Effects of butylated hydroxytoluene on membrane lipid fluidity and freeze-thaw survival in mammalian cells

Butylated hydroxytoluene (BHT) increases the fluidity of membrane lipids in the hydrocarbon but not the polar regions, as measured by electron spin resonance spin label probes. BHT also sensitizes nucleated mammalian cells to freeze-thaw damage as measured by colony formation survival assays. Furthermore, the membranes of BHT-exposed cells are more susceptible to physical stress, as reflected by the BHT-induced sensitization to hypotonic stress. Since others have shown that BHT induces hexagonal phase lipids in lipid bilayers, this phenomenon may also influence the above survival results.     

The effects of l-cycloserine on membrane fluidity and lipids of mouse brain

l-Cycloserine can inhibit the synthesis of some sphingolipids, which may play a role in determining membrane fluidity. To evaluate the effects of l-cycloserine on neural cell membranes, adult mice were treated with 100 mg/kg of this drug twice daily for 1, 2, 4, 6, 13 and 17 days. Body weights in the treated mice decreased significantly. Cholesterol and total phospholipid per mass total lipid significantly increased with time. Fluorescence depolarization after the incorporation of diphenylhexatriene into membranes was measured in order to assess membrane fluidity. it increased significantly starting at treatment day 4, with a maximum increase in polarization value of 8%. These results show that l-cycloserine significantly changes the fluidity of brain membrane, but this does not correlate with changes in major lipid classes of the brain.     

The effect of Pycnogenol on the erythrocyte membrane fluidity

In the present study, the in vitro effect of polyphenol rich plant extract, flavonoid--Pycnogenol (Pyc), on erythrocyte membrane fluidity was studied. Membrane fluidity was determined using 1-[4-trimethyl-aminophenyl]-6-phenyl-1,3,5-hexatriene (TMA-DPH), 1,6-diphenyl-1,3,5-hexatriene (DPH) and 12-(9-anthroyloxy) stearic acid (12-AS) fluorescence anisotropy. After Pyc action (50 microg/ml to 300 microg/ml), we observed decreases in the anisotropy values of TMA-DPH and DPH in a dose-dependent manner compared with the untreated erythrocyte membranes. Pyc significantly increased the membrane fluidity predominantly at the membrane surface. Further, we observed the protective effect of Pyc against lipid peroxidation, TBARP generation and oxidative hemolysis induced by H2O2. Pyc can reduce the lipid peroxidation and oxidative hemolysis either by quenching free radicals or by chelating metal ions, or by both. The exact mechanism(s) of the positive effect of Pyc is not known. We assume that Pyc efficacy to modify effectively some membrane dependent processes is related not only to the chemical action of Pyc but also to its ability to interact directly with cell membranes and/or penetrate the membrane thus inducing modification of the lipid bilayer and lipid-protein interactions.     

糖皮质激素对肥大细胞胞膜流动性的影响

目的:研究糖皮质激素(皮质酮)对肥大细胞胞膜流动性的快速作用。方法:采用荧光偏振法检测膜流动性,检测不同浓度皮质酮对肥大细胞膜流动性的快速影响以及加用糖皮质激素受体拮抗剂RU38486看其是否影响皮质酮对肥大细胞膜流动性的快速作用。结果:与阴性对照组比较,皮质酮能够在7min内剂量依赖性地快速降低肥大细胞胞膜流动性,稳定肥大细胞胞膜(P0.01);加用糖皮质激素受体拮抗剂RU38486后能部分阻断皮质酮对肥大细胞膜流动性的快速作用(P0.01)。结论:糖皮质激素能够快速降低肥大细胞胞膜流动性,稳定肥大细胞胞膜,这一作用可能是糖皮质激素快速抑制肥大细胞脱颗粒非基因组机制作用的靶点之一。     

Substance P induces alterations on cerebral lipids involved in membrane fluidity

This study was undertaken to examine the variations in rat brain of cholesterol, phospholipid and phospholipid fatty acid composition induced by substance P. The cholesterol content was increased by substance P; concomitantly, an increase of the ratio cholesterol/phospholipid was observed. These changes do not appear to be responsible of the stimulation observed in Na+,K+-ATPase activity by substance P action. Phospholipid fatty acid analysis revealed that the peptide induced a decrease in both linoleic and arachidonic acids content.     

The effect of triiodothyronine on changes of membrane fluidity in regenerating rat liver.

The increase of the membrane fluidity during the early phase of liver regeneration after partial hepatectomy was described in literature in plasma membrane and in microsomes. We found similar changes also in isolated mitochondria and in crude total membrane fraction of the liver homogenate. The administration of triiodothyronine to rats before partial hepatectomy diminished the increase of the membrane fluidity in the regenerating liver by 50%. Triiodothyronine effect is explained by hormonal modification of lipid metabolism in the regenerating liver.     

Alterations in erythrocyte membrane fluidity by phenylhydrazine-induced peroxidation of lipids

The addition of phenylhydrazine (.05 – 0.5 mM) to hemoglobin-free human erythrocyte membranes results in the peroxidation of endogenous phospholipids as measured by the thiobarbaturic acid reaction. The incorporation of 1,6-diphenyl-1,3-5-hexatriene into these membranes revealed a decrease in bulk lipid fluidity. Additionally, the fluorescence intensity of 1-anilino-8-naphthalene sulfonate was decreased and red-shifted after phenylhydrazine treatment of the membranes. The results obtained are consistent with the view that changes in the physical state of plasma membranes subsequent to the peroxidation of membrane lipids may be a determinant of the mechanical properties of drug-treated as well as aging cells.     

Radiation-induced lipid peroxidation and the fluidity of erythrocyte membrane lipids

The effect of radiation-induced peroxidation on the fluidity of the phospholipids of the erythrocyte membrane was studied using both erythrocyte ghosts and liposomes formed from the polar lipids of erythrocytes. In liposomes, the oxidation of the phospholipids increased with radiation dose, but there was no change in the fluidity of the lipids as measured by spin-label motion. Under the same conditions of irradiation, no oxidation of phospholipid was detected in erythrocyte ghosts, although changes occurred in the motion of spin labels intercalated with the membrane. These changes were attributed to radiation-induced alterations in the membrane proteins. It is concluded that alterations in motion of spin labels, observed with intact membranes after irradiation, are most likely the result of changes in the structure of membrane proteins rather than the lipids.     

Garlic allyl derivatives interact with membrane lipids to modify the membrane fluidity

As a novel approach to the mode of medicinal action of garlic, its constituents were comparatively studied with respect to their interactions with membrane lipids to modify the membrane fluidity. Allyl derivatives rigidified tumor cell and platelet model membranes consisting of unsaturated phospholipids and cholesterol at 20–500 μM with the potency being diallyl trisulfide (DATS) > diallyl disulfide (DADS) by preferentially acting on the hydrocarbon cores of lipid bilayers. They were also effective in rigidifying candida cell model membranes prepared with ergosterol and phospholipids at 100–500 μM with the potency being DADS > DATS > diallyl sulfide (DAS), but not bacteria cell model membranes without ergosterol. Alliin, a precursor of these DASs, was not active on any membranes at 500 μM. Both relative intensity and selectivity in membrane effects correlated with those in antiproliferative, antiplatelet and antimicrobial effects. In cell culture experiments, membrane-active DASs inhibited the growth of tumor cells cultured for 24 and 48 h at 20–500 μM to show the potency being DATS > DADS, together with rigidifying cell membranes by acting on their deeper regions more intensively. However, membrane-inactive allyl derivatives were not growth-inhibitory on tumor cells. The membrane lipid interactions of DASs appear to be one of possible mechanisms underlying different effects of garlic.     

Role of membrane lipids and membrane fluidity in thermosensitivity and thermotolerance of mammalian cells

The role of membrane lipids and membrane fluidity in thermosensitivity of mammalian cells is not well understood. The limited experimental data in the literature have led to conflicting results. A detailed investigation of lipid composition and membrane fluidity of cellular membranes was undertaken to determine their relationship to cell survival after hyperthermia. Ehrlich ascites (EA) cells, mouse fibroblast LM cells, and HeLa S3 cells differed in thermosensitivity as expressed by a D0 of 3.1, 5.2, and 9.7 min, respectively, at 44 degrees C. No correlation with cellular thermosensitivity could be found with respect to the amount of cholesterol and to the cholesterol to phospholipid ratio in the particulate fraction of the cells. By growing the cells for some generations in different media, cholesterol and phospholipid content could be changed in the particulate fraction, but no difference in cell survival was observed. When mouse fibroblasts were grown for 24 hr in a serum-free medium supplemented with arachidonic acid (20:4), all subcellular membranes were about eight times richer in phospholipids containing polyunsaturated acyl (PUFA) chains and membrane fluidity was increased as measured by fluorescence polarization of diphenylhexatriene (DPH). The alterations resulted in a higher thermosensitivity. When mouse fibroblasts were made thermotolerant no change in cholesterol and phospholipid content could be found in the particulate fraction of the cells. The relative weights and the quality of the phospholipids as well as the fatty acid composition of the phospholipids appeared to be the same for normal and thermotolerant cells. Fluidity measurements in whole cells, isolated plasma membranes, and liposomes prepared from phospholipids extracted from the cells revealed no significant differences between normal and thermotolerant fibroblasts when assayed by fluorescence polarization (DPH) and electron spin resonance (5-nitroxystearate). It is concluded that the mechanism of thermal adaptation resulting in differences in lipid composition as reported in the literature differs from the mechanism of the acquisition of thermal tolerance. The lower heat sensitivity of thermotolerant cells, as initiated by a nonlethal triggering heat dose followed by an induction period at 37 degrees C, does not involve changes in lipid composition and membrane fluidity. However, a prompt and clear (also nonlethal) change in membrane fluidity by an increase in PUFA does result in an increased thermosensitivity, probably because of an indirect effect via the lipids in causing disfunctioning of proteins in the membrane and/or the cytoskeleton.     

The effect of ACTH on rat brain synaptic plasma membrane lipid fluidity

The effect of ACTH on the lipid fluidity was examined in synaptic plasma membranes from rat forebrain. ACTH1-24 increased the fluidity of the synaptic plasma membranes in a dose-dependent way, the lowest effective dose being 10(-5) M. The shorter N-terminal fragment ACTH1-10 was not effective. The significance of this finding is discussed in relation to the known effects of ACTH on synaptic membrane phosphorylation.     

The effect of diabetes on hepatocyte plasma membrane fluidity and concanavalin A-induced agglutination

The techniques of fluorescence polarization and lectin-induced agglutination have been utilized to investigate the effects of the diabetic state on some of the dynamic properties of cell membranes. Hepatocyte plasma membranes from streptozotocin-induced diabetic rats exhibited a significant decrease in cholesterol and sialic acid with no alteration in phospholipid content. This membrane system also exhibited a decrease in fluorescence polarization, using the fluorescent probe, 1,6-di-phenyl-1, 3,5-hexatriene, suggesting an increase in membrane fluidity over the value observed in normal hepatocytes. When normal hepatocytes were incubated in the presence of the lectin, concanavalin A (ConA), no significant agglutination was observed. In contrast, hepatocytes from diabetic rats which exhibited a slightly decreased lectin-binding capacity underwent extensive agglutination. In addition, normal hepatocytes which were pretreated with 0.1 mM tetracaine also underwent extensive agglutination with no measurable increase in lectin-binding capacity. These results suggest that altered membrane lipid fluidity and/or cytoskeletal organization may have a profound effect on cell surface dynamics and could result in the uncoupling of the insulin receptor complex from the membrane-associated effector system(s), a defect which may play a role in the problem of insulin resistance observed in some forms of diabetes.     

The effect of 45 degrees C hyperthermia on the membrane fluidity of cells of several lines.

The membrane fluidity of cells of human (AG1522 human foreskin fibroblasts), rodent [Chinese hamster ovary (CHO) and radiation-induced mouse fibrosarcoma], and feline (Crandall feline kidney) cell lines after heating at 45 degrees C was measured by flow cytometry. In addition, a heat-resistant variant of radiation-induced mouse fibrosarcoma cells and two heat-sensitive CHO strains were studied. Fluorescence polarization of the plasma membrane probe trimethylammonium-diphenylhexatriene was used as a measure of membrane fluidity. The sensitivity of all cell lines to 45 degrees C hyperthermia was compared. The baseline membrane fluidity varied among the cell lines, but did not correlate with sensitivity to hyperthermia. However, CHO cells, especially the heat-sensitive mutants, had the largest increase in membrane fluidity after heating at 45 degrees C, while the heat-resistant mouse fibrosarcoma variants and Crandall feline kidney cells resisted changes in fluidity. In general, the more resistant the cell line was to killing by heat, the more resistant it was to changes in membrane fluidity.     

Effects of trace elements on membrane fluidity.

According to the Fluid Mosaic Model, a biological membrane is a two-dimensional fluid of oriented proteins and lipids. The lipid bilayer is the basic structure of all cell and organelle membranes. Cell membranes are dynamic, fluid structures, and most of their molecules are able to move in the plane of the membrane. Fluidity is the quality of ease of movement and represents the reciprocal value of membrane viscosity. Fluid properties of biological membranes are essential for numerous cell functions. Even slight changes in membrane fluidity may cause aberrant function and pathological processes. Several evidences suggest that trace elements, e.g., iron, copper, zinc, selenium, chromium, cadmium, mercury and lead may influence membrane fluidity. The interaction of heavy metals with cellular membranes may contribute to explain, at least partially, the toxicity associated with these metals.     

Glucose transport in Acholeplasma laidlawii B: dependence on the fluidity and physical state of membrane lipids.

The uptake of D-glucose by Acholeplasma laidlawii B occurs via a mediated transport process, as shown by the following observations: (i) glucose permeates A. laidlawii B cells at a rate at least 100 times greater than would be expected if its entry occurred only by simple passive diffusion; (ii) the apparent activation energy for glucose uptake in A. laidlawii is significantly lower than that expected and observed for the passive permeation of this sugar; (iii) glucose uptake appears to be a saturable process; (iv) glucose uptake can be completely inhibited by low concentrations of phloretin and phlorizin; and (v) glucose uptake is markedly inhibited at temperatures above 45 C, whereas the passive entry of erythritol continues to increase logarithmically until at least 60 C. The metabolism of D-glucose by this organism is rapid and, at low glucose concentrations, the intracellular radioactivity derived from D-[14-C]glucose is at any given time a reflection of the net effect of glucose transport, glucose metabolism, and loss from the cell of radioactive metabolic products. Care must thus be taken when attempting to determine the rate of glucose transport by measuring the accumulation by the cells of the total radioactivity derived from D-[14-C]glucose. The rate of uptake of D-glucose by A. laidlawii B cells is markedly dependent on the fatty acid composition and cholesterol content of the plasma membrane and exhibits a direct dependence on the fluidity of the membrane lipids as measured by their reversible, thermotropic gel to liquie-crystalline phase transition temperatures. In contrast to the transport rates, the apparent activation energy for glucose uptake above the phase transition temperature is not dependent on membrane lipid composition. At the temperature range within the membrane lipid phase transition region, the apparent activation energy of glucose uptake is different from the activation energy observed at temperatures above the phase transition. This may reflect the superimposed operation within the phase transition region of more than one temperature-dependent process.     

Effect of the viral proteins on the fluidity of the membrane lipids in Sindbis virus

The fluidity of the lipids in the membrane of Sindbis virus was studied by electron paramagnetic resonance spectroscopy. The lipids in the viral membrane are noticeably less fluid than the lipids in the membrane of the cells in which the virus was grown. This difference in fluidity is not due simply to differences in lipid composition but instead appears to be the result of the interaction of the viral proteins with the membrane lipids. This conclusion seems clear because (i) the viral lipids are more fluid after extraction with chloroform/methanol than in the lipid bilayer of the virion and because (ii) the viral membrane is made more fluid by proteolytic digestion of the viral glycoproteins.The possible role of this viral protein-mediated alteration of the physical state of membrane lipids in the maturation of Sindbis virions is discussed.     

The effect of oxidant gases on membrane fluidity and function in pulmonary endothelial cells

Free radicals and oxidant gases, such as oxygen (O2) and nitrogen dioxide (NO2), are injurious to mammalian lung cells. One of the postulated mechanisms for the cellular injury associated with these gases and free radicals involves peroxidative cleavage of membrane lipids. We have hypothesized that oxidant-related alterations in membrane lipids may result in disordering of the plasma membrane lipid bilayer, leading to derangements in membrane-dependent functions. To test this hypothesis, we examined the effect of exposure to high partial pressures of O2 or NO2 on the physical state and function of pulmonary endothelial cell plasma membranes. Both hyperoxia (95% O2 at 1 ATA) and NO2 exposure (5 ppm) caused early and significant decreases in fluidity in the hydrophobic interior of the plasma membrane lipid bilayer and subsequent depressions in plasma membrane-dependent transport of 5-hydroxytryptamine. Lipid domains at the surface of pulmonary endothelial cell plasma membranes are more susceptible to NO2-induced injury than to hyperoxic injury. Alterations in the fluidity of these more superficial domains are associated with derangements in surface dependent functions, such as receptor-ligand interaction. These results support our hypothesis and advance our understanding of how the chemical events of free radical injury associated with high O2 and NO2 tensions are translated into functional manifestations of O2 and NO2-induced cellular injury.