Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: UMLS:C0042875 (vitamin E deficiency)
916 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

One hundred and twenty female mice fed diets containing various levels of vitamin E were continuously exposed to 0.5 ppm, 1.0 ppm nitrogen dioxide (NO2), and filtered air for 17 months. Blood, lung, and liver tissues were assayed for glutathione peroxidase (GSH-peroxidase) activity. Exposure to 0.5 ppm NO2 did not affect blood and lung GSH-peroxidase activity; 1.0 ppm NO2 exposure, however, caused suppression of the enzyme. A combination of vitamin E deficiency and 1.0 ppm NO2 exposure resulted in the lowest GSH-peroxidase activities in the blood and lung. High levels of vitamin E in the diet resulted in elevated GSH-peroxidase in the blood and lung. Liver GSH-peroxidase activity was unaffected by either dietary vitamin E or NO2 exposure. No inverse relationship was found between GSH-peroxidase levels and concentrations of organic solvent soluble lipofuscin pigments present in tissues.
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PMID:Long-term NO2 exposure of mice in the presence and absence of vitamin E. II. Effect of glutathione peroxidase. 73 11

A survey is given of vitamin E and selenium deficiency syndromes in farm animals. Some syndromes can be attributed to the exclusive deficiency of one of the above-mentioned feed components. In some cases with practically complete lack of both componentspathological symptoms can be cured by the addition of one of them to the feed in sufficient amount. A synergistic effect of vitamin E and selenium is sometimes found to recur. The most important theory about the functioning of vitamin E is that it acts as an antioxidant. This theory presumes that, in case of a vitamin E deficiency, peroxidation of unsaturated lipids can occur everywhere in the body leading to oxidative chain reactions. The free radicals thus produced might participate in non-specific reactions with functional and structural compounds. Vitamin E is considered able to reduce lipid peroxides or scavenge free radicals from chain reactions. The pros' and cons' of this theory are discussed. The role of vitamin E has further been associated with thenium is part of the enzyme glutathione peroxidase. This enzyme catalyses the reaction of reduced glutathione with peroxides, whereby hydroxy-acids and oxidized glutathione are generated. Most probably the glutathione peroxidase has its antioxidative action in the cytosol, whereas vitamin E is mainly located in the membranes of the cell.
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PMID:[Vitamin E and selenium in the feed of farm animals (author's transl)]. 123 79

The influence of dietary peroxides, vitamin E and selenium on glutathione peroxidase (GSH-Px) activity in the gastrointestinal tract of the rat was investigated. Feeding 7% oxidized stripped corn oid (peroxide value 1,000) in a diet adequate in selenium and vitamin E increased the specific activity of GSH-Px in the stomach mucosa. Feeding oxidized oil produced an increase in the wet weight of the intestinal mucosa which was associated with a decrease in the specific activity of the enzyme. Total GSH-Px activity in the intestinal mucosa was unchanged or moderately increased. These changes were unaffected by the presence of vitamin E in the diet. Dietary peroxides had no effect on GSH-Px activity in the plasma or in the perirenal and paraepididymal adipose tissues. Subacute vitamin E deficiency had no consistent effect on the activity of the enzyme in several tissues examined. In rats fed a Se deficient diet glutathione peroxidase activity decreased markedly in most tissues but only slightly in the intestinal mucosa. The moderate decrease in the intestine may be explained by the accessibility of residual dietary Se to the mucosal cells. The role of Se in the detoxification of peroxides in foods and the response of gastrointestinal GSH-Px to dietary peroxides are discussed.
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PMID:Influence of dietary peroxides, selenium and vitamin E on glutathione peroxidase of the gastrointestinal tract. 126 68

Vitamin E and selenium (Se) interact synergistically as an important antioxidant defense mechanisms. Se, an essential component of glutathione peroxidase (GSH-Px) and vitamin E decompose fatty acid hydroperoxides and hydrogen peroxides generated by free radical reactions. Vitamin E and GSH-Px may modulate arachidonic acid metabolism and the activity of cyclooxygenase enzymes by affecting peroxide concentration. The balance between arterial wall prostacyclin (PGI2) production and platelet thromboxane (TX)A2 directly influences platelet activity. In order to elucidate the differential role of dietary vitamin E and Se in aortic PGI2 and platelet TXA2 synthesis, 1-mo-old F344 rats were fed semipurified diets containing different levels of vitamin E (0, 30, 200 ppm) and Se (0, 0.1, 0.2 ppm) for 2 mo. Thromboxane B2 (TXB2) and 6-keto-PGF1 alpha, were measured by radioimmunoassay (RIA) after incubation of whole blood and aortic rings at 37 degrees C for 10 and 30 min, respectively. Vitamin E deficiency reduced plasma vitamin E to 5-17% of control-fed rats, and supplementation in vitamin E-supplemented animals increased plasma GSH-Px by 17%, compared to vitamin E-deficient rats. Se and vitamin E supplementation did not have a similar effect on TXB2 and PGI2 synthesis. Se deficiency did not alter platelet TXB2 synthesis, but significantly decreased aortic PGI2 synthesis. It was necessary to supplement with both antioxidants in order to increase PGI2 synthesis. Se and vitamin E deficient groups had a higher TXB2/PGI2 ratio (0.17 +/- 0.08) compared to Se- and vitamin E-supplemented groups (0.03 +/- 0.01).(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Modulation of the platelet thromboxane A2 and aortic prostacyclin synthesis by dietary selenium and vitamin E. 137 63

Age-related alterations in both antioxidant capacity and lipid peroxidation in the cerebrum, lung and liver homogenates of normal and vitamin E-deficient rats were investigated. The antioxidant capacity, which includes superoxide dismutase, catalase and glutathione peroxidase activities and vitamin E (alpha-tocopherol) concentration, was relatively stable throughout the lifespan. It was observed, however, that catalase and glutathione peroxidase activities in livers of old rats decreased and that vitamin E concentration in lung and liver increased with age. In vitamin E-deficient animals, catalase activity in liver increased and glutathione peroxidase activity in liver and lung decreased. Lipid peroxidation was monitored by use of three different indices, i.e. the thiobarbituric acid (TBA) value, oxygen absorption and conjugated-diene formation. In the absence of any initiator, neither oxygen absorption into tissue homogenates nor conjugated-diene formation in lipid extracts from the homogenates occurred. The TBA value of each cerebrum homogenate incubated under air or an oxygen atmosphere was larger than that of the corresponding unincubated cerebrum homogenate. From comparison between the TBA value and oxygen absorption, this increase in the TBA value was suggested to be due to some reactions other than lipid peroxidation. Although tissue homogenates examined contained TBA-reacting materials, no lipid peroxidation seems to arise during incubation of them. No age-related alterations in the TBA value and oxygen absorption in rat tissue homogenates were observed. Vitamin E deficiency had no effect on the TBA values of cerebrum and lung homogenates, while it seemed to increase the TBA values of liver homogenates. Vitamin E deficiency had no effect on oxygen absorption in these tissue homogenates. The induction period of initiator-induced conjugated-diene formation in lipid extracts from liver and lung homogenates from normal and vitamin E-deficient rats tended to be extended with age. Vitamin E deficiency decreased the induction period of initiator-induced conjugated-diene formation. As a result, the length of the induction period was found to be proportional to vitamin E concentration in lipid extracts. The overall antioxidant capacity of rat tissues appears to be maintained without large variation during ageing. Decreases in the capacity of some antioxidant factors may be compensated by increases in the capacity of other factors.
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PMID:Age-related alterations in antioxidant capacity and lipid peroxidation in brain, liver, and lung homogenates of normal and vitamin E-deficient rats. 140 85

The metabolic relationships among the antioxidant nutrients selenium, sulfur, and vitamin E are particularly close. Selenium and vitamin E have long been known to spare one another in certain nutritional diseases of animals, and selenium has been considered to have a key antioxidant defense function as a component of glutathione peroxidase. However, the antioxidant role of glutathione peroxidase has been questioned and new proteins containing selenium have been identified: phospholipid hydroperoxide glutathione peroxidase, selenoprotein P, and iodothyronine deiodinase. Glutathione peroxidase activity independent of selenium resides in the glutathione S-transferases. Glutathione participates in both enzymatic and nonenzymatic antioxidant defense systems. Some low-molecular weight selenium compounds (e.g., ebselen) exhibit glutathione peroxidase-like action. Certain low molecular weight thiols decompose peroxides nonenzymatically (e.g., the ovothiols). Murine malaria appears to be a useful experimental model for investigating interrelationships of selenium and vitamin E. Vitamin E deficiency protects against the parasite, especially when the mice are concurrently fed peroxidizable fat such as fish or linseed oils. Selenium deficiency, on the other hand, has little or no protective effect against the parasite. Any practical utility of pro-oxidant diets in combating human malaria remains to be determined.
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PMID:Selenium and sulfur in antioxidant protective systems: relationships with vitamin E and malaria. 157 91

1. Food selenium content, selenium supply and selenium needs are presented, along with methods of evaluation of selenium status. Glutathione peroxidase, a selenium-containing enzyme, is ubiquitous in the organism. 2. Some experimental studies on animal models reported a positive relationship between selenium status and resistance against infections. 3. Only one study in humans concerned the mechanisms of immune functions in selenium deficiency. Several experimental works suggest that severe selenium deficiency compromises T-cell dependent immune functions such as the blastogenic response to mitogens, but selenium deficiency was concomitant with vitamin E deficiency in most of them. Delayed hypersensitivity response is controversial in selenium-supplemented rats and guinea-pigs. 4. Selenium deficiency in animals decreases the antibody response, especially if associated with vitamin E deficiency. Low dietary selenium supplementation of healthy animals has a positive effect upon humoral responses. 5. Despite some controversies, most experimental studies on selenium-deficient animals report normal phagocytosis and an altered bactericidal capacity of neutrophils. The decrease in glutathione peroxidase activity of polymorphonuclear cells following selenium deficiency could explain some of these alterations. 6. Splenic Natural Killer cells activity is enhanced in selenium-supplemented, healthy animals.
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PMID:Relationship between selenium, immunity and resistance against infection. 198 Apr 38

In AUG rats, deprived of vitamin E for 90 days, we noted a 3-fold increase of kinetic parameters of luminol-dependent chemiluminescence of macrophages, stimulated with opsonized zymosan, superoxide dismutase activity decrease and increment of plasma membrane lipid bilayer microviscosity, which was estimated by fluorescent probe pyrene eximerization method. Vitamin E deficiency did not affect glutathione peroxidase and glutathione reductase activities of macrophages.
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PMID:Effect of vitamin E deficiency on oxidative metabolism and antioxidant enzyme activity of macrophages. 240 45

To determine whether vitamin E protects against thyroxine-induced oxidative stress in heart and soleus (slow oxidative) muscles, lipid peroxide (thiobarbituric acid-reactive substances) and antioxidant enzymes were measured in those tissues of hyperthyroid rats supplemented with vitamin E. The rats were rendered hyperthyroid by the administration of L-thyroxine in their drinking water. In experiment (EXPT) I, 30 mg/kg/dose of alpha-tocopheryl acetate was administered to the vitamin E-treated group. In EXPT II, the rats were fed a diet containing either less than 1 IU/kg (deficient diet), 20 IU/kg (control E diet), or 500 IU/kg (high E diet) of vitamin E and hyperthyroidism was induced. In EXPT I, hyperthyroidism induced an increase in oxidative enzymes, mitochondrial superoxide dismutase and lipid peroxide level, and a decrease in cytosolic superoxide dismutase, glutathione peroxidase and catalase in both tissues. Vitamin E treatment inhibited the increase in lipid peroxide level totally in the heart and partially in the soleus, with minimal changes in the other biochemical indices studied. In EXPT II, the lipid peroxide level was markedly increased in both tissues of the vitamin E-deficient group, and decreased in those of the group fed high E diet. There were some adaptive changes in the levels of cytosolic superoxide dismutase, glutathione peroxidase, and catalase in response to vitamin E deficiency, whereas neither oxidative enzymes nor mitochondrial superoxide dismutase were altered. These results suggest that vitamin E protects against lipid peroxidation in hyperthyroid heart and skeletal muscle independently of the changes in oxidative enzymes and antioxidant enzymes.
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PMID:Vitamin E protects against thyroxine-induced acceleration of lipid peroxidation in cardiac and skeletal muscles in rats. 263 76

Vitamin E and glutathione protect against oxidative damage in vivo. In this study the relationship between these two defenses has been examined in the isolated perfused rat liver. The activities of glutathione reductase and glutathione S-transferase were unaffected by vitamin E deficiency, while glutathione peroxidase activity was decreased slightly. The glutathione redox status of vitamin E-deficient and control livers was assessed. GSSG was slightly higher in vitamin E-deficient livers (70 +/- 5 nmol GSH equivalents/g liver) than in controls (56 +/- 3 nmol GSH equivalents/g liver) under basal conditions. However, biliary GSSG release was 41% lower in vitamin E-deficient livers (0.46 +/- 0.08 nmol GSH equivalents/g liver.min) than in controls (0.78 +/- 0.23 nmol GSH equivalents/g liver.min). Inhibition of GSSG reduction by BCNU raised liver and biliary GSSG by a similar amount in vitamin E-deficient and control livers. Thus biliary GSSG efflux, a frequently used index of oxidant stress, is not increased in vitamin E-deficient perfused livers compared with control. Therefore, in the perfused rat liver model, no evidence was obtained that vitamin E deficiency activates the hepatic glutathione system.
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PMID:Tissue and biliary glutathione disulfide in the perfused vitamin E-deficient rat liver. 272 89


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