3-dioxygenase (TDO) activity. The decreased TDO activity was mainly due to the reduction of apo-TDO activity. When [³H]Trp was injected into the portal vein of the cirrhotic and control rats, radioactivity derived from the injected [³H]Trp in the liver was higher in the cirrhotic rats than in the control rats at 10min after the injection, while the radioactivity in the serum was lower in the former rats than in the latter rats. These results indicate that the increased Trp is easily taken up into the cirrhotic liver, and suggest that the Trp taken up into the cirrhotic liver could be utilized for the maintenance of synthesis of proteins in the tissue through the reduction of Trp metabolism due to reduced TDO activity in the tissue.     

Metabolism of ochratoxin B and its possible effects upon the metabolism and toxicity of ochratoxin A in rats.

A metabolic product was formed from ochratoxin B by rat liver microsomal fractions in the presence of NADPH. It was isolated from the incubation mixture by extraction, thin-layer chromatography, high-pressure liquid chromatography, and crystallization. On the basis of mass and nuclear magnetic resonance spectroscopy, the structure is suggested to be 4-hydroxyochratoxin B. The Km for the formation of 4-hydroxyochratoxin B was determined, and the hydroxylation of ochratoxin A was not altered by the presence of ochratoxin B. Rats were given ochratoxin A or B, or a mixture of both intraperitoneally. The ratios of the three metabolites, ochratoxin A, (4R)-4-hydroxyochratoxin A, and ochratoxin alpha, excreted in the urine did not change in the presence of ochratoxin B. Ochratoxin B was metabolized to 4-hydroxyochratoxin B and ochratoxin beta, but in a different ratio than for the ochratoxin A metabolites. When given intraperitoneally, ochratoxin beta was excreted within 24 h. In rats treated with ochratoxin A alone, the food intake was reduced by 50%, and histologically severe lesions, degeneration, and necrosis were observed in the proximal tubules. When ochratoxin A and B given in combination, the animals were clinically unaffected and histologically there was only slight damage of proximal tubules. These observations indicate that ochratoxin B considerably reduces the toxic effects of ochratoxin A.     

Zinc inhibition of hepatic fructose metabolism in rats

The ability of Zn to modulate key metabolic processes was investigated in a study of gluconeogenesis in isolated hepatocytes from fasted rats. Zn (100 μM) inhibited glucose production from fructose by 41%, sorbitol by 28%; glycerol by 17%, and glyceraldehyde by 26%. Maximum inhibition of gluconeogenesis from fructose occurred at 25 μM Zn. Zn inhibited the rate of lactate production from fructose by 24% but not from sorbitol, glycerol, or glyceraldehyde. Fructose uptake by hepatocytes was not affected by Zn. A positive linear relationship (r=0.994) was obtained between inhibition by Zn of glucose and lactate production, indicating that a common step in both pathways is inhibited by Zn. The effect of Zn on fructokinase, aldolase-B, and triokinase activities was determined on semipurified rat liver enzyme preparations. Zn had no affect on triokinase activity but inhibited the two other enzymes in a dose-dependent manner, with the inhibition of aldolase-B being much greater than of fructokinase for concentrations of Zn between 2.5 and 20 μM. Zn increased the intracellular concentration of fructose-1-P in hepatocytes incubated with fructose, indicating a more potent Zn inhibition of aldolase-B than fructokinase. In addition, hepatocytes treated with Zn had decreased ATP and ADP concentrations, but had normal energy charge, suggesting an effect of Zn on adenine nucleotide degradation or synthesis. The demonstration that Zn inhibits two enzymes in fructose metabolism adds to the growing list of metabolic pathways that are catalyzed by enzymes that are sensitive to Zn.     

The effects of vitamin A deficiency on hepatic folate metabolism in rats

The effects of severe vitamin A deficiency (liver retinol less than 2 micrograms/g) on hepatic folate metabolism in rats were studied. The oxidation of a [ring-2-14C] histidine load or a [14C]formate load to 14CO2 was significantly depressed in vitamin A-deficient rats and those given histidine also excreted more urinary formiminoglutamic acid (FiGlu) than pair-fed controls. The increase in FiGlu excretion was not due to augmented production from histidine, implicating an impairment of FiGlu catabolism. FiGlu formiminotransferase activity was unaltered in vitamin A-deficient rats, but hepatic tetrahydrofolic acid (THF) concentration was decreased by 58% in vitamin A-deficient rats given a histidine load while 5-methyl-THF concentration was increased by 39%. Formyl-THF and total folate levels were similar to controls. A redistribution of folate coenzymes was not found in vitamin A-deficient rats not force fed histidine. A 43% decrease in 10-formyl-THF dehydrogenase activity, which generates both THF and the 14CO2 from the labeled substrates, and an 81% increase in 5,10-methylene-THF reductase activity, which generates 5-methyl-THF, were found in vitamin A-deficient rats. It appears that the production of severe vitamin A deficiency results in selective changes in the activities of hepatic folate-dependent enzymes, so that when a load of a one-carbon donor is given, THF concentration decreases and metabolism of the load is impaired.     

Perinephric and epididymal fat affect hepatic metabolism in rats

The present study examined whether the perinephric and epididymal visceral fat (PEVF) depot under short-term excess nutrient protected the liver by trapping nutrient-derived nonesterified free fatty acids (NEFAs) or had deleterious effects on hepatic triglycerides (TGs) accumulation and insulin resistance due to adipokine secretion. Young rats pre-emptively underwent surgical PEVF removal or sham operations and were fed with either high-fat diet (HFD) (PEVF-HFD) or regular chow (RC) (PEVF-RC) for 3 days. Insulin sensitivity was measured by hyperinsulinemic-euglycemic clamp. Liver TG, serum NEFA, and fat-derived adipokines were assessed. Insulin and lipogenesis signaling were assessed by western blots. Pre-emptive PEVF removal significantly decreases insulin-induced suppression of hepatic glucose production (HGP) both in RC and in HFD-fed rats. In accordance with the clamp results, hepatic TG accumulation is also significantly reduced by PEVF excision both in RC and HFD-fed rats. These results are further validated by insulin signaling results, which show that pre-emptive PEVF removal increases phosphorylation of hepatic Akt, irrespective of diet. Notably, high levels of serum leptin induced by HFD are significantly reduced by pre-emptive PEVF excision. Additionally, expression of lipogenic enzyme p-acetyl-CoA-carboxylase, denoting reduced lipogenesis, is increased in the PEVF-HFD rats. In conclusion, PEVF has a deleterious effect on the liver as a source of insulin resistance-inducing adipokines irrespective of diet, and does not serve as a buffer for excess nutrients.     

Effects of thyrotoxicosis and selective hepatic autonomic denervation on hepatic glucose metabolism in rats

Thyrotoxicosis is known to induce a broad range of changes in carbohydrate metabolism. Recent studies have identified the sympathetic and parasympathetic nervous system as major regulators of hepatic glucose metabolism. The present study aimed to investigate the pathogenesis of altered endogenous glucose production (EGP) in rats with mild thyrotoxicosis. Rats were treated with methimazole in drinking water and l-thyroxine (T(4)) from osmotic minipumps to either reinstate euthyroidism or induce thyrotoxicosis. Euthyroid and thyrotoxic rats underwent either a sham operation, a selective hepatic sympathetic denervation (Sx), or a parasympathetic denervation (Px). After 10 days of T(4) administration, all animals were submitted to a hyperinsulinemic euglycemic clamp combined with stable isotope dilution to measure EGP. Plasma triiodothyronine (T(3)) showed a fourfold increase in thyrotoxic compared with euthyroid animals. EGP was increased by 45% in thyrotoxic compared with euthyroid rats and correlated significantly with plasma T(3). In thyrotoxic rats, hepatic PEPCK mRNA expression was increased 3.5-fold. Relative suppression of EGP during hyperinsulinemia was 34% less in thyrotoxic than in euthyroid rats, indicating hepatic insulin resistance. During thyrotoxicosis, Sx attenuated the increase in EGP, whereas Px resulted in increased plasma insulin with unaltered EGP compared with intact animals, compatible with a further decrease in hepatic insulin sensitivity. We conclude that chronic, mild thyrotoxicosis in rats increases EGP, whereas it decreases hepatic insulin sensitivity. Sympathetic hepatic innervation contributes only to a limited extent to increased EGP during thyrotoxicosis, whereas parasympathetic hepatic innervation may function to restrain EGP in this condition.     

Variation in the metabolism of radiocaesium between individual sheep

Considerable variability has been recorded in the radiocaesium activity concentration of muscle between individual sheep in the same flocks in upland areas that received fallout from the Chernobyl accident. In a previous paper we demonstrated that there is a propensity for certain sheep within a flock to be always amongst the most contaminated and others to be consistently the least contaminated. Here we report a study to determine the extent to which variation in the metabolism of radiocaesium by individual sheep may contribute to the observed variability within sheep flocks. The transfer coefficient and biological half-life of orally administered ionic radiocaesium in muscle were determined under controlled conditions in 22 ewes from an upland farm in an area of the UK which received comparatively high levels of Chernobyl fallout. There was considerable variation between individuals in both the transfer coefficient (0.19–0.56 day⋅kg^–1; mean 0.34 day⋅kg^–1) and biological half-life in muscle (5.2– 18.7 days; mean 9.8 days). Changes in liveweight during the study and feed intake together accounted for 72% of the variation in the derived transfer coefficients; liveweight change also accounted for 56% of the observed variation in biological half-life. In a subsequent study, the true absorption coefficient of radiocaesium was determined in 12 of the ewes. There was a positive correlation between transfer and true absorption coefficients (R=0.57). We conclude that differences in the metabolism of radiocaesium will contribute to the observed variability in radiocaesium activity concentrations within sheep flocks in areas which were contaminated by Chernobyl fallout. We also suggest that for growing animals, the influence of liveweight change and feed intake on radiocaesium transfer may be greater than observed here. Similarly, in dairy cattle, for which feed intake changes considerably during the course of a lactation, large temporal variation in radiocaesium transfer to milk could be expected. Received: 10 August 1998 / Accepted in revised form: 20 October 1998     

Model-based compartmental analysis indicates a reduced mobilization of hepatic vitamin A during inflammation in rats

Vitamin A (VA) kinetics was studied in rats with marginal VA stores before, during, and after inflammation. Rats received orally [11,12-(3)H(N)]retinol ([(3)H]VA; day 0), and inflammation was induced on day 21 with lipopolysacchride (LPS) for 3 days (n = 5) or recombinant human interleukin-6 (rhIL-6) for 7 days (n = 5). Both the fraction of [(3)H]VA and retinol concentrations in plasma were reduced significantly by LPS or rhIL-6. Compartmental analysis using the Windows version of Simulation, Analysis, and Modeling software was applied to group mean data, and non-steady-state models were developed. After absorption, VA kinetics was described by a three-compartment model that included plasma, kidney/interstitium, and liver/carcass. Four mechanisms decreasing plasma retinol were investigated: increased urinary excretion, increased irreversible loss, increased movement into interstitium, and decreased hepatic mobilization. Modeling demonstrated that a 79% reduction in hepatic mobilization of retinol (from 4.3 to 0.9 nmol/h) by 15 h after LPS best accounted for the observed changes in plasma VA kinetics (sum of squares = 9.05 x 10(-07)). rhIL-6 caused an earlier reduction (75% by 5.6 h). These models predicted a return to control values by 10 days after inflammation. If prolonged, inflammation-induced hyporetinolemia can render hepatic retinol unavailable to extrahepatic tissues, possibly leading to their impaired function, as observed in VA-deficient children with measles infection.     

Vitamin A status and its metabolism contribute to the regulation of hepatic genes during the cycle of fasting and refeeding in rats

Vitamin A (VA) status and its metabolism affect hepatic metabolic homeostasis. We investigated if VA status and metabolism contribute to energy metabolism and expression of hepatic genes in the cycle of fasting and refeeding. Zucker lean rats with VA sufficient (VAS) or VA deficient (VAD) status were respectively grouped as: ad libitum (VAS-AD or VAD-AD), 48-h fasted (VAS-Fasted or VAD-Fasted), 48-h fasted and refed a VAS diet (VAS-Refed-VAS or VAD-Refed-VAS), or refed a VAD diet (VAS-Refed-VAD or VAD-Refed-VAD) for 6 h. Respiratory exchange ratio (RER) of rats fed the VAS or VAD diet was monitored for 6 weeks. From week four, rats fed the VAS diet had higher RER than those fed the VAD diet. VAS-Refed rats had higher plasma levels of glucose, triglyceride, insulin and leptin than VAD-Refed rats. The mRNA and protein levels of hepatic genes for fuel metabolism in the fasting and refeeding cycle were determined using real-time polymerase chain reaction and immunoblot, respectively. The mRNA levels of glucokinase (Gck), sterol regulatory element-binding protein 1c (Srebp-1c), and fatty acid synthase (Fas) were lowered in VAS-Fasted and VAD-Fasted rats, and increased in VAS-Refed-VAS, VAS-Refed-VAD and VAD-Refed-VAS, but not VAD-Refed-VAD, rats. The ACL and FAS protein levels only dropped in VAS-Fasted rats and increased in VAS-Refed-VAS rats. The GK protein level decreased only in VAS-Fasted rats, and increased in VAS-Refed-VAS, VAS-Refed-VAD and VAD-Refed-VAS (but not VAD-Refed-VAD) rats. We conclude that VA status and its metabolism in the fasting and refeeding cycle contribute to the regulation of hepatic gene expression in rats.