Specificity of lipid-protein interactions as determined by spectroscopic techniques

A specific interaction between NADPH-cytochrome reductase and phosphatidylserine and phosphatidylinositol

In the present study the interaction of NADPH-cytochrome reductase with phospholipids was investigated using 31P-NMR, thin-layer chromatography combined with chemical analysis, fluorescence spectroscopy and kinetic studies with purified rat liver cytochrome P450 IIB1. 31P-NMR analysis demonstrates that the composition of the phospholipids that remain associated to NADPH-cytochrome reductase upon its purification is significantly different from the phospholipid composition of the microsomal membrane. Thin-layer chromatography followed by chemical analysis of the phospholipid composition demonstrates that the isolated NADPH-cytochrome reductase was enriched in L-alpha-1,2-diacyl-sn-glycero-3-phosphoserine (acyl2GroPSer) and L-alpha-1,2-diacyl-sn-glycero-3-phosphoinositol (acyl2GroPIns) compared to the microsomal membrane. The observed preference of NADPH-cytochrome reductase for acyl2GroPSer and acyl2GroPIns appeared not to be a result of the procedure for solubilisation and/or purification of the protein. The specific interaction of NADPH-cytochrome reductase with acyl2GroPSer and acyl2GroPIns was further investigated by comparison of the effect of acyl2GroPSer and acyl2GroPIns with that of acyl2GroPCho and acyl2GroPEtn on the 2-[3-(diphenylhexatrienyl)propanoyl]-1-hexadecanoyl-sn-glycero-3- phosphocholine-(DphPamGroPCho)-dependent quenching of the tryptophan fluorescence of purified NADPH-cytochrome reductase. The results demonstrate that the addition of acyl2GroPSer or acyl2GroPIns affects the DphPamGroPCho-dependent quenching of the tryptophan fluorescence in a manner significantly different from the addition of acyl2GroPCho or acyl2GroPEtn. The relatively larger DphPamGroPCho-induced quenching of the tryptophan fluorescence of NADPH-cytochrome reductase in the presence of acyl2GroPSer and acyl2GroPIns must result from a change in the conformation of NADPH-cytochrome reductase induced by the latter two lipids. Finally, the possible consequences of this special interaction of acyl2GroPSer and acyl2GroPIns with NADPH-cytochrome reductase on the kinetic characteristics of the cytochrome P450 system were studied using cytochrome-P450-IIB1-dependent O-dealkylation of pentoxyresorufin as the model reaction. These studies demonstrate that a 1:1 mixture of acyl2GroPCho and acyl2GroPSer results in a significantly higher apparent maximum rate (V) of O-dealkylation than a 1:1 mixture of acyl2GroPCho and acyl2ProPEtn or acyl2GroPCho alone. This increase in the apparent V can be ascribed to an acyl2GroPSer-dependent improvement of the interaction of NADPH-cytochrome reductase with cytochrome P450. This improvement of the interaction of the proteins cannot, however, be exclusively ascribed to the negative charge of acyl2GroPSer, since the other negatively charged phospholipid investigated, namely acyl2GroPIns, resulted in a significant decrease in the apparent V.(ABSTRACT TRUNCATED AT 400 WORDS)

An electron spin resonance study of interactions between gramicidin A' and phosphatidylcholine bilayers

The model of microscopic order and macroscopic disorder was used to stimulate electron spin resonance spectra of spin-labeled lipids, 5-PC, 10-PC, and 16-PC in multilamellar vesicles of dipalmitoylphosphatidylcholine (DPPC) containing gramicidin A' (GA) at temperatures above the gel-to-liquid crystal transition of DPPC. The simulations show that at a lower concentration of GA (i.e., molar ratios of DPPC/GA greater than 3), GA has only a slight effect on the acyl chain dynamics. The rotational diffusion rate around the axis parallel to the long hydrocarbon chain remains unchanged or increases slightly, while the rate around the perpendicular axes decreases slightly. These spectra from DPPC/GA mixtures could only be fit successfully with two or more components consistent with the well-known concept of "boundary lipids," that is, the peptide induces structural inhomogeneity in lipid bilayers. However, the spectra were significantly better fit with additional components that exhibit increased local ordering, implying decreased amplitude of rotational motion, rather than immobilized components with sharply a reduced rotational rate. The largest relative effects occur at the end of the acyl chains, where the average local order parameter St of 16-PC increases from 0.06 for pure lipid to 0.66 for 1:1 DPPC/GA. The inhomogeneity in ordering in DPPC bilayers due to GA decreases with increasing temperature. The hyperfine tensor component Azz increases for 10-PC and 16-PC when GA is incorporated into DPPC bilayers, indicating that water has deeply penetrated into the DPPC bilayers. Simulations of published electron spin resonance spectra of 14-PC in dimyristoylphosphatidylcholine/cytochrome oxidase complexes were also better fit by additional components that were more ordered, rather than immobilized. The average local order parameter in this case is found to increase from 0.11 for pure dimyristoylphosphatidylcholine to 0.61 for a lipid/protein ratio of 50. These spectra and their simulations are similar to the results obtained with 16-PC in the DPPC/GA mixtures. The relevance to studies of lipid-protein interactions for other proteins is briefly discussed.

Lipid enrichment and selectivity of integral membrane proteins in two-component lipid bilayers

A model recently used to study lipid-protein interactions in one-component lipid bilayers (Sperotto and Mouritsen, 1991 a, b) has been extended in order to include two different lipid species characterized by different acyl-chain lengths. The model, which is a statistical mechanical lattice model, assumes that hydrophobic matching between lipid-bilayer hydrophobic thickness and hydrophobic length of the integral protein is an important aspect of the interactions. By means of Monte Carlo simulation techniques, the lateral distribution of the two lipid species near the hydrophobic protein-lipid interface in the fluid phase of the bilayer has been derived. The results indicate that there is a very structured and heterogeneous distribution of the two lipid species near the protein and that the protein-lipid interface is enriched in one of the lipid species. Out of equilibrium, the concentration profiles of the two lipid species away from the protein interface are found to develop a long-range oscillatory behavior. Such dynamic membrane heterogeneity may be of relevance for determining the physical factors involved in lipid specificity of protein function.

Lipid clustering in bilayers detected by the fluorescence kinetics and anisotropy of trans-parinaric acid

Fluid heterogeneity in lipid bilayers and shows a simple and useful method to quantify this heterogeneity. Taking advantage of the maximum entropy method, we have resolved the probe fluorescence lifetime distributions in homogeneous solutions and in single and two-component lipid bilayers at different temperatures. A precise description of the emission kinetics was obtained as a function of viscosity in the homogeneous solution and as a function of the phase composition (gel/fluid) in the lipid bilayers. These data show, unambiguously, that the same distribution pattern, with two well resolved lifetime classes, is observed both in pure solvents and in fluid bilayers. This distribution is modified during the thermotropic phase transition, with the appearance of a long lifetime component. The anisotropy experiments confirm that the amplitude of this component is proportional to the fraction of probe located in the gel phase. From this fraction we have quantified the amount of gel phase in the binary bilayer system dimyristoyl phosphatidylcholine/dipalmitoyl phosphatidylcholine and determined the thermotropic phase diagram of the mixture. This phase diagram agrees well with that calculated assuming ideal mixing of the lipids (Marbrey, S., and J.M. Sturtevant. 1976. Proc. Natl. Acad. Sci. USA. 73:862-3866).

Bacterial solute transport proteins in their lipid environment

The cytoplasmic membrane of bacteria is a selective barrier that restricts entry and exit of solutes. Transport of solutes across this membrane is catalyzed by specific membrane proteins. Integral membrane proteins usually require specific lipids for optimal activity and are inhibited by other lipid species. Their activities are also sensitive to the lipid bilayer dynamics and physico-chemical state. Bacteria can adapt to changes in the environments (respective temperature, hydrostatic pressure, and pH) by altering the lipid composition of the membrane. Homeoviscous adaptation results in the maintenance of the liquid-crystalline phase through alterations in the degree of acyl chain saturation and branching, acyl chain length and the sterol content of the membrane. Homeophasic adaptation prevents the formation of non-bilayer phases, which would disrupt membrane organization and increase permeability. A balance is maintained between the lamellar phase, preferring lipids, and those that adopt a non-bilayer organization. As a result, the membrane proteins are optimally active under physiological conditions. The molecular basis of lipid-protein interactions is still obscure. Annular lipids stabilize integral membrane proteins. Stabilization occurs through electrostatic and possibly other interactions between the lipid headgroups and the charged amino acid residues close to the phospholipid-water interface, and hydrophobic interactions between the fatty acyl chains and the membrane-spanning segments. Reconstitution techniques allow manipulation of the lipid composition of the membrane in a way that is difficult to achieve in vivo. The physical characteristics of membrane lipids that affect protein-mediated transport functions have been studied in liposomal systems that separate an inner and outer compartment. The activity of most transport proteins is modulated by the bulk physical characteristics of the lipid bilayer, while specific lipid requirements appear rare.

A role for band 4.2 in human erythrocyte band 3 mediated anion transport

Human erythrocyte band 3 was purified essentially free of peripheral proteins, in particular band 4.2, using affinity chromatography. Band 3 protein was then reconstituted into liposomes of lipid type and ratio approximating that of erythrocyte membranes. Stilbenedisulfonate inhibition of band 3 mediated efflux of radiolabeled sulfate from preloaded liposomes was used to test the functionality and correct orientation of the protein. When sulfate efflux, mediated by purified band 3, was compared with partially purified band 3, which contained detectable amounts of bands 4.1 and 4.2, a clear difference in efflux was measured. Sulfate efflux was approximately 30% faster from liposomes containing purified band 3 compared with those containing partially purified protein. In order to investigate further any specific effect of band 4.2 protein on band 3 mediated anion transport, band 4.2 was purified. Increasing amounts of band 4.2 were complexed with purified band 3 and then reconstituted into liposomes. Increasing amounts of band 4.2 complexed with band 3 caused a decrease in band 3 mediated anion transport. The effect of band 4.2 on band 3 mediated anion transport appears to be specific since increasing concentrations of band 4.2 added exogenously to band 3 in reconstituted vesicles (rather than complexed with band 3 before reconstitution) produced no significant changes in sulfate efflux. Further, when increasing amounts of band 4.2 were added to the functionally active transmembrane domain of band 3 and then reconstituted into vesicles, there was also no significant change in sulfate efflux.(ABSTRACT TRUNCATED AT 250 WORDS)

Characterization of structural and functional phosphoinositide domains in human erythrocyte membranes

In the erythrocyte membrane, only a fraction (50-60%) of phosphatidylinositol 4,5-bisphosphate (PIP2) and of phosphatidylinositol 4-phosphate (PIP) is rapidly turned over by specific kinases and phosphatases and accessible to hydrolysis by the polyphosphoinositide (PPI)-specific phospholipase C (PLC). To investigate whether the metabolic segregation of PPI resulted from preferential interactions with proteins, we have measured the accessibility of PPI to bee venom phospholipase A2 (PLA2) in native erythrocyte membranes, or after treatments designed to remove peripheral proteins and cytoplasmic domains of integral proteins. In native membranes, PPI, as well as the other major phospholipids, behaved as two distinct fractions (R1 and R2) differing by their sensitivity to PLA2. Such a behavior was not observed in PIP and PIP2 containing artificial vesicles. Evidence was provided that the highly sensitive fraction of PIP and PIP2 (R1) may be identical to the PLC-sensitive and rapidly metabolized pool. Removal of peripheral proteins, followed by proteolysis of the cytoplasmic domain of integral proteins, mainly glycophorins and band 3, led to a reduction of the R1 fraction of PIP and of PIP2. It is proposed that the rapidly metabolized pool of PIP2 and PIP, involved in the regulation of major cellular functions, would be maintained in its functional state through interactions with integral proteins.

The kinetics and thermodynamics of bleaching of rhodopsin in dimyristoylphosphatidylcholine. Identification of meta-I, meta-II, and meta-III intermediates

The effects of light on rhodopsin reconstituted into dimyristoylphosphatidylcholine at a molar ratio of 1:70 have been studied as a function of temperature and time. The lipid phase behavior and thermal stability of rhodopsin in the system used to measure the photolytic reactions were also determined. Thus, it was shown that the gel-to-fluid phase transition of the reconstituted membrane had a marked influence on the bleaching kinetics and thermodynamics of rhodopsin-bleaching equilibria, whereas lipid-protein interactions were also directly involved. Rhodopsin photolysis resulted in temperature-sensitive equilibria between three main photoproducts, with absorption maximal of approximately 480, 380, and 465 nm. Below the lipid phase transition temperature, the main photoproduct had an absorption maximum at 480 nm. With increasing temperature progressively more of the 380 nm-absorbing species was formed. The photoproduct with a spectral-maximum at 465 nm absorption was formed more slowly. Increasing temperatures decreased the ratio of the 465:380 nm-absorbing species. The thermal reactions were reversible: on cooling the higher-temperature products were converted back to the lower-temperature products. The results indicate that rhodopsin has extensive photochemical activity when reconstituted in dimyristoylphosphatidylcholine. The equilibria that we have measured resemble those of rhodopsin in the disk membrane. However, the kinetics of meta-II and meta-III formation appear to be considerably faster in the reconstituted membranes and the meta-I-to-meta-II equilibrium is displaced in the direction of the meta-I state relative to native rod outer segment disk membranes. The displacement of the meta-rhodopsin equilibrium from its position in the rod outer segment is attributed mainly to the effects of lipid-lipid interactions in the membrane bilayer and correlates with the difference in gel-to-fluid phase transition temperature of the different lipids.

Correlation of phospholipid structure with functional effects on the nicotinic acetylcholine receptor. A modulatory role for phosphatidic acid

Fourier transform infrared spectroscopy is used to characterize specific interactions between negatively charged lipids, such as phosphatidic acid, and the purified nicotinic acetylcholine receptor from Torpedo californica. The specific interaction of phosphatidic acid with acetylcholine receptor is demonstrated by the receptor-induced perturbation of the lipid ionization state, which is monitored using Fourier transform infrared bands arising from the phosphate head group. The acetylcholine receptor shifts the pKa of phosphatidic acid molecules adjacent to the receptor to a lower value by almost 2 pH units from 8.5 to 6.6. Decreased pH also leads to changes in ion channel function and to changes in the secondary structure of the acetylcholine receptor in membranes containing ionizable phospholipids. Phospholipase D restores functional activity of acetylcholine receptor reconstituted in an unfavorable environment containing phosphatidylcholine by generating phosphatidic acid. Lipids such as phosphatidic acid may serve as allosteric effectors for membrane protein function and the lipid-protein interface could be a site for activity-dependent changes that lead to modulation of synaptic efficacy.

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.

Sarcoplasmic reticulum from rabbit and winter flounder: temperature-dependence of protein conformation and lipid motion

A comparative study of lipids and proteins in sarcoplasmic reticulum (SR) from rabbit and flounder has been undertaken. The protein/phospholipid ratio (w/w) was 3:1 in flounder SR (FSR) and 2.2:1 in rabbit SR (RSR). Both membranes had similar contents of PC (70%) and PI (6%). PE constituted 15% in RSR and 21% in FSR. PS and sphingomyelin were minor components of both SR (less than 4%). There were differences in the unsaturated chains of the total lipid extracts, PC, PE, and PI between FSR and RSR. RSR was high in linoleate and arachidonate while FSR contained substantial amounts of eicosapentaenoate and docosahexaenoate. FTIR spectroscopy revealed that the lipids of both membranes did not undergo a phase transition between 0 and 50 degrees C. The lipids were in the liquid-crystalline state at physiological temperatures and underwent monotonic increases in conformational disorder as the temperature was raised. CD spectra indicated higher content of alpha-helical structure of proteins in RSR than in FSR. Increasing temperature caused diminution of alpha-helix content. Relatively large decreases in ellipticity were observed between 20 degrees C and 40 degrees C for FSR and 30 degrees C and 60 degrees C for RSR. Measurements of intrinsic tryptophan fluorescence as a function of temperature gave similar results for membrane proteins in both FSR and RSR. The rate of change of tryptophan fluorescence and fluorescence lifetimes was constant over the temperature ranges studied, and no abrupt shifts in fluorescence occurred in the temperature regions where ellipticity decreased rapidly.

Analysis of cell membrane micro-heterogeneity using the fluorescence lifetime of DPH-type fluorophores

Heterogeneity in the lipid organization in lipid bilayers and cell membranes was probed by using the fluorescence decay of 1,6-diphenyl-1,3,5-hexatriene (DPH) and DPH attached to the sn-2 position of phosphatidylcholine (DPH-PC). In the presence of protein, it is proposed that the bulk lipids and boundary lipids can potentially provide distinct enough fluorophore environments for two different lifetime centers to be recovered from the analysis of the fluorescence decay. To test this model experiments were performed with cytochrome b5 in 1-palmitoyl-2-oleoylphosphatidylcholine bilayers. The number of boundary lipids of cytochrome b5 is known from the literature or can be calculated from known dimensions, so that for a known protein:lipid ratio the fraction of lipids in the bulk and boundary lipid regions is known. These values were found to closely correspond to the fractions associated with the lifetime centers recovered from an analysis of the fluorescence decay assuming two major fluorophore populations. This indicated that the DPH distributed in a similar manner to the lipids and that its boundary lipid residency time was greater than the excited state lifetime, showing the validity of the approach. An important requirement was that the protein should influence the fluorophore decay sufficiently enough to enable separate lifetime centers for the bulk and boundary lipid fluorophores to be recovered by the analysis. Attempts were made to analyze the fluorescence decay of DPH in liver plasma membranes and microsomes as arising from two distinct fluorophore populations, however, the basic condition was not satisfied. By contrast, using DPH-PC it was possible to extract two separate lifetime centers. The limitations and potential of this approach are critically assessed and it is concluded that in certain circumstances information pertaining to the protein-lipid interfacial region of membranes can be extracted from fluorescence decay heterogeneity properties.

Anthrylvinyl-labeled phospholipids as fluorescent membrane probes. The action of melittin on multilipid systems

The interaction of melittin with multicomponent lipid mixtures composed of phosphatidylcholine, sphingomyelin and phosphatidylserine or phosphatidylglycerol was investigated by measuring the intrinsic fluorescence of the peptide, steady state fluorescence anisotropy of, and Trp-fluorescence energy transfer to fluorescent analogs of the same phospholipids bearing the anthrylvinyl fluorophore in one of the aliphatic chains at various distances from the polar head group. Based on the finding that at high lipid/peptide ratio the peptide induces unequal changes in the fluorescence parameters of phospholipid probes differing structurally only in their polar head groups, it is concluded that melittin induces lipid demixing in its nearest environment. Comparison of the fluorescence energy transfer from Trp to different lipid probes indicates that the depth of penetration of melittin into the bilayer depends on the polar head group composition of the phospholipid matrix and that certain segments of the melittin chain display a specific affinity for a given lipid head group.

Membrane structure, toxins and phospholipase A2 activity

The phospholipid-hydrolyzing enzyme phospholipase A2 (PLA2) (EC 3.1.1.4) exists in several forms which can be located in the cytosol or on cellular membranes. We review briefly cellular regulatory mechanisms involving covalent modification by protein kinase C and the action of Ca2+, cytokines, G proteins and other cellular proteins. The major focus is the role of phospholipid structure on PLA2 activity, including (1) the mechanism of PLA2 action on synthetic phospholipid bilayers, (2) perturbation of synthetic and cellular membranes with lipophilic agents and membrane-interactive peptides and (3) the ability of these agents to activate endogenous PLA2 activity, with emphasis on the venom and plant toxins melittin, cardiotoxin and Pyrularia thionein.

Molecular species of cardiolipin in relation to other mitochondrial phospholipids. Is there an acyl specificity of the interaction between cardiolipin and the ADP/ATP carrier?

Molecular species in the three major mitochondrial lipids cardiolipin, phosphatidylcholine and phosphatidylethanolamine were analysed in bovine heart and Saccharomyces cerevisiae. In both organisms cardiolipin contains mainly diacylglycerol moieties with two unsaturated chains and a significant higher proportion of C18-C18 species than phosphatidylcholine and phosphatidylethanolamine. To study whether the specific acyl composition of cardiolipin has a functional significance in lipid-protein interaction, experiments were made with the isolated ADP/ATP carrier of bovine heart mitochondria since this dimeric protein is known to be tightly associated with six molecules of cardiolipin [Beyer, K. and Klingenberg, M. (1985) Biochemistry 24, 3821-3826]. This association seems to be very strong as protein-bound cardiolipin does not exchange with soluble cardiolipin on a time scale of hours. Analysis of the species composition suggests that one carriers dimer is associated with four molecules of tetralinoleoyl cardiolipin and two molecules of trilinoleoyl-monolinolenoyl cardiolipin. Catalytic hydrogenation of the acyl chains of carrier-bound cardiolipin does not result in release of cardiolipin as judged by 31P-NMR spectroscopy. The ADP/ATP carrier was reconstituted with saturated phosphatidylcholines and spin-labelled cardiolipin whose double bonds were subsequently saturated by catalytic hydrogenation. ESR spectroscopy shows that saturation of spin-labelled cardiolipin has no significant impact on its association with the ADP/ATP carrier. However, precipitation of the detergent-solubilized ADP/ATP carrier can only be induced by addition of unsaturated but not by saturated cardiolipin. It is concluded that the specific acyl composition of cardiolipin is not a prerequisite of its high affinity for the ADP/ATP carrier, at least when the protein is reconstituted in a saturated phosphatidylcholine environment.

Quantitation of lipid phases in phospholipid vesicles by the generalized polarization of Laurdan fluorescence

The sensitivity of Laurdan (6-dodecanoyl-2-dimethylaminonaphthalene) excitation and emission spectra to the physical state of the membrane arises from dipolar relaxation processes in the membrane region surrounding the Laurdan molecule. Experiments performed using phospholipid vesicles composed of phospholipids with different polar head groups show that this part of the molecule is not responsible for the observed effects. Also, pH titration in the range from pH 4 to 10 shows that the spectral variations are independent of the charge of the polar head. A two-state model of dipolar relaxation is used to qualitatively explain the behavior of Laurdan. It is concluded that the presence of water molecules in the phospholipid matrix are responsible for the spectral properties of Laurdan in the gel phase. In the liquid crystalline phase there is a relaxation process that we attribute to water molecules that can reorientate during the few nanoseconds of the excited state lifetime. The quantitation of lipid phases is obtained using generalized polarization which, after proper choice of excitation and emission wavelengths, satisfies a simple addition rule.

Molecular order and fluidity of the plasma membrane of human platelets from time-resolved fluorescence depolarization

The ability of seven fluorescence polarization probes (1,6-diphenyl-1,3,5-hexatriene, 1-[(4-trimethyl- amino)phenyl]-6-phenyl-1,3,5-hexatriene, (2-carboxy- ethyl)-1,6-diphenyl-1,3,5-hexatriene, 16(9-anthroyloxy)-palmitic acid, CIS-parinaric acid, trans-parinaric acid and perylene) to report changes induced by temperature and Ca2+ in the plasma membrane of human platelets has been examined. The steady-state fluorescence anisotropy of the probes was compared after being incorporated into whole resting platelets, fragments of platelet plasma membrane and multilayers of lipids extracted from these membranes. In addition, we have investigated the molecular order and dynamics of the three preparations by time-resolved fluorescence depolarization of DPH and CE-DPH as a function of temperature and Ca2+ concentration. The high values of the order parameters found in intact platelets (SDPH, 36 degrees C = 0.70) were almost identical to those in membrane fragments and lipid vesicles, suggesting that lipid-lipid interactions and, therefore, the lipid composition are the main factors influencing the probe order parameter. Other lipid interactions such as those with membrane proteins and intracellular components have little effect on the SDPH in platelets. These measurements also showed that the stationary fluorescence anisotropy of DPH and CE-DPH in platelets is largely determined (80%) by the structural order of the lipid bilayer. Therefore, the previous "microviscosity" values based on stationary anisotropy data reflect the alignment and packing rather than the mobility of the bilayer components. The dynamic component of the anisotropy decay of these probes was analyzed in terms of the wobbling-in-cone model, allowing an estimation of the apparent viscosity of platelet plasma membrane (eta DPH, 36 degrees C = 0.5 P) that is similar to that of the erythrocyte membrane. This value decreased substantially in multilayers of native lipids, indicating a large effect of the lipid-protein interactions on the probe dynamics within the bilayer. When the temperature was raised from 25 degrees to 36 degrees C a pronounced decrease was observed in the order parameter and apparent viscosity, followed by a tendency to level-off in the 36 degrees-40 degrees C interval. This may be related to the end-point of the lipid phase separation reported by Gordon et al. (1983). Finally, the rigidifying (lipid ordering) effect of Ca2+ on the platelet plasma membrane could also be observed by the fluorescence anisotropy measurements, in the form of an increase (approximately 2%) of the order parameter of CE-DPH for Ca2+ concentrations in the millimolar range.

Peptides that mimic the pseudosubstrate region of protein kinase C bind to acidic lipids in membranes

The cytoplasmic form of protein kinase C (PKC) is inactive, probably because the pseudosubstrate region in its regulatory domain blocks the substrate-binding site in its kinase domain. Calcium ions cause a translocation to the membrane: maximum activation requires a negative lipid such as phosphatidylserine (PS) and the neutral lipid diacylglycerol (DAG) but the mechanism by which PS and DAG activate PKC is unknown. Pseudosubstrate region 19-36 of PKC-beta has six basic and one acidic amino acids and region 19-29 has five basic and no acidic amino acids. Since any binding of basic residues in the pseudosubstrate region to acidic lipids in the membrane should stabilize the active form of PKC, we studied how peptides with amino acids equivalent to residues 19-36 and 19-29 of PKC-beta bound to phospholipid vesicles. We made equilibrium dialysis, filtration, and electrophoretic mobility measurements. The fraction of bound peptide is a steep sigmoidal function of the mol fraction of negative lipid in the membrane, as predicted from a simple theoretical model that assumes the basic residues provide identical independent binding sites. The proportionality constant between the number of bound peptides/area and the concentration of peptide in the bulk aqueous phase is 1 micron for a membrane with 25% negative lipid formed in 0.1 M KCl. Equivalently, the association constant of the peptide with the membrane is 10(4) M-1, or the net binding energy is 6 kcal/mol. Thus the interaction of basic residues in the pseudosubstrate region with acidic lipids in the membrane could provide 6 kcal/mol free energy towards stabilizing the active form of PKC.

Hydrophobic membrane thickness and lipid-protein interactions of the leucine transport system of Lactococcus lactis

The effect of the phospholipid acyl chain carbon number on the activity of the branched-chain amino acid transport system of Lactococcus lactis has been investigated. Major fatty acids identified in a total lipid extract of L. lactis membranes are palmitic acid (16:0), oleic acid (18:1) and the cyclopropane-ring containing lactobacillic acid (19 delta). L. lactis membrane vesicles were fused with liposomes prepared from equimolar mixtures of synthetic phosphatidylethanolamine (PE) and phosphatidylcholine (PC) with cis mono-unsaturated acyl chains. The activity of the branched-chain amino acid carrier is determined by the bulk properties of the membrane (Driessen, A.J.M., Zheng, T., In 't Veld, G., Op den Kamp, J.A.F. and Konings, W.N. (1988) Biochemistry 27, 865-872). PE acts as an activator and PC is ineffective. Counterflow and protonmotive-force driven transport of leucine is sensitive to changes in the acyl chain carbon number of both phospholipids and maximal with dioleoyl-PE/dioleoyl-PC. Above the gel to liquid-crystalline phase transition temperature of the lipid species, membrane fluidity decreased with increasing acyl chain carbon number. Our data suggest that the carbon number of the acyl chains of PE and PC determine to a large extent the activity of the transport system. This might be relevant for the interaction of PE with the transport protein. Variations in the acyl chain composition of PC exert a more general effect on transport activity. The acyl chain composition of phospholipids determines the membrane thickness (Lewis, B.A. and Engelman, D.M. (1983) J. Mol. Biol. 166, 211-217). We therefore propose that the degree of matching between the lipid-bilayer and the hydrophobic thickness of the branched-chain amino acid carrier is an important parameter in lipid-protein interactions.

Reversible unfolding of cytochrome c upon interaction with cardiolipin bilayers. 2. Evidence from phosphorus-31 NMR measurements

31P NMR measurements were conducted to determine the structural and chemical environment of beef heart cardiolipin when bound to cytochrome c. 31P NMR line shapes infer that the majority of lipid remains in the bilayer state and that the average conformation of the lipid phosphate is not greatly affected by binding to the protein. An analysis of the spin-lattice (T1) relaxation times of hydrated cardiolipin as a function of temperature describes a T1 minimum at around 25 degrees C which leads to a correlation time for the phosphates in the lipid headgroup of 0.71 ns. The relaxation behavior of the protein-lipid complex was markedly different, showing a pronounced enhancement in the phosphorus spin-lattice relaxation rate. This effect of the protein increased progressively with increasing temperature, giving no indication of a minimum in T1 up to 75 degrees C. The enhancement in lipid phosphorus T1 relaxation was observed with protein in both oxidation states, being somewhat less marked for the reduced form. The characteristics of the T1 effects and the influence of the protein on other relaxation processes determined for the lipid phosphorus (spin-spin relaxation and longitudinal relaxation in the rotating frame) point to a strong paramagnetic interaction from the protein. A comparison with the relaxation behavior of samples spinning at the "magic angle" was also consistent with this mechanism. The results suggest that cytochrome c reversibly denatures on complexation with cardiolipin bilayers, such that the electronic ground state prevailing in the native structure of both oxidized and reduced protein can convert to high-spin states with greater magnetic susceptibility.

Effect of cholesterol and lanosterol on the structure and dynamics of the cell membrane of Mycoplasma capricolum. Deuterium nuclear magnetic resonance study

Deuterium nuclear magnetic resonance (NMR) techniques were employed to study the effect of sterols on the composition and dynamics of the membrane lipids of Mycoplasma capricolum, a natural fatty acid auxotroph that requires sterols for growth. The membrane lipids of cells grown in modified Edwards medium supplemented with cholesterol, oleic acid (OA), and palmitic acid (PA) were composed primarily of phosphatidylglycerol (PG) (60%) and cardiolipin (CL) (35%). The incorporation of cholesterol and the cellular OA/PA ratio increased nonlinearly with increases in exogenous cholesterol level, whereas the levels of phospholipid increased only slightly. At the growth temperature, 37 degrees C, the residual deuterium quadrupole splittings were found to be 43-46 kHz for cells grown with (7,7,8,8-2H4) PA and 1.25 micrograms/ml (30 mol%) to 10 micrograms/ml (50 mol%) cholesterol, respectively, similar to that found in the cholesterol/lecithin binary dispersions of similar cholesterol contents. Deuterium T2e of these samples were found to be 170 +/- 10 microseconds and were independent of cellular cholesterol content. In comparison, T2e of the corresponding lipid extracts were longer (320-420 microseconds) and dependent on cholesterol content. Thus, lipid-protein interactions in the cell membrane is the dominant mechanism responsible for the reduced T2e. At lower temperatures, spectra indicative of the coexistence of gel and liquid-crystalline states were observed for cells having low cholesterol levels. For both cell membrane and membrane lipid extract containing 50 mol% cholesterol, T2e was found to be constant at the temperature range from 15 to 40 degrees C. On the other hand, T2e of cell membrane containing 30 mol% cholesterol decreased linearly at 3.2 microseconds/degrees C. T2e of the corresponding lipid extract showed much stronger temperature variation. Cells containing 39 mol% lanosterol were found to have a quadrupole splitting of 39 kHz, broader than that of the cholesterol-free lecithin dispersion (less than 30 kHz) but less than that of cell membrane containing 30 mol% cholesterol (43 kHz). T2e of the lanosterol sample was found to be 130 +/- 10 microseconds which decreased linearly at a slope similar to that observed for the low cholesterol sample. Therefore, although lanosterol appeared to be capable of modulating cell membrane physical properties it is less effective than cholesterol. When growth rates were correlated with NMR parameters, we found that the membranes of faster growing cells were also more ordered. In contrast, the T2e of the cells of M. capricolum seemed to be maintained at a relatively constant value around 170 microseconds.

Phospholipid phase transitions as revealed by NMR

Aqueous dispersions of phospholipids can adopt a range of polymorphic phases which include bilayer and non-bilayer forms. Within the bilayer form, laterally separated phases may be induced as a result of surface electrostatic associations, thermotropic behaviour, lipid-protein interactions or because of molecular mismatch between chemically distinct phospholipids. Nuclear magnetic resonance (NMR) methods, designed to exploit the properties of either indigenous nuclei or isotopic labels introduced specifically into a phospholipid, can be used in some cases to describe the molecular properties and behaviour of phospholipids in both macroscopically distinct phases and in molecularly distinct phases within the same polymorphic state. If the molecular motion of phospholipids in co-existing phases is sufficiently different, NMR methods can, in principle, give estimates of the life-time of the phases and the rate of molecular exchange between the phases.

Spontaneous insertion of plant plasma membrane (H+)ATPase into a preformed bilayer

The purified (H+)ATPase from corn roots plasma membrane inserted spontaneously into preformed bilayer from soybean lipids. The yield of the protein insertion, as measured from its H(+)-pumping activity, increased as a function of lipids and protein concentrations. In optimum conditions, all the (H+)ATPase molecules were closely associated with liposomes, exhibiting a high H(+)-pumping activity (150,000% quenching min-1.mg-1 protein of the probe 9-amino-6-chloro-2-methoxyacridine). The insertion was achieved within a few seconds. No latency of the (H+)ATPase hydrolytic activity was revealed when lysophosphatidylcholine was added to permeabilize the vesicles. This indicated that the (H+)ATPase molecules inserted unidirectionally, the catalytic sites being exposed outside the vesicles ("inside-out" orientation), and thus freely accessible to Mg-ATP. The nondelipidated (H+)ATPase could also functionally insert into bilayer from PC:PE:PG or PC:PE:PI, due to the presence of both hydrophobic defects promoted by PE, and negative phospholipids specifically required by the (H+)ATPase from corn roots. The detergent octylglucoside facilitated the delipidated (H+)ATPase reinsertion probably by promoting both a proper protein conformation and hydrophobic defects in the bilayer. Lysophosphatidylcholine facilitated the delipidated protein insertion only when hydrophobic defects were already present, and thus seemed only capable to ensure a proper protein conformation.

Differential scanning calorimetry and Fourier transform infrared analysis of lipid-protein interactions involving the nicotinic acetylcholine receptor

Lipid-protein interactions were studied using Torpedo californica acetylcholine receptor (AChR) as a model system by reconstituting purified AChR into dielaidoylphosphatidylcholine (DEPC, 18:1 trans-9,10) membranes. The structural and thermodynamic behavior of lipids in the vicinity of the protein were studied by differential scanning calorimetry and Fourier transform infrared spectroscopy. The effects of AChR on the thermodynamic parameters associated with lipid phase transitions were to reduce the enthalpy change, lower the transition temperature and reduce the cooperative behavior of the lipid molecules. A stoichiometry of approx. 95 lipids per AChR molecule was found by simulating the decrease in enthalpy in terms of a simple model in which a fixed number of lipid molecules are prevented from undergoing a cooperative phase transition. In parallel, the vibrational spectra of pure DEPC and AChR reconstituted in DEPC membranes at various lipid to protein ratios were examined. Profiles of the 3000-2800 cm-1 C-H stretching region and 1350-950 cm-1 characteristic of the headgroup region of the lipid exhibit little sensitivity to protein/lipid ratio reflecting weak interaction of AChR with DEPC. The lipid carbonyl on the other hand appear to be increasingly hydrogen bonded in the presence of AChR. The results provide new information about the size and physical state of the motionally restricted lipid environment that surrounds the acetylcholine receptor. The results are discussed in the context of lipid-mediated alterations in acetylcholine receptor function.

Analysis of time-resolved fluorescence anisotropy in lipid-protein systems. II. Application to tryptophan fluorescence of bacteriophage M13 coat protein incorporated in phospholipid bilayers

The subnanosecond fluorescence and motional dynamics of the tryptophan residue in the bacteriophage M13 coat protein incorporated within pure dioleoylphosphatidylcholine (DOPC) as well as dioleoylphosphatidylcholine/dioleoylphosphatidylglycerol (DOPC/DOPG) and dimyristoylphosphatidylcholine/dimyristoylphosphatidylglycerol (DMPC/DMPG) bilayers (80/20 w/w) with various L/P ratio have been investigated. The fluorescence decay is decomposed into four components with lifetimes of about 0.5, 2.0, 4.5 and 10.0 ns, respectively. In pure DOPC and DOPC/DOPG lipid bilayers, above the phase transition temperature, the rotational diffusion of the protein molecules contributes to the depolarization and the anisotropy of tryptophan is fitted to a dual exponential function. The longer correlation time, describing the rotational diffusion of the whole protein, shortens with increasing temperature and decreasing protein aggregation number. In DMPC/DMPG lipid bilayers, below the phase transition, the rotational diffusion of the protein is slowed down such that the subnanosecond anisotropy decay of tryptophan in this system reflects only the segmental motion of the tryptophan residue. Because of a heterogeneous microenvironment, the anisotropy decay must be described by three exponentials with a constant term, containing a negative coefficient and a negative decay time constant. From such a decay, the tryptophan residue within the aggregate undergoes a more restricted motion than the one exposed to the lipids. At 20 degrees C, the order parameter of the transition moment of the isolated tryptophan is about 0.9 and that for the exposed one is about 0.5.

Incorporation of spin-labeled fatty acids into bovine brain clathrin coated vesicles

Stearic acids with a nitroxide radical at selected positions have been incorporated in the phospholipid bilayers of clathrin coated vesicles, uncoated vesicles and sonicated liposomes made from the lipids extracted from the uncoated vesicles. The extent of incorporation was found minimum for stearic acids labeled on C-12 and for bilayers of uncoated vesicles. The ESR spectra of the spin-labeled fatty acids incorporated in the bilayers showed a pronounced temperature dependence (without discontinuity) and a decrease in the hyperfine splitting as the nitroxide group was inserted deeper in the hydrophobic core of the membranes. An abrupt phospholipid phase transition or a phase separation could be excluded. The presence of the external proteins (the clathrin coat) on the membranes was not found to noticeably influence the gradient of flexibility of the fatty acid chains of the phospholipids. The influence of the internal proteins embedded in the bilayers was evidenced by a detailed analysis of the ESR spectra of (7,8)SA in terms of two components: one component arising from the labels surrounded exclusively by phospholipids, the other component arising from labels of reduced mobility perturbed by the vicinity of the proteins. These results support the persistence of lipidic domains in the endocytic vesicles despite the accumulation of receptors which follows their formation.

Effect of proteins on fluorophore lifetime heterogeneity in lipid bilayers

The effect of three different membrane proteins on the fluorescence lifetime heterogeneity of 1,6-diphenyl-1,3,5-hexatriene (DPH) in phospholipid vesicle systems was investigated. For large unilamellar vesicles of dimyristoylphosphatidylcholine (DMPC) and 1-palmitoyl-2-oleoylphosphatidylcholine (POPC) at 37 degrees C, the fluorescence decay was essentially monoexponential (8.6 and 8.2 ns, respectively) except for a minor component typical of DPH. For gramicidin D reconstituted into DMPC vesicles at a protein/lipid molar ratio of 1/7, the most appropriate analysis of the data was found to be in the form of a bimodal Lorentzian distribution. Centers of the major lifetime components were almost identical with those recovered for vesicles without proteins, while broad distributional widths of some 4.0 ns were recovered. Variation of the protein/lipid molar ratio in sonicated POPC vesicles revealed an abrupt increase in distributional width at ratios approximating 1/15-1/20, which leveled off at about 2.5 ns. For bacteriorhodopsin in DMPC vesicles and cytochrome b5 in POPC, the most appropriate analysis of the data was again found to be in the form of a bimodal Lorentzian also with broad distributional widths in the major component. Lifetime centers were decreased for these proteins due to fluorescence energy transfer to the retinal of the bacteriorhodopsin and heme of the cytochrome b5. Fluorescence energy transfer is distance dependent, and since a range of donor-acceptor distances would be expected in a membrane, lifetime distributions should therefore be recovered independently of other effects for proteins possessing acceptor chromophores.(ABSTRACT TRUNCATED AT 250 WORDS)

Microelectrophoresis studies of the binding of glycosaminoglycans to phosphatidylcholine liposomes

The binding of the glycosaminoglycans (GAG) chondroitin sulfate and heparin and the homologous molecule dextran sulfate to multilamellar dimyristoyl phosphatidylcholine (DMPC), dilaureyl phosphatidylcholine (DLPC) and egg lecithin liposomes was investigated by microelectrophoresis measurements. Drastic changes of the zeta potential of the liposomes to negative values indicate the binding of the highly anionic macromolecules. Binding depends strongly on Ca2+ and NaCl concentrations in the medium and does not occur in the absence of Ca2+. The adsorption is saturated at concentrations of about 0.1 mg/ml chondroitin sulfate and heparin and 0.01 mg/ml dextran sulfate. In the gel state of the phospholipid bilayer more GAG can associate with the surface compared to the fluid state.

Evaluation of the annexins as potential mediators of membrane fusion in exocytosis

Membrane fusion is a central event in the process of exocytosis. It occurs between secretory vesicle membranes and the plasma membrane and also among secretory vesicle membranes themselves during compound exocytosis. In many cells the fusion event is regulated by calcium. Since the relevant membranes do not undergo fusion in vitro when highly purified, much attention has been paid to possible protein mediators of these calcium-dependent fusion events. The annexins comprise a group of calcium-dependent membrane-aggregating proteins, of which synexin is the prototype, which can initiate contacts between secretory vesicle membranes which will then fuse if the membranes are further perturbed by the addition of exogenous free fatty acids. This review discusses the secretory pathway and the evidence obtained from in vitro studies that suggests the annexins may be mediators or regulators of membrane fusion in exocytosis.

Effects of decreased pH on membrane structural organization of Escherichia coli grown in different fatty acid-supplemented media: a 31P NMR study

Total membranes from Escherichia coli cells grown in different fatty acid-supplemented media have been examined by 31P NMR at different pH values. The isolated inner and outer membranes were also studied and compared to the liposomes formed with the corresponding extracted lipids. While the liposomes show structures that are correlated with lipid composition, degree of fatty acid unsaturation, and pH, the membrane structure is mainly bilayer. The presence of two bilayer phases characterized by different chemical shift anisotropy values (delta nu csa) is detectable at neutral pH; a perturbation of the bilayer phase characterized by the smallest delta nu csa is produced by low pH. Moreover, an isotropic peak is always present in the membrane NMR spectra: its attribution to cardiolipin molecules is discussed on the basis of digestion experiments with phospholipase C.

Triggering of mannosyltransferase activity in inner mitochondrial membranes by dolichyl-monophosphate incorporation mediated through phospholipids or fatty acids

The activity of GDPmannose:dolichyl monophosphate mannosyltransferase in inner mitochondrial membranes can be triggered by dolichyl-monophosphate incorporation mediated through phospholipids or fatty acids. The efficiency of this incorporation and the efficiency of the enzyme activity are not equivalent. Among a variety of amphiphiles which were tested, the highest mannosyltransferase activity was obtained with the mixture of lipids extracted from the outer mitochondrial membranes. The results presented here appear consistent only with a mechanism involving collisional contacts of the phospholipid vesicles and fusion with the membranes. ESR spectroscopy confirms that (a) the incorporation process is followed by solubilization of dolichyl monophosphate molecules in the lipid phase and (b) the general organization of the inner mitochondrial membranes is not perturbed by the addition of dolichyl monophosphate.

On the mechanism of transbilayer transport of phosphatidylglycerol in response to transmembrane pH gradients

Previous work [Hope et al. (1989) Biochemistry 28, 4181-4187] has shown that asymmetric transmembrane distributions of phosphatidylglycerol (PG) in PG-phosphatidylcholine (PC) large unilamellar vesicles can be induced in response to transbilayer pH gradients (delta pH). Here the mechanism of PG transport has been investigated. It is shown that PG movement in response to delta pH is consistent with permeation of the uncharged (protonated) form and that the half-time for transbilayer movement of the uncharged form can be on the order of seconds at 45 degrees C. This can result in rapid pH-dependent transmembrane redistributions of PG. The rate constant for transbilayer movement exhibits a large activation energy (31 kcal/mol) consistent with transport of neutral dehydrated PG where dehydration of the (protonated) phosphate presents the largest barrier to transmembrane diffusion. It is shown that acyl chain saturation, chain length, and the presence of cholesterol modulate the rate constants for PG transport in a manner similar to that observed for small nonelectrolytes.

Influence of polar residue deletions on lipid-protein interactions with the myelin proteolipid protein. Spin-label ESR studies with DM-20/lipid recombinants

The lipid specificities of two related integral membrane proteins of central nervous system myelin, the proteolipid (PLP) and DM-20 proteins, which differ only by the deletion of a polar stretch of 35 contiguous amino acid residues, were studied with spin-labeled lipids after reconstitution into dimyristoyl-phosphatidylcholine. The selectivity in populating lipid association sites at the protein interface and in modulating the lipid exchange between protein and bulk lipid sites was quantitated by the relative association constants and the off-rate constants for exchange, respectively, for both proteins. The sequence deleted in DM-20 (residues 116-150 of PLP) is found to play a major role in determining the lipid selectivity for the parent PLP protein.

Protein kinase C penetration into lipid bilayers

Physical characteristics of the association and subsequent penetration of protein kinase C into defined lipid bilayers were analyzed using four different fluorescence probes. The enzyme demonstrated strong hydrophobic and electrostatic interactions with the bilayer as suggested by its ability to increase permeability of carboxyfluorescein-filled unilamellar vesicles. The intensity of interaction was dependent on the concentration of phosphatidylserine. The hydrophilic quencher, N-methylpicolinium perchlorate, was used to show that the tryptophan residues affected by ligand-induced conformational changes were in a hydrophobic region(s) of the enzyme. Using quenching of intrinsic tryptophan fluorescence, the enzyme was shown to penetrate the lipid bilayer to the C-16 position of labeled fatty acid probes. The association and subsequent penetration of the enzyme into the lipid bilayer was independent of divalent cations in these systems and had no significant effect on activator-independent substrate phosphorylation.

Photoaffinity labeling of the Torpedo californica nicotinic acetylcholine receptor with an aryl azide derivative of phosphatidylserine

A photoactivatable analogue of phosphatidylserine, 125I-labeled 4-azidosalicylic acid-phosphatidylserine (125I ASA-PS), was used to label both native acetylcholine receptor (AchR)-rich membranes from Torpedo californica and AchR membranes affinity purified from Torpedo reconstituted into asolectin (a crude soybean lipid extract) vesicles. The radioiodinated arylazido group attaches directly to the phospholipid head group and thus probes for regions of the AchR structure in contact with the negatively charged head group of phosphatidylserine. All four subunits of the AchR incorporated the label, with the alpha subunit incorporating approximately twice as much as each of the other subunits on a per mole basis. The regions of the AchR alpha subunit that incorporated 125I ASA-PS were mapped by Staphylococcus aureus V8 protease digestion. The majority of label incorporated into fragments representing a more complete digestion of the alpha subunit was localized to 11.7- and 10.1-kDa V8 cleavage fragments, both beginning at Asn-339 and of sufficient length to contain the hydrophobic regions M1, M2, and M3 was also significantly labeled. In contrast, V8 cleavage fragments representing roughly a third of the amino-terminal portion of the alpha subunit incorporated little or no detectable amount of probe.

Effect of phospholipids on the thermal stability of microsomal UDP-glucuronosyltransferase

The GT2P isoform of microsomal UDP-glucuronosyltransferase from pig liver is a lipid-dependent enzyme. The data in the present work indicate that, in addition to regulation of activity, the thermal stability of the enzyme also is modulated by the acyl chain composition of phosphatidylcholines (PC) used to reconstitute the activity of pure enzyme. There was a reversible, temperature-dependent change in the state of the pure enzyme to an inactive form with onset at T greater than 38 degrees C, depending on the environment of the enzyme. The midpoint for the transition shifted from 39.8 degrees C for enzyme in a bilayer of distearoylphosphatidylcholine (DSPC) to 47.5 degrees C for enzyme in a bilayer of 1-stearoyl-2-oleoylphosphatidylcholine (SOPC). For all lipids, the transition from a catalytically active to an inactive form of the enzyme was associated with large compensating changes in H and S. Lipid-induced stabilization of the active form of UDP-glucuronosyltransferase at T greater than 37 degrees C was associated with decreases in delta H and delta S, but the decreases in delta S were larger, indicating that lipid-induced stabilization of the active form of the enzyme was entropic. The transition between the active and inactive forms of the enzyme was too rapid in either direction to measure in a standard spectrophotometer. In addition to reversible inactivation of the enzyme, there was a slower irreversible, temperature-dependent inactivation. The rate of this process depended on the acyl chains of the phosphocholines interacting with the enzyme. However, there was no obvious correlation between the structures of lipids that stabilized the different inactivation reactions.

Determination of fluorescent probes localization in membranes by nonradiative energy transfer

One of the new methods of studying the structure and dimensions of biological membranes is based on the Förster's nonradiative energy transfer between special molecules, the so-called 'membrane fluorescent probes'. Further development of the approach is presented in this article. It consists of the combined use of the time-resolved and steady-state fluorescence data with subsequent computer simulation of the energy transfer in membranes. Anthracene as an energy donor, and 4-p-(dimethylamino)styryl-N-dodecylpyridinium (DSP-12) or 4-dimethylaminochalcone (DMC) as energy acceptors were bound with artificial phospholipid membrane vesicles ('liposomes'). The synchrotron radiation was used as an impulse source for the excitation light. The steady-state fluorescence data permit the area of possible probe localization in membranes to be distinguished, while the kinetic data allow them to be narrowed significantly. There is a good agreement between the obtained localization and our present-day knowledge of lipid bilayer structure. The accuracy of the method is ca. several Angströms.