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.     

Characteristics of the heterogeneity of the physical properties of the lipid phase of synaptic membranes from the rat brain using the fluorescent probe pyrene

A theoretical analysis of the dependence of pyrene excimerization on its concentration in biological membranes was carried out. It was shown that in synaptic membranes the concentration dependencies of pyrene excimerization parameter upon direct stimulation appear as nonlinear, thus being reflective of the heterogeneity of physical properties of the lipid phase. Upon pyrene excitation at the expense of the energy transfer from tryptophanyl residues the dependence is linear, which points to the homogeneity of the anular lipid pool. It was assumed that a comparison of microviscosity of the anular and bilayer lipids requires independent measurements of the coefficient of the probe distribution between the lipids or of the anular lipid content in the membrane.     

Differences in membrane fluidity and fatty acid composition between phenotypic variants of Streptococcus pneumoniae

Phase variation in the colonial opacity of Streptococcus pneumoniae has been implicated as a factor in the pathogenesis of pneumococcal disease. This study examined the relationship between membrane characteristics and colony morphology in a few selected opaque-transparent couples of S. pneumoniae strains carrying different capsular types. Membrane fluidity was determined on the basis of intermolecular excimerization of pyrene and fluorescence polarization of 1,6-diphenyl 1,3,5-hexatriene (DPH). A significant decrease, 16 to 26% (P < or = 0.05), in the excimerization rate constant of the opaque variants compared with that of the transparent variants was observed, indicating higher microviscosity of the membrane of bacterial cells in the opaque variants. Liposomes prepared from phospholipids of the opaque phenotype showed an even greater decrease, 27 to 38% (P < or = 0.05), in the pyrene excimerization rate constant compared with that of liposomes prepared from phospholipids of bacteria with the transparent phenotype. These findings agree with the results obtained with DPH fluorescence anisotropy, which showed a 9 to 21% increase (P < or = 0.001) in the opaque variants compared with the transparent variants. Membrane fatty acid composition, determined by gas chromatography, revealed that the two variants carry the same types of fatty acids but in different proportions. The trend of modification points to the presence of a lower degree of unsaturated fatty acids in the opaque variants compared with their transparent counterparts. The data presented here show a distinct correlation between phase variation and membrane fluidity in S. pneumoniae. The changes in membrane fluidity most probably stem from the observed differences in fatty acid composition.     

Effect of arachidonic acid on the physical properties of bilayer and annular lipids of synaptic membranes

It has been found by fluorescence analysis of pyrene excimerization that arachidonic acid while decreasing microviscosity of lipid bilayer increases it in the annular lipid zone. After incorporation of fatty acid into the membrane the annular lipid acquires the properties of a cooperative system manifested in the appearance of thermal transition near 25 degrees C.     

The study of rous sarcoma virus-transformed baby hamster kidney cells using fluorescent probes.

The fluorescent probes pyrene, pyrene butyric acid and N-phenyl 1-naphthylamine have been used to investigate the changes that accompany in vitro transformation of a baby hamster kidney cell line using Rous sarcoma virus. The fluorescent probes which reside in the membrane were used to compare the changes in microviscosity and polarity of the membranes of normal cells with two transformed cell lines. The spectrofluorimetric data indicate that following transformation the probe N-phenyl 1-naphthylamine resides in a more polar environment. However, using the probe pyrene, the yield of excimer indicates decreased mobility of this probe in the membrane of transformed cells. The data also indicate differences between the two transformed cell lines. Laser photolysis was used to study the lifetime of the pyrene probes and the quenching of the pyrene fluorescence in the membrane by several different quenching molecules. The data indicate differences between the three cell lines and suggest that transformation decreases movement within the membrane.     

Effect of gangliosides on intensity of the lipid peroxidation process and structural changes in neuronal membranes, caused by toxic doses of glutamate

We studied effects of gangliosides on the level of lipid peroxides and microviscosity of membrane lipid bilayer in primary dissociated cultures of cerebellar granule cells prepared from 8 day-old rats under conditions of neurotoxic effect of glutamate. It was found that glutamate (100 mkM) treatment of primary cultures activated the processes of lipid peroxidation and decreased microviscosity of neuronal membranes determined as a degree of pyrene excimerization. It was also shown that preincubation of granule cells with gangliosides did not prevent the accumulation of TBA-reactive products induced by glutamate. At the same time gangliosides significantly decreased the membrane-fluidizing effect caused by glutamate.     

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.     

Fluorescent probe studies of normal, persistently infected, rous sarcoma virus-transformed, and trypsinized rat cells

The fluorescent probes pyrene, pyrene butyric acid and N-phenyl 1-naphthylamine were used to study membranes of normal cells, RSV-transformed cells, cells treated with a proteolytic enzyme, and cells persistently infected with lymphocytic choriomeningitis virus. The lifetimes of excited pyrene and pyrene butyric acid showed only minor changes when these probes were in normal, transformed, trypsinized or persistently infected cells. However, pyrene, but not pyrene butyric acid, lifetimes are shorter in cell membranes than in homogeneous solvents. The quenching of excited pyrene in cells by quencher molecules was slower than corresponding reactions in homogeneous solutions indicating that the probe was screened from the quenchers by the membrane. However, quenching reactions with the pyrene butyric acid probe were similar in cells and homogeneous solvents. This indicates that pyrene and pyrene butyric acid reside in different lipid regions of the membrane. Transformed and trypsinized cells showed increased membrane fluidity compared to normal and persistently infected cells. Membrane fluidity was determined from the excimer/monomer fluorescence ratios of pyrene, and by the polarization of N-phenyl 1-naphthylamine fluorescence. Several techniques distinguished between normal and transformed or trypsinized cells; however, the only parameter unique to viral transformation was a blue shift of the fluorescence maxima of N-phenyl 1-naphthylamine. This shift reflected a less polar environment for N-phenyl 1-naphthylamine in virus-transformed cells.     

The study of rous sarcoma virus-transformed baby hamster kidney cells using fluorescent probes

The fluorescent probes pyrene, pyrene butyric acid and $\text{N-}\text{phenyl}$ 1-naphthylamine have been used to investigate the changes that accompany in vitro transformation of a baby hamster kidney cell line using Rous sarcoma virus. The fluorescent probes which reside in the membrane were used to compare the changes in microviscosity and polarity of the membranes of normal cells with two transformed cell lines. The spectrofluorimetric data indicate that following transformation the probe $\text{N-}\text{phenyl}$ 1-naphthylamine resides in a more polar environment. However, using the probe pyrene, the yield of excimer indicates decreased mobility of this probe in the membrane of transformed cells. The data also indicate differences between the two transformed cell lines. Laser photolysis was used to study the lifetime of the pyrne probes and the quenching of the pyrene fluorescence in the membrane by several different quenching molecules. The data indicate differences between the three cell lines and suggest that transformation decreases movement within the membrane.     

Cystic fibrosis: II. Altered microviscosity of erythrocyte membrane

Erythrocyte membrane fluidity alterations in cystic fibrosis are described. The relative flexibility of the membrane was studied using lipid spin label, i.e. methyl-5-doxylpalmitate (M5DP), and pyrene as a fluorescence probe. It was found that there was a decrease of membrane fluidity in the hydrophobic midzone of the membrane, probed by pyrene, as well as at the hydrophilic surface region, probed by M5DP.     

The lack of relationship between fluorescence polarization and lateral diffusion in biological membranes

An investigation has been carried out of the relationship between changes in the fluorescence polarization of 1,6-diphenyl-1,3,5-hexatriene (DPH) and concomittant changes in the lateral diffusion of proteins and lipid probes in membranes. Plasma membranes from lymphocytes and a CH1 mouse lymphoma line were treated with up to 70 mol% (relative to the total membrane phospholipid) of oleic or linoleic fatty acids. Under these conditions the fluorescence polarization of DPH decreased by between 8 and 15% which, in the framework of the microviscosity approach, suggests a membrane fluidity change of between 20 and 50%. The lateral diffusion coefficients of surface immunoglobin and the lipid probes 3,3′-dioctadecylindocarbocyanine and pyrene were also measured in these membranes using the fluorescence photobleaching recovery technique and the rate of pyrene excimer formation. The diffusion rates were found to be unaffected by the presence of free fatty acids. Hence despite large ‘microviscosity’ changes as reported by depolarization of DPH fluorescence, lateral diffusion coefficients are essentially unchanged. This finding is consistent with the idea that perturbing agents such as free fatty acids do not cause a general fluidization of the membrane but act locally to alter, for example, protein function. It is also consistent with the suggestion that lateral mobility of membrane proteins is not modulated by the lipid viscosity.     

Fluidity of natural membranes and phosphatidylserine and ganglioside dispersions. Effect of local anesthetics, cholesterol and protein.

The microviscosity of artificial lipid membranes and natural membranes was measured by the fluorescence polarization technique employing perylene as the probe. Lipid dispersions composed of brain gangliosides exhibited greater microviscosity than phosphatidylserine (268 cP vs 173 cP, at 25 degrees C). Incorporation of cholesterol (30-50%) increased the microviscosity of lipid phases by 200-500 cP. Cholesterol's effect on membrane fluidity was completely reversed by digitonin but not by amphotericin B. Incorporation of membrane proteins into lipid vesicles gave varying results. Cytochrome b5 did not alter membrane fluidity. However, myelin proteolipid produced an apparent increase in microviscosity, but this effect might be due to partitioning of perylene between lipid and protein binding sites since tha latter have a higher fluorescence anisotropy than the lipid. The local anesthetics tetracain and butacaine increased the fluidity of lipid dispersions, natural membranes and intact ascites tumor cell membranes. The effect of anesthetics appears to be due to an increased disordering of lipid structure. The fluidity of natural membranes at 25 degrees C varied as follows: polymorphonuclear leukocytes, 335 cP; bovine brain myelin, 270 cP; human erythrocyte, 180 cP; rat liver microsomes, 95 cP; rat liver mitochondria, 90 cP. In most cases the microviscosity of natural membranes reflects their cholesterol: phospholipid ratio. The natural variations in fluidity of cellular membranes probably reflect important functional requirements. Similarly, the effects of some drugs which alter membrane permeability may be the result of their effects on membrane fluidity.     

Modulation of membrane receptor endocytosis by chemical effectors of membrane fluidity

Several chemical effectors were used to induce changes in spleen B cell membrane fluidity. Membrane fluidity was monitored by fluorescence polarization analysis of the hydrophobic probe 1,6-diphenyl-1,3,5-hexatriene (DPH) and cell viability was checked not to be affected by the treatments. Membrane immunoglobulin (Ig) endocytosis by the living B cells with modified or unmodified membranes was quantitatively measured by flow cytometry, using a previously described method (Métézeau et al., 1982, 1984). The kinetics of endocytosis of membrane Ig was not affected by chemical effectors increasing membrane fluidity. On the contrary, increasing membrane microviscosity resulted in the slowing down and eventually the blocking of membrane Ig endocytosis. It is suggested that a step depending on membrane microviscosity is involved in the process of endocytosis; this step may become rate limiting when membranes are artificially rendered or naturally become (i.e. for pathological or particularly differentiated cells) more viscous.     

Fluidity of natural membranes and phosphatidylserine and ganglioside dispersions: Effects of local anesthetics,cholesterol and protein

The microviscosity of artificial lipid membranes and natural membranes was measured by the fluorescence polarization technique employing perylene as the probe. Lipid dispersions composed of brain gangliosides exhibited greater microviscosity than phosphatidylserine (268 cP vs 173 cP, at 25 °C). Incorporation of cholesterol (30–50%) increased the microviscosity of lipid phases by 200–500 cP. Cholesterol's effect on membrane fluidity was completely reversed by digitonin but not by amphotericin B. Incorporation of membrane proteins into lipid vesicles gave varying results. Cytochrome b₅ did not alter membrane fluidity. However, myelin proteolipid produced an apparent increase in microviscosity, but this effect might be due to partitioning of perylene between lipid and protein binding sites since the latter have a higher fluorescence anisotropy than the lipid. The local anesthetics tetracaine and butacaine increased the fluidity of lipid dispersions, natural membranes and intact ascites tumor cell membranes. The effect of the anesthetics appears to be due to an increased disordering of lipid structure. The fluidity of natural membranes at the 25 °C varied as follows:polymorphonuclear leukocytes, 335 cP; bovine brain myelin, 270 cP; human erytherocyte, 180 cP; rat liver microsomes, 95 cP; rat liver mitochondria, 90 cP. In most cases the microviscosity of natural membranes reflects their cholesterol : phospholipid ratio. The natural variations in fluidity of cellular membranes probably reflect important fuctional requirements. Similarly, the effects of some drugs which alter membrane permeability may be the result of their effects on membrane fluidity.     

Evidence for the extended phospholipid conformation in membrane fusion and hemifusion

Molecular-level mechanisms of fusion and hemifusion of large unilamellar dioleoyl phosphatidic acid/phosphocholine (DOPA/DOPC, 1:1 molar ratio) vesicles induced by millimolar Ca2+ and Mg2+, respectively, were investigated using fluorescence spectroscopy. In keeping with reduction of membrane free volume Vf, both divalent cations increased the emission polarization for 1,6-diphenyl-1,3, 5-hexatriene (DPH). An important finding was a decrease in excimer/monomer emission intensity ratio (Ie/Im) for the intramolecular excimer-forming probe 1, 2-bis[(pyren-1-)yl]decanoyl-sn-glycero-3-phosphocholine (bis-PDPC) in the course of fusion and hemifusion. Comparison with another intramolecular excimer-forming probe, namely, 1-[(pyren-1)-yl]decanoyl-2-[(pyren-1)-yl]tetradecanoyl-sn-gl ycero-3-p hosphocholine (PDPTPC), allowed us to exclude changes in acyl chain alignment to be causing the decrement in Ie/Im. As a decrease in Vf should increase Ie/Im for bis-PDPC and because contact site between adhering liposomes was required we conclude the most feasible explanation to be the adoption of the extended conformation (P.K.J., Chem. Phys. Lipids 63:251-258) by bis-PDPC. In this conformation the two acyl chains are splaying so as to become embedded in the opposing leaflets of the two adhered bilayers, with the headgroup remaining between the adjacent surfaces. Our data provide evidence for a novel mechanism of fusion of the lipid bilayers.     

Fluorescence polarization applied to cellular microrheology

The fluorescence polarization of probe molecules gives information on the "fluidity" of probe environment. Although the data cannot be related with absolute values of microviscosity, the method is largely used for probing the "fluidity" of lipid regions of biological membranes. Therefore, fluorescence polarization is of interest in clinical research, for membrane alterations are associated with either pathological processes of red cells, platelets, leukocytes or important cell functions.     

Factors altering the membrane fluidity of spinach thylakoid as determined by fluorescence polarization

Alterations in fluidity of thylakoid membranes isolated from spinach chloroplasts in response to sodium bisulfite (NaHSO₃), hydrogen peroxide (H₂O₂), sodium dodecyl sulfate (SDS), bovine serum albumin (BSA), and free linoleic acid (LA) were investigated by means of a fluorescence polarization study with 1,6-diphenyl-1,3,5-hexatriene as the fluorescence probe. A decrease in fluidity and an increase in microviscosity of membrane were caused by NaHSO₃ and H₂O₂ treatment. In contrast, SDS and BSA were found to increase thylakoid membranes fluidity and decrease microviscosity, in which the corresponding correlation coefficients were −0.9995 to −0.9516 (SDS) and −0.9359 (BSA), respectively. No changes in thylakoid membranes fluidity induced by free LA were found until its concentration above 5 mM where the polarization value (P value) declined (increased fluidity). The results suggest that the changes in thylakoids membrane fluidity might depend on the characteristics, mechanism and extent of the interactions between membrane components and compounds added.     

The effects of ionic strength on the protein conformation and the fluidity of porcine intestinal brush border membranes. Fluorometric studies using N-[7-dimethylamino-4-methylcoumarinyl]maleimide and pyrene

The effects of ionic strength on the conformation around the SH groups of the proteins and the lipid fluidity of porcine intestinal brush border membranes were studied using two fluorescent dyes, N-[7-dimethylamino-4-methylcoumarinyl]maleimide (DACM) and pyrene. The extent of DACM labeling to the SH groups of the membrane proteins was accelerated depending on the KCl concentrations in medium. A quenching study of DACM-labeled membranes with acrylamide showed that the proximity of the quencher to the fluorescence-labeled SH groups in the membrane proteins is increased with increasing ionic strength of medium. An implication of the conformational changes around SH groups in the membrane proteins with increase of ionic strength was also obtained from the stimulation of guanidine effect on the fluorescence parameters of DACM-labeled membranes by addition of KCl. On the other hand, the results of the quenching study with KI, excimer fluorescence, and polarization measurements of pyrene-labeled membranes suggested an increase of membrane fluidity on addition of KCl to medium. The temperature dependence of polarization of the complex strongly suggested that the rotational freedom of pyrene molecules embedded into the lipid layers of the membranes is increased by addition of KCl. In fact, the harmonic means of the rotational relaxation times of pyrene molecules in the membranes with and without 100 mM KCl were estimated to be about 2900 and 9000 ns at 25 degrees C, respectively. Based on these results, the salt-induced alterations of the conformation in the vicinity of the bound dyes of the membrane proteins and of the membrane fluidity are discussed.     

Effect of cholinergic ligands on the lipids of acetylcholine receptor-rich membrane preparations from torpedo californica

Ion permeation, triggered by ligand-receptor interaction, is associated with the primary events of membrane depolarization at the neuromuscular junction and synaptic connections. To explore the possible sites of ion permeation, the long-lived fluorescent probe pyrene (fluorescence lifetime ～400 nsec) has been inserted into the lipid phase of acetylcholine receptor-rich membrane (AcChR-M) preparations from Torpedo californica. The pyrene probe is susceptible to both fluidity and permeability changes in the lipid bilayer. These changes are detected by variations in the rate of decay of the excited singlet state of pyrene after pulsation with a 10-nsec ruby laser flash. Variations of these lifetimes in the membrane preparations alone or in the presence of quenchers show that binding of cholinergic agonists and antagonists, neurotoxins, and local anesthetics to AcChR-M produces varying effects on the properties of the pyrene probe in the lipid phase. It is concluded that binding of cholinergic ligands to the receptor does not significantly alter the fluidity or permeability of the lipids in the bilayer in contact with pyrene. On the other hand, local anesthetics do affect these properties.     

Localization of the lipid probe 1,6-diphenyl-1,3,5 hexatriene (DPH) in intact cells by fluorescence microscopy

The lipophilic fluorescent probe DPH, generally used to determine the microviscosity of membrane lipids, has been visualized in intact cells by fluorescence microscopy. All lipid material of the cells, including cytoplasmic lipid droplets, was found to be labelled with DPH. The fluorescent signal from inside the cells contributes to a large extent to the total cell fluorescence. The results indicate that fluorescence polarization data obtained from intact cells, using DPH as probe, give information on the total lipid material of the cells rather than exclusive information on microviscosity and fluidity of plasma membranes of these cells, as has been repeatedly suggested.