Order measurements in plasma membranes from Duchenne dystrophy fibroblasts

Plasma membranes have been isolated using different methods from Duchenne dystrophy and control human skin fibroblasts. Fluorescence techniques were utilized to resolve the rotational properties and the degree of hindered rotation of the fluorescent probe, 1,6-diphenyl-1,3,5-hexatriene in the membranes. Under specific conditions of fibroblast processing and membrane fractionation, plasma membranes from Duchenne fibroblasts showed significantly less order (0.0125 greater than P less than 0.0025) and less hindrance to probe rotation than membranes from control fibroblasts. The order differences did not seem to be the result of heterogeneity in the membrane environment sampled by the probe. The frequency dependence of the fluorescence lifetime for diphenylhexatriene indicated no measurable contribution by a short lifetime component. Analysis of diphenylhexatriene rotation in the plasma membranes using the 'wobbling-in-cone' theory suggested that both the angle of probe rotation (theta c) and the rotational rate (Dw) were important parameters in understanding the variations between Duchenne and control membranes at 16, 22 and 30 degrees C. Electron spin resonance studies with 5'-doxylstearic acid at 25 degrees C confirmed our fluorescence results. The segmental motion exhibited by the spin label revealed less order in the Duchenne membranes.     

Properties of spin labelled membranes of Fusarium oxysporum f. sp. lycopersici.

Growth temperature-induced compositional changes in membranes of Fusarium oxysporum provided a test system for study of the relationship between physical properties and composition. Growth at 15 degrees C was characterized by a decrease in phospholipid content relative to sterol content, a shift in phospholipid composition from phosphatidylcholine to phosphatidylethanolamine and a marked enhancement in the amount of polyunsaturated fatty acids in the phospholipid and triglyceride classes. Uptake of a spin labelled analog of stearic acid during growth and subsequent solution of the probe in the membranes allowed estimation of viscosity and molecular order of the membranes of live cells and of isolated membrane preparations. Less than 1/20 of the intracellular label was accessible to sodium ascorbate while none was released by sodium dodecyl sulfate. All of the label in live cells was reduced by in vivo respiratory activity above 20 degrees C but this process could be reversed or avoided by added ferricyanide. A cholestane spin probe was also incorporated into the membranes. The probes were not reduced as readily in isolated membranes and hence fluidity of the membranes could be assessed over a wide temperature range. At low temperatures (-10 degrees C) a nonlethal, liquid-solid phase transition was indicated in isolated membrane lipids while at higher (lethal) temperatures (40-45 degrees C), discontinuities appeared in Arrhenius plots of rotational correlation time. Activation energies for isotropic rotation of the stearate probes in the membranes changed markedly in this temperature range and this effect correlated closely with loss of viability of conidial cells. Correlation times for stearate probes showed little variation with growth temperature nor were any breaks in Arrhenius plots of this parameter detected in the range 0-35 degrees C in whole cells or isolated membranes. The data indicated control of membrane physical properties within close tolerances throughout the physiological temperature range regardless of growth temperature. It was concluded that this homeostatic phenomenon was due to the counteractive effects of sterol/phospholipid ratio, phospholipid composition and fatty acid polyunsaturation since the condensing and fluidizing components of the isolated total membranes vary in a reciprocal manner.     

Lipid-protein interactions in model membranes from bovine brain white matter. An ESR spin label and electron microscopy study.

Lipid-protein model membranes, prepared from bovine brain white matter and containing all the lipids and Folch-Lees proteolipids, have been studied in macroscopically oriented multibilayers. To examine the lipid environment the membranes were spin labeled with the cholestane spin label (3'-spiro(2'=(N-oxyl-4',4'-dimethyl-oxazolidine))5alpha-cholestane) and a fatty acid spin label (4',4'-dimethyloxazolidine-N-oxyl derivative of 5-ketostearic acid). The ESR spectra exhibit two components arising from fairly well oriented and completely unoriented lipids. Up to a temperature of 55 degrees C the amount of oriented lipids is almost constant, being about 35%. At higher temperatures this percentage drops rapidly to zero. It is shown that the presence of unoriented lipids arises mainly from disrupted areas in the lipid bilayer structure. This is confirmed by electron miccroscopy and from an analysis of the temperature dependence of the order parameters of the spin labels. The presence of locally disrupted lipid parts in the bilayer is discussed in relation to the interaction of the brain white matter lipids with Folch-Lees protein.     

Effects of polar carotenoids on dimyristoylphosphatidylcholine membranes: a spin-label study.

Spin labeling methods were used to study the structure and dynamic properties of dimyristoylphosphatidylcholine (DMPC) membranes as a function of temperature and the mole fraction of polar carotenoids. The results in fluid phase membranes are as follows: (1) Dihydroxycarotenoids, zeaxanthin and violaxanthin, increase order, decrease motional freedom and decrease the flexibility gradient of alkyl chains of lipids, as was shown with stearic acid spin labels. The activation energy of rotational diffusion of the 16-doxylstearic acid spin label is about 35% less in the presence of 10 mol% of zeaxanthin. (2) Carotenoids increase the mobility of the polar headgroups of DMPC and increase water accessibility in that region of membrane, as was shown with tempocholine phosphatidic acid ester. (3) Rigid and highly anisotropic molecules dissolved in the DMPC membrane exhibit a bigger order of motion in the presence of polar carotenoids as was shown with cholestane spin label (CSL) and androstane spin label (ASL). Carotenoids decrease the rate of reorientational motion of CSL and do not influence the rate of ASL, probably due to the lack of the isooctyl side chain. The abrupt changes of spin label motion observed at the main phase transition of the DMPC bilayer are broadened and disappear at the presence of 10 mol% of carotenoids. In gel phase membranes, polar carotenoids increase motional freedom of most of the spin labels employed showing a regulatory effect of carotenoids on membrane fluidity. Our results support the hypothesis of Rohmer, M., Bouvier, P. and Ourisson, G. (1979) Proc. Natl. Acad. Sci. USA 76, 847-851, that carotenoids regulate the membrane fluidity in Procaryota as cholesterol does in Eucaryota. A model is proposed to explain these results in which intercalation of the rigid rod-like polar carotenoid molecules into the membrane enhances extended trans-conformation of the alkyl chains, decreases free space in the bilayer center, separate the phosphatidylcholine headgroups and decreases interaction between them.     

Slow-motion ESR of cholestane spin labels in planar multibilayers of diacyldigalactosyldiglycerides

The orientation and restricted motion of the cholestane spin label (3-spiro-doxyl-5α-cholestane) incorporated into planar multibilayers of diacyldigalactosyldiglycerides extracted from the thylakoid membranes of chloroplasts from different plant leaves has been studied. The experimental ESR spectra were simulated in terms of the slow-tumbling ESR formalism of Freed and co-workers (Polnaszek, C.F., Bruno, G.V. and Freed, J.H. (1973) J. Chem. Phys. 58, 3185–3199). The analysis shows that the degree of orientational order is low. The spin label molecules undergo a faster reorientational motion about their long molecular axes than perpendicular to them. At room temperature the reorientational rate around the long molecular axis falls within the fast-motional limit, while the reorientation rate of the long axis itself corresponds to the slow-tumbling regime. The results indicate that the motion of the labels in bilayers of diacyldigalactosyldiglycerides is considerably slower than that of the same label incorporated into bilayers of saturated phosphatidylcholines above the main phase transition. Differences between bilayers of diacyldigalactosyldiglycerides extracted from different plant membranes have been observed.     

Lipid-protein interactions in model membranes from bovine brain white matter. An ESR spin label and electron microscopy study

Lipid-protein model membranes, prepared from bovine brain white matter and containing all the lipids and Folch-Lees proteolipids, have been studied in macroscopically oriented multibilayers. To examine the lipid environment the membranes were spin labeled with the cholestane spin label ($\text{3-spiro(2′-(N-}\text{oxyl-4′,4′-dimethyl-oxazolidine))5α-cholestane}$) and a fatty acid spin label ($\text{4′-,4′-dimethyloxazolidine-N-}\text{oxyl}$ derivative of 5-ketostearic acid). The ESR spectra exhibit two components arising from fairly well oriented and completely unoriented lipids. Up to a temperature of 55°C the amount of oriented lipids is almost constant, being about 35%. At higher temperatures this percentage drops rapidly to zero. It is shown that the presence of unoriented lipids arises mainly from disrupted areas in the lipid bilayer structure. This is confirmed by electron microscopy and from an analysis of the temperature dependence of the order parameters of the spin labels. The presence of locally disrupted lipid parts in the bilayer is discussed in relation to the interaction of the brain white matter lipids with Folch-Lees protein.     

Properties of spin labelled membranes of Fusarium Oxysporum f. sp. Lycopersici

Growth temperature-induced compositional changes in membranes of Fusarium oxysporum provided a test system for study of the relationship between physical properties and composition. Growth at 15 °C was characterized by a decrease in phospholipid content relative to sterol content, a shift on phospholipid composition from phosphatidylcholine to phosphatidylethanolamine and a marked enhancement in the amount of polyunsaturated fatty acids in the phospholipid and triglyceride classes.Uptake of a spin labelled analog of stearic acid during growth and subsequent solution of the probe in the membranes allowed estimation of viscosity and molecular order of the membranes of live cells and of isolated membrane preparations. Less than $\text{1}\text{20}$ of the intracellular label was accessible to sodium ascorbate while none was released by sodium dodecyl sulfate. All of the label in live cells was reduced by in vivo respiratory activity above 20 °C but this process could be reversed or avoided by added ferricyanide. A cholestane spin probe was also incorporated into the membranes. The probes were not reduced as readily in isolated membranes and hence fluidity of the membranes could be assessed over a wide temperature range. At low temperatures (?10 °C) a nonlethal, liquid-solid phase transition was indicated in isolated membrane lipids while at higher (lethal) temperatures (40–45 °C), discontinuities appeared in Arrhenius plots of rotational correlation time. Activation energies for isotropic rotation of the stearate probes in the membranes changed markedly in this temperature range and this effect correlated closely with loss of viability of conidial cells. Correlation times for stearate probes showed little variation with growth temperature nor were any breaks in Arrhenius plots of this parameter detected in the range 0–35 °C in whole cells or isolated membranes. The data indicated control of membrane physical properties within close tolerances throughout the physiological temperature range regardless of growth temperature. It was concluded that this homeostatic phenomenon was due to the counteractive effects of sterol/phospholipid ratio, phospholipid composition and fatty acid polyunsaturation since the condensing and fluidizing components of the isolated total membranes vary in a reciprocal manner.     

Cholesterol attenuates and prevents bilayer damage and breakdown in lipoperoxidized model membranes. A spin labeling EPR study

The stabilizing effect of cholesterol on oxidized membranes has been studied in planar phospholipid bilayers and multilamellar 1-palmitoyl-2-linoleoyl-phosphatidylcholine vesicles also containing either 1-palmitoyl-2-glutaroyl-phosphatidylcholine or 1-palmitoyl-2-(13-hydroxy-9,11-octadecanedienoyl)-phosphatidylcholine oxidized phosphatidylcholine in variable ratio. Lipid peroxidation-dependent membrane alterations in the absence and in the presence of cholesterol were analyzed using Electron Paramagnetic Resonance spectroscopy of the model membranes spin labelled with either cholestane spin label (3-DC) or phosphatidylcholine spin label (5-DSPC). Cholesterol, added to lipid mixtures up to 40% final molar ratio, decreased the inner bilayer disorder as compared to cholesterol-free membranes and strongly reduced bilayer alterations brought about by the two oxidized phosphatidylcholine species. Furthermore, Sepharose 4B gel-chromatography and cryo electron microscopy of aqueous suspensions of the lipid mixtures clearly showed that cholesterol is able to counteract the micelle forming tendency of pure 1-palmitoyl-2-glutaroyl-phosphatidylcholine and to sustain multilamellar vesicles formation. It is concluded that membrane cholesterol may exert a beneficial and protective role against bilayer damage caused by oxidized phospholipids formation following reactive oxygen species attack to biomembranes.     

Molecular motion and order in oriented lipid multibilayer membranes evaluated by simulations of spin label ESR spectra. Effects of temperature, cholesterol and magnetic field.

A simulation method to interpret electron spin resonance (ESR) of spin labelled amphiphilic molecules in oriented phosphatidylcholine multibilayers in terms of a restricted motional model is presented. Order and motion of the cholestane spin label (3-spiro-doxyl-5alpha-cholestane) incorporated into egg yolk phosphatidylcholine, dipalmitoylphosphatidylcholine and dimyristoylphosphatidylcholine, pure and in mixture with cholesterol, were studied at various temperatures. With egg yolk phosphatidylcholine identical sets of motional parameters were obtained from simulations of ESR spectra obtained at three microwave frequencies (X-, K- and Q-band). With dipalmitoylphosphatidylcholine and dimyristoylphosphatidylcholine analyses of the spectra show that phase transitions occur in samples containing up to 30 mol % cholesterol. The activation energy for the motion of the spin label is about three times larger above than below the phase transition, indicating a more collective motion in the lipid crystalline state than in the gel state. In the liquid crystalline state the activation energy is larger in the pure phosphatidylcholines than with cholesterol added. Additions of cholesterol to egg phosphatidylcholine induces a higher molecular order but does not appreciably affect correlation times. This is in contrast to dipalmitoylphosphatidylcholine where both order and correlation times are affected by the presence of cholesterol. The activation energies follow the same order as the transition temperatures: dipalmitoylphosphatidylcholine greater than dimyristoylphosphatidylcholine greater than egg yokd phosphatidylcholine, suggesting a similar order of the cooperativity of the motion of the lipid molecules. Magnetic field-induced effects on egg phosphatidylcholine multibilayers were found at Q-band measurements above 40 degrees C. The cholestane spin label mimics order and motion of cholesterol molecule incorporated into the lipid bilayers. This reflects order and motion of the portions of the lipid molecules on the same depth of the bilayer as the rigid steroid portions of the intercalated molecules.     

Transfer of phosphatidylcholine between different membranes in Tetrahymena as studied by spin labeling

Transfer of phosphatidylcholine molecules between different membrane fractions of Tetrahymena pyriformis cells grown at 15, 27 and 39.5°C was studied by electron spin resonance (ESR). Microsomes were labeled densely with a phosphatidylcholine spin label and the spin-labeled microsomes were incubated with non-labeled cilia, pellicles or microsomes. The transfer of the phosphatidylcholine spin labels was measured by decrease in the exchange broadening of the electron spin resonance spectrum. In one experiment, the lipid transfer was measured between ³²P-labeled microsomes and non-labeled pellicles by use of their radioactivity. The result was in good agreement with that by ESR. The fluidity of the membrane was estimated using a fatty-acid spin label incorporated into the membranes. Transfer between lipid vesicles was also studied. The results obtained were as follows: (1) The transfer between sonicated vesicles of egg- or dipalmitoyl phosphatidylcholine occurred rapidly in the liquid crystalline phase, with an activation energy of 20 kcal/mol, whereas it hardly occurred in the solid crystalline phase. (2) The transfer rate between microsomal membranes increased with temperature, and an activation energy of the reaction was 17.8 kcal/mol. (3) The transfer from the spin-labeled microsomes to subcellular membranes of the cells grown at 15°C was larger than that to the membranes of the cells grown at 39.5°C. The membrane fluidity was larger for the cells grown at lower temperature. (4) Similar tendency was observed for the transfer between microsomal lipid vesicles prepared from the cells grown at 15°C and at 39.5°C. (5) The transfer from microsomes to various membrane fractions increased in the order, cilia < pellicles < microsomes. The order of increase in the membrane fluidity was cilia < microsomes < pellicles, although the difference between microsomes and pellicles was slight. These results indicate a crucial role of the membrane fluidity in the transfer reaction. (6) Some evidence supported the idea that the lipid transfer between these organelles occurred through the lipid exchange rather than through the fusion.     

Lipid phase of transverse tubule membranes from skeletal muscle. An electron paramagnetic resonance study.

The lipid phase of transverse tubule membrane was probed with a variety of fatty acid spin labels. The motion of the probe increased as the distance between the spin label and polar head group increased, in agreement with results reported in other membranes. The value of the order parameter at 37 degrees C for a fatty acid spin label containing the label attached to its fifth carbon atom was closer to values reported for bacterial membranes than to the lower values reported for other mammalian membranes. Order parameters for spin labels containing the label nearer to the center of the bilayer were closer to the values reported in other mammalian membranes than to values reported for bacterial membranes. These results indicate that the lipid segments in the vicinity of the polar head group, and less so those near the center of the bilayer, are motionally more restricted in transverse tubules than in other mammalian membranes. In particular, the lipid phase of the transverse tubule membrane is less fluid than that of the sarcoplasmic reticulum membrane. A possible role of the high cholesterol content of transverse tubules in generating the lower fluidity of its lipid phase is discussed.     

Phase transitions in lipid membranes induced by carcinogenic aromatic hydrocarbons. A spin label study.

The interaction between a series of condensed aromatic hydrocarbons of different size and shape (with and without carcinogenic activity) with dipalmitoyl lecithin bilayers was investigated by the spin label method. The spectra of a cholestane spin probe in the bilayers were examined. The smaller non-carcinogenic hydrocarbons did not alter the degree of organization of the phospholipid molecules to a large extent. On the other hand, large, carcinogenic aromatic hydrocarbons interacted with the bilayers, promoting a gel to liquid crystal phase transition. These data indicate that the two types of molecules interact with the membrane in different ways.     

Specific spin labelling of the sugar-H(+) symporter, GalP, in cell membranes of Escherichia coli: site mobility and overall rotational diffusion of the protein

The D-galactose-H(+) symport protein (GalP) of Escherichia coli is a homologue of the human glucose transport protein, GLUT1. After amplified expression of the GalP transporter in E. coli, other membrane proteins were prereacted with N-ethylmaleimide in the presence of excess D-galactose to protect GalP. Inner membranes were then specifically spin labelled on Cys(374) of GalP with 4-maleimide-2,2,6,6-tetramethylpiperidine-1-oxyl. The electron paramagnetic resonance (EPR) spectra are characteristic of a single labelling site in which the mobility of the spin label is very highly constrained. This is confirmed with other nitroxyl spin labels, which are derivatives of iodoacetamide and indanedione. Saturation transfer EPR spectra indicate that the overall rotation of the GalP protein in the membrane is slow at low temperatures (approx. 2 degrees C), but considerably more rapid and highly anisotropic at physiological temperatures. The rate of rotation about the membrane normal at 37 degrees C is consistent with predictions for a 12-transmembrane helix assembly that is less than closely packed.     

An electron spin resonance spin-label study of lipophilin in oriented phospholipid bilayers

Model membranes consisting of dimyristoyl phosphatidylcholine and a hydrophobic protein from bovine myelin, lipophilin, were studied using the cholesterol-resembling cholestane ESR spin label. Orientation of the membranes made it possible to deconvolute the spectra into two fractions, one of oriented spin labels reflecting phospholipid bilayer of high order, and one of isotropically tumbling spin labels ascribed to the lipid fraction surrounding the protein molecule (boundary lipid). This isotropic tumbling is different from the behavior of phospholipid molecules near the protein, which retain some degree of order, and indicates that the boundary lipid fraction in our model system forms a rather fluid environment for the protein. A nonlinear relation was found between protein concentration and amount of boundary spin labels. Addition of cholesterol decreases the amount of boundary spin labels. Both findings form evidence for a preferential binding of cholesterol by the membrane protein.     

Spin-label studies on phosphatidylcholine-cholesterol membranes: effects of alkyl chain length and unsaturation in the fluid phase

Dynamic properties of phosphatidylcholine-cholesterol membranes in the fluid phase and water accessibility to the membranes have been studied as a function of phospholipid alkyl chain length, saturation, mole fraction of cholesterol, and temperature by using spin and fluorescence labelling methods. The results are the following: (1) The effect of cholesterol on motional freedom of 5-doxyl stearic acid spin label (5-SASL) and 16-doxyl stearic acid spin label (16-SASL) in saturated phosphatidylcholine membrane is significantly larger than the effects of alkyl chain length and introduction of unsaturation in the alkyl chain. (2) Variation of alkyl chain length of saturated phospholipids does not alter the effects of cholesterol except in the case of dilauroylphosphatidylcholine, which possesses the shortest alkyl chains (12 carbons) used in this work. (3) Unsaturation of the alkyl chains greatly reduces the ordering effect of cholesterol at C-5 and C-16 positions although unsaturation alone gives only minor fluidizing effects. (4) Introduction of 30 mol% cholesterol to dimyristoylphosphatidylcholine membranes decreases the lateral diffusion constants of lipids by a factor of four, while it causes only a slight decrease of lateral diffusion in dioleoylphosphatidylcholine membranes. (5) If compared at the same temperature, 5-SASL mobilities plotted as a function of mole fraction of cholesterol in the fluid phases of dimyristoylphosphatidylcholine-, dipalmitoylphosphatidylcholine- and distearoylphosphatidylcholine-cholesterol membranes are similar in wide ranges of temperature (45-82 degrees C) and cholesterol mole fraction (0-50%). (6) In isothermal experiments with saturated phosphatidylcholine membranes, 5-SASL is maximally immobilized at the phase boundary between Regions I and III reported by other workers (Recktenwald, D.J. and McConnell, H.M. (1981) Biochemistry 20, 4505-4510) and becomes more mobile away from the boundary in Regions I and III. (7) 5-SASL in unsaturated phosphatidylcholine membranes showed a gradual monotonic immobilization with increase of cholesterol mole fraction without showing any maximum in the range of cholesterol fractions studied. (8) By rigorously determining rigid-limit magnetic parameters of cholestane spin labels in membranes from Q-band second-derivative ESR spectra to monitor the dielectric environment around the nitroxide radical, it is concluded that cholesterol incorporation increases water accessibility in the hydrophilic loci of the membrane. In contrast, 12-(9-anthroyloxy)stearic acid fluorescence showed that water accessibility is decreased in the hydrophobic loci of the membrane.     

ESR spectral analysis of the molecular motion of spin labels in lipid bilayers and membranes based on a model in terms of two angular motional parameters and rotational correlation times.

Electron spin resonance (ESR) spectral line shapes are calculated for a nitroxide spin-labeled molecule undergoing rapid restricted rotations (twisting) about its long molecular axis while simultaneously tumbling within a cone. Explicit expressions are derived for the hyperfine splittings and g-values, as well as for the secular contributions to the motionally modulated linewidths. The present model is useful for analyzing the restricted twisting and tumbling motions, and rotational correlation times, of spin-labeled molecules in bilayers. Simulated spectra compare well with experimental spectra of lecithin bilayers marked with cholestane spin label, over a wide temperature range.     

Lipid-lipid and lipid-protein interactions in chromaffin granule membranes. A spin label ESR study

The ESR spectra of six different positional isomers of a stearic acid and three of a phosphatidylcholine spin label have been studied as a function of temperature in chromaffin granule membranes from the bovine adrenal medulla, and in bilayers formed by aqueous dispersion of the extracted membrane lipids. Only minor differences were found between the spectra of the membranes and the extracted lipid, indicating that the major portion of the membrane lipid is organized in a bilayer arrangement which is relatively unperturbed by the presence of the membrane protein. The order parameter profile of the spin label lipid chain motion is less steep over the first half of the chain than over the section toward the terminal methyl end of the chain. This 'stiffening' effect is attributed to the high proportion of cholesterol in the membrane and becomes less marked as the temperature is raised. The isotropic hyperfine splitting factors of the various positional isomers display a profile of decreasing polarity as one penetrates further into the interior of the membrane. No marked differences are observed between the effective polarities in the intact membranes and in bilayers of the extracted membrane lipids. The previously observed temperature-induced structural change occurring in the membranes at approx. 35 degrees C was found also in the extracted lipid bilayers, showing this to be a result of lipid-lipid interactions and not lipid-protein interactions in the membrane. A steroid spin label indicated a second temperature-dependent structural change occurring in the lipid bilayers at lower temperatures. This correspond to the onset of a more rapid rotation about the long axis of the lipid molecules at a temperature of approx. 10 degrees C. The lipid bilayer regions probed by the spin labels used in this study may be involved in the fusion of the chromaffin granule membrane leading to hormone release by exocytosis.     

Lipid-lipid and lipid-protein interactions in chromaffin granule membranes: A spin label ESR study

The ESR spectra of six different positional isomers of a stearic acid and three of a phosphatidylcholine spin label have been studied as a function of temperature in chromaffin granule membranes from the bovine adrenal medulla, and in bilayers formed by aqueous dispersion of the extracted membrane lipids. Only minor differences were found between the spectra of the membranes and the extracted lipid, indicating that the major portion of the membrane lipid is organized in a bilayer arrangement which is relatively unperturbed by the presence of the membrane protein. The order parameter profile of the spin label lipid chain motion is less steep over the first half of the chain than over the section toward the terminal methyl end of the chain. This ‘stiffening’ effect is attributed to the high proportion of cholesterol in the membrane and becomes less marked as the temperature is raised. The isotropic hyperfine splitting factors of the various positional isomers display a profile of decreasing polarity as one penetrates further into the interior of the membrane. No marked differences are observed between the effective polarities in the intact membranes and in bilayers of the extracted membrane lipids. The previously observed temperature-induced structural change occurring in the membranes at approx. 35°C was found also in the extracted lipid bilayers, showing this to be a result of lipid-lipid interactions and not lipid-protein interactions in the membrane. A steroid spin label indicated a second temperature-dependent structural change occurring in the lipid bilayers at lower temperatures. This corresponds to the onset of a more rapid rotation about the long axis of the lipid molecules at a temperature of approx. 10°C. The lipid bilayer regions probed by the spin labels used in this study may be involved in the fusion of the chromaffin granule membrane leading to hormone release by exocytosis.     

Preparation and properties of spin-labeled lecithin-cholesterol liposomes

Summary Lecithin-cholesterol vesicles of various compositions containing membrane-bound spin-labeled cholestane can be prepared by appropriate choice of initial concentrations of components during sonication. Increasing incorporation of spin label increases incorporation of cholesterol and decreases incorporation of lecithin, with the result that liposomes with cholesterol-lecithin molar ratios larger than 2 can be obtained. Besides associating with cholesterol-lecithin complexes in the liposome, the spin label seems to associate with cholesterol. Changes of the paramagnetic resonance spectrum of the liposome-bound spin label due to changes in liposomal cholesterol and spin label mole fractions — assessed by three parameters — can be used in cell-liposome interaction studies.     

Specific spin labelling of the sugar-H+ symporter,GalP, in cell membranes of Escherichia coli: site mobility and overall rotational diffusion of the protein

The d-galactose-H⁺ symport protein (GalP) of Escherichia coli is a homologue of the human glucose transport protein, GLUT1. After amplified expression of the GalP transporter in E. coli, other membrane proteins were prereacted with N-ethylmaleimide in the presence of excess d-galactose to protect GalP. Inner membranes were then specifically spin labelled on Cys³⁷⁴ of GalP with 4-maleimide-2,2,6,6-tetramethylpiperidine-1-oxyl. The electron paramagnetic resonance (EPR) spectra are characteristic of a single labelling site in which the mobility of the spin label is very highly constrained. This is confirmed with other nitroxyl spin labels, which are derivatives of iodoacetamide and indanedione. Saturation transfer EPR spectra indicate that the overall rotation of the GalP protein in the membrane is slow at low temperatures (approx. 2°C), but considerably more rapid and highly anisotropic at physiological temperatures. The rate of rotation about the membrane normal at 37°C is consistent with predictions for a 12-transmembrane helix assembly that is less than closely packed.