Effect of retinol on the hemolysis and lipid peroxidation in vitamin E deficiency

A study on the effect of retinolin vitro on the hemolysis of vitamin E deficient rat red blood cells showed that retinol enhanced the lysis of the E deficient cells as compared to the lysis of normal cells. The lipid peroxidation present during hydrogen peroxide induced lysis of E deficient cells was however markedly inhibited in the presence of retinol without affecting the rate of lysis. In an actively peroxidising system of non-enzymatic lipid peroxidation of rat liver or brain homogenates and of brain lysosomes incubated with human erythrocytes, no lysis was obtained; incorporation of retinol in such systems resulted in lysis but no peroxidation. Hydrogen peroxide generating substances almost completely inhibited the lysis of normal human erythrocytes by retinol, but linoleic acid hydroperoxide and auto-oxidised liver or brain homogenates and ox-brain liposomes increased the lysis. It is concluded that vitamin E deficient erythrocyte hemolysis may be augmented by retinol, an anti-oxidant, having a lytic function without the peroxidation of stromal lipids     

Zinc,iron, vitamin E,and erythrocyte stability in the rat

Previous studies have shown that deficiencies of zinc and vitamin E, as well as iron excess, contribute to peroxidative damage in several tissues in vivo. The present study reports on the sensitivity of red blood cells from young rats exposed to individual or concurrent imbalances of these three nutrients. For 21 d, rats were fed diets that were either deficient or replete in zinc and with or without excess iron or replete or deficient in vitamin E. When red blood cells from these rats were incubated in vitro, erythrocyte hemolysis, lipid peroxidation (assessed by MDA production), and hemoglobin degradation (assessed by alanine release), did not significantly increase unless vitamin E had been omitted from the diet. These results imply that either adequate tightly-bound zinc exists within the zinc-deficient cell to protect it from oxidative damage, or that other antioxidant defense mechanisms (including vitamin E) present within the plasma membrane and cytosol are sufficient to protect the cell from the otherwise damaging effects of zinc deficiency and/or iron excess.     

Role of vitamin E in ascorbate-dependent protein thiol oxidation in rat liver endoplasmic reticulum

Addition of ascorbate or its generation from gulonolactone causes the oxidation of protein thiols and a simultaneous dehydroascorbate formation in rat liver microsomes. The participation of vitamin E in the phenomenon was studied. We measured ascorbate and protein thiol oxidation and lipid peroxidation in vitamin E deficient liver microsomes. Vitamin E deficiency partly uncoupled the two processes: ascorbate oxidation increased, while protein thiol oxidation decreased. These changes were accompanied with an accelerated lipid peroxidation in the vitamin E-deficient microsomes, which indicates the accumulation of reactive oxygen species. All these effects were reduced by the in vitro addition of vitamin E to the deficient microsomes, supporting its direct role in the process. The results demonstrate that vitamin E is a component of the protein thiol oxidizing machinery in the hepatic endoplasmic reticulum transferring electrons from the thiol groups towards oxygen.     

Investigations into combined dietary deficiencies of copper,selenium, and vitamin E in the rat

Interactions between dietary Cu, Se, and vitamin E in ascorbate-induced hemolysis of erythrocytes obtained from rats fed diets deficient or adequate in these elements were investigated. Hemolysis was affected by all three dietary factors, through closely interrelated but distinct mechanisms. In vitamin E-deficient cells, hemolysis was increased and the amount of hemolysis was directly related to the amount of hemoglobin breakdown. Deficiency of Cu or Se decreased hemolysis, but only in vitamin E-deficient cells. Vitamin E did not affect the breakdown of hemoglobin, but Cu and Se did. Hemolysis and hemoglobin breakdown were decreased by the addition of glucose, through mechanisms independent of that involving reduced glutathione metabolism. These results suggest that vitamin E acts within erythrocyte membranes to prevent products of hemoglobin breakdown from initiating peroxidation and subsequent hemolysis. Effects of Cu and Se are linked with that of vitamin E by the involvement of glutathione peroxidase and Cu superoxide dismutase in the cytoplasmic breakdown of hemoglobin, rather than by a direct effect of these enzymes on lipid peroxidation. It is concluded that the erythrocyte, because of its high heme content, probably represents a special system in terms of peroxidative pathways, and these findings may not be directly applicable to other tissues.     

Enhanced sensitivity to oxidative stress in Cu,ZnSOD depleted rat erythrocytes.

The effects on red blood cells of superoxide dismutase (Cu,ZnSOD) depletion, induced by feeding Wistar rats with a copper deficient diet, were investigated. SOD depleted red blood cells were more sensitive to peroxidation and to hemolysis than normal cells when exposed to tert-butylhydroperoxide (t-BOOH). Membranes isolated from SOD depleted cells showed a lower content of vitamin E and higher (Na+, K+) and Mg2+ ATPase activities. These results support the view that superoxide dismutase plays an important role in cellular oxidative metabolism.     

Effects of diffusible products of peroxidation of rat liver microsomal lipids

The effects on cellular structures of products of peroxidation of rat liver microsomal lipids were investigated. A system containing actively peroxidizing liver microsomal fraction was separated from a revealing or target system by a dialysis membrane. The target system, contained in the dialysis tube, consisted of either intact cells (erythrocytes) or subcellular fractions (liver microsomal fraction). When liver microsomal fractions were incubated with NADPH (or an NADPH-generating system), lipid peroxidation, as measured by the amount of malonaldehyde formed, occurred very rapidly. The malon-aldehyde concentration tended to equilibrate across the dialysis membrane. When the target system consisted of erythrocytes, haemolysis occurred abruptly after a lag phase. The lysis was greatly accelerated when erythrocytes from vitamin E-deficient rats were used, but no haemolysis was observed when erythrocytes from vitamin E-treated rats were used. When, in the same system, freshly prepared liver microsomal fractions were exposed to diffusible factors produced by lipid peroxidation, the glucose 6-phosphatase activity markedly decreased. A similar decrease in glucose 6-phosphatase activity, as well as a smaller but significant decrease in cytochrome P-450, was observed when the target microsomal fractions were exposed to diffusible factors derived from the peroxidation of liver microsomal lipids in a separate preincubation step. These and additional experiments indicated that the toxicological activity is relatively stable. Experiments in which the hepatic microsomal fractions destined for lipid peroxidation contained radioactively labelled arachidonic acid, previously incorporated into the membranes, showed that part of the radioactivity released from the microsomal fraction into the incubation medium entered the dialysis tube and was recovered bound to the constituents of the microsomal fractions of the target system. These results indicate that during the course of the peroxidation of liver microsomal lipids toxic products are formed that are able to induce pathological effects at distant loci.     

Effects of dietary vitamin B-2 and vitamin E on the delta9-desaturase and catalase activities in the rat liver microsomes.

The effects of dietary vitamin B-2 and vitamin E on delta9-desaturation of stearoyl-CoA, catalase, glutathione peroxidase, superoxide dismutase and electron transport components in rat liver microsomes have been investigated. delta9-desaturase activities were decreased on diets deficient of vitamin B-2, E and supplemented with E. Among the peroxide-scavenging enzymes, only the catalase activity in microsomes correlates significantly with delta9-desaturase activity. In vitro addition of bovine catalase had no effect on microsomal delta9-desaturase activity on control diet. However, it enhanced the delta9-desaturation in microsomes on vitamin B-2-deficient diet which contained low catalase and high superoxide dismutase activities, compared to those in microsomes of control diet. It is suggested that the hydrogen peroxide-generating and -decomposing systems may play an important role on the delta9-desaturase activity in microsomes.     

Purification, composition, and some properties of rat liver carbamyl phosphate synthetase (ammonia).

Hepatic microsomes prepared from vitamin E deficient and supplemented rats were analyzed for cytochrome P-450 content and drug metabolizing activity. Reduced levels of benzo[α]pyrene hydroxylase and ethylmorphine N-demethylase activities were observed in microsomes derived from rats fed a diet deficient in vitamin E compared to those of control rats. NADPH-mediated destruction of P-450, and pentobarbital and zoxazolamine sleeping times were similar in the two groups. Induction with 3-methylcholanthrene raised the levels of benzo[α]pyrene hydroxylase activity of both supplemented and deficient rats to the same absolute levels. No differences were noted in cytochrome P-450 or P-448 content between control and tocopherol deficient rats, nor did the activity of liver catalase differ between the two dietary groups. Thus, these studies did not demonstrate any impairment of heme protein synthesis in vitamin E deficient rats.     

The effects of in vitro lipid peroxidation on the activity of rat liver microsomal glutathione S-transferase from rats supplemented or deficient in antioxidants

Glutathione S-transferases are a group of multifunctional isozymes that play a central role in the detoxification of hydrophobic xenobiotics with electrophilic centers (1). In this study we investigated the effects of in vitro lipid peroxidation on the activity of liver microsomal glutathione S-transferases from rats either supplemented or deficient in both vitamin E and selenium. Increased formation of malondialdehyde (MDA), a by-product of lipid peroxidation, was associated with a decreased activity of rat liver microsomal glutathione S-transferase. The inhibition of glutathione S-transferase occurred rapidly in microsomes from rats fed a diet deficient in both vitamin E and selenium (the B diet) but was delayed for 15 minutes in microsomes from rats fed the same diet but supplemented with these micro-nutrients (B+E+Se diet). Lipid peroxidation inhibits microsomal glutathione S-transferase and this inhibition is modulated by dietary antioxidants.     

Flavonoids can replace alpha-tocopherol as an antioxidant

Endogenous antioxidants such as the lipid-soluble vitamin E protect the cell membranes from oxidative damage. Glutathione seems to be able to regenerate alpha-tocopherol via a so-called free radical reductase. The transient protection by reduced glutathione (GSH) against lipid peroxidation in control liver microsomes is not observed in microsomes deficient in alpha-tocopherol. Introduction of antioxidant flavonoids, such as 7-monohydroxyethylrutoside, fisetin or naringenin, into the deficient microsomes restored the GSH-dependent protection, suggesting that flavonoids can take over the role of alpha-tocopherol as a chain-breaking antioxidant in liver microsomal membranes.     

Antioxidant Status and Susceptibility of Sickle Erythrocytes to Oxidative and Osmotic Stress

The purpose of this study was to determine if differences in antioxidant status between the red blood cells (RBCs) of sickle cell anemia (SCA) patients and controls are responsible for the differential responses to oxidative and osmotic stress-induced hemolysis. Susceptibility to hemolysis was examined by incubating oxygenated and deoxygenated RBCs at 37°C with 73 mM 2,2' azobis (2-amidinopropane) HC1 (AAPH), a peroxyl radical generator, for up to 3.5 hours. The ability of RBCs to maintain membrane integrity under osmotic stress was determined over a range of diluted saline-phosphate buffer. Sickled RBCs showed a lesser degree of AAPH-induced hemolysis than control groups and were more resistant to osmotic stress-induced hemolysis. SCA patients had higher levels of RBC vitamin E and RBC lipids, but lower RBC GSH, plasma lipids and plasma carotenes than those of the hospital controls. No significant differences were observed in the levels of retinol, vitamin C, vitamin E, MDA and conjugated dienes in plasma, or the levels of MDA and conjugated dienes in RBCs. The results obtained suggest that the differences in antioxidant status between sickled RBCs and controls do not appear to be responsible for their different susceptibility to oxidative or osmotic stress-induced hemolysis observed.     

Studies on the role of vitamin E in the oxidation of blood components by fatty hydroperoxides.

Studies are reported on the oxidation of vitamin E and changes in lipid and fatty acid composition of rat blood components incubated in vitro with hydroperoxides prepared from autoxidized methyl linoleate. Red blood cells, plasma, serum, and hemoglobin free stroma were incubated at 37 °C with suspensions of linoleate hydroperoxide in Tris buffer at pH 7.4. The RBC were destroyed and substances with excitation-fluorescent properties were produced. Phosphatidylethanolamine, vitamin E and unsaturated fatty acids were oxidized in the reaction. Among the reaction products were substances that gave a positive thiobarbituric acid value, tocoquinone, and an unidentified substance isolated in the nonsaponifiable fraction of the lipid extract of the hemolyzed red cells. The reaction of linoleate hydroperoxide with stroma was similar to that with red blood cells and the same products were observed. In contrast there was little reaction of linoleate hydroperoxide with vitamin E or lipids of the serum or plasma in the absence of red blood cells. The destruction of the red blood cells appeared to be closely related to the oxidation of vitamin E indicating that the strong antioxygenic action of vitamin E in vivo was due to its particular form or structural orientation in the red cell membrane.     

Glucose-dependent Protection by Dietary Selenium against Haemolysis of Rat Erythrocytes <Emphasis Type="Italic">in vitro</Emphasis>

THE occurrence in man of drug-induced haemolysis in glucose-6-phosphate dehydrogenase (G6PD) deficient erythrocytes¹ suggested the possibility of an analogy to the haemolysis which occurs in vitamin E deficient red blood cells. Cohen and Hochstein² have shown that haemolysis in G6PD deficient cells is associated with the inability of the cell to generate adequate reduced glutathione (GSH) through GSSG reductase because of the impaired generation of NADPH. Moreover, there is evidence that glucose protects red blood cells from haemolysis by its ability to provide NADPH through G6PD which subsequently generates GSH³. The G6PD deficient cell, however, cannot maintain an adequate concentration of GSH in the cell, even in the presence of glucose⁴, whereas the normal cell can maintain a normal concentration of GSH in the presence of glucose, preserving the integrity of the red blood cell. Vitamin E protects red blood cells from haemolysis whether supplied in vivo or in vitro and its effect has usually been demonstrated without glucose in the incubation medium. Although selenium prevents many of the same deficiency symptoms as vitamin E, it has not been uniformly effective in preventing the in vitro haemolysis of red blood cells. If a protective action of selenium against haemolysis were dependent on the presence of GSH, or if selenium were involved in the generation of GSH, selenium would not be expected to prevent haemolysis unless glucose was present in the incubation medium to provide a constant source of NADPH for the generation of GSH from GSSG through GSSG reductase (Fig. 1).     

Vitamin E dependent reduced glutathione inhibition of rat liver microsomal lipid peroxidation

Effects of reduced glutathione (GSH) were investigated on $\text{in}$$\text{vitro}$ lipid peroxidation of hepatic microsomes obtained from Long-Evans Hooded rats fed chemically defined, purified diets containing adequate or documented deficiencies of vitamin E (E), selenium (Se) or both. Glutathione inhibited lipid peroxidation mediated by both NADPH-dependent enzymatic and ascorbate-dependent non-enzymatic systems. The inhibitory effect of GSH was observed in microsomes obtained from E supplemented groups whereas it had no effect on microsomes from E deficient animals. Selenium status had no effect on GSH inhibition. Glutathione was found to be specific for the E dependent inhibition of lipid peroxidation and could not be substituted by other sulfhydryl compounds tested. Also, GSH did not inhibit non-enzymatic lipid peroxidation of heat-denatured microsomes from either E-supplemented groups or any of the other dietary regimens.     

Vitamin E deficiency impairs the modifications of mitochondrial membrane potential and mass in rat splenocytes stimulated to proliferate

This study was designed to evaluate the time-dependent changes of mitochondrial membrane potential and mass during Con-A-induced proliferation of splenic lymphocytes from rat fed a normal or a vitamin E deficient diet. Rhodamine 123 and Nonyl Acridine Orange were used as specific probes to monitor the membrane potential and mass of mitochondria, respectively, by means of flow cytometry. The results demonstrate that the increase of Rh-123 and NAO uptake observed in cells from normally fed rats was prevented by vitamin E deficiency, at any time considered. After 72 h from Con A stimulation, 62% of cells from controls, as against 16% of cells from vitamin E deficient rats, showed hyperpolarized mitochondria. At the same time, in this last group, 60% of cells had depolarized organelles. The same pattern was observed considering the changes of mitochondrial mass, measured using NAO as a probe. These data support that mitogenic stimulation induced an increase of the respiratory activity of mitochondria with subsequent production of superoxide radicals. This resulted in depolarization and loss of mass of the organelles if the intracellular level of vitamin E is not adequate.     

Effect of hypervitaminosis A on hemolysis and lipid peroxidation in the rat

Erythrocytes from rats fed large doses of Vitamin A alone, or large doses of vitamin A and vitamin E or diphenyl-p-phenylene diamine (DPPD) were studied for H2O2-induced hemolysis. The vitamin A-dosed rats were more susceptible than normal rats to H2O2-induced hemolysis. Hemolysis was not accompanied by lipid peroxidation. Nevertheless, the antioxidants vitamin E and DPPD inhibited hemolysis in erythrocytes from vitamin A-dosed rats. These antioxidants had the same inhibitory effect when they were included in the diet or added to erythrocyte suspensions in vitro. Erythrocytes from vitamin A-dosed rats with or without added vitamin E or DPPD were less susceptible than the erythrocytes from normal rats to osmotic challenge, showing that vitamin A was present in levels sufficient to alter the structure of the erythrocyte membrane. These studies show that oxidative hemolysis occurs when the erythrocyte membrane is modified. Furthermore, this oxidative hemolysis is unrelated to lipid peroxidation.     

Ascorbate-Fe2+ lipid-peroxidation of rat liver microsomes: Effect of vitamin E and cytosolic proteins

In the present study, we examined the effect of the intraperitoneal administration of vitamin E (100 mg/kg weight/24 h) on ascorbate (0.4 mM) induced lipid peroxidation of rat liver microsomes . We also analyzed the effect of hepatic cytosolic proteins on this process. The results indicate that the ascorbate induced light emission was 76% lower in microsomes (1 mg protein) obtained from vitamin E treated animals when compared with controls. In the presence of cytosolic protein (1 mg) the chemiluminescence of control microsomes diminished 55.8 and 59.5% when cytosol from controls and treated animals was used, respectively. The chemiluminescence of vitamin E microsomes diminished 25.03 and 22.08% when both types of cytosol were added to the medium. Dialyzed or treated at 70°C cytosol was also able to inhibit the lipid peroxidation of either control or vitamin E rat liver microsomes. By means of gas chromatography we analyzed the fatty acid composition of native and peroxidated microsomes from both animal groups. The peroxidation affected principally arachidonic acid and its diminution was more evident in the control microsomes than in the microsomes from the vitamin E treated group. By HPLC we analyzed the vitamin E content in all subcellular fractions employed. In microsomes from the vitamin E-group, the content of vitamin was 11 times higher than in the control ones (0.678 ± 0.1038 vs. 0.062 ± 0.0045 g -tocopherol/mg protein, respectively), while levels in the cytosol from the vitamin E-group were only 2 times higher than in the control cytosol (0.057 ± 0.0051 vs. 0.025 ± 0.0015 g -tocopherol/mg protein, respectively).     

Rat lung microsomal lipid peroxidation: effects of vitamin E and reduced glutathione

Lung microsomal membranes that contain the redox active components associated with the mixed-function oxidase system can be peroxidized in vitro. To investigate the characteristics of rat lung microsomal lipid peroxidation, we performed experiments using a variety of peroxidation initiators and microsomes obtained from normal and vitamin E-deficient rats. We found that lung microsomes obtained from normal rats are peroxidized much less than liver microsomes obtained from the same animals. Only initiation systems using very high concentrations of ferrous iron produced any significant peroxidation of normal rat lung microsomes. Lung microsomes obtained from vitamin E-deficient rats were found to be much more susceptible to peroxidation. Glutathione (GSH) was effective in inhibiting peroxidation when lung microsomes from normal rats were peroxidized. GSH was not effective in decreasing peroxidation when microsomes from vitamin E-deficient rats were peroxidized in the same system. We conclude that both GSH and vitamin E protect lung microsomal membranes from peroxidation. Glutathione protection appears to be related to the presence of a sulfhydryl group.     

In vitro manipulations of vitamin C and vitamin E concentrations alter intracellular O2- production of hybrid striped bass (Morone chrysops x Morone saxatilis) head-kidney cells

To examine the mechanism by which vitamins C and E alter phagocyte function, a series of in vitro manipulations were conducted with cells isolated from the head-kidney of hybrid striped bass (average weight 680 g) fed a diet supplemented with minimum requirement levels of vitamins C and E for 2 weeks. Head-kidney phagocytes were cultured in media containing physiologically deficient (23 microM, adequate (45 microM) or excessive (182 microM) concentrations of vitamin C, and physiologically deficient (5 microM), adequate (9 microM) or excessive (32 microM) concentrations of vitamin E for 18 h. Following culture and stimulation, levels of reactive oxygen intermediates and hydrogen peroxide were determined. There were no effects of vitamin C or vitamin E concentrations on hydrogen peroxide or extracellular O2- generation. Intracellular O2- production, however, was significantly (P < or = 0.05) affected. When vitamin C was supplied at deficient levels to the medium, vitamin E elevated O2- production to levels not different from those of cells incubated with requirement levels of both vitamins. Similarly, when vitamin E was deficient in the media, vitamin C supplementation at requirement levels normalised intracellular O2- production. This data provides support for the presence of a vitamin C and vitamin E sparing mechanism in phagocytic head-kidney cells of hybrid striped bass and yield some insight into the mechanisms by which vitamin C and vitamin E function in immunomodulation.     

Species differences in membrane susceptibility to lipid peroxidation

The susceptibility of liver microsomes to lipid peroxidation was evaluated in seven species: rat, rabbit, trout, mouse, pig, cow, and horse. Lipid peroxidation was measured as thiobarbituric acid reactive substances formed in the presence of either FeCl₃-ADP/ascorbate or FeCl₂/H₂O₂ initiating systems. For rat, rabbit, and trout microsomes, the order of susceptibility to peroxidation was rat > rabbit >> trout. The lack of peroxidation in trout microsomes could be explained by high microsomal vitamin E levels. Membrane fatty acid levels differed between species. Docosahexaenoic acid predominated in the trout, arachidonic acid in the rat, and linoleic acid in the rabbit. The contribution of individual fatty acids to lipid peroxidation reflected the degree of unsaturation with docosahexaenoic > arachidonic >>> linoleic. For all species except trout, the predicted susceptibility to peroxidation, based on the response of individual fatty acids, agreed well with directly measured microsomal peroxidation. With the exception of the trout, vitamin E content ranged from 0.083–0.311 nmol/mg microsomal protein between species, and low levels did not influence susceptibility to peroxidation. Trout microsomes peroxidized only after vitamin E depletion by prolonged incubation. The data indicate that below a vitamin E threshold, species differences in membrane susceptibility to peroxidation can be reasonably predicted based only on content of individual peroxidizable fatty acids.