A spin label study of rat brain membranes. Effects of temperature and divalent cations

Spectrum of neural electrical activity in guinea pig cochlea: Effects of anaesthesia regimen, body temperature and ambient noise

Spectral analysis of electric noise recorded from the round window of the cochlea is thought to represent the summed spontaneous activity of the auditory nerve. It has been postulated that it could provide a possible tinnitus index. Because experimental conditions could change this neural activity, the effect of anaesthesia regimen, body temperature and ambient noise on the spectrum of spontaneous neural noise (SNN) were investigated in guinea pig cochlea. SNN was studied in awake guinea pigs and after anaesthesia with pentobarbital (P), xylazine/ketamine (XK) or xylazine/tiletamine-zolazepam (XTZ). Body temperature varied gradually from 33 to 41 degrees C under XK regimen. In awake animals, broadband noise was generated with intensity varying from 0 to 50 dB. The SNN consisted in a broad peak at approximately 900 Hz. With ambient broadband noise, it increased exponentially with the sound level with no shift in frequency. Soon after anaesthetic induction, the lowest frequencies were constantly decreased, and gradually the 900 Hz peak either increased moderately (P) or dropped steeply (XTZ) or remained unchanged (XK). Peak frequency increased linearly with body temperature whereas the amplitude reached a maximum at around 39.5 degrees C. In conclusion, these data indicate that experimental conditions such as anaesthesia regimen, body temperature and ambient noise modify the spontaneous neural outflow of the cochlea and must be taken into account when studying SNN.

Altered microviscosity at brain membrane surface induces distinct and reversible inhibition of opioid receptor binding

In synaptosomal membranes from rat and monkey brain cortex, the addition of petroselenic (18:1, cis-delta 6) acid, oleic (18:1, cis-delta 9) acid, and vaccenic (18:1, cis-delta 11) acid or their corresponding methyl esters at 0.5 mumol/mg of membrane protein caused a similar 7-10% decrease in the microviscosity of the membrane core, whereas at the membrane surface the microviscosity was reduced 5-7% by the fatty acids but only 1% by their methyl esters. Concomitantly, the fatty acids, but not the methyl esters, inhibited the specific binding of the tritiated mu-, delta-, and kappa-opioids Tyr-D-Ala-Gly-(Me)Phe-Gly-ol (DAMGO), [D-Pen2,D-Pen5]enkephalin (DPDPE), and U69,593, respectively. As shown with oleic acid, the sensitivity of opioid receptor binding toward inhibition by fatty acids was in the order delta greater than mu much greater than kappa, whereby the binding of [3H]DPDPE was abolished, but significant inhibition of [3H]U69,593 binding, determined in membranes from monkey brain, required membrane modification with a twofold higher fatty acid concentration. Except for the unchanged KD of [3H]U69,593, the inhibition by oleic acid involved both the Bmax and affinity of opioid binding. Cholesteryl hemisuccinate (0.5-3 mumol/mg of protein), added to membranes previously modified by fatty acids, reversed the fluidization caused by the latter compounds and restored inhibited mu-, delta-, and kappa-opioid binding toward control values. In particular, the Bmax of [3H]-DPDPE binding completely recovered after being undetectable.(ABSTRACT TRUNCATED AT 250 WORDS)

pH-induced reorganization of synaptic membrane as revealed by fluorescence anisotropy and energy transfer

Two fluorescent probes, 2-(9-anthroyloxy)stearate and 12-(9-anthroyloxy)stearate, were used to investigate the effects of the neutralization of membrane charges on the organization of synaptic plasma membrane. Steady state fluorescence anisotropy measurements showed that a pH decrease provoked a rigidification of the synaptic membrane surface, whereas the bilayer core remained unaffected. The same effect was observed with negatively charged lipid vesicles. The relative distribution of proteins and the probes was estimated by fluorescence energy transfer from protein tryptophans to fluorescent probes: a pH decrease provoked an increase of the energy transfer, which was most pronounced with the surface probe, indicating an average closer packing between proteins and the probes. The modifications induced by a pH decrease were temperature dependent and were most marked at low temperatures. The results suggest that neutralization of the membrane charges provoked a redistribution of both membrane lipids and proteins. These findings are discussed in terms of a heterogeneous distribution of these membrane components.

Fatty acid composition of phospholipids of myelin and synaptosomal proteolipid complexes from vertebrate brain

1. Fatty acid composition of five main phospholipids of vertebrate brain myelin and synaptosomal proteolipids and membranes was studied. 2. Higher content of monoenoic and lower content of saturated and polyenoic fatty acids was found to be characteristic of phospholipids from myelin and myelin proteolipids as compared to phospholipids from synaptosomal proteolipids and membranes of vertebrates (from fishes to mammalians). Fatty acid composition of phospholipids of proteolipid complexes and of the membranes, from which they were isolated, were found to be similar in various species studied. 3. Microviscosity was found to be higher in myelin as compared to synaptosomal membranes of frog Rana temporaria and in rabbit Lepus cuniculus. It appears to be due to the difference in proteolipid content and in lipid composition of myelin and synaptosomal membranes.

Biophysical interpretation of membrane fluidity by catastrophe theory

We have regrouped the data of two examples where membrane fluidity was progressively modified by pharmacological and physiological agents. In our approach, each initial condition is determined by control parameters (depth of the membrane bilayer explored, concentration of agents). The fluidity is expressed as a state parameters followed on the control space. Then, according to Catastrophe Theory, the results are depicted as tridimensional patterns which can be recognized as bifurcation sets. Consequently, the fluidity is considered as resulting in a compromise phenomenon (normal factor) between two structurally attracting configurations (of hydrophilic and hydrophobic nature). The concepts of membrane activity and membrane function are then discussed on the basis of physiological functionality of biomembranes. The main application of this research interests the pharmacological domain. Indeed, a new classification of drugs could be proposed. According to the loss of membrane functionality, some drugs could imply a too high differentiation of attractors (splitting factor) and others could imply the destruction of the compromise. The first type is characterized by the physical destruction of the membrane. In the second type, the entity of the bilayer is preserved but the membrane is destructurated.

Influence of ethanol on calcium, inositol phospholipids and intracellular signalling mechanisms

Studies have implicated Ca++ in the actions of ethanol at many biochemical levels. Calcium as a major intracellular messenger in the central nervous system is involved in many processes, including protein phosphorylation enzyme activation and secretion of hormones and neurotransmitters. The control of intracellular calcium, therefore, represents a major step by which neuronal cells regulate their activities. The present review focuses on three primary areas which influence intracellular calcium levels; voltage-dependent Ca++ channels, receptor-mediated inositol phospholipid hydrolysis, and Ca++/Mg++-ATPase, the high affinity membrane Ca++ pump. Current research suggests that a subtype of the voltage-dependent Ca++ channel, the dihydropyridine-sensitive Ca++ channel, is uniquely sensitive to acute and chronic ethanol treatment. Acute exposure inhibits, while chronic ethanol exposure increases 45Ca++-influx and [3H]dihydropyridine receptor binding sites. In addition, acute and chronic exposure to ethanol inhibits, then increases Ca++/Mg++-ATPase activity in neuronal membranes. Changes in Ca++ channel and Ca++/Mg++-ATPase activity following chronic ethanol may occur as an adaptation process to increase Ca++ availability for intracellular processes. Since receptor-dependent inositol phospholipid hydrolysis is enhanced after chronic ethanol treatment, subsequent activation of protein kinase-C may also be involved in the adaptation process and may indicate increased coupling for receptor-dependent changes in Ca++/Mg++-ATPase activity. The increased sensitivity of three Ca++-dependent processes suggest that adaptation to chronic ethanol exposure may involve coupling of one or more of these processes to receptor-mediated events.

A radiolabel and electron microscopy study of the interaction of liposomes with synaptosomal membranes

The quantitative and qualitative interaction of liposomes with synaptosomes isolated from rat brain was examined using radiolabeled phospholipids and electron microscopy. Liposomes were prepared by sonication and detergent dialysis. Binding (adsorption) of radiolabeled phospholipid to synaptosomes was saturable when liposomes were in the liquid-crystalline state, were electrically neutral (egg-phosphatidylcholine), or carried increasing fractions (10:2 and 10:4 molar ratio) of negatively charged phosphatidic acid. Analysis using the Langmuir isotherm equation indicated a biphasic adsorption behavior. Adsorption increased with increasing temperature (4 degrees C and 37 degrees C). Binding was nonsaturable when liposomes were positively charged with stearylamine or composed of dimyristoylphosphatidylcholine and phosphatidylinositol (10:2 molar ratio). Due to the latter composition's solid state at 4 degrees C, temperature dependency was inverse. Electron micrographs revealed disc-shaped areas of adsorption that were free of integral membrane particles which appeared to form a condensed layer surrounding the areas of liposome adsorption. Following interaction with stearylamine-containing liposomes the vesicular structure of synaptosomes appeared largely destroyed. It is concluded that both liposome surface charge and membrane fluidity determine the extent of interaction with biological membranes.

Effects of platelet activating factor on calcium-lipid interactions and lateral phase separations in phospholipid vesicles

Recent studies localizing the inflammatory mediator, platelet activating factor (PAF, 1-O-alkyl-2-acetyl-sn-glycero-3-phosphocholine), to the membranes of stimulated neutrophils, raise the possibility that PAF may, in addition to its activities as a mediator, alter the physical properties of membranes. This, and the increasing evidence that calcium-lipid interactions may have central importance in membrane organizational structure and in functions of cell homeostasis and stimulus-response coupling, prompted us to study the effects of PAF on calcium-lipid interactions in lipid vesicles. Using fluorescence polarization of dansylated probes located in the glycerol portion of the membrane bilayer, PAF (at a concentration as low as 1 mol%) was shown to reduce membrane rigidification significantly during calcium-induced lateral phase separations. This effect of PAF was structurally dependent on both the 1-position alkyl linkage and the 2-position acetyl group as shown by studies of related lipid analogs. Furthermore, using a self-quenching probe, it was shown that inhibition of lateral phase separation did not account for this reduction in the calcium-induced membrane rigidification attributed to PAF. Data suggest that PAF at low concentrations may alter phospholipid head packing and, thereby, change membrane surface features during calcium-lipid interactions, effects which may ultimately explain some of its biological actions.

Effects of ethanol and calcium on lipid order of membranes from mice selected for genetic differences in ethanol intoxication

Fluorescent probes were used to compare the physical properties of membranes from mice selected for sensitivity (LS) and insensitivity (SS) to the hypnotic action of ethanol. Brain synaptic plasma membranes (SPM) from LS mice were more sensitive to the disordering action of ethanol than those from LS mice when probes were located near the membrane surface. However, the membrane core of membranes from the two lines was equally sensitive to ethanol. The genetic differences in ethanol sensitivity of the membrane surface were eliminated when fluorescence measurements were carried out in the presence of 2-3 mM CaCl2. Consistent with behavioral data, differential genetic sensitivity to the disordering action was not obtained with longer chain alcohols. The genetic difference in ethanol sensitivity was not detected with erythrocyte membranes or lipids extracted from SPM. These results indicate that there is a structural difference in the surface of brain membranes of LS and SS mice than may influence their sensitivity to ethanol.

Intracellular free magnesium in synaptosomes measured with entrapped eriochrome blue

The free Mg2+ concentration within synaptosomes has been measured with an entrapped Mg2+ indicator, eriochrome blue. Ionophores gramicidin and A23187 slowly increased the absorbance of the entrapped dye. Calibration of the dye response in a Na+-based medium gave a value around 0.3 mM for the internal free Mg2+ concentration at 1 mM external Mg2+. The replacement of Na+ by choline increased this value to around 0.65 mM. Depolarisation with a high K+ concentration or depletion of intrasynaptosomal ATP with FCCP and iodoacetate did not affect the level of intracellular free Mg2+ concentration. An elevation of the external Ca2+ concentration significantly reduced internal Mg2+ to about 0.1 mM. Ca2+ had no significant effect when Na+ was replaced by choline. The results indicate that the intrasynaptosomal Mg2+ activity is partially regulated by a Na+-Mg2+ exchange mechanism which does not directly require ATP as an energy source.

Changes in cell membrane fluidity affect the sodium transport across frog skin and its sensitivity to amiloride

1. 1-5 mM n-hexanol added to the outer (mucosal) medium of isolated skin of the frog Rana temporaria increases the short circuit current (Isc) across it. 2. This effect shows a saturable dependency on the outer sodium concentration, also when NaCl is replaced by Na2SO4. 3. n-Hexanol at a concentration of 1 mM, and cold acclimation of the frogs, which increases the fluidity of epidermal cell membranes, do not affect the sensitivity of Isc to the inhibiting effect of amiloride. 4. n-Hexanol at a concentration (5 mM) which causes a fluidization of cell membrane preparations from isolated frog epidermis also increases the sensitivity of Isc to amiloride. 5. The effects of low concentrations of n-hexanol and of cold acclimation probably depend on an increase of the permeability of apical membranes of epidermal cells to sodium caused by membrane fluidization. At higher concentrations of n-hexanol, a further disordering of the membrane structure occurs with a better access of amiloride to its action sites.

Measurement of cytoplasmic, free magnesium concentration with entrapped eriochrome blue in nerve endings isolated from the guinea pig brain

Cytoplasmic, free Mg2+ was measured spectrophotometrically using an intrasynaptosomally entrapped Mg2+-indicator, Eriochrome blue (EB). Addition of the ionophore A23187 or disruption of the synaptosomal plasma membrane with digitonin caused an increase in absorbance of entrapped EB with a maximum at 551 nm, which is typical for the Mg2+-EB complex. A conversion of absorbance changes to levels of free Mg2+ concentrations was performed after disruption of synaptosomal plasma membranes by digitonin. The results indicated that the internal, free Mg2+ increased from 0.34 to 2.2 mM when the extracellular Mg2+ concentration was increased from 1 to 5 mM. The low values of cytoplasmic, free Mg2+ concentrations suggest the presence of effective regulatory mechanisms in the nerve endings.

Platelet membrane molecular organization: relationship with membrane bound calcium

The fatty acid spin label 5 nitroxide stearate has been used to determine the membrane organization changes induced by platelet aggregation. A decrease in order is observed with thrombin, even in the presence of EDTA, when aggregation is inhibited. Conversely, after aggregation by the calcium ionophore A23187 the rigidity of the phospholipids is not modified. These effects are discussed in relation to the release of membrane bound calcium induced by thrombin.

Thermodynamic interpretation of effects of alcohols on membrane lipid fluidity

The effect of a series of amphiphilic compounds, the first eight n-aliphatic alcohols, on the fluidity of rat enterocyte brush border was determined by ESR using 5-doxyl stearic acid as a lipid spin probe. Packing order variations are compared to the relative hydrophobic effect of the alcohols. The concentrations, [Ci]5 of each alcohol that decrease the membrane 2T' value by 5%, vary by a factor of 1500 from methanol to octanol. From [Ci]5, the membrane concentrations Cm and the variation of free energy delta F degree due to the incorporation of the alcohols in the lipids, were calculated. These calculations were performed taking into account the respective volumes of the aqueous phase and the membrane lipids. Cm is of the order of 0.18 mol/kg for the odd chain length alcohols and of 0.27 mol/kg for the even alcohols. The value of delta F degree in cal/mol -CH2- is -687 cal on average for the eight alcohols. This work shows that for all the alcohols, the concentrations at equilibrium in the membrane and in the aqueous phase are respectively in agreement with Meyer and Overton's theory and with the gradient of free energy which constitutes the most general index of interaction of lipophilic substances with membranes.

An electron-spin-resonance spin-label study of the interaction of purified Mojave toxin with synaptosomal membranes from rat brain

The structural properties of isolated purified rat brain synaptosomal membranes, both in the presence and absence of purified active toxin of the Mojave snake Crotalus scutulatus scutulatus, were studied by spin-label electron spin resonance techniques. The spectra from eight different positional isomers of nitroxide-labelled stearic acids, a rigid steroid androstanol, and a spin-labelled phosphatidylcholine intercalated into the synaptosomal membranes, were obtained as a function of temperature from 4-40 degrees C. The flexibility gradient (from spin-label order parameters) and polarity profile (from isotropic splitting factors) across the synaptosomal membranes, was characteristic for lipid bilayers. The nitroxide spin-labelled steroid, androstanol, intercalated into the synaptosomal membrane, revealed the abrupt onset of rapid cooperative rotation about the long axis of the molecule at 12 degrees C showing that the lipid molecules are rotating rapidly around their long axes at physiological temperatures. The presence of the Mojave toxin affected the synaptosomal membrane in a complex manner, depending upon the temperature and the position of the nitroxide label on the alkyl chain of the stearic acid probe. Mojave toxin exerted little effect on the flexibility gradient of the synaptosomal membrane at 20 degrees C, a temperature at which the acyl chain labels detected a structural change in the membranes. At temperatures lower than 20 degrees C, the Mojave toxin produced a change in the flexibility gradient of the synaptosomal membrane which indicated an increased disordering in the upper region of the membrane and a concomitant increased ordering of the acyl chains in the deeper regions of the membrane. At temperatures higher than 20 degrees C, the order profile of the synaptosomal membrane was shifted by the presence of the Mojave toxin in a manner which indicated that the outer parts of the membrane were more rigid and the inner regions more fluid, than in controls. A cross-over point for the perturbation occurred at C8-9, which is about 12-14 A into the membrane. This is the approximate depth of the hydrophobic pocket shown in pancreatic phospholipase A2 [Drenth et al. (1976) Nature (Lond.) 264, 373-377], a protein likely to be homologous to the basic subunit of the toxin. At all temperatures, rotational lipid motion was inhibited by the toxin as indicated by the steroid probe. The electron spin-resonance spin-label results are interpreted in terms of the partial penetration of the basic subunit of the intact toxin into the membrane, disordering the ordered chains at low temperature and ordering the disordered chains at physiological temperatures. The purified individual toxin subunits did not perturb the membrane lipids at physiological temperatures implying that both subunits must be associated for activity of the toxin which is confirmed by toxicity studies.

Pathophysiology of ischemic cell death: III. Role of extracellular factors

The purpose of this study was to determine the effect on cell survival of extracellular changes that occur during ischemia, over and above the depletion of O2 and substrate. Rabbit retinas were deprived in vitro of both O2 and substrate, and then returned to control medium for 4 h before recovery was assessed by measuring protein synthesis, glucose utilization, and tissue water. Experimental conditions were altered in various ways during the period of O2 and substrate deprivation in order to modify the changes taking place in the interstitial fluid as a result of the failure of energy metabolism. When O2-free, substrate-free extracellular electrolyte solution was added to the retinas to reduce the ischemia-induced changes in the interstitial fluid, there was marked reduction in irreversible damage. But when energy-deprived retinas were exposed to retinas that had already been ischemic, or to interstitial fluid from ischemic retinas, there was an increase in irreversible damage. Removing Ca++ from the extracellular fluid during the period of energy deprivation increased the damage due to short deprivations in a restricted volume of extracellular fluid, but reduced the damage from longer deprivations in a large volume of extracellular fluid. The results demonstrate that several changes occur in the extracellular fluid during ischemia that significantly affect recovery.

Interaction of ticlopidine with the erythrocyte membrane

The membrane effects of ticlopidine on the erythrocyte membrane were explored by the spin label method at the proteic and phospholipidic levels. This spectroscopic study was completed by polyacrylamide gel electrophoresis of proteins, measurement of the protection against haemolysis and observation of the erythrocyte shape changes induced by the drug. Two types of effects have been observed. At concentrations higher than 5 x 10(-4) M, ticlopidine is a weak denaturating agent of the membrane proteins. At concentrations of pharmacological interest, the main effect of the drug is a protection against hypotonic haemolysis, and an increase in the fluidity of the membrane phospholipidic core. This last result could explain in part the interesting pharmacological effect of ticlopidine on various circulatory troubles.

Effect of prostaglandin E1, dopamine and dibutyryl cyclic AMP on the fluidity of synaptosome membranes

The membrane fluidity of synaptosomes, isolated from rat brain and spin-labelled with doxyl derivatives of stearic acid, was studied using electron spin resonance techniques. Prostaglandin E1 fluidized while dopamine ordered both the surface and intermediate lipid layers of the synaptosome membranes. At corresponding concentrations these substances have been shown to modulate synaptic transmission. A possible thermal phase transition of the membrane lipid bilayer was observed at about 35 degrees C (the abrupt change in the Arrhenius plot). Dopamine abolished this thermal change. Dibutyryl cyclic AMP had no significant membrane effects.

Diffuse structural alterations in cell membranes of spontaneously hypertensive rats

Plasma membranes from heart, nerve endings, and liver were compared in 3-week-old male spontaneously hypertensive rats from the Okamoto substrain (SHR) and normotensive Wistar/Kyoto control rats (WKY) [systolic blood pressure 105 +/- 4 and 95 +/- 4 mm Hg, respectively (1 mm Hg = 133 Pa)] according to two criteria: calcium binding at physiological intracellular concentrations and polarization of an embedded fluorescent probe, 1,6-diphenyl-1,3,5-hexatriene. Whatever the tissue of origin, the density of high-affinity calcium binding sites was lower in SHR than in WKY plasma membranes, and the polarization of diphenylhexatriene fluorescence was constantly higher in SHR than in WKY membranes. These membrane abnormalities are similar to those previously described in the erythrocyte membrane from SHR. The presence of diffuse structural alterations in cellular membrane from young spontaneously hypertensive rats when blood pressure is still in the normotensive range suggests a genetic origin. Such inherited abnormalities may by themselves participate in the rise in blood pressure.

Radiation and brain calcium: a review and critique

Serious controversy pervades the scientific study of radio-frequency (RF) radiation and its biological effects. The issues range broadly from international differences in safe exposure standards to questions pertaining to the neurological symptoms purportedly induced by electromagnetic radiation. In a more specialized vein, there is great concern in the discipline about the influence of different sources of radiation on the activity of calcium in the brain. A principal and very realistic reason for this concern stems from the pivotal importance of calcium ions in the normal functioning of the brain in all of its myriad complexity. The purpose of the review is to critically evaluate from an unbiased and "non-involved" viewpoint the major findings on the possible interaction between calcium ions and various radiation sources. Background information is also considered as it relates even indirectly to hypothetical mechanisms that might be used to explain any possible shift in Ca++ ion kinetics. Finally, an inclusive critique is presented which deals with the bench-top methods and strategy used in the conduct of calcium-radiation experiments.

Preparation and spectroscopic characterization of molecular species of brain phosphatidylserines

This study describes the first preparation and spectroscopic characterization of naturally occurring phospholipids separated according to degree of unsaturation. Phosphatidylserines (PS) have been prepared from bovine brain and shown to be pure by extensive thin layer chromatographic analysis as well as by infrared spectroscopy and fatty acid analysis. The PS has been separated according to degree of unsaturation and prepared using AgNO3-impregnated silica gel H thin-layer chromatography. Fatty acid analysis of the two principal PS subfractions indicates that they are enriched in the molecular species 1-octadecanoyl-2-docosahexaenoyl-sn-glycero-3-phosphorylserine and 1-octadecanoyl-2-octadecenoyl-sn-glycero-3-phosphorylserine. The identity of the two PS subfractions was further verified by rechromatographing on several thin layer systems and by infrared spectroscopy. With the use of a 100 MHz Fourier transform nuclear magnetic resonance (NMR) spectrometer, the spectra of bovine whole brain, white matter, gray matter, monoenoic, and hexaenoic PS were obtained. Distinct proton resonances were assigned to double bond protons, protons adjacent to a double bond, and protons between two double bonds, using fatty acid methyl ester standards. The various PS preparations gave different intensities of the various proton resonances which correlated with differences in fatty acid composition. The method provides a convenient, non-destructive spectroscopic method for distinguishing monoenoic and polyunsaturated species of intact phospholipids. Electron spin resonance studies of nitroxide-labelled cholestane in sonicated PS vesicles showed greater probe motion as the unsaturation of the acyl chains was increased. The hexaenoic PS vesicles were more fluid than monoenoic PS vesicles at all temperatures in the range 10-55 degrees C. These results suggest that neuronal membranes are more fluid than myelin membranes as neuronal membranes contain more hexaenoic phospholipids.

Effects of calcium, lanthanum, and temperature on the fluidity of spin-labeled human platelets

Previous platelet studies have shown that calcium plays important roles in stimulus-secretion coupling, aggregation, and other membrane-associated functions. In addition, lanthanum induces platelet aggregation and the platelet release reaction and also influences platelet responsiveness to various stimuli. The spin-label results presented here suggest that one mechanism through which calcium and lanthanum mediate their effects on platelet functions may be by decreasing the lipid fluidity of the surface membrane. The structure of platelet membrane lipids was examined with the spin-label method. Washed human platelets were labeled with the 5-, 12- and 16-nitroxide stearic acid spin probes. Order parameters which measure the fluidity of the lipid environment of the incorporated probe may be calculated from the electron spin resonance (ESR) spectra of 5-nitroxide stearate [I(12,3)]-labeled cells. Evidence is presented which indicates that these spectra principally reflect properties of the platelet surface membrane lipids. The membrane fluidity increased with temperature for the range 17 to 37 degrees C. Either calcium or lanthanum additions to intact cells increased the rigidity of the platelet membranes at 37 degrees C, although the La3+ effect was larger and occurred at lower concentrations than that of Ca2+. For example, addition of 1 mM La3+ or 4 mM Ca2+ increased the order parameter of I(12,3)-labeled platelets by 4.3 +/- 1.7% or 2.1 +/- 0.5%. Preliminary studies conducted on purified platelet plasma membranes labeled with I(12,3) indicated that 1 mM LaCl3 or 4 mM CaCl2 additions similarly decreased the lipid fluidity at 37 degrees C. The above cation-induced effects on the fluidity of whole platelets were reversed by the use of the divalent cation-chelating agent ethylene glycol-bis-(beta-aminoethyl ether)-N,N'-tetra-acetic acid (EGTA). Lastly, lanthanum (0.2-1 mM) caused rapid aggregation of platelets which were suspended in a 50-mM Tris buffer pH 7.4 that did not contain adenosine.

Effect of calcium, insulin and growth hormone on membrane fluidity. A spin label study of rat adipocyte and human erythrocyte ghosts

ESR spectra were recorded from rat epididymal adipocyte ghosts labeled with the 5-nitroxide stearic acid spin probe, I(12,3). Polarity-corrected and approximate order parameters, that are sensitive to the flexibility of the incorporated label, were used to evaluate the membrane lipid fluidity. Addition of CaCl2 a 37 degrees C decreased the fluidity, as indicated by positive increases in the order parameters. The ordering effect of Ca2+ was concentration-dependent, reached saturation at approx. 3--4 mM, and was completely reversed by excess EGTA. Previous studies indicated that low- and high-affinity sites on adipocyte plasma membranes are able to bind 45Ca2+, and our results suggest that Ca2+-induced alterations in the lipid fluidity involve cation binding to low-affinity sites. The cellular movements of Ca2+ and, in particular, the binding of Ca2+ to the plasma membrane may play important roles in insulin's action on fat cell function. The possibility that insulin directly alters the membrane fluidity was tested by adding hormone to freshly-prepared I(12,3)-labeled adipocyte ghosts. Insulin, at concentrations (10(-6) M) that enhance glucose uptake into intact adipocytes, did not affect the fluidity of ghosts suspended in buffers with or without Ca2+. The fluidities of I(12,3)-labeled rat adipocyte ghosts or human erythrocyte ghosts were also unaffected by various forms of human growth hormone.

A comparison of composition and fluidity of multiple sclerosis and normal myelin

Myelin was isolated from normal-appearing white matter from the brains of 11 multiple sclerosis (MS) patients, 11 normal individuals, and 1 patient with subacute sclerosing panencephalitis (SSPE). Ratios of protein, cholesterol, and phospholipid content, total fatty acid content, and total amino acid content were determined. The lipid bilayer fluidity of the myelin was measured using electron spin resonance and fluorescence polarization spectroscopy. The protein-to-phospholipid ratio was higher than normal, the cholesterol-to-protein ratio was lower than normal while the cholesterol-to-phospholipid ratio was normal in MS myelin. This suggested a relative increase of protein to lipid content in MS myelin. Of the fatty acid content of a total lipid extract, MS myelin had relatively more 16:0, less 18:3, and less 22:3, 24:1 than normal. The total amino acid content of MS myelin was altered in a way which suggested a decreased percentage of basic protein and an increased percentage of proteolipids. SSPE myelin had similar changes in amino acid content but not in protein-to-cholesterol or -phospholipid ratios or fatty acid content as MS myelin. There was no significant difference in myelin fluidity, however, between MS and normal myelin using fatty acid spin labels or fluorescent probes. A correlation was found between the fluidity and the cholesterol-to-phospholipid ratio but the MS and normal samples varied over a similar range. Although these alterations in lipid and protein composition had no effect on fluidity, they may nevertheless have serious consequences for myelin structure.

A spin-label study of sciatic nerves from quaking, jimpy and trembler mice

The spin labels, 5-nitroxide stearic acid and 16-nitroxide stearic acid were incorporated into whole sciatic nerves dissected from normal, quaking, jimpy and trembler mice. With 5-nitroxide stearic acid, we have studied the thermal variation of the maximal apparent coupling constant (T) between 0 degrees C and 50 degrees C. Within this range of temperatures, we obtained identical values of 2 T for nerves from normal and jimpy mice, whereas 2 T was smaller for nerves from quaking and trembler mice. With 16-nitroxide stearic acid, composite spectra were recorded, particularly in the high-field range. A line characteristic of myelin was clearly observed in the spectra of nerves from normal and jimpy mice; its intensity was somewhat less in nerves from quaking mice and much less in spectra from trembler mice. A shoulder in the principal highfield line of the spectrum is modified only with nerves from jimpy mice. The results agree well with those obtained by electron microscopy, which reveal normal myelination in nerves from jimpy mice, a slight modification of the myelin from those of quaking mice and a practically complete demyelination in peripheral nerves from trembler mice. However, the structure of the nerves of jimpy mice also seems to be modified at an, as yet, undetermined level.

Analysis of Dictyostelium discoideum plasma membrane fluidity by electron spin resonance

Dictyostelium discoideum grown axenically in media containing polyunsaturated fatty acids exhibited normal growth rates but impaired differentiation (Weeks, G. (1976) Biochim. Biophys. Acta 450, 21--32). Since cell-cell contact is vital for differentiation but unnecessary for growth we have examined the isolated plasma membranes of these cells. The lipids of the plasma membranes of cells grown in the presence of polyunsaturated fatty acids contain considerable quantities of these acids, but the total phospholipid and sterol contents of the plasma membrane are close to normal. Electron spin resonance studies using 5-doxyl-stearic acid as the spin probe reveal two things. Firstly, there are no detectable characteristic transition temperatures in the plasma membranes of D. discoideum. Secondly, the plasma membranes of cell grown in the presence of polyunsaturated fatty acids have essentially the same fluidity as that of the control cells. The possible significance of this result to impaired cell-cell interaction is discussed.

Calcium and glycoprotein metabolism as correlates for ethanol preference and sensitivity

Enzyme markers associated with calcium and glycoprotein metabolism may be correlated with the sensitivity and preference to alcohol in rodent strains.

Role of calcium in ethanol-membrane interactions: a model for tolerance and dependence

The calcium content of membranes may regulate a number of key neuronal processes. Studies are described in which acute and chronic administration of ethanol was shown to alter calcium binding to synaptosomal plasma membranes.

Crystalline patterns of myelin lipids visualized by freeze fracture

Freeze fracture of rat optic nerve reveals smooth, particle-free regions on the lammellar fracture faces of myelin when prepared by standard procedures. When the fixed, glycerin-impregnated tissue is incubated at 6 degrees C for two or more days, crystalline patterns indicative of a phase transition can be seen in the particle-free regions. The crystalline patterns can be destroyed by subsequent incubation at 37 degrees C and are not seen when the initial incubation is at room temperature or 37 degrees C. Butylated hydroxytoluene has no effect on the formation of the crystalline patterns. The time course of the formation of the crystalline patterns suggest that the rate-limiting step in the process is not the phase transition itself. We propose that the lipids associated with the particles in vivo are involved in the formation of the crystalline patterns.