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The effect of hypoglycemic drugs chlorpropamide and phenformin has been tested on isolated liver plasma membranes as to their microviscosity parameters. Results reported suggest that both drugs are able to increase in vitro plasma membrane microviscosity in a dose-dependent way.     

Enveloped viruses as model membrane systems: microviscosity of vesicular stomatitis virus and host cell membranes.

The fluorescence probe 1,6-diphenyl-1,3,5-hexatriene was used to study and compare the dynamic properties of the hydrophobic region of vesicular stomatitis virus grown on L-929 cells, plasma membrane of L-929 cells prepared by two different methods, liposomes prepared from virus lipids and plasma membrane lipids, and intact L-929 cells. The rate of penetration of the probe into the hydrophobic region of the lipid bilayer was found to be much faster in the lipid vesicle bilayer as compared with the intact membrane, but in all cases the fluorescence anisotropy was constant with time. The L-cell plasma membranes, the vesicles prepared from the lipids derived from the plasma membranes, and intact cells are found to have much lower microviscosity values than the virus or virus lipid vesicles throughout a wide range of temperatures. The microviscosity of plasma membrane and plasma membrane lipid vesicles was found to depend on the procedure for plasma membrane preparation as the membranes prepared by different methods had different microviscosities. The intact virus and liposomes prepared from the virus lipids were found to have very similar microviscosity values. Plasma membrane and liposomes prepared from plasma membrane lipids also had similar microviscosity values. Factors affecting microviscosity in natural membranes and artificially mixed lipid membranes are discussed.     

Effect of Escherichia coli lipopolysaccharide on the microviscosity of liver plasma membranes and hepatocyte suspensions and monolayers

The fluorescence probe 1,6-diphenylhexa-1,3,5-triene (DPH) was used for monitoring structural perturbations induced by lipopolysaccharide (LPS) of Escherichia coli (0111:B4) in plasma membranes of rat liver. Changes in microviscosity were observed in plasma membrane preparations from control rats after treatment with LPS and in plasma membrane preparations from liver perfused with LPS. In both systems fluorescence polarization was measured from which microviscosity was calculated. This parameter increases with LPS treatment. From temperature dependence studies was inferred that LPS interaction with plasma membrane preparations induces an increase of both the polarization term (r0/r-1)-1 and flow activation energy (delta E). Addition of LPS to hepatocyte suspensions also induces an increase on microviscosity and a delay in the fall of microviscosity induced by a temperature rise in hepatocyte monolayers grown on microcover slides. These data suggest that LPS interaction can be attributed to its binding to membrane hydrophobic regions in a non-specific manner.     

Altered cell-averaged microviscosity of murine peritoneal macrophages undergoing activation in vivo or in vitro

The cell-averaged microviscosity of intact murine peritoneal mononuclear phagocytes in various stages of activation was assessed by quantifying fluorescent depolarization of 1,6-diphenyl-1,3,5-hexatriene. Macrophages activated in vivo with Mycobacterium bovis, strain BCG, were significantly more fluid than resident peritoneal macrophages, responsive macrophages elicited with thioglycollate broth, proteose peptone broth, or fetal bovine serum, or primed macrophages elicited with pyran copolymer, MVE-2. Specifically, the cell-averaged microviscosity decreased from a mean of 3.47 +/- .07 eta 25 degrees C (poise) (range of 3.32 to 3.67 p) to 2.62 eta 25 degrees C. Exposure of responsive macrophages in vitro to bacterial endotoxin plus hybridoma supernatants containing macrophage-activating factor or purified recombinant interferon gamma resulted in decreased microviscosity; the largest effect was seen after 24 hr. Macrophages primed in vivo with MVE-2 and treated in vitro with endotoxin also developed decreased microviscosity. Similar changes in microviscosity were observed in a plasma membrane-enriched fraction isolated from macrophages activated in vitro with interferon gamma and endotoxin, thus suggesting that the cell-averaged measurements reflected changes in membrane viscosity. The optimum concentration of MAF-inducing decreased overall microviscosity was identical to that for inducing tumoricidal capacity. Taken together, the data indicate activation of lytic capacity in murine macrophages is closely associated with decreased cell-averaged microviscosity and that this change reflects, at least in part, decreased microviscosity of the plasma membrane of these cells.     

Influence of membrane fluidity of 5'-nucleotidase activity in isolated hepatocyte plasma membrane.

The influence of membrane microviscosity on 5'-nucleotidase activity has been investigated on liver plasma membrane preparations from rats during aging and following diet restriction. In addition the microviscosity of membranes from old rats was changed in vitro by the Active Lipids. During aging the membrane microviscosity increased progressively and in parallel the activity of 5'-nucleotidase decreased. Diet restriction was able to slow down the modification of both parameters. The experiment performed with the Active Lipids further supports that membrane microviscosity modulated the enzyme activity.     

Effect of aminazine and triftazin on the synaptosome membranes of the rat cerebral cortex

Fluorescent probes 1,6-diphenyl-1,3,5-hexatriene (DPH) and pyrene were employed in studying the effect of aminazine and triftazin versus that of imipramine on microviscosity of rat brain cortex synaptosomal membranes. Unlike imipramine, the neuroleptics decrease microviscosity of membrane's lipid bilayer. All drugs decrease fluorescence of endogenous tryptophan, but fail to change fluorescence of L-tryptophan in the solution. It is concluded that neuroleptics induce conformational perturbations in membrane-bound proteins modifying microviscosity of lipid bilayer whereas imipramine changes the surface electric charge of lipid bilayer of synaptosomal membranes.     

Polarization of plasma membrane microviscosity during endothelial cell migration

Cell movement is characterized by anterior-posterior polarization of multiple cell structures. We show here that the plasma membrane is polarized in moving endothelial cells (EC); in particular, plasma membrane microviscosity (PMM) is increased at the cell leading edge. Our studies indicate that cholesterol has an important role in generation of this microviscosity gradient. In vitro studies using synthetic lipid vesicles show that membrane microviscosity has a substantial and biphasic influence on actin dynamics; a small amount of cholesterol increases actin-mediated vesicle deformation, whereas a large amount completely inhibits deformation. Experiments in migrating ECs confirm the important role of PMM on actin dynamics. Angiogenic growth factor-stimulated cells exhibit substantially increased membrane microviscosity at the cell front but, unexpectedly, show decreased rates of actin polymerization. Our results suggest that increased PMM in lamellipodia may permit more productive actin filament and meshwork formation, resulting in enhanced rates of cell movement.     

Modulation of membrane composition of swine vascular smooth muscle cells by homologous lipoproteins in culture

Swine vascular smooth muscle cells were exposed to homologous low-density or high-density lipoprotein fractions for 24 h. Total cell membranes were isolated from the post-nuclear supernatant of the cell homogenates, fractionated by sucrose density gradient centrifugation and characterized by enzyme assays. The membrane fraction with the lowest density was enriched in plasma membrane marker enzymes. Cholesterol analysis showed that cells exposed to low-density lipoprotein had higher cholesterol-to-protein ratios in total cells, total cell membranes and individual membrane fractions than had the cells exposed to high-density lipoproteins. Cholesterol-to-phospholipid ratios of the plasma membrane-enriched fraction from cells exposed to low-density lipoprotein were higher than the same membrane fraction of cells exposed to high-density lipoprotein. Studies with iodinated lipoproteins showed that these compositional changes could not be due to lipoprotein contamination. Membrane microviscosity was determined by fluorescence depolarization with diphenylhexatriene and the microviscosity of the plasma membrane-enriched fraction was different in the cells exposed to the two different lipoprotein fractions. This difference in membrane microviscosity was significant only when the medium cholesterol content was 40 μg per ml or greater; cells exposed to low-density lipoprotein gave membranes with higher microviscosity.These results demonstrate that the properties of vascular smooth muscle cell membranes are influenced by exposure of the cells to homologous lipoprotein fractions.     

Stage-specific changes in membrane microviscosity in <Emphasis Type="Italic">Misgurnus fossilis</Emphasis> embryos

Natural and probe fluorescence as well as membrane microviscosity was studied in eggs and embryos of Misgurnus fossilis by fluorescence microscopy. The lateral mobility of the probe (pyrene) increased in loach embryos from early to late blastula, which indicates a decrease in plasma membrane microviscosity. At the later stage of mid-gastrula, the microviscosity remained largely invariant. Considering that the embryo exposure to different temperatures changes the quantum yield of fluorescence and the degree of pyrene excimerization, one can gain information about both the temperature-induced structural changes and changes in membrane microviscosity in the embryos. Natural and probe fluorescence of embryonic membranes is proposed as at tool to study morphogenetic mechanisms.     

Effects of native and oxidized apolipoprotein A-I on lipid bilayer microviscosity of erythrocyte plasma membrane

Using a pyrene as a fluorescent probe, we investigated the influence of native and oxidized apolipoprotein A-I (apo A-I) and their complexes with tetrahydrocortisol (THC) on the microviscosity of the erythrocyte plasma membrane. The addition of THC to isolated membranes led to a 17% increase in the membrane microviscosity. In contrast, native apo A-I reduced the microviscosity (i.e., increased the fluidity) of the membranes by 15%. A more pronounced increase (by 25%) in the membrane fluidity was found in the presence of the complex of apo A-I with THC. Unlike native apo A-I, oxidized apo A-I and its complex with THC did not change the membrane viscosity. In view of the fact that apo A-I plays an important role in the binding of membrane cholesterol we suggest that the observed increase in the membrane fluidity under the influence of the native apo A-I is associated with the cholesterol efflux from plasma membrane. Oxidative modification of apo A-I likely disturbs the mechanisms of the cholesterol efflux and prevents the decrease in the membrane microviscosity.     

Apparent microviscosity of intact and post-lipolysis ("remnant") very low density lipoprotein particles.

The apparent microviscosity of intact rat plasma very low density lipoprotein (VLDL) and post-lipolysis very low density lipoprotein was determined by fluorescence depolarization measurements and flurorescence decay measurements using 1, 6-diphenylhexatriene. Post-lipolysis very low density lipoprotein was prepared in vitro after incubation of the intact lipoprotein with either purified bovine milk lipoprotein lipase or lipoprotein lipase rich (post-heparin) plasma. During lipolysis, an average of 88% of the triglycerides were hydrolyzed, and the lipoprotein became depleted in phospholipids, cholesterol and apolipoprotein C. The apparent microviscosity of the lipoprotein increased by three-fold from 0.63 to 1.88 poise. It is concluded that the compositional changes occurring during lipolysis affect the physical properties of the lipoprotein, as measured here by the fluidity (microviscosity) of the particles.     

Lipid composition and microviscosity of subcellular fractions from rabbit thymocytes. Differences in the microviscosity of plasma membranes from subclasses of thymocytes

There are indications from freeze-fracture experiments that subclasses of rabbit thymocytes show different mobilities of plasma membrane components. Consequently, one would expect differences in the fluidity of the plasma membrane. For this reason, rabbit thymocytes were separated on a Ficoll/Metrizoate gradient yielding three subclasses representing various levels of cell differentiation. These thymocyte subclasses did not show any significant differences in the degree of fluorescence polarization using the probe 1,6-diphenyl-1,3,5-hexatriene. The fluorescence polarization of the plasma membrane may be overshadowed by the contribution of all cellular lipids due to penetration of the fluorescent probe into the cell. Therefore, plasma membranes were isolated from rabbit thymocytes using a cell-disrupting pump, differential centrifugation, and sucrose density gradient centrifugation. As shown by biochemical and electron microscopical analyses, plasma membranes with a high degree of purity were obtained. As expected the plasma membrane fractions showed a higher microviscosity than the other subcellular fractions. This was attributed to a higher cholesterol to phospholipid molar ratio and a higher degree of saturation of phospholipid fatty acid chains.Subsequently, the microviscosity was measured of plasma membrane preparations obtained from two main subclasses of thymocytes representing mature and immature lymphocytes. The immature thymocytes yielded two plasma membrane fractions with higher microviscosity than the mature cells.     

Lipid composition and microviscosity of subcellular fractions from rabbit thymocytes. Differences in the microviscosity of plasma membranes from subclasses of thymocytes.

There are indications from freeze-fracture experiments that subclasses of rabbit thymocytes show different mobilities of plasma membrane components. Consequently, one would expect differences in the fluidity of the plasma membrane. For this reason, rabbit thymocytes were separated on a Ficoll/Metrizoate gradient yielding three subclasses representing various levels of cell differentiation. These thymocyte subclasses did not show any significant differences in the degree of fluorescence polarization using the probe 1,6-diphenyl-1,3,5-hexatriene. The fluorescence polarization of the plasma membrane may be overshadowed by the contribution of all cellular lipids due to penetration of the fluorescent probe into the cell. Therefore, plasma membranes were isolated from rabbit thymocytes using a cell-disrupting pump, differential centrifugation, and sucrose density gradient centrifugation. As shown by biochemical and electron microscopical analyses, plasma membranes with a high degree of purity were obtained. As expected the plasma membrane fractions showed a higher microviscosity than the other subcellular fractions. This was attributed to a higher cholesterol to phospholipid molar ratio and a higher degree of saturation of phospholipid fatty acid chains. Subsequently, the microviscosity was measured of plasma membrane preparations obtained from two main subclasses of thymocytes representing mature and immature lymphocytes. The immature thymocytes yielded two plasma membrane fractions with higher microviscosity than the mature cells. These finding is in line with earlier observed differences in the glycerol-induced clustering of intramembranous particles. Furthermore, the results of this study support the view that the fluorescence polarization technique applied to whole cells does not exclusively monitor the plasma membrane.     

Chronic changes in plasma triglyceride levels do modify platelet membrane microviscosity in rats

Lipid metabolism disorders were proposed to mediate numerous cell membrane alterations in various forms of hypertension. Elevated plasma triglycerides were found to be associated with changes in membrane structure and function related to altered microviscosity in particular domains of the cell membrane. The aim of our study was to determine if an abnormal triglyceride metabolism might play a causal role in these alterations of membrane dynamics. Using genetically hypertensive rats of the Prague hereditary hypertriglyceridemic (HTG) strain we investigated whether the elevation of circulating triglycerides induced by high fructose intake and/or their lowering by chronic gemfibrozil treatment (for 10 weeks starting at the age of 6 weeks) are followed by reciprocal changes in membrane microviscosity. Two different fluorescent probes exploring either the outer membrane leaflet (TMA-DPH anisotropy) or the membrane lipid core (DPH anisotropy) were used in platelets of HTG rats. DPH (diphenylhexatriene) fluorescence anisotropy was decreased in platelets of fructose-treated HTG animals with highly elevated plasma triglyceride levels, whereas it was increased in gemfibrozil-treated HTG rats in which triglyceride levels were almost normalized. On the contrary, TMA-DPH (trimethylamino-diphenylhexatriene) anisotropy was not substantially altered in platelets from HTG rats by the above modifications of circulating triglycerides. No changes of plasma cholesterol or blood pressure were associated with the triglyceride-dependent modifications of membrane core microviscosity. Our interventional study demonstrates a major causal role of circulating triglycerides in the control of the microviscosity of membrane lipid core.     

Membranotropic action of cardiotonic agents and ubiquinone

Interaction of cardiotonic drugs (strophantidine acetate, suphan, para-oxybenzoic acid) and ubiquinone with phospholipid bilayers has been studied. Exothermic effect of the reaction followed by an increase in microviscosity and hydrophobicity of the bilayer from cardiolipin, but by a decrease of the microviscosity of the bilayer from lecithin has been estimated. A correlation is observed between changes in the lecithin bilayer fluidity and the heat effect of the interaction at the initial period of time after mixing of reagents.     

Cyclic GMP-induced structural transitions of photoreceptor membranes

The influence of cyclic GMP on the structural state of photoreceptor membranes was studied. The spin probe technique was used to obtain the dependences of microviscosity of lipid domains of membranes on cGMP concentration. It was shown that microviscosity of 5-doxylsteraric acid environment in rod outer segment, disc and plasma mambranes changed at concentrations of 2.10(7); 5.10(-6) and 6.10(-6). Non-cyclic GMP was ineffective. The ultrasound treatment of membraneous samples resulted on disappearance of the structural changes.     

Circadian rhythm in the membrane of circulating human blood cells: microviscosity and number of benzodiazepine binding sites. A search for regulation by plasma ions, nucleosides, proteins or hormones

Circadian rhythms in both the number of peripheral type binding sites for benzodiazepines in platelet membranes and the microviscosity of the erythrocyte membrane were demonstrated in 7 healthy men. Neither variable appeared to be linked to each other, or regulated by the plasma concentrations of total or free cortisol, testosterone, potassium, magnesium, calcium, cAMP, cGMP or proteins or by the erythrocytic concentration of magnesium or potassium or by the plasma cAMP:cGMP ratio or by the ratio of intra-erythrocyte:plasma concentrations of potassium or magnesium. A highly significant negative correlation was found between the microviscosity of the erythrocyte membrane and the activity of the membrane-bound enzyme, methyltransferase I. Such a correlation was validated both on raw data and on 24 hr-means (r = 0.84; P less than 0.01). A circadian rhythm in the activity of this enzyme was also demonstrated. Moreover, a highly significant correlation was also found between plasma transcortin concentration (TRC) and microviscosity (r = 0.50, P less than 0.01), and between TRC and methyltransferase I activity (r = 0.61, P less than 0.01). Such findings may constitute clues towards the understanding of the regulation of the circadian rhythm in the fluidity of the red blood cell membrane in man and guide future steps with regard to the role of this rhythm upon the availability of drug binding sites at the cell surface.     

Membrane microviscosity regulates endothelial cell motility

Endothelial cell (EC) movement is an initiating and rate-limiting event in the neogenesis and repair of blood vessels. Here, we explore the hypothesis that microviscosity of the plasma membrane (PM) is a key physiological regulator of cell movement. Aortic ECs treated with membrane-active agents, such as alpha-tocopherol, cholesterol and lysophospholipids, exhibited a biphasic dependency on membrane microviscosity, in which moderate increases enhanced EC migration, but increases beyond a threshold markedly inhibited migration. Surprisingly, angiogenic growth factors, that is, basic fibroblast growth factor (bFGF) and vascular endothelial growth factor (VEGF), also increased membrane microviscosity, as measured in live cells by fluorescence recovery after photobleaching (FRAP). The localization of Rac to the PM was modified in cells treated with membrane-active agents or growth factors, suggesting a molecular mechanism for how membrane microviscosity influences cell movement. Our data show that angiogenic growth factors, as well as certain lipophilic molecules, regulate cell motility through alterations in membrane properties and the consequent relocalization of critical signalling molecules to membranes.     

Microviscosity of mucosal cellular membranes in toad urinary bladder: Relation to antidiuretic hormone action on water permeability

Summary The microviscosity of cellular membranes (or membrane fluidity) was measured in suspensions of single mucosal cells isolated from the urinary bladder of the toad,Bufo marinus, by the technique of polarized fluorescence emission spectroscopy utilizing the hydrophobic fluorescent probe, perylene. At 23°C, 5mm dibutyryl cyclic 3,5-AMP decreased the apparent microviscosity of the cell membranes from 3.31 to 3.07 P, a minimum decrease of 7.3% (P<0.001) with a physiological time course. Direct visualization of the cell suspension indicated that 98% of the cells were viable, as indicated by Trypan Blue dye exclusion. The fluorescent perylene could be seen only in plasma membranes, suggesting that the measured viscosity was that of plasma membrane with little contribution from the membranes of cellular organelles. Addition of antidiuretic hormone to intact hemibladders stained with perylene produced changes in fluorescence consistent with a similar 7% decrease in apparent microviscosity with a physiological time course. However, finite interpretation of the findings in intact tissue cannot be made because the location and the fluorescent lifetime of the probe could only be conducted on the isolated cells. Comparison with previously determined relationships between water permeability and microviscosity in artificial bilayers suggests that the 7% (a lower limit) decrease in microviscosity would produce only a 6.5% increase in water permeability.     

Modulation of prolactin binding sites in vitro by membrane fluidizers. IV. Differential effects on plasma membrane and Golgi fractions of male prostate and female liver in the rat

In vitro treatment of crude particulate fractions of male rat ventral prostate and female rat liver with membrane fluidizers (aliphatic alcohols) has been previously reported by us to increase prolactin (PRL) receptor levels, presumably by unmasking cryptic prolactin receptors. The objective of this study was to determine if similar in vitro treatment of purified plasma membrane- and Golgi-rich fractions of male rat prostate and female rat liver with ethanol produced differential effects on prolactin binding in these two subcellular fractions. The degree of fluidization was monitored by a fluorescence polarization method using 1,6-diphenylhexatriene. 125I-PRL specific binding to Golgi-rich fractions of male ventral prostate and female liver was approximately 4-fold higher than that observed in plasma membrane-rich fractions. The microviscosity parameter, inversely related to lipid fluidity, was consistently lower in Golgi-rich fractions than that in plasma membrane-rich fractions in both prostate and liver. In vitro ethanol treatment of prostatic and hepatic plasma membrane fractions produced a dose-related increase and then decline in prolactin binding and a maximal (60-75%) increase in prolactin binding was observed at 4.8% and 2.0% ethanol in prostatic and hepatic membranes, respectively. This in vitro treatment also produced a significant increase in apparent lipid fluidity of plasma membrane-rich fractions of prostate gland and liver. However, similar in vitro ethanol treatment of Golgi fractions of both prostate gland and liver exhibited little increase in prolactin binding without changing microviscosity. Our observations are consistent with the direct relationship between membrane fluidity and prolactin receptor levels. The changes in prostatic and hepatic plasma membrane fractions following in vitro ethanol treatment suggest that prolactin receptors located on the plasma membranes may be modulated (via membrane lipid microviscosity changes) in vivo to a greater extent by various physiological agents than those located within the Golgi fraction.