Erythrocyte membranes - compression of lipid phases by increased cholesterol content

Lipid and protein interactions were studied in guinea pig erythrocytes containing a normal or a two-fold increased amount of cholesterol. The electron spin resonance (ESR) spectra of cholesterol-loaded cells labeled with fatty-acid probes showed an increase in the local viscosity of the membrane as compared with control cells. This increase reflects changes in the interior of the lipid matrix of the membrane because the probes resisted destruction by ascorbate, were unaffected by the action of pronase, and gave spectra similar to those of liposomes. No differences were observed between control and cholesterol-loaded cells in the conformation of the membrane proteins by either the infrared spectra or the ESR spectra of cells labeled with maleimide probes.     

Lipid peroxidation increases the molecular order of microsomal membranes

The effect of enzymatic lipid peroxidation on the molecular order of microsomal membranes was evaluated by ESR spectroscopy using the spin probes 5-, 12-, and 16-doxyl-stearic acid. Rat liver microsomal membranes were peroxidized by the NADPH-dependent reaction in the presence of the chelate ADP-Fe3+. Peroxidation resulted in a preferential depletion of polyenoic fatty acids and an increase in the percentage composition of shorter fatty acyl chains. There was no change in the cholesterol/phospholipid ratio of the peroxidized microsomes. The molecular order of both control and peroxidized membranes decreased toward the central region of the bilayer, and the order parameter (S) of each probe was temperature dependent. Peroxidation of the microsomal membrane lipids resulted in an increase in the order parameter determined with the three stearic acid spin probes. Of the three probes, 12-doxylstearic acid was the most sensitive to the changes in membrane organization caused by peroxidation. These data indicate that ESR spectroscopy is a sensitive method of detecting changes in membrane order accompanying peroxidation of membrane lipids.     

Fluorescence and ESR spectroscopy studies on the interaction of isoflavone genistein with biological and model membranes

Genistein (5,7,4′-trihydroxyisoflavone) the common soy beans isoflavone has attracted scientific interest due to its antioxidant, estrogenic, antiangiogenic and aniticancer activities. The aim of the present study was to investigate the interaction of genistein with biological (erythrocyte) and model membranes (dimyristoyl- and dipalmitoylphosphatidylcholine). Using Laurdan and Prodan as fluorescent probes, we demonstrated phase behavior and membrane fluidity changes induced by genistein. ESR spectroscopy revealed alterations caused by genistein in membrane domains structure and mobility of spin probes with free radicals located at different depths of membrane. The method of ESR spectra decomposition and computer simulation of the recorded spectra were used in order to visualize domain coexistence by GHOST condensation method. Fluorescence and ESR spectroscopy experiments performed at different temperatures enabled us to observe the effect of isoflavone on phospholipid bilayers in either gel or liquid crystalline phase. It was concluded that genistein preferentially intercalated into lipid headgroup region, to some extent into polar–apolar interface and only in minimal degree into hydrophobic core of the membrane. According to our best knowledge this is the first study on modification of domain structure of membranes by genistein.     

Two-step impact of Amphotericin B (AmB) on lipid membranes: ESR experiment and computer simulations

Abstract

In this study, the electron spin resonance (ESR) method was used to examine the effect of Amphotericin B (AmB) molecules on the fluidity of model membranes made of dipalmitoylphosphatidylcholine (DPPC). The changes occurring under increased AmB concentrations in the spectroscopic parameters of spin probes placed in liposomes were determined. Three probes were used, penetrating the membrane at different depths which allowed the changes in its fluidity to be found in the transverse section. A computer model of the surface layer of membrane, with AmB admixture, was developed and subjected to computer simulation. The effect of changing concentration of the admixture on the binding energy in the system of dipoles representing the surface of the membrane was examined. The ESR studies showed that the process of accumulation of AmB molecules in the membrane has two stages, marked by local maxima in the ESR spectra. The first appears for concentrations of ca. 0.25–0.5% and the second appears for ca. 2.5–3% AmB of its molar ratio to DPPC. The computer simulations permitted reconstructing the two-stage mechanism of interaction between the molecules and the membrane. They demonstrated that, at low concentrations, the AmB molecules position themselves flat on the membrane surface. After the threshold concentration is exceeded, they re-orientate to a vertical position. This process leads to the perforation of the membrane.     

Reliability of nitroxide spin probes in reporting membrane properties: a comparison of nitroxide- and deuterium-labeled steroids

The reliability for the study of membrane properties of the steroid nitroxide spin probe, 3-doxylcholestane, was tested by comparison of analogous data for the deuterated steroid, cholesterol-3 alpha-d. Good agreement between the two probes was found for the dependence of their order parameters on variation of temperature or cholesterol concentration in egg phosphatidylcholine bilayers. This finding is contrasted with the results of a previous study of fatty acid probes where poor agreement was found for the spectral responses of nitroxide- and deuterium-labeled species. The angular dependence of the ESR spectra of nitroxide-labeled probes in oriented multibilayer films was examined to determine if the probes were oriented in a tilted fashion in the bilayer. The 3-doxylcholestane probe and a doxylstearic acid labeled at position 14 orient with their long molecular axes perpendicular to the bilayer plane. In contrast, the stearic acid probe nitroxide labeled at position 5 does not appear to orient in such a fashion. We suggest that the behavior of the latter probe reflects the difficulty of inserting a bulky nitroxide group into a highly ordered region of the bilayer rather than an inherent tilting of the phospholipid acyl chains. On the basis of the comparisons between various types of probes, some suggestions are made concerning the choice of ESR spin probe to obtain reliable information in membrane studies.     

The conformations of nitroxide-labelled fatty acid probes of membrane structure as studied by 2H-NMR

The electron spin resonance (ESR) spectrum of a nitroxide spin probe intercalated in a membrane is influenced by the amplitude of anisotropic motion of the nitroxide group and by the geometry of the oxazolidine ring of the nitroxide. In the analysis of the ESR spectra of nitroxide-labelled fatty acid probes, it is generally assumed that the five-membered oxazolidine ring system is oriented rigidly perpendicular to the long molecular axis of the probe. This assumption is tested in the present study, using 2H-NMR of specifically deuterium-labelled nitroxide spin probes. Evidence is presented that the nitroxide does not display the assumed geometry in membranes. The departure from this geometry depends on the position of the nitroxide label on the acyl chain, with a more pronounced departure for position 5 relative to position 12. These and previous data provide an explanation for the discrepancies between spin-probe ESR and 2H-NMR order parameters in membranes.     

Quantification of lipid bilayer effective microviscosity and fluidity effect induced by propofol

Electron spin resonance (ESR) spectroscopy with nitroxide spin probes was used as a method to probe the liposome microenvironments. The effective microviscosities have been determined from the calibration of the ESR spectra of the probes in solvent mixtures of known viscosities. In the first time, by measuring ESR order parameter (S) and correlation time (tau(c)) of stearic spin probes, we have been able to quantify the value of effective microviscosity at different depths inside the liposome membrane. At room temperature, local microviscosities measured in dimyristoyl-l-alpha phosphatidylcholine (DMPC) liposome membrane at the different depths of 7.8, 16.95, and 27.7 A were 222.53, 64.09, and 62.56 cP, respectively. In the gel state (10 degrees C), those microviscosity values increased to 472.56, 370.61, and 243.37 cP. In a second time, we have applied this technique to determine the modifications in membrane microviscosity induced by 2,6-diisopropyl phenol (propofol; PPF), an anaesthetic agent extensively used in clinical practice. Propofol is characterized by a unique phenolic structure, absent in the other conventional anaesthetics. Indeed, given its lipophilic property, propofol is presumed to penetrate into and interact with membrane lipids and hence to induce changes in membrane fluidity. Incorporation of propofol into dimyristoyl-l-alpha phosphatidylcholine liposomes above the phase-transition temperature (23.9 degrees C) did not change microviscosity. At 10 degrees C, an increase of propofol concentration from 0 to 1.0 x 10(-2) M for a constant lipid concentration mainly induced a decrease in microviscosity. This fluidity effect of propofol has been qualitatively confirmed using merocyanine 540 (MC540) as lipid packing probe. Above 10(-2) M propofol, no further decrease in microviscosity was observed, and the microviscosity at the studied depths (7.8, 16.95, and 27.7 A) amounted 260.21, 123.87, and 102.27 cP, respectively. The concentration 10(-2) M was identified as the saturation limit of propofol in dimyristoyl-l-alpha phosphatidylcholine liposomes.     

The conformations of nitroxide-labelled fatty acid probes of membrane structure as studied by 2H-NMR

The electron spin resonance (ESR) spectrum of a nitroxide spin probe intercalated in a membrane is influenced by the amplitude of anisotropic motion of the nitroxide group and by the geometry of the oxazolidine ring of the nitroxide. In the analysis of the ESR spectra of nitroxide-labelled fatty acid probes, it is generally assumed that the five-membered oxazolidine ring system is oriented rigidly perpendicular to the long molecular axis of the probe. This assumption is tested in the present study, using ²H-NMR of specifically deuterium-labelled nitroxide spin probes. Evidence is presented that the nitroxide does not display the assumed geometry in membranes. The departure from this geometry depends on the position of the nitroxide label on the acyl chain, with a more pronounced departure for position 5 relative to position 12. These and previous data provide an explanation for the discrepancies between spin-probe ESR and ²H-NMR order parameters in membranes.     

Macromolecular spin pH-probes on the basis of human serum albumin

Human serum albumin has been chemically modified by two different spin pH-sensitive labels of the imidazoline series containing in their structure alkylating and carboxyl groups, respectively. The ESR spectra of spin-labeled proteins are sensitive to pH of the medium. The pK values of spin-labeled proteins measured by the ESR method are: pKI = 3.2 +/- 0.1; pKII = 4.75 +/- 0.1. The resulting macromolecular spin pH probes may be used for measuring the local values of pH by the ESR technique within the pH range of 1.8-6.2.     

Cholesterol modulation of lipid-protein interactions in liver microsomal membrane: a spin label study.

ESR spectra of spin probes were used to monitor lipid-protein interactions in native and cholesterol-enriched microsomal membranes. In both systems composite spectra were obtained, one characteristic of bulk bilayer organization and another due to a motionally restricted population, which was ascribed to lipids in a protein microenvironment. Computer spectral subtractions revealed that cholesterol modulates the order/mobility of both populations in opposite ways, i.e., while the lipid bilayer region gives rise to more anisotropic spectra upon cholesterol enrichment, the spectra of the motionally restricted population become indicative of increased mobility and/or decreased order. These events were evidenced by measurement of both effective order parameters and correlation times. The percentages of the motionally restricted component were invariant in native and cholesterol-enriched microsomes. Variable temperature studies also indicated a lack of variation of the percentages of both spectral components, suggesting that the motionally restricted one was not due to protein aggregation. The results correlate well with the effect of cholesterol enrichment on membrane-bound enzyme kinetics and on the behavior of fluorescent probes [Castuma & Brenner (1986) Biochemistry 25, 4733-4738]. Several hypothesis are put forward to explain the molecular mechanism of the cholesterol-induced spectral changes.     

Phospholipid spin probes measure the effects of ethanol on the molecular order of liver microsomes

Ethanol, in vitro, is known to perturb the molecular order of the phospholipids in biological membranes, while chronic ethanol exposure, in vivo, leads to resistance to disordering. Such changes have usually been measured by electron spin resonance, utilizing fatty acid spin probes. The use of such probes is controversial, since their orientation in the membrane may not accurately represent that of individual phospholipids. We, therefore, compared ethanol-induced structural perturbations in the membranes of rat hepatic microsomes measured with the spin probe 12-doxylstearic acid (SA 12) with those assayed with various phospholipid spin probes. With SA 12, the addition of increasing amounts of ethanol (50-250 mM) in vitro caused a progressive decrease in the membrane molecular order, as measured by electron spin resonance (ESR). By contrast, microsomes obtained from rats chronically fed ethanol were resistant to the disordering effect of ethanol. Microsomes labeled with the phospholipid spin probes 1-palmitoyl-2-(12-doxylstearoyl)phosphatidylcholine, -phosphatidylethanolamine, or -phosphatidic acid also exhibited increased disordering with the addition of increasing amounts of ethanol. However, the effect noted with phospholipid spin probes was less than that observed with the fatty acid probe. Microsomes obtained from the livers of chronically intoxicated animals labeled with the phospholipid probes were also resistant to the disordering effects of ethanol in vitro. These results suggest that fatty acid spin probes are qualitatively valid for measuring membrane perturbations in biological membranes, ethanol affects all microsomal phospholipids, regardless of chemical dissimilarities (e.g., head-group structure), in a qualitatively similar fashion, and the fluidization of fatty acyl chains in microsomal membranes is comparable in different membrane phospholipids.     

Slow-motion ESR study of order and dynamics in oriented lipid multibilayers: effects of unsaturation and hydration

Electron spin resonance (ESR) experiments were carried out on 3-doxyl-5 alpha-cholestane spin-label (CSL) molecules embedded in macroscopically oriented multibilayers of dimyristoylphosphatidylcholine (DMPC), palmitoyloleoylphosphatidylcholine (POPC), dioleoylphosphatidylcholine (DOPC) and dilinoleoylphosphatidylcholine (DLPC). For these lipids we studied the effects of temperature, hydration and unsaturation on the orientational order parameters and rotational motions of the probe molecules in the liquid crystalline phase. The experimental ESR spectra were simulated by a numerical solution of the stochastic Liouville equation (SLE) for the density matrix of a spin-label molecule. This allows extraction of detailed information about both molecular order and rotational dynamics. The data show that, in our temperature range, the lipid systems are in the slow-motion regime, thereby precluding a motional narrowing interpretation. This is illustrated by a simple model calculation which shows that a fast-motion interpretation seriously overestimates the order parameters. We have compared our results with data obtained independently from angle-resolved fluorescence depolarization (AFD) experiments on oriented bilayers in which 1-[4-(trimethylammonio)phenyl]-6-phenyl-1,3,5-hexatriene (TMA-DPH) molecules were used as fluorescent probes (Deinum et al., (1988) Biochemistry 27, 852-860). It is found that the orientational order and the rotational dynamics obtained with both techniques agree well. This shows that the probe molecules do not perturb the local bilayer structure to any large extent and that they indeed reflect the intrinsic behaviour of the lipid molecules. Upon increase in temperature or hydration, we observe faster reorientational motion and lower molecular ordering. In contrast, we do not find any systematic effect of unsaturation on molecular reorientational motion. Our results indicate that changes in membrane molecular order and reorientational dynamics have to be considered separately and are not necessarily correlated as implied by the common concept of membrane fluidity.     

The two sides of a lipid-protein story

Protein–membrane interactions play essential roles in a variety of cell functions such as signaling, membrane trafficking, and transport. Membrane-recruited cytosolic proteins that interact transiently and interfacially with lipid bilayers perform several of those functions. Experimental techniques capable of probing changes on the structural dynamics of this weak association are surprisingly limited. Among such techniques, electron spin resonance (ESR) has the enormous advantage of providing valuable local information from both membrane and protein perspectives by using intrinsic paramagnetic probes in metalloproteins or by attaching nitroxide spin labels to proteins and lipids. In this review, we discuss the power of ESR to unravel relevant structural and functional details of lipid–peripheral membrane protein interactions with special emphasis on local changes of specific regions of the protein and/or the lipids. First, we show how ESR can be used to investigate the direct interaction between a protein and a particular lipid, illustrating the case of lipid binding into a hydrophobic pocket of chlorocatechol 1,2-dioxygenase, a non-heme iron enzyme responsible for catabolism of aromatic compounds that are industrially released in the environment. In the second case, we show the effects of GPI-anchored tissue-nonspecific alkaline phosphatase, a protein that plays a crucial role in skeletal mineralization, and on the ordering and dynamics of lipid acyl chains. Then, switching to the protein perspective, we analyze the interaction with model membranes of the brain fatty acid binding protein, the major actor in the reversible binding and transport of hydrophobic ligands such as long-chain, saturated, or unsaturated fatty acids. Finally, we conclude by discussing how both lipid and protein views can be associated to address a common question regarding the molecular mechanism by which dihydroorotate dehydrogenase, an essential enzyme for the de novo synthesis of pyrimidine nucleotides, and how it fishes out membrane-embedded quinones to perform its function.     

Spin label study of detergents in the region of critical micelle concentration.

A series of spin probes was employed to examine the behavior of the detergent sodium dodecyl sulfate (SDS) at concentrations above and below the critical micelle concentration (cmc). The existence of detergent aggregates below the cmc was evidenced by the appearance of composite electron spin resonance (ESR) spectra for probes that have measurable solubility in water. The spectra were indicative of two probe populations: one in an aqueous environment and another in detergent aggregates. The ESR spectra of probes which are highly insoluble in water exhibited line broadening due to intermolecular spin exchange interactions, indicating that the probes were concentrated in detergent aggregates present below the experimental cmc. The results are discussed in terms of their significance for the study of the mechanisms of micelle formation and for the detection of detergent aggregates at very low concentrations.     

Effects of freezing on the structure of chloroplast membranes

Electron spin resonance (ESR) spectra of stearic acid spin labels incorporated into spinach thylakoids can be used to monitor membrane changes during freezing. Changes in the ESR parameters can be directly correlated to the extent of functional freeze damage. Freeze-induced changes in the ESR parameters strongly depend on the osmotic conditions of the incubation medium. Similar changes as on freezing can be observed by transferring thylakoids from an isotonic to a hypotonic medium, i.e., by swelling osmotically flattened thylakoids. This and computer simulations of spin label ESR spectra, which allow for variation of vesicle shape, lead to the conclusion that freeze-induced ESR spectral changes are due to swelling of the thylakoids. Indeed, van't Hoff plots of thylakoid packed volume indicate a freeze-induced increase in the apparent number of osmotically active molecules within the intrathylakoid lumen. During freezing, salt and/or sugar leak into the lumen. Simultaneously, proton channels are irreversibly opened. As the structural alterations obtained upon freezing are not accompanied by a change in bulk fluidity, these data are interpreted in terms of a local action of cryotoxic agents on critical microstructures, possibly at the rims of the thylakoid membranes.     

Influence of phospholipid unsaturation on the cholesterol distribution in membranes.

Over the last half decade, we have studied saturated and unsaturated phosphatidylcholine (PC)-cholesterol membranes, with special attention paid to fluid-phase immiscibility in cis-unsaturated PC-cholesterol membranes. The investigations were carried out with fatty acid and sterol analogue spin labels for which reorientational diffusion of the nitroxide was measured using conventional ESR technique. We also used saturation recovery ESR technique where dual probes were utilized. Bimolecular collision rates between a membrane-soluble square-planar copper complex,3-ethoxy-2-oxobutyraldehyde bis(N4,N4-dimethylthiosemicarbazonato)copper(II) (CuKTMS2) and one of several nitroxide radical lipid-type spin labels were determined by measuring the nitroxide spin-lattice relaxation time (T1). The results obtained in all these studies can be explained if the following model is assumed: 1) at physiological temperatures, fluid-phase micro-immiscibility takes place in cis-unsaturated PC-cholesterol membranes, which induces cholesterol-rich domains in the membrane due to the steric nonconformability between the rigid fused-ring structure of cholesterol and the 30 degrees bend at the cis double bond of the alkyl chains of unsaturated PC. 2) The cholesterol-rich domains are small and/or of short lifetime (10(-9) s to less than 10(-7) s). Our results also suggest that the extra space that is available for conformational disorder and accommodation of small molecules is created in the central part of the bilayer by intercalation of cholesterol in cis-unsaturated PC membrane due to the mismatch in the hydrophobic length and nonconformability between cis-unsaturated PC alkyl chains and the bulky tetracyclic ring of cholesterol.     

Spectroscopic studies of interactions of chondroitin sulfates with cisplatin

Complexation of cisplatin (CDDP) and chondroitin sulfate A (CSA) or C (CSC) has been reported to reduce the nephrotoxicity of CDDP. However the mechanism of interaction between CDDP and CSA or CSC was not known. In this study, spectroscopic analyses including NMR were carried out to examine the complexation interactions of CSA and CSC with CDDP. The time-dependent changes in the UV spectra indicate that CSA and CSC effectively complexes with CDDP in aqueous solution and that the reaction occurs subsequent to the hydrolysis of CDDP. The time-dependent change results measured by capillary electrophoresis showed that complexation of chondroitin sulfate (CS) followed first-order reaction kinetics and that the rate of CDDP hydrolysis in the complexation for both CSA and CSC was the same. These results suggested that the mechanism of complexation was a two-step process with monoaqua formation proved to be the first step, which was also the reaction rate controlling step. Moreover, NMR data suggested that the carboxylic and sulfate groups of CS played an important role in its interaction with CDDP.     

Local Pharmacokinetic Analysis of a Stable Spin Probe in Mice by In Vivo L-band ESR with Surface-coil-type Resonators

In vivo ESR spectroscopy using a low frequency microwave of approximately 1 GHz has been developed to measure non-invasive ESR spectra in animals given paramagnetic compounds, in which a loop-gap-type resonator was used and ESR spectra were measured at the animal's head or abdomen. Therefore, the concentrations of paramagnetic species in both the blood and organs were compositely contributed to the spectra. When we understand the kinetics of paramagnetic species in detail, it is essentially important to know how these kinetics are expressed in each organ. For this purpose, a surface-coil-type resonator, which enabled local ESR measurement in specific organs, has been developed. By using this method, we studied the real-time pharmacokinetics of spin clearance curves detected in the organs of mice given 4-hydroxy-2,2,6,6-tetramethylpiperidine-1-oxyl (4-hydroxy-TEMPO) intravenously (i.v.), by monitoring the inferior vena cava, liver and kidney. Quantified clearance curves in the organs were analyzed on the basis of a two-compartment model, and pharmacokinetic parameters were estimated based on the curve-fitting. The obtained pharmacokinetic parameters were found to depend on the measurement site, and the distribution and elimination processes of the spin probe were successfully separated between the blood and organs of mice.     

Local pharmacokinetic analysis of a stable spin probe in mice by in vivo L-band ESR with surface-coil-type resonators

In vivo ESR spectroscopy using a low frequency microwave of approximately 1 GHz has been developed to measure non-invasive ESR spectra in animals given paramagnetic compounds, in which a loop-gap-type resonator was used and ESR spectra were measured at the animal's head or abdomen. Therefore, the concentrations of paramagnetic species in both the blood and organs were compositely contributed to the spectra. When we understand the kinetics of paramagnetic species in detail, it is essentially important to know how these kinetics are expressed in each organ. For this purpose, a surface-coil-type resonator, which enabled local ESR measurement in specific organs, has been developed. By using this method, we studied the real-time pharmacokinetics of spin clearance curves detected in the organs of mice given 4-hydroxy-2,2,6,6-tetramethylpiperidine-1-oxyl (4-hydroxy-TEMPO) intravenously (i.v.), by monitoring the inferior vena cava, liver and kidney. Quantified clearance curves in the organs were analyzed on the basis of a two-compartment model, and pharmacokinetic parameters were estimated based on the curve-fitting. The obtained pharmacokinetic parameters were found to depend on the measurement site, and the distribution and elimination processes of the spin probe were successfully separated between the blood and organs of mice.     

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.