Lipid-protein interactions in frog rod outer segment disc membranes. Characterization by spin labels

Freely-diffusing phospholipid spin labels have been employed to study rhodopsin-lipid interactions in frog rod outer segment disc membranes. Examination of the ESR spectra leads us to the conclusion that there are two motionally distinguishable populations of lipid existing in frog rod outer segment membranes over a wide physiological temperature range. Each of the spin probes used shows a two-component electron spin resonance (ESR) spectrum, one component of which is motionally restricted on the ESR timescale, and represents between 33 and 40% of the total integrated spectral intensity. The second spectral component which accounts for the remainder of the spectral intensity possesses a lineshape characteristic of anisotropic motion in a lipid bilayer, very similar in shape to that observed from the same spin labels in dispersions of whole extracted frog rod outer segment lipid. The motionally restricted spectral component is attributed to those spin labels in contact with the surface of rhodospin, while the major component is believed to originate from spin labels in the fluid lipid bilayer region of the membranes. Calculations indicate that the motionally restricted lipid is sufficient to cover the protein surface. This population of lipids is shown here and elsewhere (Watts, A., Volotovski, I.D. and Marsh, D. (1979) Biochemistry 18, 5006-5013) to be by no means rigidly immobilized, having motion in the 20 ns time regime as opposed to motions in the one nanosecond time regime found in the fluid bilayer. Little selectivity for the motionally restricted population is observed between the different spin-labelled phospholipid classes nor with a spin-labelled fatty acid or sterol.     

Selective detection of the rotational dynamics of the protein-associated lipid hydrocarbon chains in sarcoplasmic reticulum membranes.

We have developed a saturation transfer EPR (ST-EPR) method to measure selectively the rotational dynamics of those lipids that are motionally restricted by integral membrane proteins and have applied this methodology to measure lipid-protein interactions in native sarcoplasmic reticulum (SR) membranes. This analysis involves the measurement of spectral saturation using a series of six stearic acid spin labels that are labeled with a nitroxide at different carbon atom positions. A large amount of spectral saturation is observed for spin labels in native SR membranes, but not for spin labels in dispersions of extracted SR lipids, implying that the motional properties of those lipids interacting with the Ca-ATPase, i.e., the boundary or annular lipid, can be directly measured without the need for spectral subtraction procedures. A comparison of the motional properties of the restricted lipid, measured by ST-EPR, with those measured by digital subtraction of conventional EPR spectra qualitatively agree, for in both cases the Ca-ATPase restricts the rotational mobility of a population of lipids, whose rotational mobility increases as the nitroxide is positioned toward the center of the bilayer. However, the ability of ST-EPR to directly measure the motionally restricted lipid in a model-independent means provides the greater precision necessary to measure small changes in the rotational dynamics of the lipid at the protein-lipid interface, providing a valuable tool in clarifying the relationship between the physical nature of the protein-lipid interface and membrane function.     

Effects of melittin on lipid-protein interactions in sarcoplasmic reticulum membranes.

To investigate the physical mechanism by which melittin inhibits Ca-adenosine triphosphatase (ATPase) activity in sarcoplasmic reticulum (SR) membranes, we have used electron paramagnetic resonance spectroscopy to probe the effect of melittin on lipid-protein interactions in SR. Previous studies have shown that melittin substantially restricts the rotational mobility of the Ca-ATPase but only slightly decreases the average lipid hydrocarbon chain fluidity in SR. Therefore, in the present study, we ask whether melittin has a preferential effect on Ca-ATPase boundary lipids, i.e., the annular shell of motionally restricted lipid that surrounds the protein. Paramagnetic derivatives of stearic acid and phosphatidylcholine, spin-labeled at C-14, were incorporated into SR membranes. The electronic paramagnetic resonance spectra of these probes contained two components, corresponding to motionally restricted and motionally fluid lipids, that were analyzed by spectral subtraction. The addition of increasing amounts of melittin, to the level of 10 mol melittin/mol Ca-ATPase, progressively increased the fraction of restricted lipids and increased the hyperfine splitting of both components in the composite spectra, indicating that melittin decreases the hydrocarbon chain rotational mobility for both the fluid and restricted populations of lipids. No further effects were observed above a level of 10 mol melittin/mol Ca-ATPase. In the spectra from control and melittin-containing samples, the fraction of restricted lipids decreased significantly with increasing temperature. The effect of melittin was similar to that of decreased temperature, i.e., each spectrum obtained in the presence of melittin (10:1) was nearly identical to the spectrum obtained without melittin at a temperature approximately 5 degrees C lower. The results suggest that the principal effect of melittin on SR membranes is to induce protein aggregation and this in turn, augmented by direct binding of melittin to the lipid, is responsible for the observed decreases in lipid mobility. Protein aggregation is concluded to be the main cause of inactivation of the Ca-ATPase by melittin, with possible modulation also by the decrease in mobility of the boundary layer lipids.     

Competition between cholesterol and phosphatidylcholine for the hydrophobic surface of sarcoplasmic reticulum Ca2+-ATPase

A multiple equilibrium binding model is used to examine phospholipid and cholesterol binding with the transmembranous protein Ca2+-ATPase (calcium pump). The protein was reconstituted in egg phosphatidylcholine bilayers by lipid substitution of rabbit muscle sarcoplasmic reticulum. Electron spin resonance spectra of a phosphatidylcholine spin-label and a recently developed cholesterol spin-label show two major spectral contributions, a motionally restricted component consistent with interactions between the label and the protein surface and another component characteristic of motion of the label in a fluid lipid bilayer. The number of lipid binding (or contact) sites at the hydrophobic surface of the protein is calculated to be N = 22 +/- 2. Experiments with intact sarcoplasmic reticulum membranes give approximately the same value for N. The relative binding constants are Kav approximately 1 for the phosphatidylcholine label and Kav approximately 0.65 for the cholesterol spin-label. Thus, cholesterol does contact the surface of the protein, but with a somewhat lower probability than phosphatidylcholine. This is confirmed by competition experiments where unlabeled cholesterol and the phospholipid spin-label are both present in the bilayer. Evidently the flexible acyl chains of the phospholipid molecules accommodate more readily to the irregular surface of the protein than does the rigid steroid structure of cholesterol.     

Influence of lipid headgroup on the specificity and exchange dynamics in lipid-protein interactions. A spin-label study of myelin proteolipid apoprotein-phospholipid complexes

The pH and salt dependences of the interaction of phosphatidic acid, phosphatidylserine, and stearic acid with myelin proteolipid apoprotein (PLP) in dimyristoylphosphatidylcholine (DMPC) recombinants have been studied by electron spin resonance spectroscopy, using spin-labeled lipids. The two-component spin-label spectra have been analyzed both by spectral subtraction and by simulation using the exchange-coupled Bloch equations to give the fraction of lipids motionally restricted by the protein and the rate of lipid exchange between the fluid and motionally restricted lipid populations. For stearic acid, phosphatidic acid, and phosphatidylserine, the fraction of motionally restricted spin-label increases with increasing pH, with pKa's of 7.7, 7.6, and ca. 9.4, respectively. The corresponding pKa's for the bulk lipid regions of the bilayer are estimated, from changes in the ESR spectra, to be 6.7, 7.4, and 11, respectively. In the dissociated state at pH 9.0, the fraction of motionally restricted component decreases with increasing salt concentration, reaching an approximately constant value at [NaCl] = 0.5-1.0 M for all three negatively charged lipids. The net decreases for stearic acid and phosphatidic acid are considerably smaller (by ca. 30%) than those obtained on protonating the two lipids, whereas for phosphatidylserine the fraction of motionally restricted lipid in high salt is reduced to that corresponding to phosphatidylcholine. For a fixed lipid/protein ratio, the on-rate for exchange at the lipid-protein interface is independent of the degree of selectivity and has a shallow temperature dependence, as expected for a diffusion-controlled process.(ABSTRACT TRUNCATED AT 250 WORDS)     

Lipid mobility and order in bovine rod outer segment disk membranes. A spin-label study of lipid-protein interactions

Lipid-protein interactions in bovine rod outer segment disk membranes have been studied by using a series of eight stearic acid spin-label probes which were labeled at different carbon atom positions in the chain. In randomly oriented membrane dispersions, the electron spin resonance (ESR) spectra of the C-8, C-9, C-10, C-11, C-12, C-13, and C-14 atom positional isomers all apparently consist of two components. One of the components corresponds closely to the spectra obtained from dispersions of the extracted membrane lipids, and the other, which is characterized by a considerably greater degree of motional restriction of the lipid chains, is induced by the presence of the protein. Digital subtraction has been used to separate the two components. The proportion of the motionally restricted lipid component is approximately constant, independent of the position of the spin-label group, and corresponds to 30-40% of the total spin-label spectral intensity. The hyperfine splitting of the outer maxima in the difference spectra of the motionally restricted component decreases, and concomitantly, the line widths increase with increasing temperature but change relatively little with increasing distance of the spin-label group from the polar head-group region. This indicates that the corresponding chain motions of the protein-interacting lipids lie in the slow-motion regime of spin-label ESR spectroscopy (tau R approximately 10(-8) S) and that the mobility of these lipids increases with increasing temperature but does not vary greatly along the length of the chain. The data from the hyperfine splittings also suggest the existence of a polarity gradient immediately adjacent to the protein surface, as observed in the fluid lipid regions of the membrane. The more fluid lipid component is only slightly perturbed relative to the lipids alone (for label positions 5-14, inclusive), indicating the presence of chain motions on the nanosecond time scale, and the spectra also reveal a similar polarity profile in both lipid and membrane environments. ESR spectra have also been obtained as a function of magnetic field orientation with oriented membrane samples. For the C-14 atom positional isomer, the motionally restricted component is observed to have a large hyperfine splitting, with the magnetic field oriented both parallel and perpendicular to the membrane normal. This indicates that the motionally restricted lipid chains have a broad distribution of orientations at this label position.(ABSTRACT TRUNCATED AT 400 WORDS)     

Apocytochrome c binding to negatively charged lipid dispersions studied by spin-label electron spin resonance

The interaction of apocytochrome c with aqueous dispersions of phosphatidylserine from bovine spinal cord and with other negatively charged phospholipids has been studied as a function of pH and salt concentration by using spin-label electron spin resonance (ESR) spectroscopy and chemical binding assays. The ESR spectra of phospholipids spin-labeled at different positions on the sn-2 chain indicate a generalized decrease in mobility of the lipids, while the characteristic flexibility gradient toward the terminal methyl end of the chain is maintained, on binding of apocytochrome c to phosphatidylserine dispersions. This perturbation of the bulk lipid mobility or ordering is considerably greater than that observed on binding of cytochrome c. In addition, a second, more motionally restricted, lipid component is observed with lipids labeled close to the terminal methyl ends of the chains. This second component is not observed on binding of cytochrome c and can be taken as direct evidence for penetration of apocytochrome c into the lipid bilayer. It is less strongly motionally restricted than similar spectral components observed with integral membrane proteins and displays a steep flexibility gradient. The proportion of this second component increases with increasing protein-to-lipid ratio, but the stoichiometry per protein bound decreases from 4.5 lipids per 12 000-dalton protein at low protein contents to 2 lipids per protein at saturating amounts of protein. Apocytochrome c binding to phosphatidylserine dispersions decreases with increasing salt concentration from a saturation value corresponding to approximately 5 lipids per protein in the absence of salt to practically zero at 0.4 M NaCl.(ABSTRACT TRUNCATED AT 250 WORDS)     

Elucidation of intermediate (mobile) and slow (solidlike) protein motions in bovine lens homogenates by carbon-13 NMR spectroscopy

The motional dynamics of lens cytoplasmic proteins present in calf lens homogenates were investigated by two 13C nuclear magnetic resonance (NMR) techniques sensitive to molecular motion to further define the organizational differences between the cortex and nucleus. For the study of intermediate (mobile) protein rotational reorientation motion time scales [rotational correlation time (tau 0) range of 1-500 ns], we employed 13C off-resonance rotating frame spin-lattice relaxation, whereas for the study of slow (solidlike) motions (tau 0 greater than or equal to 10 microseconds) we used the solid-state NMR techniques of dipolar decoupling and cross-polarization. The frequency dependence of the peptide bond carbonyl off-resonance rotating frame spectral intensity ratio of the lens proteins present in native calf nuclear homogenate (42% protein) at 35 degrees C indicates the presence of a polydisperse mobile protein fraction with a tau 0,eff (mean) value of 57 ns. This mean value is consistent with the average value calculated from the known water-soluble nuclear lens protein polydispersity assuming a cytoplasmic viscosity 3 times that of pure water. Lowering the temperature to 1 degree C, a temperature which produces the cold cataract, results in an overall decrease in tau 0,eff to 43 ns, suggesting a selective removal of beta H-, LM-, and possibly gamma s-crystallins from the mobile lens protein population. The presence of solidlike or motionally restricted protein species was established by dipolar decoupling and cross-polarization. The fraction of motionally restricted protein in the nuclear region varied from 0.35 to 0.45 in the temperature range of 35-1 degree C. For native cortical homogenate (25% protein), the off-resonances rotating frame spectral intensity ratio frequency-dependent curves for the protein carbonyl resonance yielded tau 0,eff values of 34 and 80 ns at 35 and 1 degree C, respectively. Both values were reconciled with the known lens cortex soluble protein polydispersity using an assumed cytoplasmic viscosity 1.5 times that of pure water at the same temperature. Comparison of proton dipolar-decoupled and nondecoupled 13C NMR spectra of native cortical homogenate at 20 degrees C indicates the absence of significant contributions from slowly tumbling, motionally restricted species. This interpretation was confirmed by the failure to detect significant lens protein 13C-1H cross-polarization at this temperature. However, at 1 degree C, the fraction of solidlike protein was 0.15. Concentrated cortical homogenates at 20 degrees C (42% protein), by contrast, gave cross-polarization spectra with maximum absolute signal intensities 50-70% of native nuclear homogenates, but with similar magnetization parameters...     

A study of the effect of general anesthetics on lipid-protein interactions in acetylcholine receptor enriched membranes from Torpedo nobiliana using nitroxide spin-labels

Stearic acid, phosphatidylcholine, and phosphatidylglycerol nitroxide spin-labels were used to probe the effect of 1-hexanol, urethane, diethyl ether, and ethanol on lipid-protein interactions in nicotinic acetylcholine receptor (nAcChoR) rich membranes from Torpedo nobiliana. For stearic acid spin-labeled at the C-14 position of the sn-1 acyl chain, 1-hexanol induced little change (over a wide concentration range, 0-16.7 mM) in either the ESR line shape or the proportion of motionally restricted spectral component from labels probing the protein interface. The main effect of 1-hexanol was limited to an increase in the mobility of stearic acid spin-labels probing the non-protein-associated environment. In contrast, for C-14 phosphatidylcholine spin-label, 1-hexanol decreased the fraction of spin-labels motionally restricted at the protein interface from 0.33 without 1-hexanol to 0.20 with 16.7 mM 1-hexanol, with no change in the line shape of the spectral component of these labels. The ESR spectral line shape of the fluid component due to phosphatidylcholine labels in sites away from the protein interface displayed a gradual decrease in spectral anisotropy on addition of increasing amounts of 1-hexanol. At a concentration of 1-hexanol that desensitizes half the receptors, the fraction of motionally restricted phosphatidylcholine spin-label is reduced by approximately 15%. The effect of 1-hexanol on phosphatidylglycerol spin-labels was intermediate between these two cases. Similar effects were measured with other general anesthetics, including urethane, diethyl ether, and ethanol.(ABSTRACT TRUNCATED AT 250 WORDS)     

5'-Nucleotidase is activated upon cholesterol-depletion of liver plasma membranes

The cholesterol content of rat liver plasma membranes was manipulated using either cholesterol-free or cholesterol-enriched liposomes. Removal of cholesterol from the membranes led to a marked increase in 5'-nucleotidase activity. However, increase in cholesterol content failed to exert any significant effect on 5'-nucleotidase activity. Arrhenius plots of the activity of the native enzyme exhibited a break at around 28 degrees C with the activation energy of the reaction less above this temperature than below. In cholesterol-depleted membranes a single break at around 26 degrees C was observed with activation energies greater above this temperature than below it. In cholesterol-enriched membranes Arrhenius plots were linear over the range examined. It is suggested that the lipid environment of the external half of the bilayer only influences 5'-nucleotidase activity in these membranes and that cholesterol exerts controlling effects on both the activity and conformation of the enzyme in native membranes.     

Efflux of lipid from fibroblasts to apolipoproteins: dependence on elevated levels of cellular unesterified cholesterol.

Earlier work from this laboratory showed that enrichment of cells with free cholesterol enhanced the efflux of phospholipid to lipoprotein acceptors, suggesting that cellular phospholipid may contribute to high density lipoprotein (HDL) structure and the removal of sterol from cells. To test this hypothesis, we examined the efflux of [3H]cholesterol (FC) and [32P]phospholipid (PL) from control and cholesterol-enriched fibroblasts to delipidated apolipoproteins. The percentages of [3H]cholesterol and [32P]phospholipid released from control cells to human apolipoprotein A-I were 2.2 +/- 0.5%/24 h and 0.8 +/- 0.1%/24 h, respectively. When the cellular cholesterol content was doubled, efflux of both lipids increased substantially ([3H]FC efflux = 14.6 +/- 3.6%/24 h and [32P]PL efflux = 4.1 +/- 0.3%/24 h). Phosphatidylcholine accounted for 70% of the radiolabeled phospholipid released from cholesterol-enriched cells. The cholesterol to phospholipid molar ratio of the lipid released from cholesterol-enriched cells was approximately 1. This ratio remained constant throughout an incubation time of 3 to 48 h, suggesting that there was a coordinate release of both lipids. The concentrations of apoA-I, A-II, A-IV, E, and Cs that promoted half-maximal efflux of phospholipid from cholesterol-enriched fibroblasts were 53, 30, 68, 137, and 594 nM, respectively. With apoA-I and A-IV, these values for half-maximal efflux of phospholipid were identical to the concentrations that resulted in half-maximal efflux of cholesterol. Agarose gel electrophoresis of medium containing apoA-I that had been incubated with cholesterol-enriched fibroblasts revealed a particle with alpha to pre-beta mobility. We conclude that the cholesterol content of cellular membranes is an important determinant in the ability of apolipoproteins to promote lipid removal from cells. We speculate that apolipoproteins access cholesterol-phosphatidylcholine domains within the plasma membrane of cholesterol-enriched cells, whereupon HDL is generated in the extracellular compartment. The release of cellular lipid to apolipoproteins may serve as a protective mechanism against the potentially damaging effects of excess membrane cholesterol.     

Side chain mobility and ligand interactions of the G strand of tear lipocalins by site-directed spin labeling.

Side chain mobility, accessibility, and backbone motion were studied by site-directed spin labeling of sequential cysteine mutants of the G strand in tear lipocalins (TL). A nitroxide scan between residues 98 and 105 revealed the alternating periodicity of mobility and accessibility to NiEDDA and oxygen, characteristic of a beta-strand. Residue 99 was the most inaccessible to NiEDDA and oxygen. EPR spectra with the fast relaxing agent, K(3)Fe(CN)(6), exhibited two nitroxide populations for most residues. The motionally constrained population was relatively less accessible to K(3)Fe(CN)(6) because of dynamic tertiary contact, probably with side chain residues of adjacent strands. With increasing concentrations of sucrose, the spectral contribution of the immobile component was greater, indicating a larger population with tertiary contact. Increased concentrations of sucrose also resulted in a restriction of mobility of spin-labeled fatty acids which were bound within the TL cavity. The data suggest that sucrose enhanced ligand affinity by slowing the backbone motion of the lipocalin. The correlation time of an MTSL derivative (I) attached to F99C resulted in the lack of side chain motion and therefore reflects the overall rotation of the TL complex. The correlation time of F99C in tears (13.5 ns) was the same as that in buffer and indicates that TL exists as a dimer under native conditions. TL-spin-labeled ligand complexes have a shorter correlation time than the protein alone, indicating that the fatty acids are not rigidly anchored in the cavity, but move within the pocket. This segmental motion of the ligand was modulated by protein backbone fluctuations. Accessibility studies with oxygen and NiEDDA were performed to determine the orientation and depth of a series of fatty acid derivatives in the cavity of TL. Fatty acids are oriented with the hydrocarbon tail buried in the cavity and the carboxyl group oriented toward the mouth. In general, the mobility of the nitroxide varied according to position such that nitroxides near the mouth had greater mobility than those located deep in the cavity. Nitroxides positioned up to 16 carbon units from the hydrocarbon tail of the ligand are motionally restricted and inaccessible, indicating the cavity extends to at least this depth. EPR spectra obtained with and without sucrose showed that the intracavitary position of lauric acid in TL is similar to that in beta-lactoglobulin. However, unlike beta-lactoglobulin, TL binds 16-doxyl stearic acid, suggesting less steric hindrance and greater promiscuity for TL.     

Ganglioside-protein interactions: spin-label electron spin resonance studies with (Na+,K+)-ATPase membranes

Lipid-protein interactions in (Na+,K+)-ATPase-rich membranes from Squalus acanthias have been studied using spin-labeled derivatives of the mono- and disialogangliosides GM1, GM2, GM3, and GD1b, in conjunction with electron spin resonance (ESR) spectroscopy. Ganglioside-protein interactions are revealed by the presence of a second component in the ESR spectra of the membranes in addition to a component that corresponds closely to the ESR spectra obtained from dispersions of the extracted membrane lipids. This second component corresponds to spin-labeled gangliosides whose chain motion is significantly restricted relative to that of the fluid lipids in the membrane or the lipid extract. A small selectively for the motionally restricted component associated with the protein is found in the order GD1b greater than GM1 approximately equal to GM2 approximately equal to GM3. Comparison with previous results from spin-labeled phospholipids in the same system [Esmann, M., Watts, A., & Marsh, D. (1985) Biochemistry 24, 1386-1393] shows that the spin-labeled monosialogangliosides GM1, GM2, and GM3 display little selectivity in the lipid-protein interaction relative to spin-labeled phosphatidylcholine. The spectral characteristics of both the fluid and motionally restricted spin-labeled components differ very significantly, however, between the gangliosides and the phospholipids. The outer hyperfine splitting of the motionally restricted component is smaller for the gangliosides than for the phospholipids, indicating a smaller degree of motional restriction on interaction of the ganglioside lipid chains with the protein.(ABSTRACT TRUNCATED AT 250 WORDS)     

Electron spin resonance studies of starch-water-probe interactions

Interactions between starch, water and stable nitroxide radicals were studied by electron spin resonance. The motional properties of TEMPO, 4-(2-bromoacetamido) TEMPO (BrAcTEMPO), 5-DOXYL-stearic acid and 16-DOXYL-stearic acid probes as well as a label covalently attached to amylopectin were investigated in concentrated (10–50%) starch-water systems as a function of temperature, concentration of polymer and storage period. Compared with the free probes in solution, TEMPO and BrAcTEMPO showed slower tumbling rates in starch-water dispersions or gels, suggesting a higher microviscosity in the probe's environment. The spectra, however, remained motionally narrowed. In contrast, the three line spectra of the fatty acid probes in solution became highly anisotropic in the presence of starch. The results indicated that these probes were highly immobilized at room temperature by the starch granules or by the polysaccharide gel matrix. These interactions are weakened at elevated temperatures where the spectra revealed the presence of both motionally narrowed and motionally slowed spin populations. The nitroxide label on the amylopectin exhibited a much slower mobility than the corresponding free probe as well as being found to be more motionally sensitive to temperature changes; such motional behavior was interpreted as reflecting contributions from rotation of the label around the chain backbone as well as local segmental motion of the polymer chain itself. Starch gels doped with free probes or the spin labelled amylopectin displayed no change in the motion of the nitroxide group upon storage, i.e. the tumbling rates did not follow the time-dependent conformational changes associated with the retrogradation phenomenon.     

Thermotropic lipid phase separations in human platelet and rat liver plasma membranes

Electron spin resonance (ESR) studies were conducted on human platelet plasma membranes using 5-nitroxide stearate, I(12,3). The polarity-corrected order parameter S and polarity-uncorrected order parameters S(T parallel) and S(T perpendicular) were independent of probe concentration at low I(12.3)/membrane protein ratios. At higher ratios, S and S(T perpendicular) decreased with increasing probe concentration while S(T parallel) remained unchanged. This is the result of enhanced radical interactions due to probe clustering. A lipid phase separation occurs in platelet membranes that segregates I(12,3) for temperatures less than 37 degrees C. As Arrhenius plots of platelet acid phosphatase activity exhibit a break at 35 to 36 degrees C, this enzyme activity may be influenced by the above phase separation. Similar experiments were performed on native [cholesterol/phospholipid ratio (C/P) = 0.71] and cholesterol-enriched [C/P = 0.85] rat liver plasma membranes. At 36 degrees C, cholesterol loading reduces I(12,3) flexibility and decreases the probe ratio at which radical interactions are apparent. The latter effects are attributed to the formation of cholesterol-rich lipid domains, and to the inability of I(12,3) to partition into these domains because of steric hinderance. Cholesterol enrichment increases both the high temperature onset of the phase separation occurring in liver membranes from 28 degrees to 37 degrees C and the percentage of probe-excluding, cholesterol-rich lipid domains at elevated temperatures. A model is discussed attributing the lipid phase separation in native liver plasma membranes to cholesterol-rich and -poor domains. As I(12,3) behaves similarly in cholesterol-enriched liver and human platelet plasma membranes, cholesterol-rich and -poor domains probably exist in both systems at physiologic temperatures.     

2H and31P nuclear magnetic resonance studies of membranes containing bovine rhodopsin

Summary Purified, delipidated rhodopsin is recombined with phospholipid using octyl-glucoside (OG) and preformed vesicles. Normal egg phosphatidylcholine, phosphatidylcholine in which the N-methyl groups are fully deuterated, and dioleoyl phosphatidylcholine labeled with deuterium at carbons 9 and 10 were used.³¹P nuclear magnetic resonance (NMR) and²H NMR measurements were obtained of the pure phospholipids and of the recombined membranes containing rhodopsin.³¹P NMR of the recombined membrane (containing the deuterated phospholipid) showed two overlapping resonances. One resembled a normal phospholipid bilayer, and the other was much broader, representing a motionally restricted phospholipid headgroup environment. The population of phospholipids in the motionally restricted environment can be modulated by conditions in the media.²H NMR spectra of the same recombined membranes showed only one component. These experimental results agree with a theoretical analysis that predicts an insensitivity of²H NMR to lipids bound to membrane proteins. A model containing at least three different phospholipid environments in the presence of the membrane protein rhodopsin is described.Deceased.     

Exchange rates at the lipid-protein interface of myelin proteolipid protein studied by spin-label electron spin resonance

The electron spin resonance (ESR) spectra from spin-labeled phospholipids in recombinants of myelin proteolipid apoprotein with dimyristoylphosphatidylcholine have been simulated with the exchanged-coupled Bloch equations to obtain values for both the fraction of motionally restricted lipids and the exchange rate between the fluid and motionally restricted lipid populations. The rate of exchange between the two spin-labeled lipid components is found to lie in the slow exchange regime of nitroxide ESR spectroscopy. The values obtained for the fraction of motionally restricted component in the exchanged-coupled spectra are found to be in good agreement with those obtained previously by spectral subtraction for the same system [Brophy, P. J., Horváth, L. I., & Marsh, D. (1984) Biochemistry 23, 860-865]. The rate of lipid exchange off the protein is independent of lipid/protein ratio for a given spin-labeled phospholipid, as expected, and decreases with increasing selectivity of the various phospholipids for the protein. At 30 degrees C and for ionic strength 0.1 and pH 7.4, the off-rate constants are 4.6 X 10(6) s-1 for phosphatidic acid, 1.1 X 10(7) s-1 for phosphatidylserine, 1.6 X 10(7) s-1 for phosphatidylcholine, and 2.2 X 10(7) s-1 for phosphatidylethanolamine. These values are in the inverse ratio of the relative association constants of the various lipids for the protein (Brophy et al., 1984) and are appreciably slower than the rate of lipid lateral diffusion in dimyristoylphosphatidylcholine bilayers.(ABSTRACT TRUNCATED AT 250 WORDS)     

Novel spin-labels for the study of lipid-protein interactions. Application to (Na+, K+)-ATPase membranes

The interactions of a series of spin-labeled fatty acids, in which the nitroxide ring is incorporated in different ways as an integral part of the hydrocarbon chain, with the (Na+,K+)-ATPase in membranes from Squalus acanthias, have been studied by electron spin resonance spectroscopy. The fatty acids are 2,4-, 2,5-, and 3,2-substituents of 2,2,5,5-tetramethylpyrrolidine-N-oxyl and belong to the class of minimal perturbation nitroxide probes. For all five fatty acid labels, a motionally restricted lipid component was observed in the ESR spectra of (Na+,K+)-ATPase membranes, in addition to the fluid component, which was found in the spectra of the extracted membrane lipids. The pH dependence of the motionally restricted spin-label population indicated a sensitivity in the selectivity of the lipid-protein interaction to the protonation state of the fatty acid. These results agree with those found previously for the conventional oxazolidine (doxyl) fatty acid and phospholipid spin-label derivatives [Esmann, M., Watts, A., & Marsh, D. (1985) Biochemistry 24, 1386-1393] and indicate that the motion of the lipid chains is significantly hindered by interaction with the protein, irrespective of the nature of the spin-label group.     

Temperature-dependent 13C nuclear magnetic resonance studies of human serum low density lipoproteins.

The natural abundance 13C nuclear magnetic resonance (NMR) spectrum of human serum low density lipoproteins (LDL) shows significant temperature-dependent changes. These temperature-dependent spectra have been used to monitor changes in the organization of cholesterol esters within the LDL particle. Comparison with 13C NMR spectra of both cholesterol linoleate and an aqueous codispersion of cholesterol linoleate and egg phosphatidylcholine suggests that at low temperatures (10 degrees C), the cholesterol esters in LDL are organized in a smectic-like, liquid-crystalline arrangement. At temperatures above the order-disorder transition exhibited by the cholesterol esters of LDL, the cholesterol esters appear to be partially melted but still are motionally restricted compared with liquid cholesterol esters.