Specificity in the interaction of phospholipids and fatty acids with vesicle reconstituted cytochrome P-450. A spin label study

The association of fatty acids, androstane, phosphatidylcholine, phosphatidylethanolamine, and phosphatidic acid with purified and phospholipid-vesicle reconstituted cytochrome $\text{P-450}$ was studied by spin labeling. Spin-labeled fatty acids were found to be motionally restricted by cytochrome $\text{P-450}$ in both phospholipid vesicles and in microsomes to a much greater extent than spin-labeled phospholipids. The equilibrium of spin-labeled fatty acid between the bulk membrane lipid and the protein interface could be shifted towards an increased amount in the bulk phospholipid phase by the addition of oleic acid or lysophosphatidylcholine, but not by sodium cholate. Microsomes from different animals showed a variable extent of motional restriction of fatty acids, independent of pretreatment of the animals with phenobarbital or β-naphthoflavone, of cytochrome $\text{P-450}$ content, of the presence of type I and type II substrates for cytochrome $\text{P-450}$. These differences are attributed to the presence of varying amounts of lipid breakdown products in the microsomal membrane such as lysolipids or fatty acids which compete with the externally added spin-labeled fatty acids, or with spin-labeled androstane for the binding to cytochrome $\text{P-450}$. The negative charge of the fatty acid was found to be involved in its association with the protein. Cytochrome $\text{P-450}$ was shown to interact only with a few spin-labeled phospholipid molecules in such a way that the motional restriction of the spin acyl chains can be detected by electron paramagnetic resonance ($\text{τ}{}_{\mathrm{<mtext>R</mtext>}}\text{> 10}{}^{\mathrm{?8}}\text{s}$). The number of associated lipid molecules per protein probably is too small to form a complete shell around the protein. This lipid-protein interaction could be destroyed by the addition of sodium cholate, in contrast to the fatty acid-protein interaction.     

Theoretical conformational analysis of phospholipids II. Role of hydration in the gel to liquid crystal transition of phospholipids

To obtain a satisfactory agreement between computed transition temperatures and those determined experimentally, we introduce explicitly water molecules which hydrate the polar headgroup of dipalmitoylphosphatidylethanolamine molecules. The calculated free energy curves as a function of the intermolecular interchain distance and the degree of hydration of the polar groups permit the determination of the transition of the phospholipid system from the gel to the liquid crystalline phase. The detailed structure of the hydration shell is defined using the supermolecular approach.     

The effect of cholesterol and gramicidin A′ on the carbonyl groups of dimyristoylphosphatidylcholine dispersions

Proton-enhanced carbon-13 magnetic resonance measurements have been made of the natural abundance carbon-13 carbons in hydrated L_α phase dispersions of 1,2-dimyristoyl-sn-glycero-3-phosphocholine (DMPC) codispersed with cholesterol or with the polypeptide gramicidin A′. The carbonyl group spectrum consists of a superposition of two peaks derived from the two carbonyl sites within the lipid. In the L_α phase of DMPC both carbonyl sites contribute axially symmetric spectra, one with a chemical shift anisotropy of –29 ppm and the other with a chemical shift anisotropy of less than –5 ppm. The chemical shift anisotropy of the broader carbonyl resonance was found to increase with increasing cholesterol content. However, in DMPC dispersions with gramicidin A′, the chemical shift anisotropy of the broader carbonyl signal initially increased slightly from that of pure DMPC and then decreased with increasing concentrations of gramicidin A′. The width of the narrower spectral component was essentially unaltered by cholesterol or gramicidin A′. The presence of a narrow component at all concentrations of cholesterol or gramicidin A′ suggests that it is unlikely that any significant conformational changes have occurred at the carbonyl level of the bilayer. We propose that the major effect of cholesterol or gramicidin A′ is to alter the molecular order parameter, S_mol, which reflects the range of angles through which the local molecular long axis of the phospholipid is tumbling.     

Absence of subtransition in racemic dipalmitoylphosphatidylcholine vesicles

dl-Dipalmitoylphosphatidylcholine multilamellar vesicle suspensions were examined by the method of differential scanning calorimetry. A lack of the subtransition at 18°C was established. Such a subtransition is characteristic for l-dipalmitoylphosphatidylcholine suspensions. This lack is supposed to be the result of the impossibility of the racemic phospholipid mixture to form the low-temperature crystal structure L_c.     

Changes in membrane phospholipid distribution during platelet activation

(1) Exposure of phospholipids at the outer surface of activated and control platelets was studied by incubation with a mixture of phospholipase A₂ from Naja naja and bee venom, solely or in combination with sphingomyelinase from Staphylococcus aureus, using conditions under which cell lysis remained below 10%. (2) Incubation with phospholipase A₂ alone revealed a markedly increased susceptibility of the phospholipids in platelets activated by a mixture of collagen plus thrombin, by the SH-oxydizing compound diamide, or by calcium ionophore A23187, as compared to control platelets or platelets activated separately by collagen or thrombin. (3) Collagen plus thrombin, diamide, and ionophore treated platelets revealed an increased exposure of phosphatidylserine at the outer surface accompanied by a decreased exposure of sphingomyelin, as could be concluded from incubations with a combination of phospholipase A₂ and sphingomyelinase. These alterations were much less apparent in platelets activated either by thrombin or by collagen alone. (4) The increased exposure of phosphatidylserine in activated platelets is accompanied by an increased ability of the platelets to enhance the conversion of prothrombin to thrombin by coagulation factor Xa, in the presence of factor Va and calcium. (5) It is concluded that the altered orientation of the phospholipids in the plasma membrane of platelets activated by collagen plus thrombin, by diamide, or by calcium ionophore, is the result of a transbilayer movement. Moreover, the increased exposure of phosphatidylserine in platelets stimulated by the combined action of collagen and thrombin might be of considerable importance for the hemostatic process.     

Interaction of fatty acids with lipid bilayers

We present a method by which it is possible to describe the binding of fatty acids to phospholipid bilayers. Binding constants for oleic acid and a number of fatty acids used as spectroscopic probes are deduced from electrophoresis measurements. There is a large shift in $\text{p}\text{K}$ value for the fatty acids on binding to the phospholipid bilayers, consistent with stronger binding of the uncharged form of the fatty acid. For dansylundecanoic acid, fluorescence titrations are consistent with the binding constants derived from the electrophoresis experiments. For 12-(9-anthroyloxy)stearic acid, fluorescence and electrophoresis data are inconsistent, and we attribute this to quenching of fluorescence at high molar ratios of 12-anthroylstearic acid to phospholipid in the bilayer.     

Studies on the complex formed between glucagon and dicaprylphosphatidylcholine

The interaction between glucagon and dicaprylphosphatidylcholine (DCPC) was studied by fluorescence, circular dichroism and calorimetry, as well as by ¹H- and ³¹P-nuclear magnetic resonance. The water-soluble lipid-protein complex was also characterized by gel filtration and ultracentrifugation. The complex appeared to be monodisperse by sedimentation equilibrium measurements, with a molecular weight of (4.55 ± 0.57)·10⁴. This complex contained approximately 7 molecules of glucagon and 35 molecules of phospholipid. Proton-decoupled ³¹P-NMR spectra of the phospholipid in the lipid-protein complex display narrower resonances than those of sonicated vesicles of DCPC, and ¹H-³¹P coupling could be detected in proton coupled spectra. These NMR results, together with gel-filtration results, suggest that glucagon ‘solubilizes’ phospholipid aggregates, forming a lipid-protein complex which is smaller than sonicated preparations of DCPC. ¹H-NMR resonance of both the methionine methyl group (met-27) and the aromatic envelope of glucagon are broadened by the phospolipid, indicating that the C-terminal region and the aromatic residues are involved in the interaction with the phospholipid. Nuclear magnetic resonance titrations of the imidazole ring C(2) and C(4) protons of the histidine residue of glucagon show that DCPC lowers the pK of the imidazole. The alterations caused by the phospholipid in the far and near ultraviolet CD spectra of glucagon reflect, respectively, the increased helix content of the hormone and the fact that the aromatic residues are located in a more structured environment. The phospholipid also alters the fluorescence properties of glucagon, shifting the fluorescence emission maximum of the hormone to shorter wavelength, and enhancing its relative intensity. This suggests that the fluorophore is experiencing a more hydrophobic environment in the presence of the lipid. Binding of glucagon to the phospholipid was analysed by Scatchard plots of the enhancement of fluorescence caused by the phospholipid and showed that the equilibrium binding constants of glucagon to DCPC are (4.4 ± 0.5)·10⁴M^?1 and (7.5±0.5)·10⁴M^?1, at 15°C and 25°C, respectively. The average number of moles of phospholipid bound per mole of glucagon is 4.4±0.6. The isothermal enthalpy of reaction of glucagon with DCPC is ?20.5 kcal/mol of glucagon at 25°C and ?32.5 kcal/mol of glucagon at 15°C. The observed enthalpies can arise from glucagon-induced cyrstallization of the phospholipid, from the non-covalent interactions between the peptide and lipid as well as from the lipid-induced conformational change in the protein. These results demonstrate that, unlike the complexes formed between glucagon and phospholipids which form more stable bilayers, the complex formed between glucagon and DCPC is stable over a wide range of temperatures, including temperatures well above the phase transition.     

The determination of the separate Ca pump protein and phospholipid profile structures within reconstituted sarcoplasmic reticulum membranes via X-ray and neutron diffraction

We have previously compared the electron density profiles for several highly-functional reconstituted sarcoplasmic reticulum membranes with that for the isolated sarcoplasmic reticulum membrane (Herbette, L., Scarpa, A., Blasie, J.K., Wang, C.T., Saito, A. and Fleischer, S. (1981) Biophys. J. 36, 47–72). In this paper, we compare the separate calcium pump protein profile within these reconstituted sarcoplasmic reticulum membranes, as derived by X-ray and neutron diffraction methods, with that within isolated sarcoplasmic reticulum membranes. In addition, the time-average perturbation of the lipid bilayer by the incorporated calcium pump protein within these reconstituted sarcoplasmic reticulum membranes has been determined in some detail.     

Serum Albumin Washing Specifically Enhances Arachidonate Incorporation into Synaptosomal Phosphatidylinositols

Arachidonate incorporation into synaptosomal phospholipids was shown to be affected by factors including the procedure for preparation of the membrane fractions and preincubation of synaptosomes prior to assay of incorporation of arachidonate into both phosphatidylcholine (PC) and phosphatidylinositol (PI). However, the inhibition toward incorporation into PIs, but not PCs, was fully reversed when the membranes were washed with bovine serum albumin. A twofold increase in arachidonate incorporation into PIs was also observed when freshly prepared synaptosomes were washed with serum albumin immediately before assay of incorporation activity. The inhibitory action is thought to be due to an increase in polyunsaturated fatty acids and/or their oxidation products which may then elicit a special effect on the acyltransferase responsible for transferring arachidonate into phosphatidylinositols. The differences in fatty acid uptake and response to serum albumin also suggest the presence of different acyltransferase for acyl transfer to PIs and PCs.     

Modulation of the orientational order profile of the lipid acyl chain in the Lα phase

The orientational order profile along the lipid acyl chain has been characterized under several different conditions of polar headgroup composition, temperature, and cholesterol content. Despite the different nature of these factors, the variation of the order is governed by two common trends. First, the relative change of order induced by the variation of these factors is always more pronounced towards the end of the chain than for the methylene groups near the interface. Second, there is, to a first approximation, a distinct correlation between the magnitude of the order parameters and the shape of the order profile. For example when the chain is highly ordered, the relative width of the order distribution is narrow indicating that the plateau region is longer. These conclusions suggest that the orientational order profile depends on only a small number of parameters and demonstrate clearly that the correlation length for changes in orientational order is much greater than one C-C bond length. Our results also show that the reduced temperature is not related in simple terms to orientational order and probably has little theoretical significance. The orientational order profiles of POPC and POPE bilayers are significantly different even when expressed in terms of reduced temperature. The behavior of POPC/cholesterol systems also indicates that the orientational order of the lipid chain and the gel-to-liquid crystalline phase transition temperature are not related in a straightforward manner.Abbreviations POPC 1-palmitoyl-2-oleoyl-phosphatidylcholine - POPE 1-palmitoyl-2-oleoyl-phosphatidylethanolamine - PC phosphatidylcholine - PE phosphatidylethanolamine - NMR nuclear magnetic resonance - EDTA ethylenediaminetetraacetic acid Offprint requests to: M. Bloom